CN117125126B

CN117125126B - Connecting flange transfer device

Info

Publication number: CN117125126B
Application number: CN202311397831.2A
Authority: CN
Inventors: 王吉陶; 王志强; 王凤光
Original assignee: Shandong Huida Vermilion Equipment Co ltd
Current assignee: Shandong Huida Vermilion Equipment Co ltd
Priority date: 2023-10-26
Filing date: 2023-10-26
Publication date: 2024-03-19
Anticipated expiration: 2043-10-26
Also published as: CN117125126A

Abstract

The invention relates to the technical field of flange transfer equipment, in particular to a connecting flange transfer device which comprises a trolley, wherein a plurality of pipe seats are fixedly arranged on the trolley, the pipe seats are of an up-down through structure, the pipe seats penetrate through the upper surface and the lower surface of a trolley hopper, and flange storage cylinders are arranged in the pipe seats. The flange storage cylinder comprises a combined cylinder arranged in the tube seat, and a capsule for slowing down the sliding speed of the flange is arranged on the inner wall of the combined cylinder. An inner column is arranged in the combined cylinder, a column hole is vertically formed in the middle of the inner column, and a rotating shaft is rotatably connected in the column hole. Compared with the traditional transfer equipment, the combined cylinder and the inner column can be matched with the upper support bar and the lower support bar to rapidly release the flanges besides the placement of the flanges, and a user does not need to take out the flanges one by one, so that the operation is more labor-saving, and the transfer efficiency can be accelerated.

Description

Connecting flange transfer device

Technical Field

The invention relates to the technical field of flange transfer equipment, in particular to a connecting flange transfer device.

Background

The flange is a part for connecting pipes and is used for connecting the pipe ends; the flange is also applicable to the inlet and outlet of equipment, is used for connecting two pieces of equipment, such as a speed reducer flange, and is widely applied in various fields.

At present, in the flange production process, workpieces after processing of each procedure is finished are usually stored by using a turnover box, the turnover box is carried to a conveying trolley by an operator, or a box body, a cabinet body and the like for placing the flanges are fixedly arranged on the trolley, the flanges are carried on the trolley, and then are transported among the procedures, but after being transported to a destination, the flanges placed in the storage cabinet need operators to be lifted one by one, so that the operation is time-consuming and labor-consuming, and the subsequent transportation efficiency is affected.

In view of this, we propose a flange transfer device.

Disclosure of Invention

The invention aims to provide a connecting flange transferring device which is used for solving the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a flange transfer device, includes the shallow, fixedly on the shallow be provided with a plurality of tube socket, and the tube socket is the upper and lower through structure, the tube socket runs through the upper and lower two sides of shallow car hopper, be provided with the flange storage tube in the tube socket.

Preferably, the flange storage cylinder comprises a combined cylinder arranged in the tube seat, and a capsule for slowing down the sliding speed of the flange is arranged on the inner wall of the combined cylinder.

An inner column is arranged in the combined cylinder, a column hole is vertically formed in the middle of the inner column, and a rotating shaft is rotatably connected in the column hole.

The side surface of the inner column is provided with two groups of grooves, and the two groups of grooves are respectively positioned on the upper side and the lower side of the inner column.

The inside of interior post has seted up the opening, and opening intercommunication lack groove and post hole, the upper position department of lack groove inside wall is the symmetry and has seted up two spouts, and two spout sliding connection have the balladeur train, relative breach one side fixedly connected with rack in balladeur train surface, and the tooth flank of rack is located its upper surface and arranges along the radial of pivot.

Two ring grooves are formed in the surface of the rotating shaft, the two ring grooves correspond to the two groups of notch grooves and the sliding frame respectively, threads are arranged on the inner top wall of the ring groove, the rack penetrates through the through hole to extend into the ring groove, and the rack is meshed with the threads.

The threads in the two ring grooves are oppositely arranged.

The sliding frame is of a C-shaped structure, the connecting shaft is fixedly arranged on the inner side of the sliding frame, the supporting bar is rotatably arranged on the connecting shaft, a circular groove is formed in the side surface of the supporting bar corresponding to the connecting shaft, a torsion spring is arranged in the circular groove, two ends of the torsion spring are respectively connected to the connecting shaft and the supporting bar, and the torsion spring pushes the supporting bar to rotate upwards to be transversely arranged.

