CN214054353U - Automatic beam machining assembly line - Google Patents

Abstract

The utility model discloses an automatic processing assembly line of roof beam, include: the processing detection platform is provided with a first inductor; the feeding device is arranged at one end of the processing detection platform and is used for conveying the beam to pass through the processing detection platform; the multi-axis drilling machine is arranged on one side of the machining detection platform and is used for drilling the beam passing through the machining detection platform; and the sawing machine is arranged at the other end of the processing detection platform and is used for cutting the beam passing through the processing detection platform. The utility model discloses a roof beam on the first inductor response material feeding unit on the processing testing platform realizes the automatic drilling and the cutting of this roof beam, and labour saving and time saving has improved production efficiency, has reduced manufacturing cost.

Description

Automatic beam machining assembly line

Technical Field

The utility model relates to an automatic door roof beam machining production line's technical field especially relates to an automatic assembly line of processing of roof beam.

Background

In the prior art, the cutting and the drilling of automatically-controlled door roof beam are separately processed, carry the roof beam to the processing bench of saw cutting machine earlier, cut according to the size as required, pass through manual operation to the roof beam after the cutting again and shift, and the material loading is drilled to the processing bench of drilling machine, and the size position in hole as required is drilled, because separately processing and manual operation's loaded down with trivial details process for operating personnel intensity of labour is big, wastes time and energy, has reduced production efficiency, and manufacturing cost is higher.

Disclosure of Invention

Aiming at the above problems of the existing beam processing equipment, the beam automatic processing assembly line is provided, the beam on the feeding device is sensed by the first sensor on the processing detection platform, the automatic drilling and cutting of the beam are realized, the time and the labor are saved, the production efficiency is improved, and the production cost is reduced.

The specific technical scheme is as follows:

an automated beam processing line, comprising:

the processing detection platform is provided with a first inductor;

the feeding device is arranged at one end of the processing detection platform and is used for conveying the beam to pass through the processing detection platform;

the multi-axis drilling machine is arranged on one side of the machining detection platform and is used for drilling the beam passing through the machining detection platform;

and the sawing machine is arranged at the other end of the processing detection platform and is used for cutting the beam passing through the processing detection platform.

The automatic beam machining assembly line comprises:

the feeding frame is arranged at one end of the processing detection platform;

the first feeding mechanism is arranged on one side of the feeding frame and used for conveying the beam along the length direction of the feeding frame and penetrating through the processing and detecting platform.

The automatic beam machining assembly line comprises a feeding device and a discharging device, wherein the feeding device further comprises: and the second feeding mechanism is arranged on the feeding frame and used for conveying the beam to one side of the feeding frame along the width direction of the feeding frame.

The automatic beam machining assembly line comprises the following components:

the plurality of rollers are sequentially and rotatably arranged on one side of the feeding frame along the length direction of the feeding frame;

the tensioning cylinders are sequentially arranged on one side of the feeding frame along the length direction of the feeding frame;

the feeding assembly is movably arranged on one side of the feeding frame and used for conveying one beam on one side of the feeding frame to pass through the processing and detecting platform.

In the automatic beam processing assembly line, a conveying frame is arranged on one side of the feeding frame, the conveying frame is arranged along the length direction of the feeding frame, the rollers are respectively rotatably arranged on one side of the conveying frame, the tensioning cylinders are respectively arranged on one side of the conveying frame, and the feeding assembly is movably connected with the conveying frame along the length direction of the conveying frame.

The automatic beam machining assembly line comprises:

the driving piece is arranged on the conveying frame;

the finger cylinder is in transmission connection with the driving part and used for clamping the beam on one side of the feeding frame, and the driving part is used for driving the finger cylinder and conveying the beam to pass through the processing detection platform.

In the automatic beam processing line, one side of the conveying frame is provided with a plurality of datum backer.

In the automatic beam processing line, the second inductor is arranged on one side of the feeding frame.

In the automatic beam processing line, the driving piece is provided with a third inductor and a fourth inductor.

