CN114952613B

CN114952613B - Rotary workbench system for machining steel structure of metal product

Info

Publication number: CN114952613B
Application number: CN202210648933.6A
Authority: CN
Inventors: 罗大川
Original assignee: Yuncheng New Oriental Heavy Steel Structure Co ltd
Current assignee: Yuncheng New Oriental Heavy Steel Structure Co ltd
Priority date: 2022-06-09
Filing date: 2022-06-09
Publication date: 2023-11-28
Anticipated expiration: 2042-06-09
Also published as: CN114952613A

Abstract

The invention discloses a rotary workbench system for machining a steel structure of a metal product, which relates to the technical field of metal machining operation tables and comprises a base; the base is integrally formed by jointly welding a peripheral circular ring and a star-shaped support welded in the peripheral circular ring, wherein a vertical support pillar is welded at the center of the star-shaped support, a round workbench is rotatably arranged on the top end section of the vertical support pillar, six strip-shaped sliding grooves are formed in a surrounding and penetrating mode on the round workbench, two T-shaped fixing pieces are symmetrically sleeved on six positioning shafts through spring pushing in a sliding mode and are used for clamping and fixing steel structure plates to be polished; an L-shaped mounting rod is welded on the peripheral ring in a vertical supporting mode, and an L-shaped supporting rod is welded on the peripheral ring on the opposite side of the L-shaped mounting rod in a vertical supporting mode. The invention can save the trouble of implementing tightness of the workpiece by additionally manually operating the clamp during processing operation, and solves the problems of complicated processing operation steps and low processing efficiency.

Description

Rotary workbench system for machining steel structure of metal product

Technical Field

The invention relates to the technical field of metal processing operation tables, in particular to a rotary workbench system for processing a steel structure of a metal product.

Background

The metal product steel structure plate needs to be polished and derusted before being processed, so that follow-up coating and paint spraying are facilitated, a workbench for bearing and fixing a workpiece is needed during polishing and derusting operation, a feeding assembly of the workpiece and a clamp assembly of the workpiece on the existing workbench are not reasonable enough in design, most of the workpiece cannot be connected with a rotary driving mechanism of the workbench in a power mode, the rotary driving mechanism of the workbench cannot be utilized for linkage to drive actions, feeding and tightness are implemented, additional manual force is needed before and after use to feed and tighten the workpiece, the use is troublesome and inconvenient, and the problem of processing use efficiency is lowered.

Disclosure of Invention

The invention aims to provide a rotary workbench system for processing a steel structure of a metal product, which is provided with an arc-shaped rack, and a driven gear can drive rotation by utilizing the power transmission of the rotation of a circular workbench through the power transmission of the arc-shaped rack, so as to control the opposite sliding tightness of two T-shaped fixing pieces, thereby saving the trouble of implementing tightness of a workpiece by an additional manual operation clamp during processing operation, and solving the problems of complicated processing operation steps and low processing efficiency.

In order to achieve the above purpose, the present invention provides the following technical solutions: a rotary workbench system for processing a steel structure of a metal product comprises a base; the base is integrally formed by jointly welding a peripheral circular ring and a star-shaped support welded in the peripheral circular ring, wherein a vertical support column is welded at the center of the star-shaped support, a round workbench is rotatably arranged on the top end section of the vertical support column, six strip-shaped sliding grooves are formed in a surrounding and penetrating mode on the round workbench, a positioning shaft is welded in each of the six strip-shaped sliding grooves, two T-shaped fixing pieces are symmetrically sleeved on each of the six positioning shafts through spring pushing and sliding, and the two T-shaped fixing pieces are used for clamping and fixing steel structure plates to be polished; an L-shaped mounting rod is vertically supported and welded on the peripheral ring, and an L-shaped supporting rod is also vertically supported and welded on the peripheral ring at the opposite side of the L-shaped mounting rod; the top end of the L-shaped supporting rod is fixedly welded with a material containing frame, the whole material containing frame is formed by welding two vertical U frames and a horizontal U-shaped frame welded at the bottoms of the two vertical U frames together, a vertical baffle plate is welded in an outer opening of the vertical U frame positioned at the outer side, and the material containing frame is used for stacking a row of steel structure plates to be processed; six groups of hanging shafts are welded around the hanging support at the middle section of the six strip-shaped sliding grooves at the bottom of the circular workbench, and six sliding parts are sleeved on the six groups of hanging shafts in a sliding manner.