The upper side and the lower side of the inner wall of the combined cylinder are respectively provided with a socket corresponding to the supporting bar on the same side.

Preferably, the combined cylinder comprises a main spiral cylinder wall fixedly arranged in the tube seat, an auxiliary spiral cylinder wall is rotationally embedded on the main spiral cylinder wall, and the auxiliary spiral cylinder wall and the main spiral cylinder wall are combined to form a hollow cylinder structure with upper and lower openings.

The upper side of the socket is positioned on the main spiral cylinder wall, and the lower side of the socket is respectively positioned on the auxiliary spiral cylinder wall and the main spiral cylinder wall.

The upper side of the outer surface of the secondary spiral cylinder wall is fixedly provided with a handle, and the inner bottom of the secondary spiral cylinder wall is fixedly provided with a tray.

And a slow release device is arranged on the tray and the inner column.

Preferably, the slow release device comprises a column opening arranged on the tray, the column opening is used for inserting an inner column, a plurality of grooves are formed in the bottom of the side surface of the inner column, and the grooves are in an annular array along the inner column.

The spring plate is arranged in the groove, the top end of the spring plate is fixedly connected along the inner top wall of the groove, the spring plate deflects outwards from the groove, and the bottom end of the spring plate is fixedly provided with an edge for propping against the column opening.

Preferably, a knob is fixedly arranged at the top end of the rotating shaft.

Preferably, the surface of the handle is fixedly provided with a frosted rubber sleeve.

Preferably, the engagement surface of the main spiral cylinder wall is provided with a spiral groove adapted to the spiral track, and the engagement surface of the auxiliary spiral cylinder wall is provided with a convex edge adapted to the spiral groove.

Preferably, the tray is fixedly mounted on the wall of the secondary spiral tube through bolts.

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

according to the invention, the rotating shaft is rotated to enable the two groups of threads to rotate, the upper side threads drive the upper side racks, the sliding rack and the supporting bars to move inwards close to the axis of the rotating shaft, the upper side supporting bars are separated from the inserting holes, the connection between the inner column and the upper part of the combined cylinder is released, the lower side threads drive the lower side racks, the sliding rack and the supporting bars to move outwards away from the axis of the rotating shaft, the lower side supporting bars are inserted into the inserting holes to connect and fix the upper side supporting bars and the lower side supporting bars along the lower part of the combined cylinder, and after the transfer is completed, the rotating shaft enables the upper side supporting bars to be inserted into the upper side inserting holes to be connected and fixed, and the lower side supporting bars are separated from the lower side inserting holes to unlock, so that the flange in the combined cylinder can be pressed to rotate, and then the lower side supporting bars can be discharged from the combined cylinder.

According to the invention, after the lower support bar is unlocked, the flange falls onto the tray along the inner column, the parallel combination of the lower support bar and the inner column is synchronously released between the main spiral cylinder wall and the auxiliary spiral cylinder wall, and then the auxiliary spiral cylinder wall is pushed to rotate along the main spiral cylinder wall by the handle so as to drive the tray to move downwards and push out the inner flange outwards, so that the released flange is restrained by the tray, the flange can be under the control of a user and can be stably released, and potential safety hazards and damage to the flange caused by the fact that the inner flange quickly falls to the ground after the lower support bar is unlocked are avoided.

According to the invention, when the auxiliary spiral cylinder wall rotates to drive the tray to move downwards, the flange positioned on the tray moves downwards, which is not influenced by the elastic sheet and the edge, and leaves the combined cylinder downwards for a user to take out, and after the tray and the flange leave the combined cylinder, the elastic sheet pushes the edge to expand outwards, the upper flange falls down and is blocked by the edge, and can not directly leave the combined cylinder along with the tray, so that the internal flanges are released and taken out one by one, the phenomenon that the upper flange is piled on the bottommost flange to influence the taking out is avoided, and the phenomenon that the upper flange falls down directly to collide with and injure an operator due to the taking out of the bottommost flange is avoided.

