CN211337822U - Ceramic tile production is with transferring mechanism - Google Patents

Abstract

The utility model provides a ceramic tile production is with transmitting mechanism belongs to the conveying equipment field. Wherein, the belt conveyor is vertically connected with the outlet end of the roller conveyor; the belt conveyor comprises a plurality of belt conveying parts and a driving motor for driving the belt conveying parts to work; a plurality of rollers which are evenly spaced and are positioned between the adjacent belt conveying parts are rotatably arranged at the outlet end of the roller conveyor; the axial direction of the roller is consistent with the conveying direction of the belt conveying component; the jacking mechanism comprises a support frame positioned below the roller, a lifting device for driving the support frame to lift, and a plurality of rollers which are rotatably arranged on the support frame corresponding to each belt conveying component; the roller is axially vertical to the conveying direction of the belt conveying component, and the rolling top surface of the roller is in rolling contact with the bottom surface of a belt of the belt conveying component; the position detector detects whether the ceramic tile is moved onto the roller or moved out of the roller; the controller is connected to the lifting device and the position detector. The utility model discloses aim at accomplishing ceramic tile 90 and transmitting work and guaranteeing that it is intact not hindered.

Description

Ceramic tile production is with transferring mechanism

Technical Field

The utility model belongs to the technical field of conveying equipment, concretely relates to ceramic tile production is with transmitting mechanism.

Background

Ceramic tiles, also known as ceramic tiles, are acid and alkali resistant porcelain or stony, building or decorative materials, called ceramic tiles, made of refractory metal oxides and semimetal oxides by grinding, mixing, pressing, glazing, sintering and other processing steps, and are made of mixed raw materials such as clay and quartz sand.

Set up in the workshop and can accomplish above-mentioned manufacturing procedure's multiple production facility, connect the transfer chain in the inlet outlet end of various equipment, the transfer chain carries pending ceramic tile for production facility, in order to save space, accomplishes arranging of whole ceramic tile production line in narrow and small workshop, often need use the transfer chain that has the right angle function of commuting, carries out 90 with the ceramic tile and forwards (also right angle switching-over or quarter turn).

In prior art, the transfer chain that has the right angle switching-over function adopts roller conveyer and the band conveyer combination that the perpendicular meets, set up the baffle at roller conveyer's end, band conveyer's belt sets up the space between roller conveyer's the roller, and set up the ejector pin below the belt, when the ceramic tile carries to the band conveyer top through roller conveyer, the ejector pin will be in running state's band jack-up, thereby with the ceramic tile lifting, make the ceramic tile remove along band conveyer's direction of delivery, finally realize the right angle switching-over of ceramic tile.

At transfer chain during operation, the ceramic tile is carried to baffle department, roller conveyer shut down, then ejector pin work, with the ceramic tile lifting, let band conveyer continue to carry the ceramic tile, but, the ejector pin jack-up belt at band during operation can lead to belt and ejector pin to take place sliding friction, causes the bottom surface wearing and tearing of belt very fast to, the ceramic tile contacts with the baffle, leads to the side of ceramic tile impaired easily, can't ensure that the ceramic tile is intact, thereby has increased the ceramic tile rejection rate.

It is seen that improvements and enhancements to the prior art are needed.

SUMMERY OF THE UTILITY MODEL

In view of the deficiencies of the prior art, the utility model aims to provide a ceramic tile production is with transferring mechanism, degree of automation is high, and is reliable durable, aims at accomplishing ceramic tile 90 and transfers work and guarantee that it is intact not hindered.

In order to achieve the technical purpose, the utility model discloses following technical scheme has been taken:

a transfer mechanism for ceramic tile production comprises a belt conveyor and a roller conveyor which are vertically connected with each other, wherein the belt conveyor is arranged at the outlet end of the roller conveyor; wherein, the transfer mechanism for producing the ceramic tiles further comprises a jacking mechanism, a position detector and a controller;

the belt conveyor comprises a plurality of belt conveying components arranged in parallel and a driving motor for driving the belt conveying components to work;

a plurality of rollers which are uniformly spaced and can be rotatably arranged are arranged at the outlet end of the roller conveyor; the rollers are arranged between the adjacent belt conveying components; the axial direction of the roller is consistent with the conveying direction of the belt conveying component;

the jacking mechanism comprises a support frame positioned below the roller, a lifting device used for driving the support frame to lift, and a plurality of rollers which are rotatably arranged on the support frame corresponding to each belt conveying part; the axial direction of the roller is vertical to the conveying direction of the belt conveying component, and the rolling top surface of the roller is in rolling contact with the bottom surface of the belt conveying component;

the position detector is used for detecting whether the ceramic tile is moved onto the roller or out of the roller;

the controller is electrically connected with the lifting device and the position detector.

