CN221603838U - Synchronous processing tool for a plurality of strip-shaped workpieces - Google Patents

Abstract

The application discloses a synchronous processing tool for a plurality of strip-shaped workpieces, which comprises clamping assemblies for synchronously positioning and clamping a plurality of strip-shaped workpieces, wherein the clamping assemblies can be used for completely exposing the processing surface of the strip-shaped workpieces successively in a position adjusting state. The clamping assembly comprises a first clamping plate and a second clamping plate, wherein clamping grooves which are embedded into a strip-shaped workpiece and are of a step structure are formed in the first clamping plate at intervals, the second clamping plate is of a grid-shaped structure and comprises an upper beam and a lower beam, pressing beams are vertically and at intervals connected between the upper beam and the lower beam, and fastening bolts connected with the first clamping plate are uniformly distributed on the upper beam and the lower beam in a penetrating mode. The synchronous processing tool can realize synchronous clamping of a plurality of strip-shaped workpieces through the clamping assembly, and further can realize continuous processing operation and improve batch processing efficiency of the strip-shaped workpieces when a machine tool is used for processing. The clamping assembly can clamp a workpiece on the machine tool for high-precision machining, and the problem that the existing manual handheld machining is low in dimensional precision is solved.

Description

Synchronous processing tool for a plurality of strip-shaped workpieces

Technical Field

The application relates to the technical field of machining of strip-shaped workpieces, in particular to a synchronous machining tool for a plurality of strip-shaped workpieces.

Background

The strip-shaped workpiece is widely applied in the field of industrial production, such as copper plates for replacing wire communication in an electrical power distribution cabinet, lightning-protection grounding flat irons of high-rise buildings and the like. Typical machining processes for such elongated workpieces include locating holes, surface milling, grinding, etc., to facilitate their connection in later use, etc.

The strip-shaped workpiece is usually small in external dimension, particularly in thickness, so that the strip-shaped workpiece is easy to bend under external force. Because of its small thickness, it is often subject to excessive clamping forces during processing clamping to deform, so that long workpieces cannot be clamped very well and quickly at present during processing. Because the processing technology of the strip-shaped workpiece is simple, manual holding operation is usually adopted, such as manual drilling, surface polishing by using a grinder to hold the workpiece, and the like. Under the influence of artificial factors, the processing quality of the strip-shaped workpiece is poor, and particularly, the deflection existing during hole site processing influences the connection operation of the subsequent hole sites, so that the hole sites are not aligned and reworked for reaming. Meanwhile, during batch processing production, the manual processing efficiency is lower.

Disclosure of Invention

The application aims to provide a synchronous processing tool for a plurality of long workpieces, which can realize synchronous clamping of the plurality of long workpieces, further realize continuous processing operation when a machine tool is used for processing, further improve the batch processing efficiency of the long workpieces and solve the problem of low manual handheld processing precision.

In order to achieve the above purpose, the technical scheme adopted by the application is as follows: a synchronous processing frock of a plurality of strip work pieces, its characterized in that: the synchronous processing tool comprises a clamping assembly for synchronously positioning and clamping a plurality of strip-shaped workpieces, and the clamping assembly can be used for gradually exposing the processing surface of the strip-shaped workpieces in a position adjusting state.

Preferably, the clamping assembly comprises a first clamping plate and a second clamping plate, wherein clamping grooves embedded into the long-strip-shaped workpiece and having a step structure are formed in the first clamping plate at intervals, one ends of the clamping grooves penetrate through the clamping grooves, and the lengths and the widths of the clamping grooves are smaller than the corresponding sizes of the long-strip-shaped workpiece.

Preferably, the second clamping plate is of a grid-shaped structure and comprises an upper beam and a lower beam, wherein pressing beams are vertically and alternately connected between the upper beam and the lower beam, and fastening bolts connected with the first clamping plate are uniformly distributed on the upper beam and the lower beam in a penetrating manner.

Preferably, waist-shaped holes for adjusting the dislocation of the pressing positions of the pressing beams are formed in the upper beam and the lower beam.

The beneficial effects of the application are as follows: the synchronous processing tool can realize synchronous clamping of a plurality of strip-shaped workpieces through the clamping assembly, and further can realize continuous processing operation when a machine tool is used for processing, so that the batch processing efficiency of the strip-shaped workpieces is improved. Meanwhile, the clamping assembly can avoid the influence on the surface machining interference of the workpiece through position adjustment, and further the complete exposure and complete machining of the machining surface of the strip-shaped workpiece are realized. The clamping assembly can clamp the workpiece on the machine tool for high-precision machining, and the problem of low precision of the existing manual handheld machining size is solved.

Drawings

Fig. 1 is a schematic view of the structure of an elongated workpiece according to the present application (top view, bottom view, front view).

Fig. 2 is a structural diagram of the synchronous processing tool of the present application.

Fig. 3 is a side view structural diagram of a first clamping plate of the present application.

Fig. 4 is a side view structural diagram of a second clamping plate of the present application.

Fig. 5 is a side view of a synchronous machining tool for clamping a strip-shaped workpiece.

Fig. 6 is a right side view of fig. 5 in accordance with the present application.

