CN210051122U - Bar brick extrusion roller platform - Google Patents

Abstract

The utility model discloses a long brick extruding roller platform, which comprises a frame, a roller platform arranged on the frame, an upper extruding water absorption device arranged above the roller platform and a lower extruding water absorption device arranged below the upper extruding water absorption device; the upper extrusion water absorption device comprises a frame body, a first bearing arranged on the frame body and an upper water absorption rod arranged on the first bearing in parallel; the lower extrusion water absorption device comprises a plurality of lower water absorption rods, a second bearing is arranged between each lower water absorption rod and the rack, the lower water absorption rods are connected with a power assembly, and the power assembly drives the lower water absorption rods to rotate; the roller table is provided with a driving assembly, and the driving assembly and the power assembly drive the ceramic tiles to move. The utility model discloses applicable extrusion in slender strip ceramic tile absorbs water, and the ceramic tile transportation is steady, and drying effect is good.

Description

Bar brick extrusion roller platform

Technical Field

The utility model relates to a ceramic tile production facility technical field especially relates to a rectangular brick extrusion roller stick platform.

Background

The existing ceramic tile production often needs to carry out edging treatment on the ceramic tile, and the edging wheels and the ceramic tile are ground at a high speed during edging, so that high heat generated at the grinding part can cause the phenomena of cracking, black edge and the like of the ceramic tile. To avoid this, cooling water is often introduced into the grinding area to reduce the temperature. Therefore, water stains generally remain on the surface of the ceramic tile after edging treatment, and influence the further production process of the ceramic tile. Existing tile drying means include blow drying or oven drying. The blowing drying efficiency is low; more energy is needed for drying, so that the production cost is increased; and the ceramic tile can be heated for the second time during drying, which easily causes the defect of the ceramic tile.

Current ceramic tile drying method still absorbs water the drying including the extrusion, nevertheless because the too big and roller that absorbs water in clearance between the running roller of the platform that absorbs water of current extrusion does not have power device, often blocks easily between two roller sticks during the transportation of slender stick ceramic tile, causes the damage of ceramic tile, influences drying efficiency.

Disclosure of Invention

The utility model aims to solve the technical problem that a rectangular brick extrusion roller stick platform is provided, applicable extrusion in slender rectangular ceramic tile absorbs water, and the ceramic tile transportation is steady, and drying effect is good.

In order to solve the technical problem, the utility model provides a long brick extruding roller platform, which comprises a frame, a driving assembly, a roller platform arranged on the frame, an upper extruding water absorption device arranged above the roller platform and a lower extruding water absorption device arranged below the upper extruding water absorption device;

the upper extrusion water absorption device comprises a frame body, a first bearing arranged on the frame body and an upper water absorption rod arranged on the first bearing in parallel;

the lower extrusion water absorption device comprises a plurality of lower water absorption rods, and a second bearing is arranged between each lower water absorption rod and the rack; the lower water absorption rod is connected with a power assembly, and the power assembly drives the lower water absorption rod to rotate.

As an improvement of the technical scheme, the roller table comprises a plurality of roller rods, and a third bearing is arranged between each roller rod and the rack;

the first bearing and the second bearing are UCHA series bearings or plastic bearings of the same type, and the third bearing is a seated bearing of UCFB series.

As an improvement of the technical scheme, the driving assembly comprises a driven gear arranged at the tail end of the roller rod, a driving gear meshed with the driven gear, a rotating shaft for fixing a plurality of driving gears and a motor for driving the rotating shaft.

As an improvement of the technical scheme, the lower water absorption rod and the roller rod are arranged at intervals.

As an improvement of the technical scheme, the distance between the adjacent roller rods and the lower water absorption rod is not more than 70 mm.

As an improvement of the technical scheme, the power assembly comprises a chain wheel sleeved on the lower water absorbing rod and the roller rod and a chain wound on the chain wheel.

