CN220282751U - Automatic stainless steel bridge frame production line - Google Patents

Abstract

The utility model discloses an automatic stainless steel bridge production line, and particularly relates to the field of automatic production lines. According to the utility model, the formed bridge can be supported through each rolling assembly, friction is avoided between the bridge and the material receiving table, so that the output of the bridge is smoother, the bridge is prevented from deforming in the output process, the pressure sensor is pressed by the bridge, and the bridge on the material receiving table is pushed onto the material placing table by the pushing mechanism, so that automatic material receiving and discharging are realized, cutting caused by manual material receiving is avoided, and the working efficiency of integral processing is improved.

Description

Automatic stainless steel bridge frame production line

Technical Field

The utility model relates to the technical field of automatic production lines, in particular to an automatic stainless steel bridge frame production line.

Background

The cable bridge is formed by directly shearing, punching and bending a steel plate into a plurality of parts in advance, and then combining and welding the parts. Conventional cable bridge frames generally comprise two molding modes of welding molding and bending integrated molding.

However, the existing bridge frame needs to be manually connected after being output by bending forming, and needs to be manually placed after being connected, so that when workers are easy to connect materials, the edges of the bridge frame are easy to scratch hands of the workers, meanwhile, when materials are placed, the labor intensity of the workers is improved, the bridge frame connecting and connecting performance of the next batch of bridge frames is poor, other deformation is easily caused by bending of the formed bridge frames due to self gravity and extrusion of equipment, and products are unqualified, and therefore, an automatic stainless steel bridge frame production line is proposed.

Disclosure of Invention

The technical scheme of the utility model aims at solving the technical problem of overlarge singleness in the prior art and provides a solution which is obviously different from the prior art. In order to overcome the above-mentioned drawbacks of the prior art, the present utility model provides an automated stainless steel bridge production line to solve the above-mentioned problems set forth in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: automatic change stainless steel bridge production line, including receiving the material platform, install multiunit rolling element on receiving the material platform, connect material platform one end to install the backup pad, install pressure sensor in the backup pad, it is provided with the brace table to connect material platform one side, install pushing mechanism on the brace table, it is provided with pendulum material platform to connect material platform opposite side, pendulum material platform bottom support has four electric telescopic handle of group, each electric telescopic handle bottom is connected with the bottom plate jointly, bend the shaping through the bender and carry out slow output, make fashioned crane span structure one end slowly be in and connect material platform top, the rolling element with the bottom links up, the friction that the rotary drum receives the release of crane span structure and rotates along with going on, the crane span structure slowly wholly all moves to receiving the material bench, receive inertial influence, make crane span structure one end top connect on pressure sensor, make the hydraulic pump move, the hydraulic rod extends, promote the push pedal, thereby make the crane span structure on receiving the material bench is pushed to pendulum material bench, four groups electric telescopic handle shrink to a take a altitude in step, then keep away from two electric telescopic handle of receiving the material platform shrink once more, make the crane span structure slope, thereby make the crane span structure from pendulum material bench to put and slide to ground.

Preferably, the material receiving table is provided with a mounting groove, each rolling assembly is uniformly mounted in the mounting groove, and each rolling assembly is sequentially connected and matched.

Preferably, four groups of connecting frames are symmetrically welded at the bottom of the material placing table, each connecting frame is connected with the top end of the corresponding electric telescopic rod, and a shaft rod is inserted between the connecting frame and the electric telescopic rod.

Preferably, the material arranging table, the four groups of electric telescopic rods, the four groups of connecting frames, the four groups of shaft rods and the bottom plate form a material arranging mechanism, and the top end of the material arranging mechanism is flush with the top of the material receiving table.

Preferably, the rolling assembly comprises a supporting rod, and two ends of the supporting rod are connected with inner walls on two sides of the mounting groove.

The rotary drums are sleeved and mounted on the supporting rods, and the tops of the rotary drums are connected to form the height of the material receiving table at the position of the supporting surface.

Preferably, the pushing mechanism comprises a hydraulic pump, the hydraulic pump is arranged on the supporting table, and the hydraulic pump is electrically connected with the pressure sensor.

And one end of the hydraulic rod is connected with the hydraulic pump.

The push plate is arranged at the other end of the hydraulic rod, and the bottom end of the push plate is higher than the height of the position where the supporting surface formed by connecting the tops of the rotary drums is located.

Preferably, the shaft is perpendicular to the support bar, while the support bar is parallel to the hydraulic bar.

