CN111532745A

CN111532745A - Upper row device

Info

Publication number: CN111532745A
Application number: CN202010375604.XA
Authority: CN
Inventors: 徐龙辉; 丁幸宇; 刘辉丽; 周玉焕; 雷翼
Original assignee: Guangdong Jma Aluminium Profile Factory Group Co ltd; Foshan JMA Aluminium Co Ltd
Current assignee: Guangdong Jma Aluminium Profile Factory Group Co ltd; Foshan JMA Aluminium Co Ltd
Priority date: 2020-05-07
Filing date: 2020-05-07
Publication date: 2020-08-14

Abstract

The invention discloses an upper-row device, which comprises a transmission mechanism, wherein the transmission mechanism comprises a transmission mechanism and an upper-row mechanism, the transmission mechanism comprises a first rolling shaft, a second rolling shaft, a first conveying belt and a first driving mechanism, the first conveying belt is sleeved outside the first rolling shaft and the second rolling shaft, the first rolling shaft is connected with the second rolling shaft through the first conveying belt, and the first driving mechanism is used for driving the first rolling shaft to rotate and driving the second rolling shaft to rotate through the first conveying belt; the upper row of mechanisms comprises a second conveying belt, a third roller and a second driving mechanism, the second conveying belt is sleeved outside the second roller and the third roller, the second roller is connected with the third roller through the second conveying belt, the second driving mechanism is used for driving the third roller to lift, and the second roller drives the third roller to rotate through the second conveying belt. By adopting the invention, automatic upward discharging is realized, the labor intensity is reduced, and the production efficiency is improved.

Description

Upper row device

Technical Field

The invention relates to the field of aluminum profile processing, in particular to an upper row auxiliary device for horizontal oxidation pretreatment of an aluminum profile.

Background

The horizontal oxidation pretreatment is to perform chemical polishing treatment on the surface of the aluminum profile to remove substances such as grease on the surface of the aluminum profile. The traditional sectional material racking mode of horizontal pretreatment is that the material is lifted out of a material frame manually and is lifted up to be hung on a vertical row rod and is bound by an aluminum wire or fixed by a clamp.

Disclosure of Invention

The invention aims to provide an upper discharging device, which realizes automatic upper discharging, reduces labor intensity and improves production efficiency.

In order to solve the technical problem, the invention provides an upper row device, which comprises a transmission mechanism, wherein the transmission mechanism comprises a transmission mechanism and an upper row mechanism, the transmission mechanism comprises a first rolling shaft, a second rolling shaft, a first conveying belt and a first driving mechanism connected with the first rolling shaft, the first conveying belt is sleeved outside the first rolling shaft and the second rolling shaft, the first rolling shaft is connected with the second rolling shaft through the first conveying belt, and the first driving mechanism is used for driving the first rolling shaft to rotate and driving the second rolling shaft to rotate through the first conveying belt;

the upper row of mechanisms comprises a second conveying belt, a third roller and a second driving mechanism connected with the third roller, the second conveying belt is sleeved outside the second roller and the third roller, the second roller is connected with the third roller through a second conveying belt, the second driving mechanism is used for driving the third roller to lift, and the second roller drives the third roller to rotate through the second conveying belt.

As an improvement of the above scheme, the first roller and the second roller are engaged with the first belt through gear hobbing, and the second roller and the third roller are engaged with the second belt through gear hobbing.

As an improvement of the above scheme, the conveying device further comprises a supporting mechanism for supporting the conveying mechanism, wherein the supporting mechanism comprises a first supporting component for supporting the first roller, a second supporting component for supporting the second roller, a third supporting component for supporting the third roller and a supporting frame for supporting the first driving mechanism.

As an improvement of the above scheme, the first support assembly comprises a first support rod and a first bearing arranged at the top end of the first support rod, and the first support rod is movably connected with the first roller through the first bearing;

the second support assembly comprises a second support rod and a second bearing arranged at the top end of the second support rod, and the second support rod is movably connected with the second rolling shaft through the second bearing;

the third supporting assembly comprises a third supporting rod and a third bearing arranged at the top end of the third supporting rod, and the third supporting rod is movably connected with a third rolling shaft through the third bearing.