The automatic beam machining assembly line comprises a first feeding mechanism and a second feeding mechanism, wherein the first feeding mechanism comprises:

the first motor is arranged on the other side of the feeding frame;

the first driving wheel is in transmission connection with the first motor;

the belt conveyor components are arranged on the feeding frame, each belt conveyor component is arranged along the width direction of the feeding frame, the belt conveyor components are distributed in sequence along the length direction of the feeding frame respectively, and the first driving wheel is in transmission connection with the belt conveyor components through a belt.

Compared with the prior art, the technical scheme has the positive effects that:

the utility model discloses a material feeding unit is used for carrying the roof beam and passes processing testing platform, responds to material feeding unit through the first inductor on the processing testing platform and carries the roof beam to processing testing platform on, and system's automatic calculation length, multiaxis drilling machine and saw cutter read system parameter size, whether start according to system's processing parameter, accomplish until processing cutting drilling. The utility model discloses realize the automatic drilling and the cutting of this roof beam, labour saving and time saving has improved production efficiency, has reduced manufacturing cost.

Drawings

Fig. 1 is a top view of an automated beam processing line of the present invention;

fig. 2 is an enlarged view of a portion a in fig. 1 of the automated beam processing line of the present invention;

fig. 3 is a side view of an automated beam processing line of the present invention;

fig. 4 is an enlarged view of a portion B of the automated beam processing line of the present invention shown in fig. 3;

in the drawings: 1. processing the detection platform; 2. a feeding device; 3. a multi-axis drilling machine; 4. sawing and cutting machine; 5. A first feeding mechanism; 6. a second feeding mechanism; 7. a feeding assembly; 11. a first inductor; 12. a second inductor; 13. a third inductor; 14. a fourth inductor; 21. a feeding frame; 22. a carriage; 23. A reference backer; 51. a drum; 52. tensioning the cylinder; 53. a lifting cylinder; 61. a first motor; 62. A first drive wheel; 63. a belt transport assembly; 64. a belt; 7. a feeding assembly; 71. a drive member; 72. finger cylinder.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and specific embodiments, but the present invention is not limited thereto.

Fig. 1 is the utility model relates to a top view of automatic assembly line of processing of roof beam, fig. 2 is the utility model relates to an A department's enlargements in the figure 1 of automatic assembly line of processing of roof beam, fig. 3 is the utility model relates to an automatic assembly line of processing of roof beam's side view, fig. 4 is the utility model relates to an automatic assembly line of processing of roof beam's B department's enlargements in fig. 3, as shown in fig. 1 to fig. 4, the automatic assembly line of processing of roof beam of a preferred embodiment is shown, include: processing testing platform 1, material feeding unit 2, multi-axis drilling machine 3 and saw cutter 4, be equipped with first inductor 11 on the processing testing platform 1, material feeding unit 2 locates the one end of processing testing platform 1, material feeding unit 2 is used for carrying the roof beam and passes processing testing platform 1, one side of processing testing platform 1 is located to multi-axis drilling machine 3, multi-axis drilling machine 3 is used for holing the roof beam that passes processing testing platform 1, the other end of processing testing platform 1 is located to saw cutter 4, saw cutter 4 is used for cutting the roof beam that passes processing testing platform 1.

Preferably, the beam is conveyed to the processing detection platform 1 through the positions of the multi-axis drilling machine 3 and the sawing machine 4 in an induction mode through the first sensor 11, the length of the system is automatically calculated through signal connection of the first sensor 11 and the system, the parameter size of the system is read through the multi-axis drilling machine 3 and the sawing machine 4, whether the system is started according to the processing parameters of the system is judged, and the beam is firstly drilled or cut through the system until the processing is finished.

Further, as a preferred embodiment, the feeding device 2 includes: the feeding frame 21 is arranged at one end of the processing and detecting platform 1, the first feeding mechanism 5 is arranged at one side of the feeding frame 21, and the first feeding mechanism 5 is used for conveying the beam along the length direction of the feeding frame 21 and penetrating through the processing and detecting platform 1.

Further, as a preferred embodiment, the feeding device 2 further includes: and the second feeding mechanism 6 is arranged on the feeding frame 21, and the second feeding mechanism 6 is used for conveying the beam to one side of the feeding frame 21 along the width direction of the feeding frame 21.

