CN210231149U - Dense bus pressing equipment - Google Patents

Abstract

The utility model discloses an intensive generating line compresses tightly equipment, support post install on main workstation, support cantilever's first end is installed on support post's top, support cantilever and support post rotate the installation through vertical pivot, support cantilever can be for support post horizontal rotation, be in different angles; the punching device is arranged on the supporting cantilever and can move up and down in a reciprocating manner to punch the dense bus conveyed on the main workbench; the second end of joint support cantilever can be dismantled to the upper end of cantilever pull rod, main workstation is connected to the lower extreme, the cantilever pull rod makes the cantilever end of supporting the cantilever form with main workstation and is connected, when carrying out the punching press operation through stamping device, the support cantilever bears ascending impact force, the first end of support cantilever is connected by the support post, the second end is connected by the cantilever pull rod, the both ends of support cantilever are connected respectively by support post and cantilever pull rod, will support the impact transfer to the main workstation that the cantilever received, structural strength is high, and is not fragile.

Description

Dense bus pressing equipment

Technical Field

The utility model relates to a wire production technical field further relates to an intensive generating line compresses tightly equipment.

Background

The intensive bus duct is suitable for power supply and distribution systems of alternating current three-phase four-wire and three-phase five-wire systems, and is a bus system which is composed of a metal plate as a protective shell, a conductive bar, an insulating material and related accessories.

The bus conductors of the dense buses are coated by insulating materials, no space gap exists among the conductors, the bus conductors as a whole radiate heat outwards, no connecting space exists in the buses, no air flows, and the chimney effect is avoided; the heat dissipation area is large, the temperature rise is low, the compact and small appearance can save space, and the transportation and the installation are convenient.

The equipment for processing the intensive bus duct generally adopts a cylinder telescopic stamping form, a plurality of cylinders are arranged on a frame beam, and the cylinders reciprocate to transversely stretch and move in a reciprocating manner to continuously stamp the compact bus duct.

The moving range of the cylinder is influenced by the width of the frame beam, so that the defects of complex structure, high processing difficulty and the like are caused; for those skilled in the art, how to design an intensive bus duct production device with high structural strength and simple structure is a technical problem to be solved at present.

SUMMERY OF THE UTILITY MODEL

The utility model provides an intensive generating line compresses tightly equipment, simple structure, structural strength is high, and is not fragile, and concrete scheme is as follows:

a dense busbar pressing apparatus comprising:

the main workbench is used for conveying the dense buses;

the supporting upright post is arranged on the main workbench;

a first end of the supporting cantilever is rotatably mounted at the top end of the supporting upright post through a vertical rotating shaft, and the supporting cantilever can transversely rotate relative to the supporting upright post;

the stamping device is arranged on the supporting cantilever and can vertically reciprocate to stamp the dense bus conveyed on the main workbench in a translation manner;

the upper end of the cantilever pull rod is detachably connected with the second end of the supporting cantilever, and the lower end of the cantilever pull rod is connected with the main workbench.

Optionally, one side of the main workbench is transversely provided with an upright slide rail, and the other side of the main workbench is transversely provided with a pull rod slide rail; the support upright post can transversely move along the upright post slide rail, and the cantilever pull rod can transversely move along the pull rod slide rail;

and the supporting upright is provided with an upright jacking bolt which is used for matching with the main workbench to jack up and limit.

Optionally, the cantilever pull rod comprises a sliding seat, a fixed seat and a vertical rod;

the pull rod slide rail is a straight rod with a smooth surface, and the slide seat is slidably sleeved on the pull rod slide rail; the fixed seat is fixedly arranged at the second end of the supporting cantilever; the two ends of the vertical rod are respectively connected with the sliding seat and the fixed seat.

Optionally, the positions of the side wall of the vertical rod, which are close to the two ends, are respectively provided with a U-shaped notch, and the sliding seat and the connecting column which is convexly arranged on the fixed seat can stretch into the U-shaped notches.

Optionally, a locking rod is installed on the vertical rod, one end of the locking rod is rotatably installed on the vertical rod, and the other end of the locking rod can be detachably assembled with the vertical rod through a bolt.

Optionally, a cylindrical roller is arranged on the inner wall of the sliding groove of the sliding seat.

Optionally, the support column and the cantilever pull rod are both steel structure frames, and the support column and the cantilever pull rod are connected through a slewing bearing.

Optionally, the upper surface of the support column is provided with a circular arc-shaped cantilever guide rail, and a cantilever guide pin arranged on the support cantilever is matched with the cantilever guide rail for guiding;

and the support cantilever is provided with a cantilever locking device which is used for being matched with the support upright post to tightly support and limit.

