CN211140860U - Ceramic tile stacking device - Google Patents

Abstract

The utility model discloses a pile up neatly device is stacked to ceramic tile relates to pile up neatly device technical field. The utility model comprises a double-station material bearing mechanism and a stacking mechanism, wherein the double-station material bearing mechanism comprises a base, and a lead screw transmission assembly is fixedly arranged in the base; the stacking mechanism comprises a base; one side surface of the base is fixedly connected with the base; two first hydraulic rods are embedded in the base; one end of each of the two first hydraulic rods is fixedly connected with a lifting seat; two side surfaces of the lifting seat are fixedly connected with a group of second hydraulic rods; and one end of each of the two groups of second hydraulic rods is fixedly connected with a side plate. The utility model discloses a duplex position holds the design of material mechanism and pile up neatly mechanism, makes the device can be through with defeated material platform butt joint, the automatic pile up neatly operation of accomplishing among the ceramic tile production process, and holds the design of material platform through the duplex position, and the seamless material that holds when guaranteeing to hold the material realizes the operation of not shutting down then, effectively improves pile up neatly efficiency.

Description

Ceramic tile stacking device

Technical Field

The utility model belongs to the technical field of the pile up neatly device, especially, relate to a ceramic tile stacks pile up neatly device.

Background

In building construction, decorative tiles are the main raw materials for exterior decoration and floor paving, and with the high development of building engineering, the decorative tiles are increasingly used, and the production of the tiles goes through the processes of material selection → batching → ball milling pulping → spraying powder making → press forming → drying → printing (seeping pattern) → chemical material → batching → ball milling → firing → polishing, edging → grading → waxing → packing → warehousing and the like, wherein the packing process is an important step and the process needs to carry, stack and pack the tiles.

For a long time, the carrying and stacking and boxing of ceramic tiles are usually carried out manually, so that a production mode of a production line always requires a worker to work uninterruptedly for 24 hours, a large amount of labor is consumed, the production cost is improved, the working efficiency is low, the yield is difficult to improve, along with the rapid development of the ceramic tile mechanical industry, the trend that carrying and stacking are carried out by utilizing mechanical equipment instead of manpower becomes a trend, how to develop a carrying and stacking and boxing device capable of carrying and stacking efficiently and safely is a problem which needs to be solved urgently in the field of ceramic tile production.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a pile up neatly device is stacked to ceramic tile has solved the problem that current ceramic tile stacks pile up neatly device inefficiency through the design of duplex position holding mechanism and pile up neatly mechanism.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme:

the utility model relates to a ceramic tile stacking device, which comprises a double-station material bearing mechanism and a stacking mechanism, wherein the double-station material bearing mechanism comprises a base, and a lead screw transmission assembly is fixedly arranged inside the base; the stacking mechanism comprises a base; one side surface of the base is fixedly connected with the base; two first hydraulic rods are embedded in the base; one end of each of the two first hydraulic rods is fixedly connected with a lifting seat; two side surfaces of the lifting seat are fixedly connected with a group of second hydraulic rods; one end of each of the two groups of second hydraulic rods is fixedly connected with a side plate; two sliding grooves are formed in one surface of the base; a movable seat is connected to one surface of the sliding chute in a sliding manner; one surface of the moving seat is connected with the screw rod transmission assembly; two material bearing components are fixedly connected to one surface of the movable seat; the two material bearing assemblies comprise pedestals; one surface of the pedestal is fixedly connected with the movable seat; a group of third hydraulic rods is embedded at the bottom of the inner surface of the movable seat; one end of the third hydraulic rod is fixedly connected with a material platform; a material bearing plate is clamped on one surface of the material platform; a fourth hydraulic rod is fixedly connected between the opposite surfaces of the two side plates; one surface of each of the two side plates is rotatably connected with an annular conveying assembly; and the top surfaces of the two side plates are fixedly connected with limiting plates.

Furthermore, two groups of limiting holes are formed in one surface of the pedestal; two groups of positioning columns are fixedly connected to one surfaces of the two material bearing plates; the peripheral side surface of the positioning column is clamped with the limiting hole; and a gap is fixedly arranged between the opposite surfaces of the material bearing plate and the pedestal.

Furthermore, friction convex strips are arranged on one surface of each material bearing plate; the friction raised strips are distributed on one surface of the material bearing plate in a linear array.

Further, the annular conveying assembly comprises a driving roller, a driven roller and a first transmission motor; one ends of the driving roller and the driven roller are rotatably connected with the side plate; one surface of the first transmission motor is fixedly connected with the side plate; one end of the output shaft of the first transmission motor is fixedly connected with the driving roller; the circumferential side surfaces of the driving roller and the driven roller are connected with an annular conveying belt through a power transmission wheel in a transmission way.

Furthermore, the limiting plates are all of an L-shaped structure and are positioned right above the annular conveying assembly.