Drawings

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

FIG. 2 is a schematic view of a tube holder and a combined cylinder according to the present invention;

FIG. 3 is a schematic perspective view of a combined cylinder according to the present invention;

FIG. 4 is a schematic perspective view of a combined cylinder according to the present invention (bottom view);

FIG. 5 is a perspective cross-sectional view of a combined cylinder according to the present invention;

FIG. 6 is a front cross-sectional view of a combined cylinder of the present invention;

FIG. 7 is an exploded view of the main and secondary screw barrels of the present invention;

FIG. 8 is a schematic perspective view of an inner column according to the present invention;

FIG. 9 is a partial cross-sectional view of the inner column of the present invention;

FIG. 10 is an enlarged view of the invention at A in FIG. 9;

FIG. 11 is a schematic view of the structure of the upper and lower threads of the present invention;

fig. 12 is a partial elevation sectional view of the combined cylinder of the present invention.

In the figure: 1. a cart; 2. a tube seat; 3. a flange storage cylinder; 31. a combined cylinder; 31-1, a main spiral cylinder wall; 31-2, an auxiliary spiral cylinder wall; 31-3, a handle; 31-4, a tray; 31-5, a slow release device; 31-51, column mouth; 31-52, grooves; 31-53, shrapnel; 31-54, edges; 32. a capsule; 33. an inner column; 34. a post hole; 35. a rotating shaft; 36. a groove is formed; 37. a through port; 38. a chute; 39. a carriage; 310. a rack; 311. a ring groove; 312. a thread; 313. a connecting shaft; 314. a support bar; 315. a circular groove; 316. a torsion spring; 317. a socket.

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. All other embodiments, which are obtained by a worker of ordinary skill in the art without creative efforts, are within the protection scope of the present invention based on the embodiments of the present invention.

Referring to fig. 1 to 12, the present invention provides a technical solution: the utility model provides a flange transfer device, includes shallow 1, fixedly is provided with a plurality of tube socket 2 on the shallow 1, and tube socket 2 is upper and lower through structure, and tube socket 2 runs through the upper and lower two sides of shallow 1 car hopper, is provided with flange storage tube 3 in the tube socket 2, and during the use, pack into flange storage tube 3 with the flange and pile up and place in, then utilize shallow 1 can realize the transportation of flange.

In this embodiment, as shown in fig. 2 to 11, the flange storage cylinder 3 includes a combined cylinder 31 disposed in the tube seat 2, and a capsule 32 for slowing down the sliding speed of the flange is disposed on the inner wall of the combined cylinder 31, so that when the flange moves down along the inner column 33 and the combined cylinder 31, the flange can be blocked by the capsule 32, and can not fall down quickly, but slowly fall to the bottom of the combined cylinder 31;

an inner column 33 is arranged in the combined cylinder 31, a column hole 34 is vertically formed in the middle of the inner column 33, and a rotating shaft 35 is rotatably connected in the column hole 34;

the side surface of the inner column 33 is provided with two groups of grooves 36, and the two groups of grooves 36 are respectively positioned on the upper side and the lower side of the inner column 33;

the inner column 33 is internally provided with a through hole 37, the through hole 37 is communicated with the notch 36 and the column hole 34, the upper position of the inner side wall of the notch 36 is symmetrically provided with two sliding grooves 38, the sliding grooves 38 are slidably connected with a sliding frame 39, one side of the surface of the sliding frame 39 opposite to the notch is fixedly connected with a rack 310, and the tooth surface of the rack 310 is positioned on the upper surface of the rack and is arranged along the radial direction of the rotating shaft 35;

two ring grooves 311 are formed in the surface of the rotating shaft 35, the two ring grooves 311 correspond to the two groups of notch grooves 36 and the sliding frame 39 respectively, threads 312 are formed in the inner top wall of the ring groove 311, a rack 310 penetrates through the through hole 37 to extend into the ring groove 311, the rack 310 is meshed with the threads 312, the rotating shaft 35 is rotated to enable the threads 312 to rotate, and the threads 312 drive the rack 310, the sliding frame 39 and the supporting bars 314 to move;

the threads 312 in the two ring grooves 311 are oppositely arranged, and when the upper side threads 312 drive the upper side racks 310, the sliding frame 39 and the supporting bars 314 to move inwards near the axle center of the rotating shaft 35, the lower side threads 312 drive the lower side racks 310, the sliding frame 39 and the supporting bars 314 to move outwards far away from the axle center of the rotating shaft 35, and vice versa;