The utility model has the technical effects and advantages that:

1. through setting up bracing piece, rotary drum, pressure sensor, hydraulic pump, hydraulic pressure pole and push pedal, compare with prior art, can connect the bridging of shaping automatically, and can reduce the friction that produces between bridge and the material receiving platform of taking the in-process, thereby avoid the bridge to produce crookedly, simultaneously, can utilize pressure sensor to respond to the input of bridge voluntarily, make pushing mechanism automatic with the bridge on the material receiving platform pass to the pendulum material bench, realize automatic material receiving, avoid the manual work to connect the material to cause the cutting wound, simultaneously, reduce workman's labour's use, improve the work efficiency of whole processing;

2. through setting up of pendulum material platform, electric telescopic handle, link and axostylus axostyle, compare with prior art, can be automatically put the crane span structure that pendulum material bench supported subaerial, realize automatic unloading, and put automatically, need not artificial use, reduce the recruitment person.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is a schematic structural view of a rolling assembly according to the present utility model.

Fig. 3 is a schematic structural view of the pushing mechanism of the present utility model.

Fig. 4 is a schematic structural view of a material arranging mechanism of the present utility model.

The reference numerals are: 1. a receiving table; 2. a rolling assembly; 201. a support rod; 202. a rotating drum; 3. a support plate; 4. a pressure sensor; 5. a support table; 6. a pushing mechanism; 601. a hydraulic pump; 602. a hydraulic rod; 603. a push plate; 7. a material placing table; 8. an electric telescopic rod; 9. a bottom plate; 10. a connecting frame; 11. and a shaft lever.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The automatic stainless steel bridge production line shown in fig. 1-4 comprises a material receiving table 1, a plurality of groups of rolling assemblies 2 are installed on the material receiving table 1, a supporting plate 3 is installed at one end of the material receiving table 1, a pressure sensor 4 is installed on the supporting plate 3, a supporting table 5 is arranged on one side of the material receiving table 1, a pushing mechanism 6 is installed on the supporting table 5, a material placing table 7 is arranged on the other side of the material receiving table 1, four groups of electric telescopic rods 8 are supported at the bottom end of the material placing table 7, a bottom plate 9 is jointly connected to the bottom end of each electric telescopic rod 8, a bridge frame is subjected to bending forming through a bending machine to be slowly output, one end of the formed bridge frame is slowly located at the top of the material receiving table 1 and is connected with the rolling assemblies 2 at the bottom, the rotating drum 202 is subjected to friction generated by pushing of the bridge frame, the bridge frame slowly integrally moves to the material receiving table 1 and is influenced by inertia, one end of the bridge frame is propped against the pressure sensor 4 to operate, a hydraulic rod 601 is stretched, a push plate 603 is pushed to enable the bridge frame 1 to be pushed onto the material placing table 7, four groups of electric telescopic rods 8 are synchronously contracted to be located at the height of the electric telescopic rods 8, and then the two electric telescopic rods are inclined to enable the bridge frames 7 to slide down from the ground, and the bridge frame 7 is placed on the ground, and the bridge frames are contracted.

As shown in fig. 1, the material receiving table 1 is provided with a mounting groove, each rolling assembly 2 is uniformly mounted in the mounting groove, and each rolling assembly 2 is sequentially engaged and matched, so that the rolling assemblies 2 are mounted, and the top ends of the rolling assemblies 2 are slightly higher than the material receiving table 1, so that the bridge frame is supported and engaged.

As shown in fig. 4, four groups of connecting frames 10 are symmetrically welded at the bottom of the material placing table 7, each connecting frame 10 is connected with the top end of the corresponding electric telescopic rod 8, and a shaft rod 11 is inserted between the connecting frame 10 and the electric telescopic rod 8.

As shown in fig. 1, the material placing table 7, the four groups of electric telescopic rods 8, the four groups of connecting frames 10, the four groups of shaft rods 11 and the bottom plate 9 form a material placing mechanism, and the top end of the material placing mechanism is flush with the top of the material receiving table 1, so that the bridge can be automatically pushed onto the material placing table 7 under the action of the pushing mechanism 6, and the bridge can be smoother in the moving process.

As shown in fig. 2, the rolling assembly 2 comprises a supporting rod 201, and two ends of the supporting rod 201 are connected with two inner walls of the two sides of the installation groove.

The rotary drums 202, the rotary drums 202 are sleeved on the supporting rods 201, and the tops of the rotary drums 202 are connected to form a supporting surface, and the supporting surface is located at the height of the material receiving table 1.

As shown in fig. 3, the pushing mechanism 6 includes a hydraulic pump 601, where the hydraulic pump 601 is mounted on the support stand 5, and the hydraulic pump 601 is electrically connected with the pressure sensor 4, so that when the pressure sensor 4 receives pressure, a signal can be fed back, so that the hydraulic pump 601 operates, and the pressure sensor 4 can be matched with the hydraulic pump 601.

And a hydraulic rod 602, wherein one end of the hydraulic rod 602 is connected with the hydraulic pump 601.

The push plate 603, the push plate 603 is installed at the other end of the hydraulic rod 602, and the bottom end of the push plate 603 is higher than the height of the supporting surface formed by connecting the tops of the drums 202.