The utility model provides a dense bus pressing device, wherein a main workbench supports a dense bus and drives the dense bus to move for conveying; the supporting upright post is arranged on the main workbench, the first end of the supporting cantilever is arranged at the top end of the supporting upright post, the supporting cantilever is rotatably arranged with the supporting upright post through a vertical rotating shaft, and the supporting cantilever can transversely rotate relative to the supporting upright post and is positioned at different angles; the punching device is arranged on the supporting cantilever and driven by the supporting cantilever to move synchronously, and can move up and down in a reciprocating manner to punch the dense buses conveyed on the main workbench; the second end of joint support cantilever can be dismantled to the upper end of cantilever pull rod, main workstation is connected to the lower extreme, the cantilever pull rod makes the cantilever end of supporting the cantilever form with main workstation and is connected, when carrying out the punching press operation through stamping device, the support cantilever bears ascending impact force, the first end of support cantilever is connected by the support post, the second end is connected by the cantilever pull rod, the both ends of support cantilever are connected respectively by support post and cantilever pull rod, will support the impact transfer to the main workstation that the cantilever received, structural strength is high, and is not fragile.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1A is an isometric view of a front perspective of the dense busbar pressing apparatus of the present invention;

fig. 1B is an isometric view of a rear perspective of the dense busbar pressing apparatus of the present invention;

fig. 2 is a side view of the dense busbar pressing device of the present invention;

FIG. 3A is an isometric view of a cantilever pull rod;

FIG. 3B is a front view of the cantilever pull rod;

FIG. 3C is a side view of the cantilever pull rod;

fig. 4 is a schematic structural view of a vertical rod.

The figure includes:

the device comprises a main workbench 1, a stand column slide rail 11, a pull rod slide rail 12, a support stand column 2, a stand column jacking bolt 21, a cantilever guide rail 22, a support cantilever 3, a cantilever guide pin 31, a cantilever locking device 32, a stamping device 4, a cantilever pull rod 5, a sliding seat 51, a fixed seat 52, a vertical rod 53, a U-shaped notch 531, a connecting column 54, a lock rod 55 and a rotary bearing 6.

Detailed Description

The core of the utility model is to provide an intensive generating line compresses tightly equipment, simple structure, structural strength is high, and is not fragile.

In order to make those skilled in the art better understand the technical solution of the present invention, the following will describe the dense busbar pressing device of the present invention in detail with reference to the accompanying drawings and specific embodiments.

As shown in fig. 1A and 1B, an axonometric view of a front visual angle and an axonometric view of a rear visual angle of the intensive busbar pressing equipment of the present invention are shown, respectively; fig. 2 is a side view of the dense busbar pressing device of the present invention; the bus bar stamping device comprises a main workbench 1, a support upright post 2, a support cantilever 3, a stamping device 4, a cantilever pull rod 5 and other structures, wherein the main workbench 1 is of a support structure, dense buses are placed on the main workbench 1, and the main workbench 1 can be in a roller way or a conveying belt or other forms and is used for conveying the dense buses placed on the main workbench; the supporting upright post 2 is arranged on the main workbench 1, the supporting upright post 2 is positioned on the side of the main workbench 1, and the supporting upright post 2 is vertically arranged; support cantilever 3 is horizontal setting, and the first end of supporting cantilever 3 is installed on the top of support post 2, rotates through vertical rotating shaft between support cantilever 3 and support post 2 and is connected the assembly, and support cantilever 3 can be for support post 2 lateral rotation, and the motion trail of supporting cantilever 3 is a fan-shaped in the horizontal plane promptly, and the motion trail of supporting cantilever 3 is.

The stamping device 4 is arranged on the supporting cantilever 3, the stamping device 4 synchronously moves along with the supporting cantilever 3, and the stamping device 4 can rotate to different positions along with the supporting cantilever 3; the stamping device 4 can move up and down in a reciprocating mode to stamp the dense bus conveyed on the main workbench 1, the stamping device 4 is an air cylinder or a hydraulic cylinder, and the bottom of the telescopic end of the stamping device 4 is in contact with the dense bus to apply stamping acting force to the dense bus.

The support device comprises a main workbench 1, a plurality of support columns 2 are arranged along the transverse extension direction of the main workbench 1, a stamping device 4 is installed on each support column 2, when dense buses need to be stamped, the stamping device 4 is rotated right above the dense buses, when stamping is not needed, a support cantilever 3 is rotated to one side of the main workbench 1, and the length direction of the support cantilever 3 is approximately parallel to the transverse extension direction of the main workbench 1.