As an improvement of the technical scheme, the lower water absorbing rods and the upper water absorbing rods are arranged in a staggered mode.

As an improvement of the technical scheme, the outer layers of the upper water absorption rod and the lower water absorption rod are both made of water absorption materials.

As an improvement of the technical scheme, at least one blowing mechanism is arranged on the frame body.

As an improvement of the technical scheme, the blowing mechanism comprises a blowing pipe arranged above the rack in a spanning mode and a duckbill blowing port arranged on the blowing pipe.

Implement the utility model discloses, following beneficial effect has:

the utility model comprises a frame, a roller table, an upper extrusion water absorption device and a lower extrusion water absorption device, wherein the upper extrusion water absorption device and the lower extrusion water absorption device are arranged oppositely, the lower extrusion water absorption device comprises a lower water absorption rod, a power assembly is connected on the lower water absorption rod, the power assembly drives the lower water absorption rod to rotate, a ceramic tile is transported on the roller table, the upper extrusion water absorption device and the lower extrusion water absorption device are extruded and absorb water, and the ceramic tile has a motion trend of moving up and down; the lower water absorption rod is provided with a power assembly which provides power for the ceramic tile to move forward, so that the ceramic tile has the effect of eliminating the trend of the ceramic tile moving up and down to a certain extent, and the ceramic tile moves stably;

and (II) a blowing mechanism is further arranged on the rack, and the water film formed on the surface of the ceramic tile due to extrusion is quickly dried by further blowing and drying the ceramic tile after water absorption by extrusion.

Drawings

FIG. 1 is an overall view of a long brick extruding roller platform according to the present invention;

fig. 2 is a partially enlarged view of a portion a in fig. 1.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the present invention will be described in further detail with reference to the accompanying drawings. Only this statement, the utility model discloses the upper and lower, left and right, preceding, back, inside and outside etc. position words that appear or will appear in the text only use the utility model discloses an attached drawing is the benchmark, and it is not right the utility model discloses a concrete restriction.

Referring to fig. 1 and 2, the utility model discloses a rectangular brick extrusion roller stick platform absorbs water through the mode that extrudees remaining water stain behind the ceramic tile wet process edging futilely, is applicable to the ceramic tile that the width is less than 200 mm. The utility model comprises a frame 1, a roller table 2 arranged on the frame 1, an upper extrusion water absorption device 3 arranged above the roller table 2 and a lower extrusion water absorption device 4 arranged below the upper extrusion water absorption device 3;

the upper extrusion water absorption device 3 comprises a frame body 31, a first bearing 32 arranged on the frame body 31 and an upper water absorption rod 33 arranged on the first bearing 32 in parallel;

the lower extrusion water absorption device 4 comprises a plurality of lower water absorption rods 41, a second bearing 42 is arranged between each lower water absorption rod 41 and the rack 1, the lower water absorption rods 41 are connected with a power assembly 5, and the power assembly 5 drives the lower water absorption rods 41 to rotate;

the roller table 2 is connected with a driving component 6, and the driving component 6 and the power component 5 drive the tile to move.

Specifically, be equipped with roller platform 2 on frame 1, roller platform 2 includes a plurality of roller bars 21 of parallel arrangement, roller bar 21 connects drive assembly 6, drive assembly 6 drive roller bar 21 rotates. An upper extrusion water absorption device 3 is arranged above the roller table 2, a plurality of upper water absorption rods 33 of the upper extrusion water absorption device 3 are horizontally arranged, the distance between every two adjacent upper water absorption rods 33 is equal, and the distance is about one half of the width of the ceramic tile to be dried. The lower extrusion water absorption device 4 is correspondingly arranged below the upper extrusion water absorption device 3 to form an extrusion drying area. The lower squeeze water absorbing device 4 includes a plurality of lower water absorbing sticks 41. The water absorption rod is provided with a power assembly 5, and the power assembly 5 drives the lower water absorption rod 41 to roll; in the extrusion drying area, the lower water absorption rod 41 and the roller rod 21 are both driven forwards, so that compared with the driving component 6 singly arranged on the roller table 2, the added power component 5 provides more stable driving force for the ceramic tile, and the problem that the ceramic tile is clamped between the roller rod 21 and the lower water absorption rod 41 due to the movement tendency of the long and thin ceramic tile which moves up and down when being extruded can be avoided.