In the transfer mechanism for producing the ceramic tiles, the roller conveyor comprises a first frame, a plurality of conveying rollers which are rotatably arranged on the first frame at uniform intervals, and a roller motor for driving the conveying rollers to rotate; a transmission chain is arranged between the adjacent conveying rollers, the conveying rollers are provided with double-row chain wheels, and the transmission chain is meshed and connected with the double-row chain wheels; the roller motor is fixedly connected to the first rack.

In the transfer mechanism for producing the ceramic tiles, the roller motor is in power connection with any one of the conveying rollers.

In the transfer mechanism for producing the ceramic tiles, a motor shaft of the roller is connected to the conveying roller.

In the transfer mechanism for producing the ceramic tiles, the roller is rotatably arranged on the first rack, and the first rack is provided with a notch for the belt of the belt conveying component to pass through.

In the tile production transfer mechanism, the lifting device is a telescopic cylinder fixedly connected to the first frame.

In the ceramic tile production is with transporting mechanism, the position detector is fixed in on the first frame and be located the right side of roller, the position detector is photoelectric switch.

In the transfer mechanism for producing the ceramic tiles, the belt conveying part comprises a driving wheel, a driven wheel, a driving shaft, a driven shaft and a belt wound between the driving wheel and the driven wheel; the driving wheels are fixedly connected to the driving shaft, and the driven wheels are fixedly connected to the driven shaft; the driving motor is in power connection with the driving shaft; the driving motor is fixedly connected with a second rack; the driving shaft and the driven shaft are rotatably arranged on the second rack.

In the transfer mechanism for producing the ceramic tiles, the driving motor is connected with the driving shaft.

In the transfer mechanism for producing the ceramic tiles, the belt is a triangular belt.

Has the advantages that:

compared with the prior art, the utility model provides a ceramic tile production is with transmitting mechanism, degree of automation is high, and is reliable durable, aims at accomplishing ceramic tile 90 and transmits work and guarantee that it is intact not hindered.

The utility model discloses set up jacking mechanism, driven the vertical removal of support frame by lifting device, and the support frame has set up a plurality of gyro wheels, and the back that targets in place rises of support frame, and the roll top surface of gyro wheel contacts with the bottom surface of belt, with belt jack-up to make the ceramic tile fall to band conveyer on, carry out the ceramic tile by band conveyer and carry, realize the right angle switching-over of ceramic tile. The arrangement of the idler wheels ensures that the belt and the idler wheels have rolling friction when the belt works, so that the friction between the belt and the jacking mechanism is greatly reduced, the belt abrasion speed is reduced, and the transfer mechanism for ceramic tile production is prolonged.

In addition, a plurality of rollers are arranged at the outlet end of the roller conveyor, the rollers are arranged between adjacent belt conveying parts, and when the ceramic tiles are conveyed by the roller conveyor to move onto the rollers and slowly stop on the rollers; and then the controller starts the jacking mechanism according to the detection signal of the position detector, so that the ceramic tile is lifted by the belt and is continuously conveyed by the belt conveyor, a baffle is not required to be arranged, and the whole ceramic tile can be ensured to be intact.

Drawings

Fig. 1 is a perspective view of the structure of the transfer mechanism for producing ceramic tiles provided by the utility model.

Figure 2 is the utility model provides a ceramic tile production is with transporting structure plan view of mechanism.

Figure 3 is the utility model provides a ceramic tile production is with structure right side view that passes on mechanism.

Figure 4 is the utility model provides a ceramic tile production is with structure front view who passes on mechanism.

Figure 5 is the utility model provides a ceramic tile production is with transporting on mechanism, roller conveyer's structure stereogram.

Fig. 6 is a perspective view of the structure of the belt conveying component in the transfer mechanism for ceramic tile production provided by the utility model.

Fig. 7 is a perspective view of the structure of the jacking mechanism in the transfer mechanism for producing ceramic tiles provided by the utility model.

