CN108857424B

CN108857424B - Automatic processing device for marine floor buckle chassis

Info

Publication number: CN108857424B
Application number: CN201810741222.7A
Authority: CN
Inventors: 张健
Original assignee: Individual
Current assignee: Shu Ting
Priority date: 2018-07-08
Filing date: 2018-07-08
Publication date: 2020-09-01
Anticipated expiration: 2038-07-08
Also published as: CN108857424A

Abstract

The invention relates to the technical field of machining of ship floor buckles, in particular to an automatic machining device for a ship floor buckle bottom plate, which comprises a workbench, a conveying device, a workpiece positioning device, a bottom plate feeding device, a slotting device and a hole opening device, wherein the workpiece positioning device comprises a positioning component and a control component, the bottom plate feeding device comprises a feeding component and a feeding component, the slotting device comprises a driving component and a slotting component, and the hole opening device comprises a supporting component and a hole opening component. Therefore, the whole processing flow is an automatic flow, the production efficiency is greatly improved, and the human resources are reduced.

Description

Automatic processing device for marine floor buckle chassis

Technical Field

The invention relates to the technical field of machining of ship floor buckles, in particular to an automatic machining device for a bottom plate of a ship floor buckle.

Background

The boat generally involves the storage of items and the like, and thus the floor buckle is an indispensable item for the boat or yacht.

The existing floor installation generally adopts two methods of a flat buckle and a lock catch, the floor is fixed on a floor ridge or is tiled on the ground, the floor can be fastened only by translating in the installation method of the flat buckle or the lock catch, the floor is installed along one direction in sequence, and the installation is inconvenient; when the floor paved by the flat buckles or the lock catches needs to be additionally arranged or maintained on the under-floor pipelines or needs to be maintained on partial floors, the floors are required to be completely assembled, partial moving and assembling cannot be realized, time and labor are wasted, and the cost is high.

Chinese patent publication No.: CN 105649298A; the publication date is as follows: 2016.06.08 discloses a floor fastener, wherein a clamp spring on the fastener can be directly matched with a buckle arranged at the bottom of a floor, a bulge arranged on the clamp spring can effectively clamp a floor groove, and the floor can be locally moved only by moving in the vertical direction during installation and removal; the cavity that fastener main part and two jump rings formed can conveniently be used for the installation of pipelines such as electric wire, water pipe, and the processing method of this fastener has not realized full automatic processing yet, consequently needs a section can automatic processing, batch production's machine.

Disclosure of Invention

The invention aims to provide an automatic processing device of a marine floor buckle chassis, aiming at the defects of the prior art.

In order to solve the above problems, the present invention provides the following technical solutions: an automatic processing device for a marine floor buckle chassis comprises a workbench, a conveying device arranged at the top of the workbench, a workpiece positioning device arranged at the top of the workbench, a chassis feeding device arranged at the top of the workbench, a slotting device arranged at the top of the workbench and a hole opening device arranged at the top of the workbench, wherein the conveying device comprises a conveying assembly, the conveying assembly is fixedly arranged at the top of the workbench, the workpiece positioning device comprises a positioning assembly and a control assembly, the positioning assembly is slidably arranged at the top of the conveying assembly, the control assembly is fixedly arranged on the workbench and is in splicing fit with the positioning assembly, the chassis feeding device comprises a feeding assembly and a feeding assembly, the feeding assembly is arranged at the top of the workbench and is positioned beside the feeding assembly, the slotting device comprises a driving assembly and a slotting assembly, the driving assembly is arranged at the top of the workbench, the slotting assembly is arranged on the driving assembly and is in transmission connection with the driving assembly, the slotting device comprises a supporting assembly and a slotting assembly, the supporting assembly is fixedly arranged at the top of the workbench, and the slotting assembly is fixedly arranged on the supporting assembly and is in plug-in fit with the supporting assembly;