The utility model discloses following beneficial effect has:

the utility model discloses a duplex position holds the design of material mechanism and pile up neatly mechanism, makes the device can be through with defeated material platform butt joint, the automatic pile up neatly operation of accomplishing among the ceramic tile production process, and holds the design of material platform through the duplex position, and the seamless material that holds when guaranteeing to hold the material realizes the operation of not shutting down then, effectively improves pile up neatly efficiency.

Of course, it is not necessary for any particular product to achieve all of the above-described advantages at the same time.

Drawings

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

Fig. 1 is a schematic structural view of a tile stacking and palletizing device;

FIG. 2 is a schematic top view of the structure of FIG. 1;

FIG. 3 is a schematic structural view of a double-station material bearing mechanism;

FIG. 4 is a schematic cross-sectional view of the material loading assembly;

FIG. 5 is a schematic structural view of a pedestal, a material table and a limiting hole;

FIG. 6 is a schematic illustration of the palletizing mechanism;

in the drawings, the components represented by the respective reference numerals are listed below:

1-double-station material bearing mechanism, 2-stacking mechanism, 101-base, 102-screw transmission assembly, 103-chute, 104-moving seat, 105-material bearing assembly, 106-pedestal, 107-third hydraulic rod, 108-material platform, 109-material bearing plate, 110-limit hole, 111-positioning column, 201-base, 202-first hydraulic rod, 203-lifting seat, 204-second hydraulic rod, 205-side plate, 206-fourth hydraulic rod, 207-annular conveying assembly and 208-limit plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-6, the utility model relates to a ceramic tile stacking device, which comprises a double-station material bearing mechanism 1 and a stacking mechanism 2, wherein the double-station material bearing mechanism 1 comprises a base 101, a screw rod transmission assembly 102 is fixedly arranged inside the base 101, the screw rod transmission assembly 102 comprises a motor and a transmission screw rod for transmission, one end of an output shaft of the motor is connected with the transmission screw rod, the motor is connected with the base 101, the transmission screw rod is used for being connected with a movable seat 104, and the stacking mechanism 2 comprises a base 201; one side surface of the base 101 is fixedly connected with the base 201; two first hydraulic rods 202 are embedded in the base 201; one end of each of the two first hydraulic rods 202 is fixedly connected with a lifting seat 203; two side surfaces of the lifting seat 203 are fixedly connected with a group of second hydraulic rods 204, the number of each group of second hydraulic rods 204 is two, and one end of each group of second hydraulic rods 204 is fixedly connected with a side plate 205; two sliding grooves 103 are formed in one surface of the base 101; a moving seat 104 is connected to one surface of the sliding groove 103 in a sliding manner; one surface of the movable base 104 is connected with the screw rod transmission assembly 102; one surface of the movable base 104 is fixedly connected with two material bearing components 105;

both stock holding assemblies 105 include a pedestal 106; a surface of the pedestal 106 is fixedly connected to the movable base 104; a group of third hydraulic rods 107 is embedded at the bottom of the inner surface of the movable seat 104, the number of the third hydraulic rods 107 is four, and one end of each third hydraulic rod 107 is fixedly connected with a material platform 108; a material bearing plate 109 is clamped on one surface of the material platform 108;

a fourth hydraulic rod 206 is fixedly connected between the opposite surfaces of the two side plates 205; one surface of each of the two side plates 205 is rotatably connected with an annular conveying component 207; the top surfaces of the two side plates 205 are fixedly connected with limit plates 208.

Wherein, two sets of limiting holes 110 are disposed on one surface of the pedestal 106; two positioning columns 111 are fixedly connected to one surface of each material bearing plate 109; the peripheral side surface of the positioning column 111 is clamped with the limiting hole 110; a gap is fixedly arranged between the material bearing plate 109 and the opposite surface of the pedestal 106, and the gap is arranged so as to be used for connecting with a material bearing trolley or other transfer platforms.

Wherein, one surface of the material bearing plate 109 is provided with a friction convex strip; the friction raised strips are distributed on one surface of the material bearing plate 109 in a linear array, and the annular conveying assembly 207 comprises a driving roller, a driven roller and a first transmission motor; one end of each of the driving roller and the driven roller is rotatably connected with the side plate 205; one surface of the first transmission motor is fixedly connected with the side plate 205; one end of the output shaft of the first drive motor is fixedly connected with the drive roll; the peripheral side surfaces of the driving roller and the driven roller are connected with an annular conveying belt through a power transmission wheel in a transmission way.

The position-limiting plates 208 are all of L-shaped structures, and the position-limiting plates 208 are located right above the endless conveyor assembly 207.