Fig. 8 is a right side view of the structure of the jacking mechanism in the transfer mechanism for producing ceramic tiles provided by the utility model.

Detailed Description

The utility model provides a ceramic tile production is with transmitting mechanism, for making the utility model discloses a purpose, technical scheme and effect are clearer, clear and definite, and it is right that the embodiment is lifted to follow with the figure reference the utility model discloses further detailed description. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

In the description of the present invention, it should be understood that the terms "left", "right", "upper", "lower", "front", "rear", "top", "bottom", etc. indicate the orientation or position relationship of the present invention based on the drawings, and are only for convenience of description and simplified description. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated.

The direction of the arrows in figure 2 indicates the direction of transport of the tiles.

Referring to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, and fig. 8, the present embodiment provides a transfer mechanism for tile production, which includes a belt conveyor 100 and a roller conveyor 200 connected perpendicularly to each other, wherein the belt conveyor 100 is disposed at an outlet end of the roller conveyor 200. Wherein, the transfer mechanism for producing ceramic tiles further comprises a jacking mechanism 400, a position detector and a controller.

The belt conveyor 100 includes a plurality of belt conveying members arranged in parallel, and a driving motor 120 for driving the belt conveying members to operate. Specifically, the belt conveying unit includes a driving wheel 140, a driven wheel 160, a driving shaft 150, a driven shaft 170, and a belt 130 wound between the driving wheel 140 and the driven wheel 160. A plurality of the action wheel 140 through key-type connection mode or welding mode fixed connection in the driving shaft 150, it is a plurality of from driving wheel 160 fixed connection in driven shaft 170 realizes a plurality of action wheels 140, a plurality of synchronous rotations from driving wheel 160, driving motor 120 with driving shaft 150 power is connected, can drive a plurality of action wheels 140 rotatory simultaneously through a driving motor 120, reduces energy consumption, cost.

The driving motor 120 is fixedly connected to the second frame 110 by a bolt connection. The driving shaft 150 and the driven shaft 170 are rotatably disposed on the second frame 110 through a bearing seat.

In this embodiment, the driving motor 120 is connected to the driving shaft 150 through a coupling. Of course, the power transmission between the driving motor 120 and the driving shaft 150 may be achieved by a belt transmission manner or a chain transmission manner.

A plurality of rollers 500 which are uniformly spaced and can be rotatably arranged are arranged at the outlet end of the roller conveyor 200; the roller 500 is arranged between the adjacent belts 130 of the belt conveying components; the axial direction of the roller 500 coincides with the conveying direction of the belt conveying means. Ceramic tile 300 carries toward roller 500 direction through the transport effect of roller conveyer 200, when ceramic tile 300 removed to roller 500 on, the bottom surface of ceramic tile and roller 500's the top surface roll contact that rolls, make roller 500 rotate, and turn into the rotation kinetic energy of roller through the kinetic energy with the ceramic tile, frictional heat between roller and the ceramic tile, make the ceramic tile can slowly stop on the roller, need not to set up the baffle and block the ceramic tile, thereby ensure that the side of ceramic tile can avoid the effort of baffle and impaired.

The jacking mechanism 400 includes a supporting frame 420 located below the roller 500, a lifting device 410 for driving the supporting frame 420 to move up and down, and a plurality of rollers 430 rotatably disposed on the supporting frame 420 through bearings corresponding to each belt conveying member. The axial direction of the roller 430 is perpendicular to the conveying direction of the belt conveying means, and the rolling top surface of the roller 430 is in rolling contact with the bottom surface of the belt 130 of the belt conveying means.

When the belt 130 is operated, the jacking mechanism 400 is activated to lift the supporting frame 420 by the lifting device 410, and jack up the belt 130 by the rollers 430 provided on the supporting frame 420. The bottom surface of the belt 130 contacts with the rolling top surface of the roller 430, when the belt 130 moves fast relative to the roller 430, the roller 430 rotates due to the friction between the roller 430 and the belt, and the rolling friction mode is adopted, so that the wear rate of the belt can be greatly reduced, the service life of the belt is prolonged, and the low production efficiency caused by frequent replacement of the belt is avoided.

In the embodiment where the belt 130 is a triangular belt, the width of the top surface is greater than that of the bottom surface, and a smaller roller 430 may be provided to ensure that the roller 430 can pass through the gap between the rollers 500.