Preferably, six positioning rings are welded on the circumference outer ring of the circular workbench in a surrounding manner, two shaft sleeves are welded on the upper half section of the L-shaped mounting rod at intervals up and down, the inserted rod is in sliding fit with the two shaft sleeves in a penetrating manner through spring pushing, a protruding shaft rod is welded on one side, facing the L-shaped mounting rod, of the middle section of the vertical supporting column, and an arc-shaped rack is welded and fixed on the outer side end of the protruding shaft rod.

Preferably, six pushing strips are welded around adjacent positions of the top end of the circular workbench, which are located at six strip-shaped sliding grooves, and the six pushing strips are in abutting contact with the bottommost steel structure plate in the material containing frame sequentially along with the rotation of the circular workbench.

Preferably, the bottom of the center position of the circular workbench is welded with a rotary ring through six hanging posts, six mounting shafts are welded on the rotary ring in a radial surrounding mode, and the head ends of the six mounting shafts are respectively sleeved with a driven gear in a rotary mode.

Preferably, six driven gears rotate along with the circular workbench to sequentially mesh with the arc racks, and a poking shaft is welded on the circumferences of the six driven gears.

Preferably, a pressing plate is slidably installed on the horizontal part of the top end of the T-shaped fixing piece through spring pushing, and a connecting rod is rotatably connected to the bottom of the vertical supporting part of the T-shaped fixing piece.

Preferably, four rail shafts are symmetrically welded on the left side of the material containing frame in a front-back mode, two jacking frames of U-shaped structures are slidably installed on the four rail shafts through spring pushing, and a limiting part is rotatably installed at the bottom of the left side of the material containing frame.

Preferably, the whole two otic placodes of welding on the pivot interlude of spacing portion comprises jointly by pivot and symmetry, and wherein two otic placodes erect and prop and block on the left side ejection of compact gap between flourishing work or material rest and circular workstation, and symmetrical welding has two horizontal atress boards on the left and right sides end section of pivot, and two spacing troops under one's command and two horizontal atress boards support and lean on the contact.

Preferably, the whole sliding part is composed of two convex side plates and two connecting shafts symmetrically welded at the head end and the tail end of the two convex side plates, wherein a T-shaped force transmission part is welded downwards between the middle sections of the two convex side plates, and the tail ends of two connecting rods at the bottoms of the two T-shaped fixing parts which are corresponding to each other in an internal and external mode are correspondingly connected with the two connecting shafts in a rotating mode.

Preferably, a force transmission groove is formed in the horizontal part of the bottom of the T-shaped force transmission piece in a penetrating mode, and a poking shaft on the driven gear is correspondingly in plug-in fit with the force transmission groove.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, the six pushing bars are matched with the material containing frame for use together, so that the workpiece can be ejected out of the bottom of the material containing frame along the belt when the workpiece is rotationally conveyed and fed between the two T-shaped fixing pieces, the trouble that in the processing process, the workpiece is fed between the clamps on the circular workbench frequently due to additional manual force of personnel is omitted, and the workpiece feeding device is convenient to use, and saves time and labor;

2. according to the invention, through power transmission of the arc-shaped rack, the driven gear can drive rotation by using the power transmission linkage of the rotation of the circular workbench, and the two T-shaped fixing pieces are controlled to slide in opposite directions to tighten and loosen, so that the trouble of additionally manually operating the clamp to tighten and loosen a workpiece during processing operation is omitted, the processing operation steps are simplified, and the processing efficiency is improved;

3. according to the invention, the pushing holding force of the springs on the four track shafts can be transmitted to the limiting part by the two pushing frames, so that the limiting part can resist the friction force between the circular worktable and the workpiece, and the limiting part can block and limit the bottom steel structure plate, so that the phenomenon that the steel structure plate is pushed out of the material containing frame by the circular worktable due to the friction force when the pushing strip is not contacted with the steel structure plate, and the steel structure plate cannot be accurately fed between the clamps (two T-shaped fixing pieces) is avoided, and the whole processing procedure is disturbed, so that the normal clamping and polishing of the workpiece are affected.