As an improvement of the above scheme, the supporting mechanism further comprises a first cross bar and a second cross bar, the first cross bar is fixedly connected with the first supporting rod and the second supporting rod respectively, and the second cross bar is hinged with the second supporting rod and the third supporting rod respectively.

As an improvement of the above scheme, the device further comprises a moving assembly for moving the transmission mechanism, wherein the moving assembly comprises a guide rail and a sliding block capable of sliding along the guide rail, and the sliding block comprises a first sliding block arranged at the bottom end of the first supporting rod, a second sliding block arranged at the bottom end of the second supporting rod and a third sliding block arranged at the bottom of the second driving mechanism.

As the improvement of the scheme, the first sliding block, the second sliding block and the third sliding block are provided with first pulleys, and the supporting frame is provided with second pulleys.

As a modification of the above, the third support member is provided with a distance sensor.

As an improvement of the scheme, the first roller, the second roller and the third roller are parallel to each other, and the included angle formed by the plane where the first roller and the second roller are located and the plane where the second roller and the third roller are located is 0-60 degrees.

As an improvement of the scheme, the outer wall of the second conveying belt is provided with an anti-skid piece.

The implementation of the invention has the following beneficial effects:

according to the automatic material lifting device, automatic conveying, lifting and upward discharging are achieved through the conveying mechanism, the problem that materials are lifted out of the material frame and hung on the discharging rod manually is avoided, the labor intensity of workers is reduced, the production efficiency is improved, and potential safety hazards are reduced.

In addition, the whole or part of the conveying mechanism can be moved by the moving assembly, and the conveying mechanism can be moved to different positions to discharge materials on different discharge rods. The arrangement of the guide rail ensures that the transmission mechanism always keeps linear movement, and the normal operation of the transmission mechanism is ensured. The arrangement of the first pulley and the second pulley enables the transmission mechanism to move smoothly, reduces resistance and ensures normal operation of the transmission mechanism. The arrangement of the first cross rod and the second cross rod enables the distance between the first supporting component and the second supporting component and the distance between the second supporting component and the third supporting component to be kept unchanged all the time, so that the first conveying belt and the second conveying belt are kept in a tightened state, and the normal operation of the conveying mechanism is guaranteed. The arrangement of the distance sensor ensures that the section bar can accurately fall on the row rod bracket. The outer wall of second conveyer belt is equipped with anti-skidding piece, and the material landing when preventing the lifting of third roller bearing.

Drawings

FIG. 1 is a schematic view of an upper tier apparatus of the present invention;

FIG. 2 is an enlarged view at A in FIG. 1;

FIG. 3 is a view showing a state of use of an upper tier apparatus of the present invention;

FIG. 4 is a schematic view of the internal structure of the first slider shown in FIG. 1;

fig. 5 is a view showing a state of use of the third roller, the third support assembly and the gang bar of fig. 1.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the invention is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the invention.

Referring to fig. 1-5, the invention discloses an upper-row device, which is used for conveying and lifting an aluminum profile 100 material to a height corresponding to a row rod support 21 on a row rod 20, and comprises a transmission mechanism, wherein the transmission mechanism comprises a transmission mechanism and an upper-row mechanism, the transmission mechanism comprises a first roller 1, a second roller 2, a first conveyer belt 4 and a first driving mechanism 6 connected with the first roller 1, the first conveyer belt 4 is sleeved outside the first roller 1 and the second roller 2, the first roller 1 is connected with the second roller 2 through the first conveyer belt 4, and the first driving mechanism 6 is used for driving the first roller 1 to rotate and driving the second roller 2 to rotate through the first conveyer belt 4;

the upper row mechanism comprises a second conveying belt 5, a third roller 3 and a second driving mechanism 7 connected with the third roller 3, the second conveying belt 5 is sleeved outside the second roller 2 and the third roller 3, the second roller 2 is connected with the third roller 3 through the second conveying belt 5, the second driving mechanism 7 is used for driving the third roller 3 to ascend and descend, and the second roller 2 drives the third roller 3 to rotate through the second conveying belt 5.