the sliding frame 39 is of a C-shaped structure, a connecting shaft 313 is fixedly arranged on the inner side of the sliding frame 39, a supporting bar 314 is rotatably arranged on the connecting shaft 313, a circular groove 315 is formed in the side surface of the supporting bar 314 corresponding to the connecting shaft 313, a torsion spring 316 is arranged in the circular groove 315, two ends of the torsion spring 316 are respectively connected to the connecting shaft 313 and the supporting bar 314, and the torsion spring 316 pushes the supporting bar 314 to rotate upwards to be transversely arranged;

the upper and lower sides of the inner wall of the combined cylinder 31 are respectively provided with a socket 317 corresponding to the same side support bar 314, when the upper side support bar 314 is separated from the socket 317, the connection between the inner column 33 and the upper part of the combined cylinder 31 is released, the lower side support bar 314 is inserted into the socket 317, the connection between the inner column 33 and the lower part of the combined cylinder 31 is performed, otherwise, the upper side support bar 314 is inserted into the socket 317, and the lower side support bar 314 is separated from the socket 317.

In this embodiment, as shown in fig. 1, 2, 3, 4, 5 to 12, the combined cylinder 31 includes a main spiral cylinder wall 31-1 fixedly installed in the tube holder 2, and a sub spiral cylinder wall 31-2 is rotatably fitted on the main spiral cylinder wall 31-1, and the sub spiral cylinder wall 31-2 and the main spiral cylinder wall 31-1 are combined to form a hollow cylinder structure with upper and lower openings;

the upper jack 317 is located on the main screw cylinder wall 31-1, the lower jack 317 is located on the auxiliary screw cylinder wall 31-2 and the main screw cylinder wall 31-1, and after unlocking the lower support bar 314, the parallel combination performed by the lower support bar 314 and the inner column 33 is synchronously released between the main screw cylinder wall 31-1 and the auxiliary screw cylinder wall 31-2;

the upper side of the outer surface of the auxiliary spiral cylinder wall 31-2 is fixedly provided with a handle 31-3, the inner bottom of the auxiliary spiral cylinder wall 31-2 is fixedly provided with a tray 31-4, the auxiliary spiral cylinder wall 31-2 is pushed by the handle 31-3 to rotate along the main spiral cylinder wall 31-1 so as to drive the tray 31-4 to move downwards and push out an inner flange outwards;

the tray 31-4 and the inner column 33 are provided with a sustained release device 31-5.

In this embodiment, as shown in fig. 3 to 12, the sustained release device 31-5 includes a post opening 31-51 formed on the tray 31-4, wherein the post opening 31-51 is for inserting the inner post 33, a plurality of grooves 31-52 are formed at the bottom of the side surface of the inner post 33, and the plurality of grooves 31-52 are formed in a ring array along the inner post 33;

the elastic sheet 31-53 is arranged in the groove 31-52, the top end of the elastic sheet 31-53 is fixedly connected along the inner top wall of the groove 31-52, the elastic sheet 31-53 deflects outwards from the groove 31-52, an edge 31-54 for propping the column opening 31-51 is fixedly arranged at the bottom end of the elastic sheet 31-53, after the tray 31-4 moves downwards away from the combined cylinder 31, the edge 31-54 is pushed by the elastic sheet 31-53 to expand outwards, the upper flange is blocked by the edge 31-54 after falling, and cannot directly leave the combined cylinder 31 along with the tray 31-4, along with the upward movement of the tray 31-4, the elastic sheet 31-53 can be propped along the edge 31-54, the blocked flange falls on the tray 31-4, and moves downwards along with the tray 31-4 to be released.

In this embodiment, as shown in fig. 3 and 5, a knob is fixedly disposed at the top end of the rotating shaft 35, so that a user can rotate the rotating shaft 35 to control the movement of the upper and lower sets of support bars 314.

In this embodiment, as shown in fig. 3 and 7, the surface of the handle 31-3 is fixedly provided with a rubber sleeve with a frosted surface, so that the friction force when the palm of a user contacts the handle 31-3 can be effectively improved, and the auxiliary spiral cylinder wall 31-2 can be conveniently and stably operated.