Drawings

FIG. 1 is a schematic view of a circular table structure according to the present invention;

FIG. 2 is a schematic view of the rear side structure of the circular table of the present invention;

FIG. 3 is a schematic view of the bottom structure of the circular table of the present invention;

FIG. 4 is a schematic view of the installation position of the positioning shaft of the present invention;

FIG. 5 is a schematic view of a slider sliding installation of the present invention;

FIG. 6 is a schematic view of a swivel structure according to the present invention;

FIG. 7 is a schematic view of a T-shaped fastener of the present invention;

FIG. 8 is a schematic view of a limiting portion according to the present invention;

FIG. 9 is a schematic view of a material rack according to the present invention;

in the figure, the correspondence between the component names and the drawing numbers is:

1. a base; 101. a vertical support pillar; 102. an L-shaped mounting bar; 103. a rod; 104. an arc-shaped rack; 105. an L-shaped stay bar; 2. a circular workbench; 201. a positioning ring; 202. pushing the strip; 203. positioning a shaft; 204. a swivel; 205. a driven gear; 206. hanging the shaft; 3. a T-shaped fixing member; 301. a pressing plate; 302. a connecting rod; 4. a material containing frame; 401. a rail shaft; 402. a limit part; 403. pressing the frame; 5. a slider; 501. t-shaped force transfer member.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments.

Referring to fig. 1 to 9, an embodiment of the present invention provides: a rotary workbench system for processing a steel structure of a metal product comprises a base 1; the base 1 is integrally formed by jointly welding a peripheral circular ring and a star-shaped support welded in the peripheral circular ring, wherein a vertical support column 101 is welded at the center of the star-shaped support, a round workbench 2 is rotatably arranged on the top end section of the vertical support column 101, six strip-shaped sliding grooves are formed in a surrounding and penetrating mode on the round workbench 2, a positioning shaft 203 is welded in each of the six strip-shaped sliding grooves, two T-shaped fixing pieces 3 are symmetrically sleeved on each of the six positioning shafts 203 in a sliding mode through spring pushing, and the two T-shaped fixing pieces 3 are used for clamping and fixing steel structure plates to be polished; an L-shaped mounting rod 102 is vertically welded on the peripheral ring, and an L-shaped supporting rod 105 is also vertically welded on the peripheral ring at the opposite side of the L-shaped mounting rod 102; the top end of the L-shaped supporting rod 105 is fixedly welded with a material containing frame 4, the whole material containing frame 4 is formed by welding two vertical U frames and a horizontal U-shaped frame welded at the bottoms of the two vertical U frames together, a vertical baffle plate is welded in an outer opening of the vertical U frame positioned at the outer side, and the material containing frame 4 is used for stacking a row of steel structure plates to be processed; six groups of hanging shafts 206 are welded around the hanging support at the middle section of the six strip-shaped sliding grooves at the bottom of the circular workbench 2, and six sliding pieces 5 are sleeved on the six groups of hanging shafts 206 in a sliding manner; six positioning rings 201 are welded around the circumference outer ring of the circular workbench 2, two shaft sleeves are welded on the upper half section of the L-shaped mounting rod 102 at intervals up and down, the inserted rod 103 is in sliding fit with the two shaft sleeves in a penetrating way through spring pushing, a protruding shaft rod is welded on one side, facing the L-shaped mounting rod 102, of the middle section of the vertical support column 101, an arc-shaped rack 104 is welded and fixed on the outer side end of the protruding shaft rod, the inserted rod 103 can be inserted and positioned with the circular workbench 2, and workpieces clamped and fixed on the inserted rod 103 can be conveniently machined; the bottom of the center position of the circular workbench 2 is welded with a rotating ring 204 through six hanging posts, six mounting shafts are welded on the rotating ring 204 in a radial surrounding manner, and the head ends of the six mounting shafts are respectively sleeved with a driven gear 205 in a rotating manner.

As shown in fig. 2, six pushing bars 202 are welded around adjacent positions of six bar-shaped sliding grooves on the top end of the circular workbench 2, the six pushing bars 202 rotate along with the circular workbench 2 to sequentially contact with steel structure plates at the bottommost part of the material containing frames 4 in an abutting mode, the six pushing bars 202 are matched with the material containing frames 4 to be used together, and can eject and feed workpieces from the bottom of the material containing frames 4 between two T-shaped fixing pieces 3 along the belt when the workpieces are conveyed in a rotating mode, the trouble that in the machining process, additional manual force of a person frequently feeds the workpieces between clamps on the circular workbench 2 is omitted, and the circular workbench is convenient to use, time-saving and labor-saving.