The position detector is used for detecting whether the ceramic tile 300 moves onto the roller 500 or moves out of the roller 500; the controller is electrically connected with the lifting device 410 and the position detector of the jacking mechanism 400 through data transmission lines.

When the position detector detects that the ceramic tile 300 moves to the roller 500 from the roller conveyor 200 and is in a static state, a detection signal is sent to the controller, the controller sends a control signal, the jacking mechanism 400 is started, and the jacking mechanism 400 jacks up the belt 130 in an operating state, so that the ceramic tile is lifted up, the belt conveyor 100 continues to convey the ceramic tile, 90-degree angle transfer work of the ceramic tile is realized, and the whole ceramic tile can be guaranteed to be intact.

When the position detector detects that the tile 300 has moved outside the area of the roller 500 by the belt conveyor 100, the controller receives the detection signal from the position detector and controls the operation of the jacking mechanism 400 so that the belt 130 moves down and returns to the original height position, waiting for the first batch of tiles to be transferred.

In this embodiment, the controller may be, but is not limited to, a PLC controller.

As shown in fig. 1 and 5, in detail, the roller conveyor 200 includes a first frame 210, a plurality of conveying rollers 230 rotatably disposed on the first frame 210 through bearings and disposed at uniform intervals, and a roller motor 220 for driving the conveying rollers 230 to rotate. A transmission chain (not shown) is arranged between adjacent conveying rollers 230, the conveying rollers 230 are provided with a duplex sprocket 240, and the transmission chain is engaged with the duplex sprocket 240 and drives each conveying roller 230 to rotate together through the transmission chain. The roller motor 220 is fixedly connected to the first frame 210 by a bolt installation method.

The roller motor 220 is in power connection with any one of the conveying rollers 230, and the roller motor 220 operates to drive the conveying rollers 230 in power connection with the roller motor to rotate, and the rotation of all the conveying rollers 230 is realized by means of the power transmission effect of the transmission chain. The roller 500 is rotatably disposed on the first frame 210 through a bearing, and the first frame 210 is provided with a notch 250 for the belt 130 of the belt conveying component to pass through, so as to prevent the running belt 130 from being worn by the influence of the first frame 210.

In this embodiment, the roll motor 220 is coupled to one of the feed rollers 230 through a coupling shaft. Of course, the power connection between the roller motor and the conveying roller can also be realized by a belt transmission mode or a chain transmission mode.

As shown in fig. 1, 7 and 8, in particular, the lifting device 410 is a telescopic cylinder fixedly connected to the first frame 210. In this embodiment, the lifting device 410 is a two-axis telescopic cylinder. In addition, when the supporting frame 420 moves upwards, the supporting frame is prevented from contacting the roller 500, so that the supporting frame is provided with a groove 421, and the width of the groove 421 is larger than the diameter of the roller 500.

As shown in fig. 1, 5, 6 and 7, the position detector is fixed on the first frame 210 and located at the right side of the roller 500, only one position detector is used, and when the tile 300 stops on the roller 500, the position detector measures that the distance between the position detector and the tile is a set value, and then a first detection signal is generated; when the tile 300 moves out of the roller 500 area under the conveying of the belt conveyor 100, the position detector measures that the distance between the tile and the position detector is another set value, a second detection signal is generated, and the controller controls the jacking mechanism 400 to work according to the two detection signals, so that the roller is controlled to move up and down. By lifting the belt, the tiles are transferred from the roller 500 onto the belt 130.

In this embodiment, the position detector is a photoelectric switch. Also, two position detectors, position detector 600 and position detector 700, respectively, are provided. Wherein, the position detector 600 is fixedly arranged at the right side of the roller 500, the detection direction of which is consistent with the axial direction of the roller 500, and is used for detecting whether the ceramic tile is stopped on the roller 500. The position detector 700 is fixedly disposed at the left side of the roller 500, and the detection direction thereof is perpendicular to the axial direction of the roller 500, and is used for detecting whether the tile moves out of the roller area.

To sum up, the utility model provides a ceramic tile production is with transmitting mechanism, degree of automation is high, and is reliably durable, aims at accomplishing ceramic tile 90 and transmits work and guarantee that it is intact not hindered.