The main spiral cylinder wall 31-1 is provided with a spiral groove matched with the spiral track, the auxiliary spiral cylinder wall 31-2 is provided with a convex edge matched with the spiral groove, and when the auxiliary spiral cylinder wall 31-2 moves downwards along the main spiral cylinder wall 31-1, the convex edge is embedded in the spiral groove to stably rotate downwards, so that the two are prevented from being separated from each other.

The tray 31-4 is fixedly installed on the secondary spiral cylinder wall 31-2 through bolts, and the tray 31-4 can be rapidly operated by screwing out the bolts through related tools, so that a user can maintain and overhaul.

As shown in fig. 1 to 12, the use method and advantages of the present invention:

the flanges are put into the flange storage cylinder 3 for stacking and placing, and then the transportation of the flanges can be realized by using the cart 1;

before the flange is installed in the combined cylinder 31, the rotating shaft 35 is rotated to enable the two groups of threads 312 to rotate, the upper side threads 312 drive the upper side rack 310, the sliding rack 39 and the supporting bar 314 to move inwards close to the axis of the rotating shaft 35, the upper side supporting bar 314 is separated from the inserting opening 317, the connection between the inner column 33 and the upper part of the combined cylinder 31 is released, in the process, the lower side threads 312 drive the lower side rack 310, the sliding rack 39 and the supporting bar 314 to move outwards far away from the axis of the rotating shaft 35, the lower side supporting bar 314 is inserted into the inserting opening 317, the connection between the inner column 33 and the lower part of the combined cylinder 31 is carried out, then the flange is installed between the inner column 33 and the combined cylinder 31, the upper side supporting bar 314 is pushed to fall into the combined cylinder 31, the damping of the capsule 32 is gradually reduced to the bottom of the combined cylinder 31, after the transfer is completed, the rotating shaft 35 is rotated, the upper side supporting bar 314 is inserted into the upper side inserting opening 317 to be connected and fixed, and the lower side supporting bar 314 is separated from the lower side inserting opening 317, the flange in the process, the flange in the combined cylinder 31 can be pushed down from the combined cylinder 31 to be discharged, and the flange in the combined cylinder 31 can be quickly removed;

after unlocking the lower support bar 314, the flange falls down onto the tray 31-4 along the inner column 33, and the parallel combination of the lower support bar 314 and the inner column 33 is synchronously released between the main screw cylinder wall 31-1 and the auxiliary screw cylinder wall 31-2, and then the auxiliary screw cylinder wall 31-2 is pushed by the handle 31-3 to rotate along the main screw cylinder wall 31-1 so as to drive the tray 31-4 to move downwards and push out the internal flange outwards;

when the auxiliary spiral cylinder wall 31-2 rotates to drive the tray 31-4 to move downwards, the flange on the tray 31-4 moves downwards, is not influenced by the elastic sheet 31-53 and the edge 31-54, and leaves the combined cylinder 31 downwards for a user to take out, after the tray 31-4 and the flange leave the combined cylinder 31, the elastic sheet 31-53 pushes the edge 31-54 to expand outwards, the upper flange falls down and is blocked by the edge 31-54, and the upper flange cannot directly leave the combined cylinder 31 after the tray 31-4 moves away from the combined cylinder 31, and along with the upward movement of the tray 31-4, the curved elastic sheet 31-53 can be compressed along the edge 31-54, so that the blocked flange falls on the tray 31-4 for discharging again.

Claims

1. The utility model provides a flange transfer device, includes shallow (1), fixed a plurality of tube socket (2) that are provided with on shallow (1), and tube socket (2) are upper and lower through structure, two sides about the handcart (1) car hopper are run through to tube socket (2), its characterized in that: a flange storage cylinder (3) is arranged in the tube seat (2);

the flange storage cylinder (3) comprises a combined cylinder (31) arranged in the tube seat (2), and a capsule (32) for slowing down the sliding speed of the flange is arranged on the inner wall of the combined cylinder (31);

an inner column (33) is arranged in the combined cylinder (31), a column hole (34) is vertically formed in the middle of the inner column (33), and a rotating shaft (35) is rotationally connected to the column hole (34);