the driving assembly comprises a second supporting frame, a first limiting plate, a driving motor, a screw rod and two supports, the second supporting frame is fixedly arranged at the top of the workbench, the first limiting plate is arranged on the second supporting frame, the two supports are fixedly arranged at the top of the second supporting frame, the screw rod is rotatably inserted into the two supports, the driving motor is fixedly arranged on the side wall of one support, and the output end of the driving motor is fixedly connected with the screw rod;

the slotting component comprises a first rotating shaft, a driven gear, a first connecting rod, a second cylinder and a first milling head, wherein the first rotating shaft is rotatably inserted into the top of the second support frame, the driven gear and the first connecting rod are integrally formed and are arranged at the top of the first rotating shaft in a non-rotatable mode, the driven gear is meshed with the screw rod, arc grooves are formed in the second support frame and the first limiting plate, the second cylinder is slidably arranged in the arc grooves, one end of the second cylinder is fixedly connected with the top of the second cylinder and the first connecting rod, and the first milling head is fixedly arranged at the output end of the second cylinder.

Further, the supporting component comprises a third supporting frame and a second limiting plate, the third supporting frame is fixedly arranged at the top of the workbench, and the second limiting plate is fixedly arranged on the third supporting frame.

Furthermore, the trompil subassembly includes third cylinder and second cutter head, the fixed top that sets up at the third support frame of third cylinder and with the cooperation of pegging graft of third support frame, the fixed setting of second cutter head is on the output of third cylinder.

Has the advantages that: according to the automatic processing device for the marine floor buckle chassis, when the chassis of the marine floor buckle needs to be processed in batches, the chassis to be processed is fixed through the positioning assembly, the positioning assembly moves to the slotting assembly and the perforating assembly along with the positioning assembly, the positioning assembly is controlled to slide to an accurate position through the insertion and matching of the control assembly and the positioning assembly, the slotting assembly conducts slotting on the chassis to be processed, the perforating assembly conducts perforating again, finally, the chassis is automatically processed into a finished chassis product, and the feeding assembly are also automatically completed, so that the whole processing flow is an automatic flow, the production efficiency is greatly improved, and the manpower resources are reduced.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a front view of the present invention;

FIG. 3 is a side view of the present invention;

FIG. 4 is a cross-sectional view taken along line A-A of FIG. 3;

FIG. 5 is a top view of the present invention;

FIG. 6 is a first diagram illustrating a partially disassembled structure according to the present invention;

FIG. 7 is an enlarged schematic view at B of FIG. 6;

FIG. 8 is a second schematic diagram of the partially disassembled structure of the present invention;

FIG. 9 is an enlarged schematic view at C of FIG. 8;

FIG. 10 is a third schematic view of the partially disassembled structure of the present invention;

FIG. 11 is a fourth schematic view of the partially disassembled structure of the present invention;

description of reference numerals: a workbench 1, a conveying device 2, a conveying component 2a, a conveying belt 2b, a conveying track 2c, a workpiece positioning device 3, a positioning component 3a, a control component 3b, a sliding plate 3c, a fixed block 3d, a fixed cylinder 3e, a controller 3f, a position sensor 3g, a control cylinder 3h, a chassis feeding device 4, a feeding component 4a, a feeding component 4b, a feeding track 4c, a pushing cylinder 4d, a supporting seat 4e, a first supporting frame 4f, a first sliding block 4g, a first cylinder 4h, a limiting block 4i, a sucking disc 4j, a slotting device 5, a driving component 5a, a slotting component 5b, a second supporting frame 5c, a first limiting plate 5d, a driving motor 5e, a spiral rod 5f, a support 5g, a first rotating shaft 5h, a driven gear 5i, a first connecting rod 5j, a second cylinder 5k and a first milling head 5m, the hole forming device 6, the supporting component 6a, the hole forming component 6b, the third supporting frame 6c, the second limiting plate 6d, the third cylinder 6e and the second milling head 6 f.