The cantilever pull rod 5 is vertically arranged, the upper end of the cantilever pull rod 5 is detachably connected with the second end of the supporting cantilever 3, the lower end of the cantilever pull rod 5 is connected with the main workbench 1, the cantilever pull rod 5 enables the cantilever end of the supporting cantilever 3 to be connected with the main workbench 1, when stamping operation is carried out through the stamping device 4, the supporting cantilever 3 bears upward impact force, the first end of the supporting cantilever 3 is connected by the supporting upright post 2, the second end of the supporting cantilever 3 is connected by the cantilever pull rod 5, the supporting upright post 2 and the cantilever pull rod 5 are respectively connected with the two ends of the supporting cantilever 3, the impact borne by the supporting cantilever 3 is transferred to the main workbench 1, the supporting cantilever 3 is not in a cantilever beam structure any more during operation, the phenomenon of stress concentration between the supporting cantilever 3 and the supporting upright post 2 is greatly; because stamping device 4 punches intensive generating line through the mode of vertical flexible punching press, the stroke does not receive the restriction of main workstation 1 width, connects main workstation 1 through support cantilever 3 and support post 2, simple structure.

On the basis of the above scheme, the utility model discloses one side of well main workstation 1 transversely sets up stand slide rail 11, and the opposite side transversely sets up pull rod slide rail 12, and stand slide rail 11 and pull rod slide rail 12 are located main workstation 1's relative both sides respectively, with main workstation 1's length direction syntropy.

The supporting upright post 2 and the cantilever pull rod 5 are respectively positioned at two sides of the main workbench 1, the upright post slide rail 11 is used for guiding the supporting upright post 2, and the supporting upright post 2 can transversely move along the upright post slide rail 11; the pull rod slide rail 12 is used for guiding the cantilever pull rod 5, and the cantilever pull rod 5 can transversely move along the pull rod slide rail 12.

Because the supporting upright column 2 and the cantilever pull rod 5 are respectively connected to two ends of the supporting cantilever 3, and the supporting upright column 2, the supporting cantilever 3 and the cantilever pull rod 5 keep moving synchronously; in the production and processing process, the position of the stamping device 4 needs to be adjusted according to the length and the size of the dense bus and the difference of the stamping position, the support upright post 2 is guided by the upright post slide rail 11, and the cantilever pull rod 5 is guided by the pull rod slide rail 12, so that the support upright post 2, the support cantilever 3, the cantilever pull rod 5 and the stamping device 4 keep synchronous sliding movement, and the stamping device 4 is adjusted to a proper position.

The supporting upright post 2 is provided with an upright post puller bolt 21, as shown in fig. 2, the upright post puller bolt 21 is transversely arranged and is in threaded connection with the supporting upright post 2, and the end part of the upright post puller bolt 21 can be contacted with the main workbench 1 and is used for being matched with the main workbench 1 to carry out puller limiting, so that the positions of the supporting upright post 2 and the main workbench 1 are kept relatively fixed; after moving to the set position, the support column 2 is locked on the main worktable 1 through the column jacking bolt 21.

As shown in fig. 3A, is an isometric view of the cantilever pull rod 5; fig. 3B and 3C are a front view and a side view, respectively, of the cantilever pull rod 5; the cantilever pull rod 5 of the utility model comprises a sliding seat 51, a fixed seat 52 and a vertical rod 53; the pull rod slide rail 12 is a straight rod with smooth appearance, the section of the pull rod slide rail 12 is I-shaped, the section of the part of the slide seat 51 matched with the pull rod slide rail 12 is C-shaped, and the slide seat 51 is sleeved on the pull rod slide rail 12 in a sliding way; the fixed seat 52 is fixedly arranged at the second end of the supporting cantilever 3; the two ends of the vertical rod 53 are respectively connected with the sliding seat 51 and the fixed seat 52, and the vertical rod 53 can transmit acting force between the sliding seat 51 and the fixed seat 52.

As shown in fig. 4, it is a schematic structural diagram of the vertical rod 53; the positions of the side wall of the vertical rod 53 close to the two ends are respectively provided with a U-shaped notch 531, the connecting columns 54 are respectively arranged on the sliding seat 51 and the fixed seat 52, the connecting columns 54 protruding out of the sliding seat 51 and the fixed seat 52 can stretch into the U-shaped notches 531, and the sliding seat 51 and the vertical rod 53, the fixed seat 52 and the vertical rod 53 are both movably connected structures, so that the stress concentration phenomenon can be avoided.

A lock rod 55 is arranged on the vertical rod 53, one end of the lock rod 55 is rotatably arranged on the vertical rod 53, and the other end of the lock rod 55 can be detachably assembled with the vertical rod 53 through a bolt; as shown in fig. 4, one end of the lock rod 55 is provided with a closed circular hole, the other end is provided with a U-shaped opening, the end provided with the closed circular hole is rotatably connected with the vertical rod 53, and one end of the U-shaped opening is screwed on the vertical rod 53 through a bolt; the locking rod 55 closes the opening of the U-shaped notch 531 to form a closed ring shape, so as to prevent the connecting column 54 arranged on the sliding seat 51 and the fixed seat 52 from being separated from the U-shaped notch 531.