the side surfaces of the inner columns (33) are provided with notches (36), the notches (36) are arranged in two groups, and the notches (36) in two groups are respectively positioned on the upper side and the lower side of the inner columns (33);

the inner column (33) is internally provided with a through hole (37), the through hole (37) is communicated with a notch (36) and a column hole (34), two sliding grooves (38) are symmetrically formed in the upper position of the inner side wall of the notch (36), the sliding grooves (38) are slidably connected with a sliding frame (39), one side of the surface of the sliding frame (39) opposite to the notch is fixedly connected with a rack (310), and tooth surfaces of the rack (310) are positioned on the upper surface of the sliding frame and are arranged along the radial direction of a rotating shaft (35);

two ring grooves (311) are formed in the surface of the rotating shaft (35), the two ring grooves (311) correspond to the two groups of notch grooves (36) and the sliding frame (39) respectively, threads (312) are formed in the inner top wall of the ring groove (311), the rack (310) penetrates through the through hole (37) to extend into the ring groove (311), and the rack (310) is meshed with the threads (312);

threads (312) in the two ring grooves (311) are oppositely arranged;

the sliding frame (39) is of a C-shaped structure, a connecting shaft (313) is fixedly arranged on the inner side of the sliding frame (39), a supporting bar (314) is rotatably arranged on the connecting shaft (313), a circular groove (315) is formed in the side surface of the supporting bar (314) corresponding to the connecting shaft (313), a torsion spring (316) is arranged in the circular groove (315), two ends of the torsion spring (316) are respectively connected to the connecting shaft (313) and the supporting bar (314), and the torsion spring (316) pushes the supporting bar (314) to rotate upwards to be transversely arranged;

the upper side and the lower side of the inner wall of the combined cylinder (31) are respectively provided with a socket (317) corresponding to the same side supporting bar (314).

2. The connection flange transfer device of claim 1, wherein: the combined cylinder (31) comprises a main spiral cylinder wall (31-1) fixedly arranged in the tube seat (2), an auxiliary spiral cylinder wall (31-2) is rotationally embedded on the main spiral cylinder wall (31-1), and the auxiliary spiral cylinder wall (31-2) and the main spiral cylinder wall (31-1) are combined to form a hollow cylinder structure with upper and lower openings;

the upper side of the socket (317) is positioned on the main spiral cylinder wall (31-1), and the lower side of the socket (317) is positioned on the auxiliary spiral cylinder wall (31-2) and the main spiral cylinder wall (31-1) respectively;

a handle (31-3) is fixedly arranged on the upper side of the outer surface of the auxiliary spiral cylinder wall (31-2), and a tray (31-4) is fixedly arranged at the inner bottom of the auxiliary spiral cylinder wall (31-2);

the tray (31-4) and the inner column (33) are provided with a slow release device (31-5).

3. The connection flange transfer device of claim 2, wherein: the slow release device (31-5) comprises a column opening (31-51) formed in the tray (31-4), the column opening (31-51) is used for inserting an inner column (33), a plurality of grooves (31-52) are formed in the bottom of the side surface of the inner column (33), and the grooves (31-52) are in an annular array along the inner column (33);

elastic pieces (31-53) are arranged in the grooves (31-52), the top ends of the elastic pieces (31-53) are fixedly connected along the inner top wall of the grooves (31-52), the elastic pieces (31-53) deflect outwards from the grooves (31-52), and edges (31-54) for supporting and pressing the column openings (31-51) are fixedly arranged at the bottom ends of the elastic pieces (31-53).

4. The connection flange transfer device of claim 2, wherein: the surface of the handle (31-3) is fixedly provided with a frosted rubber sleeve.

5. The connection flange transfer device of claim 2, wherein: spiral grooves matched with the spiral track are formed in the embedded surface of the main spiral cylinder wall (31-1), and ribs matched with the spiral grooves are arranged on the embedded surface of the auxiliary spiral cylinder wall (31-2).

6. The connection flange transfer device of claim 2, wherein: the tray (31-4) is fixedly arranged on the secondary spiral cylinder wall (31-2) through bolts.

7. The connection flange transfer device of claim 1, wherein: the top end of the rotating shaft (35) is fixedly provided with a knob.