Preferably, a third bearing 22 is arranged between the roller bar 21 and the frame 1, the first bearing 32 and the second bearing 42 are UCHA series bearings or plastic bearings of the same type, and the third bearing 22 is a seated bearing of UCFB series. The UCHA series bearings are spherical outside surface ball bearings with suspension type seats, and the UCFB series bearings are spherical outside surface ball bearings with seats. The bearing can effectively reduce the space between the two roller rods 21 and the space between the roller rods 21 and the lower water absorption rod 41 and the space between the roller rods 33 and the upper water absorption rods, so that the space meets the requirement of conveying the long and thin strip-shaped ceramic tiles.

The driving assembly 6 drives the roller bar 21 to move, and the driving assembly 6 can be a chain transmission mechanism, a gear transmission mechanism or a gear rack transmission mechanism, but is not limited to the above. In this embodiment, the driving assembly 6 includes a driven gear 61 disposed at the end of the roller rod 21, a driving gear 62, a rotating shaft 63 for fixing the driving gears 62, and a motor 64 for driving the rotating shaft 63 through a chain drive. The motor 64 rotates to drive the rotating shaft 63 to rotate, so that the driving gears 62 on the rotating shaft 63 drive the driven gears 61 meshed with the driving gears to rotate, so that the roller rod 21 rotates to convey the tiles forward.

Preferably, the distance between two adjacent rollers 21 is not greater than 70 mm. In order to solve the transportation problem of the ceramic tiles with the width smaller than 200mm, the distance between the two roller rods 21 is required to be smaller than 70mm, and the ceramic tiles can be effectively prevented from being clamped between the two roller rods 21.

In the extrusion drying zone, the lower water absorption rod 41 is arranged at a distance from the roller rod 21. Since the frictional resistance of the tile is much greater than that of the roll bar 21 when the tile is in contact with the lower water absorption bar 41. In order to ensure the stable transportation of the ceramic tiles while achieving the effective drying of the ceramic tiles, it is preferable that the lower water absorption rod 41 and the roller rod 21 are spaced apart from each other, so that the smooth transportation and drying efficiency of the ceramic tiles can be balanced.

The power assembly 5 is used for driving the lower water absorption rod 41 to move, and preventing the ceramic tiles from being clamped between the lower water absorption rod 41 and the roller rod 21. The power assembly 5 includes a chain transmission mechanism or a rack and pinion transmission mechanism, but is not limited thereto. In this embodiment, the power assembly 5 includes a plurality of sets of chain wheels 51 sleeved on the lower water absorbing rod 41 and the roller rod 21, and a chain (not shown) wound around the chain wheels 51. Specifically, the chain wheel 51 provided between the lower water absorption bar 41 and the roller bar 21 is disposed along the same horizontal line. The roller rod 21 rotates to drive the chain to transmit, so as to drive the lower water absorption rod 41 to rotate. By adopting the structure, the driving assembly 6 is used as a power source, the structure is simple, and the synchronization effect of the roller rod 21 and the lower water absorption rod 41 is good.

Preferably, the lower water absorption rods 41 and the upper water absorption rods 33 are arranged in a staggered manner. In order to ensure smooth transportation of the ceramic tiles, the lower water absorbing rods 41 and the upper water absorbing rods 33 are arranged in a staggered mode, so that the transportation resistance of the ceramic tiles can be reduced while the drying of the top surfaces and the bottom surfaces of the ceramic tiles is met.