As shown in fig. 3, six driven gears 205 rotate along with the circular workbench 2 to sequentially mesh with the arc-shaped racks 104, a shifting shaft is welded on the circumferences of the six driven gears 205, and the driven gears 205 can drive rotation by utilizing the power transmission linkage of the rotation of the circular workbench 2 through the power transmission of the arc-shaped racks 104, so that the two T-shaped fixing pieces 3 are controlled to slide in opposite directions to be tightness, the trouble of implementing tightness of the workpiece by an additional manual operation clamp during processing operation is omitted, the processing operation steps are simplified, and the processing efficiency is improved.

As shown in fig. 7, a pressing plate 301 is slidably mounted on the horizontal part of the top end of the T-shaped fixing member 3 by pushing with a spring, and a connecting rod 302 is rotatably connected to the bottom of the vertical supporting part of the T-shaped fixing member 3; four track shafts 401 are symmetrically welded on the left side of the material containing frame 4 in a front-back mode, two jacking frames 403 with U-shaped structures are slidably installed on the four track shafts 401 through spring pushing, a limiting portion 402 is rotatably installed at the bottom of the left side of the material containing frame 4, pushing retaining force of the springs on the four track shafts 401 can be transmitted to the limiting portion 402 through the two jacking frames 403, and the limiting portion 402 can resist friction force between the circular workbench 2 and a workpiece.

As shown in fig. 9, the whole limiting portion 402 is composed of a rotating shaft and two ear plates symmetrically welded on the middle section of the rotating shaft, wherein the two ear plates are vertically supported and blocked on a left discharging gap between the material containing frame 4 and the circular workbench 2, two horizontal stress plates are symmetrically welded on the left end section and the right end section of the rotating shaft, the two limiting portions 402 slide downwards to be in abutting contact with the two horizontal stress plates, the limiting portion 402 can block and limit the bottom steel structure plate through the two ear plates, and the circular workbench 2 can prevent the steel structure plate from being pushed out from the material containing frame 4 due to friction force when the pushing bar 202 is not in contact with the steel structure plate, so that the steel structure plate cannot be accurately fed between the clamps (two T-shaped fixing pieces 3), the whole processing procedure is disturbed, and the normal clamping and polishing of workpieces are affected.

As shown in fig. 7, the sliding part 5 integrally consists of two convex side plates and two connecting shafts symmetrically welded at the front end and the rear end of the two convex side plates, wherein a T-shaped force transmission part 501 is welded downwards between the middle sections of the two convex side plates, the tail ends of two connecting rods 302 at the bottoms of two corresponding T-shaped fixing parts 3 inside and outside are correspondingly connected with the two connecting shafts in a rotating way, the two T-shaped fixing parts 3, the two connecting rods 302 and the sliding part 5 are jointly connected to form a double-crank sliding block mechanism, and the sliding part 5 can drive the two T-shaped fixing parts 3 to slide oppositely to implement tightness on a workpiece by sliding up and down through the mechanism; a force transmission groove is formed in the horizontal portion of the bottom of the T-shaped force transmission piece 501 in a penetrating mode, a poking shaft on the driven gear 205 is correspondingly matched with the force transmission groove in a splicing mode, and the driven gear 205 can rotate to drive the T-shaped force transmission piece 501 and the sliding piece 5 to slide up and down to provide elastic driving force for the two T-shaped fixing pieces 3 through the poking shaft.