The above is merely an example of the preferred embodiments of the present invention, and the embodiments and the protection scope of the present invention are not limited thereby.

The utility model discloses still have following embodiment on above-mentioned basis:

in a further embodiment of the present invention, please continue to refer to fig. 1 to 4, the first feeding mechanism 5 includes: the automatic feeding device comprises a plurality of rollers 51, a plurality of tensioning cylinders 52 and a feeding assembly 7, wherein the rollers 51 are sequentially and rotatably arranged on one side of the feeding frame 21 along the length direction of the feeding frame 21, the tensioning cylinders 52 are sequentially arranged on one side of the feeding frame 21 along the length direction of the feeding frame 21, the feeding assembly 7 is movably arranged on one side of the feeding frame 21, and the feeding assembly 7 is used for conveying a beam on one side of the feeding frame 21 and penetrating through the processing detection platform 1.

The utility model discloses a in the further embodiment, one side of going up work or material rest 21 is equipped with carriage 22, and carriage 22 sets up along the length direction of going up work or material rest 21, and a plurality of cylinders 51 rotate one side of locating carriage 22 respectively, and one side of carriage 22 is located respectively to a plurality of taut cylinders 52, and pay-off subassembly 7 is along the length direction and carriage 22 swing joint of carriage 22.

Preferably, two adjacent rollers 51 are equally spaced and two adjacent tensioning cylinders 52 are equally spaced.

Preferably, the beam is in rolling fit with the roller 51 to reduce friction force during the transportation of the beam to the processing and detecting platform 1.

In a further embodiment of the present invention, the feeding assembly 7 comprises: the driving part 71 is arranged on the conveying frame 22, the finger cylinder 72 is in transmission connection with the driving part 71, the finger cylinder 72 is used for clamping the beam on one side of the feeding frame 21, and the driving part 71 is used for driving the finger cylinder 72 and conveying the beam to pass through the processing detection platform 1.

In a further embodiment of the present invention, one side of the carriage 22 is provided with a plurality of reference buttresses 23. Preferably, when the plurality of belt conveyor assemblies 63 convey the beam, one beam is conveyed onto the plurality of rollers 51, and the plurality of tensioning cylinders 52 and the reference backer 23 clamp the one beam.

Preferably, the plurality of reference backer 23 are arranged at equal intervals along the length direction of the feeding frame 21.

In a further embodiment of the present invention, the first feeding mechanism 5 further includes: a plurality of lifting cylinders 53, and a plurality of lifting cylinders 53 are provided at one side of the carrier 22. Preferably, a plurality of lifting cylinders 53 lift the beam on the plurality of rollers 51.

In a further embodiment of the present invention, one side of the feeding frame 21 is provided with a second sensor 12.

Preferably, the second sensor 12 senses a beam and transmits a signal to the system, which controls the feeding assembly 7 to feed the beam to the processing and inspection platform 1.

In a further embodiment of the present invention, a third sensor 13 and a fourth sensor 14 are disposed on the driving member 71.

Preferably, after the second sensor 12 senses the beam, the third sensor 13 senses that the material is placed at the corresponding position, the system drives the finger cylinder 72 to clamp the beam, and after the fourth sensor 14 senses that the finger cylinder 72 clamps the beam, the system controls the driving part 71 to decelerate and feed the material.

Preferably, the driving member 71 may be a driving mechanism such as a drag chain, a worm gear, a ball screw, etc.

In a further embodiment of the present invention, the second feeding mechanism 6 includes: first motor 61, first action wheel 62 and a plurality of belt conveyor components 63, the opposite side of material loading frame 32 is located to first motor 61, first motor 61 is connected with the transmission of first action wheel 62, each belt conveyor component 63 is located on the material loading frame 21, and each belt conveyor component 63 all sets up along the width direction of material loading frame 21, a plurality of belt conveyor components 63 distribute in proper order along the length direction of material loading frame 21 respectively, first action wheel 62 passes through belt 64 and is connected with a plurality of belt conveyor components 63 transmission respectively.