Detailed Description

The following detailed description of specific embodiments of the present invention is made with reference to the accompanying drawings and examples:

referring to fig. 1 to 11, the automatic machining device for the marine floor buckle chassis comprises a workbench 1, a conveying device 2 arranged at the top of the workbench 1, a workpiece positioning device 3 arranged at the top of the workbench 1, a chassis feeding device 4 arranged at the top of the workbench 1, a slotting device 5 arranged at the top of the workbench 1 and a perforating device 6 arranged at the top of the workbench 1, wherein the conveying device 2 comprises a conveying assembly 2a, the conveying assembly 2a is fixedly arranged at the top of the workbench 1, the workpiece positioning device 3 comprises a positioning assembly 3a and a control assembly 3b, the positioning assembly 3a is slidably arranged at the top of the conveying assembly 2a, the control assembly 3b is fixedly arranged on the workbench 1 and is in inserted fit with the positioning assembly 3a, the chassis feeding device 4 comprises a feeding assembly 4a and a feeding assembly 4b, the feeding component 4a is arranged at the top of the workbench 1, the feeding component 4b is arranged at the top of the workbench 1 and located beside the feeding component 4a, the slotting device 5 comprises a driving component 5a and a slotting component 5b, the driving component 5a is arranged at the top of the workbench 1, the slotting component 5b is arranged on the driving component 5a and is in transmission connection with the driving component 5a, the perforating device 6 comprises a supporting component 6a and a perforating component 6b, the supporting component 6a is fixedly arranged at the top of the workbench 1, the perforating component 6b is fixedly arranged on the supporting component 6a and is in inserting connection with the supporting component 6a, the marine floor buckle is used on a ship or a yacht to provide a pull handle for personnel on the ship, when the chassis of the marine floor buckle needs to be processed in batches, the chassis to be processed is fixed through the positioning component 3a, and along with locating component 3a removes fluting subassembly 5b and trompil subassembly 6b department, cooperate control locating component 3a to slide to accurate position through control component 3b and locating component 3a grafting, fluting subassembly 5b treats the processing chassis and slots, trompil subassembly 6b carries out the trompil again, final automatic processing becomes the chassis finished product, pay-off subassembly 4a and material loading subassembly 4b also accomplish automatically, consequently, whole process flow is automatic flow, very big production efficiency that improves reduces manpower resources.

The positioning assembly 3a comprises a sliding plate 3c, a fixed block 3d and two fixed cylinders 3e, the sliding plate 3c is slidably arranged on the conveying assembly 2a, the fixed block 3d is fixedly arranged on the sliding plate 3c, the fixed block 3d is provided with a plurality of insertion rods for fixing the chassis, the two fixed cylinders 3e are symmetrically arranged at the top of the fixed block 3d, the output end of each fixed cylinder 3e is fixedly provided with a pressing block, the bottom of the sliding plate 3c is also provided with a hinged block hinged with the conveying component 2a, the sliding plate 3c can slide on the conveying component 2a and drive the fixed block 3d and the fixed cylinder 3e, when the base plate to be processed is placed on the top of the fixing block 3d to be fixed, the two fixing cylinders 3e are opened, and the base plate to be processed is extruded and further fixed by the two pressing blocks.

The control component 3b comprises a controller 3f, a position sensor 3g and a control cylinder 3h, the controller 3f is fixedly arranged at the top of the workbench 1, the position sensor 3g is fixedly arranged at the top of the workbench 1, the control cylinder 3h is fixedly arranged at the top of the workbench 1 and is positioned beside the position sensor 3g, a detection block corresponding to the position sensor 3g is arranged on the side wall of the sliding plate 3c, an insertion hole for inserting the control cylinder 3h is also arranged on the sliding plate 3c, the position sensor 3g is electrically connected with the controller 3f, the controller 3f is electrically connected with the control cylinder 3h, the position sensor 3g senses the position of the detection block on the sliding plate 3c and transmits a signal to the controller 3f, the controller 3f controls the control cylinder 3h to be opened, the control cylinder 3h is inserted and matched with the sliding plate 3c to fix the sliding block, the grooving and the holing operations can be accurately performed conveniently.