According to the invention, the materials are conveyed to the upper discharging mechanism through the transmission mechanism, the transmission mechanism drives the upper discharging mechanism, and the materials are discharged upwards through the lifting of the third roller. According to the automatic material lifting device, automatic conveying, lifting and upward discharging are achieved through the conveying mechanism, the problem that materials are lifted out of the material frame and hung on the discharging rod manually is avoided, the labor intensity of workers is reduced, the production efficiency is improved, and potential safety hazards are reduced. Specifically, the material is conveyed to the upper row of the mechanism through the transmission mechanism, the transmission mechanism drives the upper row of the mechanism, and the material is lifted by the third rolling shaft to be discharged.

Specifically, the first roller 1 and the second roller 2 are engaged with the first conveyer belt 4 through gear hobbing, and the second roller 2 and the third roller 3 are engaged with the second conveyer belt 5 through gear hobbing 2 a. The first driving mechanism drives the first roller 1 to rotate, and the first roller 1 drives the first conveying belt 4 through gear hobbing. Similarly, the first belt conveyor 4 drives the second roller 2 to rotate and the second roller 2 drives the second belt conveyor 5 by the gear teeth 2a on the second roller 2. Under the gear hobbing action of the third roller 3, the third roller 3 is driven by the second conveyer belt 5, so that the third roller 3 rotates. The first roller 1, the second roller 2, and the third roller 3 have the same gear structure.

The first driving mechanism 6 comprises a coupler and a motor, wherein the motor is connected with the first roller 1 through the coupler to drive the first roller 1 to rotate, so that the first conveying belt 4 rotates, and materials are conveyed to the second conveying belt 5. The second driving mechanism 7 is a hydraulic mechanism, and the structure thereof is the same as that of the prior art, and is not described again.

The first roller 1, the second roller 2 and the third roller 3 are parallel to each other, and an included angle a formed by a plane where the first roller 1 and the second roller 2 are located and a plane where the second roller 2 and the third roller 3 are located is 0-60 degrees. The third roller 3 is driven by the second driving mechanism 7 to ascend or descend so as to convey and place the materials on the row bar support 21 of the corresponding height. The plane of the first roller 1 and the second roller 2 is the plane of the first belt 4, and the plane of the first belt 4 is horizontal. The plane of the second roller 2 and the third roller 3 is the plane of the second belt 5. The third roller 3 is lifted, so that the plane of the second conveyer belt 5 and the plane of the first conveyer belt 4 are not on the same plane and form a certain included angle. The process of the third roller 3 rising is the process of the third roller 3 rotating around the second roller 2 under the traction of the second conveyer belt 5, and the rotation angle is 0-60 degrees. If the third roller bearing lifting is too high, the inclination of the plane where the second conveying belt is located is too large, the materials easily slide off, and potential safety hazards exist. Thus, the angle between the two planes is defined not to exceed 60 °.

Preferably, the present invention further comprises a support mechanism for supporting the transport mechanism, the support mechanism comprising a first support assembly for supporting the first roller 1, a second support assembly for supporting the second roller 2, a third support assembly for supporting the third roller 3 and a support frame 9 for supporting the first drive mechanism 6. The first supporting component, the second supporting component and the third supporting component are arranged in pairs and are respectively arranged at two ends of the first rolling shaft 1, the second rolling shaft 2 and the third rolling shaft 3.

The first support assembly comprises a first support rod 11 and a first bearing 12 arranged at the top end of the first support rod 11, and the first support rod 11 is movably connected with the first roller 1 through the first bearing 12; the second support assembly comprises a second support rod 14 and a second bearing 15 arranged at the top end of the second support rod 14, and the second support rod 14 is movably connected with the second roller 2 through the second bearing 15; the third supporting component comprises a third supporting rod 17 and a third bearing 18 arranged at the top end of the third supporting rod 17, and the third supporting rod 17 is movably connected with the third roller 3 through the third bearing 18. The resistance of the connection between the rolling shaft and the supporting rod can be reduced through the arrangement of the bearing, and the rotation of the rolling shaft is facilitated.