One specific application of this embodiment is: when the double-station material bearing mechanism 1 is used, the double-station material bearing mechanism 1 is arranged below the ground, the installation standard is based on the fact that the material platform 108 is flush with the ground, when stacking is needed, the stacking mechanism 2 is butted with a material conveying platform, the material conveying platform refers to material conveying components such as a conveying belt, the height of the annular conveying component 207 is guaranteed to be flush with the height of the material conveying platform during butting, then tiles can naturally enter the annular conveying component 207 after being output from the material conveying platform, and meanwhile, the material bearing component 105 is guaranteed to be aligned with the stacking mechanism 2 during stacking;

the specific working process is that before stacking, the height of the material bearing plate 109 is changed by the third hydraulic rod 107, the material bearing plate 109 is slightly lower than the height of the side plates 205, the height difference is set as H, simultaneously before working, the minimum distance and the maximum distance of the two side plates 205 are set by a program, so as to ensure that the stacking mechanism 2 can bear the ceramic tile materials and effectively limit the ceramic tile materials, the stacking mechanism 2 bears the ceramic tile materials at the minimum distance, when bearing the ceramic tile materials, the annular conveying assembly 207 works, after the annular conveying assembly 207 works for a set time, the work is automatically stopped, the ceramic tile materials are contacted with the limiting plate 208, then under the action of the first hydraulic rod 202, the side plates 205 are lowered by the height of H, after lowering, the two side plates 205 reach the maximum distance under the action of the second hydraulic rod 204, so that the borne ceramic tile materials are placed on the material bearing plate 109, and after placing, the two side plates 205 automatically return, after returning, the distance returns to the minimum distance again, the annular conveying assembly 207 works again, next materials are received, the material receiving plate 109 automatically descends to set the height under the control of a linkage program after receiving the materials at each time, the descending height is the thickness of one ceramic tile at each time, the material receiving assembly 105 works after reaching the set height, therefore, the two material receiving assemblies 105 are switched, seamless material receiving and non-stop operation are achieved, and the material receiving plate 109 and the materials can be transported integrally through the transport trolley.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the present invention disclosed above are intended only to help illustrate the present invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The present invention is limited only by the claims and their full scope and equivalents.

Claims (5)

1. A ceramic tile stacking device comprises a double-station material bearing mechanism (1) and a stacking mechanism (2), wherein the double-station material bearing mechanism (1) comprises a base (101), and a screw rod transmission assembly (102) is fixedly arranged in the base (101); the stacking mechanism (2) comprises a base (201); one side surface of the base (101) is fixedly connected with the base (201); two first hydraulic rods (202) are embedded in the base (201); one end of each of the two first hydraulic rods (202) is fixedly connected with a lifting seat (203); two side surfaces of the lifting seat (203) are fixedly connected with a group of second hydraulic rods (204); two sets of second hydraulic stem (204) one end equal fixedly connected with curb plate (205), its characterized in that:

one surface of the base (101) is provided with two sliding grooves (103); one surface of the sliding groove (103) is connected with a moving seat (104) in a sliding manner; one surface of the moving seat (104) is connected with the screw rod transmission assembly (102); one surface of the movable seat (104) is fixedly connected with two material bearing components (105);

both of the material bearing assemblies (105) comprise a pedestal (106); one surface of the pedestal (106) is fixedly connected with the movable seat (104); a group of third hydraulic rods (107) are embedded at the bottom of the inner surface of the movable seat (104); one end of the third hydraulic rod (107) is fixedly connected with a material platform (108); a material bearing plate (109) is clamped on one surface of the material platform (108);

a fourth hydraulic rod (206) is fixedly connected between the opposite surfaces of the two side plates (205); one surface of each side plate (205) is rotatably connected with an annular transmission assembly (207); the top surfaces of the two side plates (205) are fixedly connected with limit plates (208).

2. The stacking and stacking device for ceramic tiles as recited in claim 1, wherein two sets of limiting holes (110) are formed in one surface of each of the two pedestals (106); one surface of each of the two material bearing plates (109) is fixedly connected with two groups of positioning columns (111); the peripheral side surface of the positioning column (111) is clamped with the limiting hole (110); and a gap is fixedly arranged between the material bearing plate (109) and the opposite surface of the pedestal (106).

3. A tile stacking and palletizing device as in claim 1, wherein both said material-receiving plates (109) are provided on one surface with friction ridges; the friction convex strips are distributed on one surface of the material bearing plate (109) in a linear array.

4. A tile stacking and palletizing device as in claim 1, characterized in that said annular conveying assembly (207) comprises a driving roller, a driven roller and a first transmission motor; one ends of the driving roller and the driven roller are rotationally connected with the side plate (205); one surface of the first transmission motor is fixedly connected with the side plate (205); one end of the output shaft of the first transmission motor is fixedly connected with the driving roller; the circumferential side surfaces of the driving roller and the driven roller are connected with an annular conveying belt through a power transmission wheel in a transmission way.

5. The device for stacking and palletizing ceramic tiles as in claim 1, wherein both said limit plates (208) are of the "L" type, said limit plates (208) being positioned directly above the endless conveyor assembly (207).

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