The feeding assembly 4a comprises a feeding rail 4c, a pushing cylinder 4d and a supporting seat 4e, the supporting seat 4e is fixedly arranged at the top of the workbench 1, the feeding rail 4c is fixedly arranged on the supporting seat 4e, a transverse rail and a longitudinal rail are arranged on the feeding rail 4c, the pushing cylinder 4d is fixedly arranged in the longitudinal rail, the to-be-processed chassis is conveyed to the joint of the longitudinal rail and the transverse rail, the to-be-processed chassis is pushed into the longitudinal rail by the pushing cylinder 4d and is fixed to an accurate position, and the supporting seat 4e is used for supporting the feeding rail 4 c.

The feeding component 4b comprises a first supporting frame 4f, a first sliding block 4g, a first air cylinder 4h, a limiting block 4i and a plurality of suckers 4j, the first supporting frame 4f is fixedly arranged at the top of the workbench 1, the first sliding block 4g is arranged on the first supporting frame 4f in a sliding way, the first cylinder 4h is fixedly arranged on the first sliding block 4g and is in inserted fit with the first sliding block 4g, the limiting block 4i is fixedly arranged on the first support frame 4f, the suckers 4j are fixedly arranged at the output end of the first air cylinder 4h, the first sliding block 4g drives the first air cylinder 4h and the suckers 4j to move back and forth on the first support frame 4f, the suckers 4j adsorb the base plate to be machined and place the base plate on the fixed assembly, the limiting block 4i plays a role in limiting the sliding of the first sliding block 4g, and the first sliding block 4g is guaranteed to slide to an accurate position and put down the base plate to be machined.

Drive assembly 5a includes second support frame 5c, first limiting plate 5d, driving motor 5e, hob 5f and two supports 5g, the fixed top that sets up at workstation 1 of second support frame 5c, first limiting plate 5d sets up on second support frame 5c, two the fixed top that sets up at second support frame 5c of support 5g, the rotatable grafting of hob 5f sets up in two supports 5g, driving motor 5e is fixed to be set up on the lateral wall of a support 5g, driving motor 5 e's output and hob 5f fixed connection open driving motor 5e, and driving motor 5e is rotatory to drive hob 5f, and driving motor 5e is step motor, and the hob 5f is rotatory to be driven the corresponding motion of fluting subassembly 5 b.

The slotting component 5b comprises a first rotating shaft 5h, a driven gear 5i, a first connecting rod 5j, a second cylinder 5k and a first milling head 5m, the first rotating shaft 5h is rotatably inserted and arranged at the top of a second supporting frame 5c, the driven gear 5i and the first connecting rod 5j are of an integrally formed structure and are sleeved at the top of the first rotating shaft 5h in a non-rotatable manner, the driven gear 5i is meshed with a spiral rod 5f, arc-shaped grooves are formed in the second supporting frame 5c and the first limiting plate 5d, the second cylinder 5k is slidably arranged in the arc-shaped grooves, the top of the second cylinder 5k and the first connecting rod 5j are fixedly connected with one end far away from the driven gear 5i, the first milling head 5m is fixedly arranged at the output end of the second cylinder 5k, the spiral rod 5f rotates to drive the driven gear 5i and the first connecting rod 5j to rotate and further drive the first rotating shaft 5h to rotate, the first connecting rod 5j drives the second air cylinder 5k and the first milling head 5m to rotate, the second air cylinder 5k is a rotating air cylinder and can drive the first milling head 5m to rotate and extend downwards, and finally the effect of arc-shaped grooving is achieved.

The supporting assembly 6a comprises a third supporting frame 6c and a second limiting plate 6d, the third supporting frame 6c is fixedly arranged at the top of the workbench 1, the second limiting plate 6d is fixedly arranged on the third supporting frame 6c, and the third supporting frame 6c and the second limiting plate 6d are used for supporting the punching assembly 6 b.