Wherein, the outer layers of the upper water absorption rod 33 and the lower water absorption rod 41 are both made of water absorption materials. The water-absorbing material is sponge, but not limited thereto.

After being extruded by the upper water suction roller and the lower water suction roller, a layer of water film is formed on the surface of the ceramic tile, and at least one blowing mechanism 7 is arranged on the frame body 31 for further drying. Preferably, the blowing mechanism 7 comprises a blowing pipe 71 (not shown in the drawings) straddling the frame 1. Specifically, the upper end of the blowpipe 71 is provided with an air inlet pipe 72, and the lower end of the blowpipe 71 is provided with a duckbilled air outlet. Through constantly blowing to the ceramic tile surface, weather the water film fast to the ceramic tile carries out next process.

To sum up, the utility model comprises a frame 1, a roller table 2, an upper extrusion water absorption device 3 and a lower extrusion water absorption device 4, wherein the upper extrusion water absorption device 3 and the lower extrusion water absorption device 4 are arranged oppositely, the lower extrusion water absorption device 4 comprises a lower water absorption rod 41, a power assembly 5 is connected on the lower water absorption rod 41, the power assembly 5 drives the lower water absorption rod 41 to rotate, a ceramic tile is transported on the roller table 2, the upper extrusion water absorption device 3 and the lower extrusion water absorption device 4 are extruded and absorb water, and the ceramic tile has a motion trend of moving up and down; the lower water absorption rod 41 is provided with a power assembly 5 which provides power for the forward movement of the ceramic tile, and the ceramic tile has the effect of eliminating the tendency of the ceramic tile to move up and down, so that the ceramic tile moves stably.

The foregoing is a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations are also considered as the protection scope of the present invention.

Claims (10)

1. A long brick extruding roller rod table is characterized by comprising a frame, a roller table arranged on the frame, a driving assembly, an upper extruding water absorption device arranged above the roller table and a lower extruding water absorption device arranged below the upper extruding water absorption device;

the upper extrusion water absorption device comprises a frame body, a first bearing arranged on the frame body and an upper water absorption rod arranged on the first bearing in parallel;

the lower extrusion water absorption device comprises a plurality of lower water absorption rods, a second bearing is arranged between the lower water absorption rods and the rack, the lower water absorption rods are connected with a power assembly, and the power assembly drives the lower water absorption rods to rotate.

2. The bar block extrusion roller table of claim 1, wherein the roller table comprises a plurality of roller bars, and a third bearing is arranged between the roller bars and the frame;

the first bearing and the second bearing are UCHA series bearings or plastic bearings of the same type, and the third bearing is a seated bearing of UCFB series.

3. The bar block extruding roller table as claimed in claim 2, wherein the driving assembly includes a driven gear provided at a distal end of the roller, a driving gear engaged with the driven gear, a rotation shaft fixing the plurality of driving gears, and a motor driving the rotation shaft.

4. The bar block extrusion roller bar station of claim 2, wherein said lower water absorption bar is spaced from said roller bar.

5. A bar block extrusion roller platform as set forth in claim 4, wherein the distance between adjacent rollers and the lower suction bar is no greater than 70 mm.

6. The bar block extrusion roller platform of claim 5, wherein the power assembly comprises a chain wheel sleeved on the lower water absorption bar and the roller bar and a chain wound on the chain wheel.

7. The bar block extrusion roller platform of claim 1, wherein the lower water absorption bars are staggered from the upper water absorption bars.

8. The elongated brick extrusion roller platform according to any one of claims 1 to 7, wherein the outer layers of the upper and lower water absorbing rods are made of water absorbing material.

9. The long bar brick extrusion roller platform according to claim 1, wherein at least one blowing mechanism is arranged above the frame body.

10. The long bar brick extrusion roller table of claim 9 wherein the blowing mechanism comprises a blowpipe straddling the frame and a duckbill blow port above the blowpipe.

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