Preferably, the supporting mechanism further comprises a first cross bar 11a and a second cross bar 14a, the first cross bar 11a is fixedly connected with the first supporting bar 11 and the second supporting bar 14, respectively, and the second cross bar 14a is hinged with the second supporting bar 14 and the third supporting bar 17, respectively. The first cross bar 11a is vertically connected to the first support bar 11 and the second support bar 14, respectively. When the third roller 3 is in an initial state, that is, the first roller 1, the second roller 2 and the third roller 3 are in the same plane, the second cross bar 14a is vertically connected to the second support bar 14 and the third support bar 17. The arrangement of the first cross rod and the second cross rod enables the distance between the first supporting component and the second supporting component and the distance between the second supporting component and the third supporting component to be kept unchanged all the time, even if the transmission mechanism integrally moves or because the second driving mechanism enables the third roller to move, under the action of the first cross rod and the second cross rod, the distance between the first roller and the second roller and the distance between the second roller and the third roller are kept unchanged all the time, the first conveying belt and the second conveying belt are kept in a tightened state, and the normal operation of the transmission mechanism is guaranteed. When the third roller 3 is lifted, the third support bar 17 will move towards the second support bar 14 under the action of the second cross bar 14 a; when the third roller 3 descends, the third supporting rod 17 will move to the opposite direction of the second supporting rod 14 under the action of the second cross rod 14a, and the second conveyer belt is always kept in a tight state in the process.

Preferably, the present invention further comprises a moving assembly for moving the transmission mechanism, wherein the moving assembly comprises a guide rail 8 and a slider capable of sliding along the guide rail 8, and the slider comprises a first slider 13 arranged at the bottom end of the first support rod 11, a second slider 16 arranged at the bottom end of the second support rod 14, and a third slider 19 arranged at the bottom of the second driving mechanism 7. The invention can realize the whole or partial movement of the transmission mechanism through the moving assembly, and can move to different positions to arrange materials on different discharge rods. The arrangement of the guide rail ensures that the transmission mechanism always keeps linear movement, and the normal operation of the transmission mechanism is ensured.

Preferably, the first sliding block 13, the second sliding block 16 and the third sliding block 19 are provided with a first pulley 13a, and the supporting frame 9 is provided with a second pulley 10. The arrangement of the first pulley and the second pulley enables the transmission mechanism to move smoothly, reduces resistance and ensures normal operation of the transmission mechanism.

Preferably, the invention also comprises traction means (not shown) for driving the transfer means to slide along the guide 8. The traction mechanism provides power for the transmission mechanism, so that the transmission mechanism can slide along the guide rail, automatic production is realized, labor intensity is reduced, and potential safety hazards are reduced. According to the invention, the outer wall of the first conveyor belt 4 is preferably provided with a scale (not shown). Because the section sizes of the aluminum profiles are different, in order to ensure that the aluminum profiles can be accurately conveyed to the supports of the row rods through the transmission mechanism, the aluminum profiles with different section sizes are generally divided into three types according to the size, the size and the size, the row rods with different intervals of the three types of row rod supports are arranged, and the support and the placement of all the different types of the aluminum profiles can be met. The outer wall of conveyer belt is equipped with the scale, can arrange the emission position of aluminium alloy on transmission device according to row's pole support interval.

As shown in figure 3, the arrangement schematic diagram of the aluminum profiles on the row rods is that the aluminum profiles are conveyed to the supports of the row rods through the transmission mechanism to be supported, and then are fixed on the row rods through a clamp in a manual mode so as to prevent the aluminum profiles from sliding to the bottoms of the front treatment tanks.