The trompil subassembly 6b includes third cylinder 6e and second cutter head 6f, the fixed top that sets up at third support frame 6c of third cylinder 6e and pegs graft the cooperation with third support frame 6c, second cutter head 6f is fixed to be set up on the output of third cylinder 6e, and third cylinder 6e is revolving cylinder, and third cylinder 6e can drive second cutter head 6f rotation and lift, finally reaches the purpose of trompil, and the fluting position is used for placing the handle, and the trompil position is convenient for pull up the handle from the inslot.

The conveying assembly 2a comprises a conveying belt 2b and two conveying rails 2c, the two conveying rails 2c are parallel and fixedly arranged at the top of the workbench 1, the conveying belt 2b is slidably arranged at the top of the workbench 1 and located between the two conveying rails 2c, a plurality of hinged seats hinged with the sliding plate 3c are further arranged on the conveying belt 2b, and the conveying belt 2b can drive the sliding plate 3c to slide on the conveying rails 2 c.

The working principle is as follows: the ship floor buckle is used on a ship or a yacht, a pull handle is provided for personnel on the ship, when the chassis of the ship floor buckle needs to be processed in batches, a sliding plate 3c can slide on a conveying component 2a and drive a fixed block 3d and a fixed cylinder 3e, when the chassis to be processed is placed on the top of the fixed block 3d to be fixed, the two fixed cylinders 3e are opened, the chassis to be processed is extruded and further fixed by the two pressing blocks, a position sensor 3g senses the position of a detection block on the sliding plate 3c and transmits a signal to a controller 3f, the controller 3f controls a control cylinder 3h to be opened, the control cylinder 3h is in splicing fit with the sliding plate 3c to further fix the sliding block, slotting and perforating operations are accurately carried out, the chassis to be processed is conveyed to the joint of a longitudinal rail along a transverse rail, and then the chassis to be processed is pushed into the longitudinal rail by a material pushing cylinder 4d, the supporting seat 4e is used for supporting the feeding track 4c, the first slider 4g drives the first cylinder 4h and the plurality of suckers 4j to move back and forth on the first supporting frame 4f, the suckers 4j adsorb the chassis to be processed and are placed on the fixing component, the limiting block 4i plays a role of limiting the sliding of the first slider 4g, the first slider 4g is ensured to slide to an accurate position, the chassis to be processed is put down, the driving motor 5e is turned on, the driving motor 5e rotates to drive the screw rod 5f to rotate, the driving motor 5e is a stepping motor, the screw rod 5f rotates to drive the driven gear 5i and the first connecting rod 5j to rotate and further drive the first rotating shaft 5h to rotate, the first connecting rod 5j drives the second cylinder 5k and the first milling head 5m to rotate, the second cylinder 5k is a rotating cylinder and can drive the first milling head 5m to rotate and extend downwards, finally reach the grooved effect of arc, third cylinder 6e is revolving cylinder, and third cylinder 6e can drive second cutter head 6f rotation and lift, finally reaches the purpose of trompil, and the fluting position is used for placing the handle, and the trompil position is convenient for pull up the handle from the inslot, and whole process flow is automatic flow, and very big production efficiency who improves reduces manpower resources.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any minor modifications, equivalent changes and modifications made to the above embodiment according to the technical spirit of the present invention are within the technical scope of the present invention.