Preferably, each belt conveyor assembly 63 comprises: the drive wheel, from the driving wheel and respectively with the drive wheel, from the conveyer belt that driving wheel transmission is connected, and the drive wheel through a plurality of belt conveyor components 63 passes through first connecting axle coaxial coupling, a plurality of belt conveyor components 63 pass through second connecting axle coaxial coupling from the driving wheel, a plurality of coaxial rotations of drive wheel, a plurality of coaxial rotations from the driving wheel, and first action wheel 62 is connected with first connecting axle transmission through the belt, realize a plurality of belt conveyor components 63 through first motor 61 and carry the roof beam.

The utility model discloses earlier carry a plurality of roof beams through a plurality of belt conveyor components 63 to carry the roof beam of foremost side to a plurality of cylinders 51 on, through the cooperation of a plurality of taut cylinders 52 and a plurality of benchmark backer 23, press from both sides this roof beam tightly, through lifting cylinder 53 with this roof beam lifting, rethread finger cylinder 72 presss from both sides tight this roof beam, this roof beam of driving piece 71 drive is carried to processing testing platform 1 on, is responded to by first inductor 11, accomplishes drilling and cutting at last.

The utility model discloses realize the automatic drilling and the cutting of this roof beam, labour saving and time saving has improved production efficiency, has reduced manufacturing cost.

The above description is only an example of the preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and those skilled in the art should be able to realize the equivalent alternatives and obvious variations of the present invention.

Claims (10)

1. The utility model provides an automatic assembly line that processes of roof beam which characterized in that includes:

the processing detection platform is provided with a first inductor;

the feeding device is arranged at one end of the processing detection platform and is used for conveying the beam to pass through the processing detection platform;

the multi-axis drilling machine is arranged on one side of the machining detection platform and is used for drilling the beam passing through the machining detection platform;

and the sawing machine is arranged at the other end of the processing detection platform and is used for cutting the beam passing through the processing detection platform.

2. The automated beam processing line of claim 1, wherein the feeder device comprises:

the feeding frame is arranged at one end of the processing detection platform;

the first feeding mechanism is arranged on one side of the feeding frame and used for conveying the beam along the length direction of the feeding frame and penetrating through the processing and detecting platform.

3. The automated beam processing line of claim 2, wherein the feeder device further comprises: and the second feeding mechanism is arranged on the feeding frame and used for conveying the beam to one side of the feeding frame along the width direction of the feeding frame.

4. The automated beam processing line of claim 2, wherein the first feed mechanism comprises:

the plurality of rollers are sequentially and rotatably arranged on one side of the feeding frame along the length direction of the feeding frame;

the tensioning cylinders are sequentially arranged on one side of the feeding frame along the length direction of the feeding frame;

the feeding assembly is movably arranged on one side of the feeding frame and used for conveying one beam on one side of the feeding frame to pass through the processing and detecting platform.

5. The automated beam processing line of claim 4, wherein a conveyor is disposed on one side of the loading frame, the conveyor is disposed along a length direction of the loading frame, the rollers are rotatably disposed on one side of the conveyor, the tensioning cylinders are rotatably disposed on one side of the conveyor, and the feeding assembly is movably connected to the conveyor along a length direction of the conveyor.

6. The automated beam processing line of claim 5, wherein the feed assembly comprises:

the driving piece is arranged on the conveying frame;

the finger cylinder is in transmission connection with the driving part and used for clamping the beam on one side of the feeding frame, and the driving part is used for driving the finger cylinder and conveying the beam to pass through the processing detection platform.

7. The automated beam processing line of claim 5, wherein the carriage is provided with a plurality of datum abutments on one side.

8. The automated beam processing line of claim 2, wherein a second sensor is disposed on one side of the loading frame.

9. The automated beam processing line of claim 6, wherein the drive member includes a third sensor and a fourth sensor.

10. The automated beam processing line of claim 3, wherein the second feed mechanism comprises:

the first motor is arranged on the other side of the feeding frame;

the first driving wheel is in transmission connection with the first motor;

the belt conveyor components are arranged on the feeding frame, each belt conveyor component is arranged along the width direction of the feeding frame, the belt conveyor components are distributed in sequence along the length direction of the feeding frame respectively, and the first driving wheel is in transmission connection with the belt conveyor components through a belt.

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