Preferably, cylindrical rollers are arranged on the inner wall of the sliding groove of the sliding seat 51 to reduce the friction force, and similarly, corresponding cylindrical rollers are arranged on the sliding seat between the support column 2 and the column slide rail 11.

Preferably, the supporting upright post 2 and the cantilever pull rod 5 are both steel structure frames, the supporting upright post 2 and the cantilever pull rod 5 are connected through a slewing bearing 6, and the slewing bearing 6 plays a dual role in supporting and rotating connection.

Preferably, a circular arc-shaped cantilever guide rail 22 is arranged on the upper surface of the support upright 2, and the cantilever guide rail 22 is of a groove-shaped structure; support and set up cantilever guide pin 31 on cantilever 3, cantilever guide pin 31 can stretch into cantilever guide rail 22 in, with cantilever guide rail 22 cooperation direction, cantilever guide pin 31 and cantilever guide rail 22 contact play the supporting role, also support cantilever 3 under the cantilever beam state, provide the holding power by slewing bearing 6 and cantilever guide pin 31 simultaneously.

Support and set up on the cantilever 3 and be used for supporting stand 2 cooperation top spacing cantilever locking device 32, cantilever locking device 32 is the bolt of vertical setting, keeps the threaded connection cooperation with support cantilever 3, and cantilever locking device 32 during screwing up with support stand 2's upper surface contact top tightly, prescribes a limit to and supports cantilever 3 and can't rotate.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (8)

1. A dense busbar pressing apparatus, comprising:

the main workbench (1) is used for conveying dense buses;

the supporting upright post (2) is arranged on the main workbench (1);

a supporting cantilever (3), the first end of which is rotatably mounted at the top end of the supporting upright (2) through a vertical rotating shaft, the supporting cantilever (3) can transversely rotate relative to the supporting upright (2);

the stamping device (4) is arranged on the supporting cantilever (3) and can reciprocate up and down to stamp the dense bus conveyed on the main workbench (1);

and the upper end of the cantilever pull rod (5) is detachably connected with the second end of the supporting cantilever (3), and the lower end of the cantilever pull rod is connected with the main workbench (1).

2. The dense busbar pressing equipment according to claim 1, wherein one side of the main workbench (1) is transversely provided with a column slide rail (11), and the other side of the main workbench (1) is transversely provided with a pull rod slide rail (12); the support upright post (2) can transversely move along the upright post slide rail (11), and the cantilever pull rod (5) can transversely move along the pull rod slide rail (12);

and the supporting upright post (2) is provided with an upright post puller bolt (21) which is used for matching with the main workbench (1) to jack and limit.

3. The dense busbar pressing device according to claim 2, wherein the cantilever pull rod (5) comprises a sliding seat (51), a fixed seat (52) and a vertical rod (53);

the pull rod slide rail (12) is a straight rod with a smooth surface, and the slide seat (51) is slidably sleeved on the pull rod slide rail (12); the fixed seat (52) is fixedly arranged at the second end of the supporting cantilever (3); two ends of the vertical rod (53) are respectively connected with the sliding seat (51) and the fixed seat (52).

4. The dense busbar pressing device according to claim 3, wherein U-shaped notches (531) are respectively formed in the side walls of the vertical bars (53) near the two ends, and connecting columns (54) protruding from the sliding seat (51) and the fixed seat (52) can extend into the U-shaped notches (531).

5. The dense busbar pressing device according to claim 4, wherein a locking rod (55) is mounted on the vertical rod (53), one end of the locking rod (55) is rotatably mounted on the vertical rod (53), and the other end of the locking rod can be detachably assembled with the vertical rod (53) through a bolt.

6. The dense busbar pressing apparatus according to claim 5, wherein cylindrical rollers are provided on the inner wall of the sliding groove of the sliding seat (51).

7. The dense busbar pressing equipment according to claim 5, wherein the support column (2) and the cantilever pull rod (5) are both steel structure frames, and the support column (2) and the cantilever pull rod (5) are connected through a slewing bearing (6).

8. The dense busbar pressing equipment according to claim 7, wherein the upper surface of the support column (2) is provided with a cantilever guide rail (22) in the shape of a circular arc, and a cantilever guide pin (31) provided on the support cantilever (3) is guided in cooperation with the cantilever guide rail (22);

and the support cantilever (3) is provided with a cantilever locking device (32) which is used for being matched with the support upright post (2) to jack and limit.

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