Preferably, the outer wall of the second conveyor belt 5 is provided with an anti-slip member 23, and in order to prevent the aluminum profile from slipping off when the third roller rises, the surface of the second conveyor belt is specially treated to increase the surface friction. The anti-slip members 23 are formed by upwardly protruding conveyor belt surfaces. Furthermore, two adjacent anti-skid members may be arranged at a specific distance, for example: 10 cm, the arrangement of a scale can be omitted.

Preferably, the outer walls of the first conveyor belt 4 and the second conveyor belt 5 are provided with anti-slip means 23.

The transmission mechanism adopts a PLC controller to control the first driving mechanism and the second driving mechanism so as to achieve the purpose of cooperatively controlling the transmission speed and the rising speed of the third roller, and the aluminum profile can smoothly fall onto the row rod support when the highest point of the third roller is just aligned with the row rod support.

Preferably, the third support assembly is provided with a distance sensor 22. Specifically, as shown in fig. 5, a distance sensor 22 is disposed on a side of an outer wall of the third bearing 18 facing the gang bar support 21. The distance sensor can accurately detect the distance between the third roller 3 and the row rod support 21, when the third roller 3 ascends or descends, the distance sensor 22 sends a signal to the PLC controller when detecting that the distance between the third roller and the row rod support 21 is the shortest, the controller controls the second driving mechanism 7 to stop operating, and controls the first driving mechanism 6 to operate, so that the first roller 1 rotates, and the section bar falls onto the row rod support 21. The arrangement of the distance sensor ensures that the section bar can accurately fall on the row rod bracket.

The implementation of the invention has the following beneficial effects:

In summary, the invention provides an upper discharging device, which realizes automatic upper discharging, reduces labor intensity and improves production efficiency.

While the foregoing is directed to the preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention.

Claims

1. An upper-row device is characterized by comprising a transmission mechanism, wherein the transmission mechanism comprises a transmission mechanism and an upper-row mechanism, the transmission mechanism comprises a first rolling shaft, a second rolling shaft, a first conveying belt and a first driving mechanism connected with the first rolling shaft, the first conveying belt is sleeved outside the first rolling shaft and the second rolling shaft, the first rolling shaft is connected with the second rolling shaft through the first conveying belt, and the first driving mechanism is used for driving the first rolling shaft to rotate and driving the second rolling shaft to rotate through the first conveying belt;

2. The upper tier device of claim 1 wherein the first roller and the second roller are engaged with the first web by gear hobbing and the second roller and the third roller are engaged with the second web by gear hobbing.

3. The upper tier device as recited in claim 1 further comprising a support mechanism for supporting the transport mechanism, the support mechanism including a first support assembly for supporting the first roller, a second support assembly for supporting the second roller, a third support assembly for supporting the third roller, and a support bracket for supporting the first drive mechanism.

4. The upper tier device of claim 3, wherein the first support assembly includes a first support rod and a first bearing disposed at a top end of the first support rod, the first support rod being movably coupled to the first roller via the first bearing;

5. The upper array of claim 4 wherein the support mechanism further comprises a first cross bar and a second cross bar, the first cross bar being fixedly attached to the first support bar and the second support bar, respectively, and the second cross bar being hingedly attached to the second support bar and the third support bar, respectively.

6. The upper tier device as claimed in claim 4, further comprising a moving assembly for moving the transport mechanism, the moving assembly including a guide rail and a slider capable of sliding along the guide rail, the slider including a first slider provided at a bottom end of the first support rod, a second slider provided at a bottom end of the second support rod, and a third slider provided at a bottom end of the second driving mechanism.

7. The upper tier device of claim 6, wherein the first slider, the second slider, and the third slider are provided with a first pulley and the support frame is provided with a second pulley.

8. Upper row arrangement according to any of claims 3 to 7, wherein the third support member is provided with a distance sensor.

9. The upper tier device of claim 1 wherein the first roller, the second roller and the third roller are parallel to one another, and the first roller and the second roller are in a plane that forms an angle of 0 ° to 60 ° with the plane of the second roller and the third roller.

10. The upper tier device as set forth in claim 1, wherein the outer wall of the second conveyor belt is provided with a slip prevention member.