Claims

1. An automatic machining device for a marine floor buckle chassis comprises a workbench (1), a conveying device (2) arranged at the top of the workbench (1), a workpiece positioning device (3) arranged at the top of the workbench (1), a chassis feeding device (4) arranged at the top of the workbench (1), a slotting device (5) arranged at the top of the workbench (1) and a hole forming device (6) arranged at the top of the workbench (1); the conveying device (2) comprises a conveying assembly (2 a), the conveying assembly (2 a) is fixedly arranged at the top of the workbench (1), the workpiece positioning device (3) comprises a positioning assembly (3 a) and a control assembly (3 b), the positioning assembly (3 a) is slidably arranged at the top of the conveying assembly (2 a), the control assembly (3 b) is fixedly arranged on the workbench (1) and is in insertion fit with the positioning assembly (3 a), the chassis feeding device (4) comprises a feeding assembly (4 a) and a feeding assembly (4 b), the feeding assembly (4 a) is arranged at the top of the workbench (1), the feeding assembly (4 b) is arranged at the top of the workbench (1) and is positioned beside the feeding assembly (4 a), the slotting device (5) comprises a driving assembly (5 a) and a slotting assembly (5 b), the driving assembly (5 a) is arranged at the top of the workbench (1), and the slotting assembly (5 b) is arranged on the driving assembly (5 a) and is in transmission connection with the driving assembly (5 a);

the punching device (6) comprises a supporting component (6 a) and a punching component (6 b), the supporting component (6 a) is fixedly arranged at the top of the workbench (1), and the punching component (6 b) is fixedly arranged on the supporting component (6 a) and is in plug-in fit with the supporting component (6 a); the supporting assembly (6 a) comprises a third supporting frame (6 c) and a second limiting plate (6 d), the third supporting frame (6 c) is fixedly arranged at the top of the workbench (1), and the second limiting plate (6 d) is fixedly arranged on the third supporting frame (6 c); the hole opening assembly (6 b) comprises a third cylinder (6 e) and a second milling head (6 f), the third cylinder (6 e) is fixedly arranged at the top of a third supporting frame (6 c) and is in plug-in fit with the third supporting frame (6 c), and the second milling head (6 f) is fixedly arranged at the output end of the third cylinder (6 e);

the method is characterized in that: the positioning assembly (3 a) comprises a sliding plate (3 c), a fixed block (3 d) and two fixed cylinders (3 e), the sliding plate (3 c) is slidably arranged on the conveying assembly (2 a), the fixed block (3 d) is fixedly arranged on the sliding plate (3 c), a plurality of insertion rods used for fixing the chassis are arranged on the fixed block (3 d), the two fixed cylinders (3 e) are symmetrically arranged at the top of the fixed block (3 d), a pressing block is fixedly arranged at the output end of each fixed cylinder (3 e), and a hinge block hinged with the conveying assembly (2 a) is further arranged at the bottom of the sliding plate (3 c);

the driving assembly (5 a) comprises a second supporting frame (5 c), a first limiting plate (5 d), a driving motor (5 e), a screw rod (5 f) and two supports (5 g), the second supporting frame (5 c) is fixedly arranged at the top of the workbench (1), the first limiting plate (5 d) is arranged on the second supporting frame (5 c), the two supports (5 g) are fixedly arranged at the top of the second supporting frame (5 c), the screw rod (5 f) is rotatably inserted into the two supports (5 g), the driving motor (5 e) is fixedly arranged on the side wall of one support (5 g), and the output end of the driving motor (5 e) is fixedly connected with the screw rod (5 f);

the slotting component (5 b) comprises a first rotating shaft (5 h), a driven gear (5 i), a first connecting rod (5 j), a second cylinder (5 k) and a first milling head (5 m), the first rotating shaft (5 h) is rotatably inserted and arranged at the top of the second supporting frame (5 c), the driven gear (5 i) and the first connecting rod (5 j) are of an integrally formed structure and are sleeved on the top of the first rotating shaft (5 h) in a non-rotatable manner, the driven gear (5 i) is meshed with the screw rod (5 f), arc-shaped grooves are formed in the second supporting frame (5 c) and the first limiting plate (5 d), the second cylinder (5 k) is arranged in the arc-shaped groove in a sliding way, the top of the second cylinder (5 k) is fixedly connected with one end of the first connecting rod (5 j) far away from the driven gear (5 i), the first milling head (5 m) is fixedly arranged on the output end of the second cylinder (5 k); the second cylinder (5 k) is a rotary cylinder and can drive the first milling head (5 m) to rotate and extend downwards to realize arc-shaped grooving.