As shown in fig. 1, the shaft 11 is perpendicular to the supporting rod 201, and the supporting rod 201 is parallel to the hydraulic rod 602, so as to adjust the tilting direction of the material placing table 7, so that when the material placing table 7 tilts, the bridge frame can slide down towards one side of the material placing table 7.

The working principle of the utility model is as follows: when the bridge frame is utilized to carry out material receiving in the bridge frame production line, the bending machine bends and shapes the bridge frame to carry out slow output, so that one end of the formed bridge frame is slowly positioned at the top of the material receiving table 1 and is connected with the rolling assembly 2 at the bottom, the rotating drum 202 is subjected to friction generated by pushing out of the bridge frame and rotates along with the material receiving table 1, the bridge frame slowly and integrally moves onto the material receiving table 1 and is influenced by inertia, one end of the bridge frame is propped against the pressure sensor 4, the hydraulic pump 601 runs, the hydraulic rod 602 stretches to push the push plate 603, the bridge frame on the material receiving table 1 is pushed onto the material placing table 7, the four groups of electric telescopic rods 8 synchronously shrink to a certain height, and then the two electric telescopic rods 8 far away from the material receiving table 1 shrink again, so that the material placing table 7 tilts, and the bridge frame slides from the material placing table 7 to the ground for placement.

According to the utility model, the formed bridge can be supported through each rolling assembly 2, friction is avoided between the bridge and the material receiving table 1, so that the output of the bridge is smoother, deformation of the bridge is prevented in the output process, the pressure sensor 4 is used for receiving the pressure of the bridge, the pushing mechanism 6 can push the bridge on the material receiving table 1 onto the material placing table 7, so that automatic material receiving and discharging are realized, meanwhile, each electric telescopic rod 8 at the bottom of the material placing table 7 is matched with each other, one side of the bridge placed on the material placing table 7 is placed, automatic material discharging and placing are realized, automation of receiving the bridge is realized, cutting caused by manual material receiving is avoided, meanwhile, the use of labor force of workers is reduced, and the working efficiency of integral processing is improved.

The foregoing description of the preferred embodiments of the utility model is not intended to limit the utility model to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and principles of the utility model are intended to be included within the scope of the utility model.

Claims (7)

1. Automatic change stainless steel bridge frame production line, including receiving material platform (1), its characterized in that: connect install multiunit rolling element (2) on material platform (1), connect material platform (1) one end to install backup pad (3), install pressure sensor (4) on backup pad (3), connect material platform (1) one side to be provided with supporting bench (5), install on supporting bench (5) and push mechanism (6), connect material platform (1) opposite side to be provided with pendulum material platform (7), pendulum material platform (7) bottom support has four sets of electric telescopic handle (8), each electric telescopic handle (8) bottom is connected with bottom plate (9) jointly.

2. The automated stainless steel bridge production line of claim 1, wherein: the material receiving table (1) is provided with a mounting groove, each rolling assembly (2) is uniformly mounted in the mounting groove, and each rolling assembly (2) is sequentially connected and matched.

3. The automated stainless steel bridge production line of claim 1, wherein: four groups of connecting frames (10) are symmetrically welded at the bottom of the material placing table (7), each connecting frame (10) is connected with the top end of the corresponding electric telescopic rod (8), and a shaft rod (11) is inserted between the connecting frame (10) and the electric telescopic rod (8).

4. An automated stainless steel bridge production line according to claim 3, characterized in that: the material placing device comprises a material placing table (7), four groups of electric telescopic rods (8), four groups of connecting frames (10), four groups of shaft rods (11) and a bottom plate (9), wherein the top end of the material placing mechanism is flush with the top of the material receiving table (1).

5. The automated stainless steel bridge production line of claim 1, wherein: the rolling assembly (2) comprises a supporting rod (201), and two ends of the supporting rod (201) are connected with inner walls at two sides of the mounting groove;

the rotary drums (202), the rotary drums (202) are sleeved and mounted on the supporting rods (201), and the tops of the rotary drums (202) are connected to form the height of the material receiving table (1) at the position of the supporting surface.

6. The automated stainless steel bridge production line of claim 1, wherein: the pushing mechanism (6) comprises a hydraulic pump (601), the hydraulic pump (601) is arranged on the supporting table (5), and the hydraulic pump (601) is electrically connected with the pressure sensor (4);

a hydraulic rod (602), wherein one end of the hydraulic rod (602) is connected with a hydraulic pump (601);

the push plate (603), push plate (603) are installed at the other end of hydraulic stem (602), and push plate (603) bottom is higher than the position height that each rotary drum (202) top is connected the bearing surface that forms and is located.

7. An automated stainless steel bridge production line according to claim 3, characterized in that: the shaft lever (11) is vertical to the supporting rod (201), and the supporting rod (201) is parallel to the hydraulic rod (602).