Working principle: when the polishing machine is used, firstly, a row of steel structure plates to be processed are stacked and placed in the material containing frame 4, then the inserting rod 103 is driven to slide downwards and be pulled away from the positioning ring 201 by foot, the circular workbench 2 is loosened, then the circular workbench 2 is rotated rightwards, six pushing strips 202 follow the rotation of the circular workbench 2 and are sequentially abutted against and contacted with the bottommost steel structure plates in the material containing frame 4, the steel structure plates are sequentially ejected from the bottom of the material containing frame 4 and conveyed to a polishing station (a worker holds an angle grinder to polish a workpiece at the position of the L-shaped mounting rod 102), when the workpiece rotates to the position of the L-shaped mounting rod 102, the driven gear 205 corresponding to the workpiece is meshed and driven with the arc-shaped rack 104, the workpiece can be driven to slide inwards to clamp and polish the workpiece, the circular workbench 2 is rotated rightwards after polishing is completed, and after the driven gear 205 is separated from the arc-shaped rack 104, the springs on the positioning shaft 203 can automatically push the two T-shaped fixing pieces 3 to slide outwards and loosen the workpiece after the processing is completed, and finally the processed workpiece is taken down.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. A rotary table system for metal product steel structure processing, which is characterized in that: comprises a base (1); the base (1) is integrally formed by jointly welding a peripheral circular ring and a star-shaped support welded in the peripheral circular ring, wherein a vertical support column (101) is welded at the center of the star-shaped support, a round workbench (2) is rotatably arranged on the top end section of the vertical support column (101), six strip-shaped sliding grooves are formed in a surrounding and penetrating mode on the round workbench (2), a positioning shaft (203) is welded in each of the six strip-shaped sliding grooves, two T-shaped fixing pieces (3) are symmetrically sleeved on each of the six positioning shafts (203) in a sliding mode through spring pushing, and the two T-shaped fixing pieces (3) are used for clamping and fixing steel structure plates to be polished; an L-shaped mounting rod (102) is vertically supported and welded on the peripheral ring, and an L-shaped supporting rod (105) is also vertically supported and welded on the peripheral ring at the opposite side of the L-shaped mounting rod (102); a material containing frame (4) is welded and fixed at the top end of the L-shaped supporting rod (105), the material containing frame (4) is integrally formed by welding two vertical U frames together with a horizontal U-shaped frame welded at the bottom of the two vertical U frames, a vertical baffle plate is welded in an outer opening of the vertical U frame positioned at the outer side, and the material containing frame (4) is used for stacking a row of steel structure plates to be processed; six groups of hanging shafts (206) are welded around the hanging support at the middle section of the six strip-shaped sliding grooves at the bottom of the circular workbench (2), and six sliding pieces (5) are sleeved on the six groups of hanging shafts (206) in a sliding manner;

six positioning rings (201) are welded around the circumference outer ring of the circular workbench (2), two shaft sleeves are welded on the upper half section of the L-shaped mounting rod (102) at intervals up and down, the inserted rod (103) is in penetrating sliding fit with the two shaft sleeves through spring pushing, a protruding shaft rod is welded on one side, facing the L-shaped mounting rod (102), of the middle section of the vertical support column (101), and an arc-shaped rack (104) is welded and fixed at the outer side end of the protruding shaft rod;

six pushing strips (202) are welded around adjacent positions of the top end of the circular workbench (2) at six strip-shaped sliding grooves, and the six pushing strips (202) rotate along with the circular workbench (2) to sequentially contact with the bottommost steel structure plate in the material containing frame (4) in an abutting mode;

the bottom of the center position of the circular workbench (2) is welded with a rotating ring (204) through six hanging posts, six mounting shafts are welded on the rotating ring (204) in a radial surrounding manner, and the head ends of the six mounting shafts are respectively sleeved with a driven gear (205) in a rotating manner;

six driven gears (205) rotate along with the circular workbench (2) to sequentially mesh with the arc-shaped racks (104), and a shifting shaft is welded on the circumferences of the six driven gears (205);

a pressing plate (301) is slidably arranged on the horizontal part of the top end of the T-shaped fixing piece (3) through spring pushing, and a connecting rod (302) is rotatably connected to the bottom of the vertical supporting part of the T-shaped fixing piece (3);

the sliding part (5) is integrally formed by two convex side plates and two connecting shafts symmetrically welded at the head end and the tail end of the two convex side plates, wherein a T-shaped force transmission part (501) is welded downwards between the middle sections of the two convex side plates, and the tail ends of two connecting rods (302) at the bottoms of the two T-shaped fixing parts (3) which are corresponding to each other in the inside and outside are correspondingly connected with the two connecting shafts in a rotating way;

a force transmission groove is formed in the horizontal portion of the bottom of the T-shaped force transmission piece (501) in a penetrating mode, and a poking shaft on the driven gear (205) is correspondingly in plug-in fit with the force transmission groove.

2. A rotary table system for the fabrication of metal product steel structures as set forth in claim 1 wherein: four track shafts (401) are symmetrically welded on the left side of the material containing frame (4) in a front-back mode, two jacking frames (403) with U-shaped structures are slidably installed on the four track shafts (401) through spring pushing, and a limiting part (402) is rotatably installed at the bottom of the left side of the material containing frame (4).

3. A rotary table system for the fabrication of metal product steel structures as set forth in claim 2 wherein: the limiting part (402) is integrally formed by a rotating shaft and two lug plates symmetrically welded on the middle section of the rotating shaft, wherein the two lug plates are vertically supported and blocked on a left discharging gap between the material containing frame (4) and the circular workbench (2), two horizontal stress plates are symmetrically welded on the left end section and the right end section of the rotating shaft, and the two limiting parts (402) slide downwards to be in abutting contact with the two horizontal stress plates.