The utility model discloses set up jacking mechanism, driven the vertical removal of support frame by lifting device, and the support frame has set up a plurality of gyro wheels, and the back that targets in place rises of support frame, and the roll top surface of gyro wheel contacts with the bottom surface of belt, with belt jack-up to make the ceramic tile fall to band conveyer on, carry out the ceramic tile by band conveyer and carry, realize the right angle switching-over of ceramic tile. The arrangement of the idler wheels ensures that the belt and the idler wheels have rolling friction when the belt works, so that the friction between the belt and the jacking mechanism is greatly reduced, the belt abrasion speed is reduced, and the transfer mechanism for ceramic tile production is prolonged.

In addition, a plurality of rollers are arranged at the outlet end of the roller conveyor, the rollers are arranged between adjacent belt conveying parts, and when the ceramic tiles are conveyed by the roller conveyor to move onto the rollers and slowly stop on the rollers; and then the controller starts the jacking mechanism according to the detection signal of the position detector, so that the ceramic tile is lifted by the belt and is continuously conveyed by the belt conveyor, a baffle is not required to be arranged, and the whole ceramic tile can be ensured to be intact.

It should be understood that equivalent alterations and modifications can be made by those skilled in the art according to the technical solution of the present invention and the inventive concept thereof, and all such alterations and modifications should fall within the scope of the appended claims.

Claims (10)

1. A transfer mechanism for ceramic tile production comprises a belt conveyor and a roller conveyor which are vertically connected with each other, wherein the belt conveyor is arranged at the outlet end of the roller conveyor; the device is characterized by also comprising a jacking mechanism, a position detector and a controller;

the belt conveyor comprises a plurality of belt conveying components arranged in parallel and a driving motor for driving the belt conveying components to work;

a plurality of rollers which are uniformly spaced and can be rotatably arranged are arranged at the outlet end of the roller conveyor; the rollers are arranged between the adjacent belt conveying components; the axial direction of the roller is consistent with the conveying direction of the belt conveying component;

the jacking mechanism comprises a support frame positioned below the roller, a lifting device used for driving the support frame to lift, and a plurality of rollers which are rotatably arranged on the support frame corresponding to each belt conveying part; the axial direction of the roller is vertical to the conveying direction of the belt conveying component, and the rolling top surface of the roller is in rolling contact with the bottom surface of the belt conveying component;

the position detector is used for detecting whether the ceramic tile is moved onto the roller or out of the roller;

the controller is electrically connected with the lifting device and the position detector.

2. The transfer mechanism for producing ceramic tiles of claim 1, wherein the roller conveyor comprises a first frame, a plurality of conveying rollers rotatably and uniformly spaced on the first frame, and a roller motor for driving the conveying rollers to rotate; a transmission chain is arranged between the adjacent conveying rollers, the conveying rollers are provided with double-row chain wheels, and the transmission chain is meshed and connected with the double-row chain wheels; the roller motor is fixedly connected to the first rack.

3. A transfer mechanism for the production of ceramic tiles as claimed in claim 2 in which the roller motor is in powered connection with any one of the feed rollers.

4. A transfer mechanism for the production of ceramic tiles as claimed in claim 3 in which the roller motor shaft is connected to the feed rollers.

5. The transfer mechanism for tile production according to claim 4, wherein said rollers are rotatably mounted on said first frame, said first frame having a recess for a belt of said belt conveyor to pass through.

6. The tile producing transfer mechanism of claim 5, wherein the lifting device is a telescopic cylinder fixedly connected to the first frame.

7. The transfer mechanism for tile production according to claim 6, wherein said position detector is fixed to said first frame and located on the right side of said roller, said position detector being a photoelectric switch.

8. The transfer mechanism for producing ceramic tiles of claim 1, wherein the belt conveying part comprises a driving wheel, a driven wheel, a driving shaft, a driven shaft and a belt wound between the driving wheel and the driven wheel; the driving wheels are fixedly connected to the driving shaft, and the driven wheels are fixedly connected to the driven shaft; the driving motor is in power connection with the driving shaft; the driving motor is fixedly connected with a second rack; the driving shaft and the driven shaft are rotatably arranged on the second rack.

9. A transfer mechanism for the production of ceramic tiles according to claim 8 in which the drive motor is connected to the drive shaft.

10. A transfer mechanism for the production of ceramic tiles as claimed in claim 9, in which the belt is a v-belt.

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