Fig. 7 is a position adjustment illustration of the second clamping plate of the present application compared to the first clamping plate.

In the figure: 4-strip-shaped workpieces.

Detailed Description

In order to enable those skilled in the art to better understand the technical solution of the present application, the technical solution of the present application is further described below with reference to the accompanying drawings and examples.

1-7, The synchronous processing tool comprises a clamping assembly for synchronously positioning and clamping a plurality of strip-shaped workpieces, wherein the synchronous clamping assembly can synchronously clamp the plurality of strip-shaped workpieces, and further can realize continuous processing operation when a machine tool is used for processing, so that the batch processing efficiency of the strip-shaped workpieces is improved.

Because the processing technology of the strip-shaped workpiece is usually to process (such as drilling, polishing and the like) on the surface of the strip-shaped workpiece, in order to avoid the influence of the clamping assembly on the surface processing interference of the workpiece during processing, the clamping assembly can also gradually expose the processing surface of the strip-shaped workpiece in a position adjustment state. Furthermore, the clamping assembly is used for avoiding interference influence on the processing surface of the workpiece on the basis of realizing batch clamping of the workpiece.

Specifically, as shown in fig. 2-3, the clamping assembly includes a first clamping plate 1 and a second clamping plate 2, and clamping grooves 1a embedded in the strip-shaped workpiece and having a step structure are formed on the first clamping plate 1 at intervals. The clamping groove 1a is arranged to be of a step structure, so that after a strip-shaped workpiece to be processed is embedded into the clamping groove 1a for positioning and clamping, the bottom surface (a large part position, namely, an opening position) of the workpiece is not contacted with the inner bottom surface of the clamping groove 1a, and further, when the drilling operation is carried out, a drilling tool does not contact with the inner bottom surface of the clamping groove 1a after passing through the workpiece, so that the processing of the clamping groove 1a is damaged.

As shown in fig. 3, one end of the clamping groove 1a is penetrated, and the length and width of the clamping groove 1a are smaller than the corresponding dimensions of the strip-shaped workpiece. The through structure at one end of the clamping groove 1a is convenient for the smooth embedding of the long-strip-shaped workpiece, and is also suitable for embedding and clamping of the workpiece with the length longer than that of the clamping groove 1 a; the depth of the clamping groove 1a is smaller than the thickness of the workpiece, so that the outer surface of the workpiece extends out of the clamping groove 1a, and when the workpiece is clamped by the first clamping plate 1 and the second clamping plate 2 in a matched mode, the outer surface of the workpiece can be in flat contact with the second clamping plate 2, and clamping is achieved.

Specifically, as shown in fig. 4, the second clamping plate 2 has a grid-shaped structure, and includes an upper beam 21 and a lower beam 22, and a pressing beam 23 is vertically and at a distance between the upper beam 21 and the lower beam 22, and fastening bolts 3 connected with the first clamping plate 1 are uniformly distributed on the upper beam 21 and the lower beam 22. After the plurality of strip-shaped workpieces to be processed are embedded and positioned in the clamping groove 1a, the strip-shaped workpieces are synchronously pressed and stuck on the plurality of strip-shaped workpieces through the plurality of pressing beams 23 of the second clamping plate 2, the second clamping plate 2 is connected and fastened with the first clamping plate 1 through the fastening bolts 3, the clamping force on the workpieces is applied, and then the workpieces are integrally clamped on a machine tool, so that continuous batch processing can be performed.

When the workpiece is clamped and processed, the surface of the workpiece which is not pressed by the pressing beam 23 can be processed, and the surface of the workpiece pressed by the pressing beam 23 causes processing interference, so that the processing of the workpiece part covered by the pressing beam 23 is realized, and as shown in fig. 7, the upper beam 21 and the lower beam 22 are respectively provided with a waist-shaped hole 2a for adjusting the position dislocation of the pressing beam 23. Under the condition that the second clamping plate 2 and the first clamping plate 1 are connected through the fastening bolt 3 is guaranteed through the waist-shaped hole 2a, the second clamping plate 2 and the pressing beam 23 thereof can be shifted, and then the workpiece part pressed by the pressing beam 23 can be processed, so that the complete processing operation on the surface of the strip-shaped workpiece is realized.

The principle of the application is as follows: when a plurality of strip-shaped workpieces are processed, each workpiece is embedded into the clamping groove 1a, one end of the workpiece is propped against the inner end surface of the clamping groove 1a to realize positioning, then the plurality of pressing beams 23 of the second clamping plate 2 are synchronously pressed on the plurality of strip-shaped workpieces, the second clamping plate 2 is connected and fastened with the first clamping plate 1 through the fastening bolts 3, the clamping force on the workpiece is applied, and then the whole workpiece is clamped on a machine tool, so that continuous batch processing can be performed.

The foregoing has shown and described the basic principles, principal features and advantages of the application. The present application is subject to various changes and modifications without departing from the spirit and scope thereof, and such changes and modifications fall within the scope of the application as hereinafter claimed.

Claims (2)

1. A synchronous processing frock of a plurality of strip work pieces, its characterized in that: the synchronous processing tool comprises a clamping assembly for synchronously positioning and clamping a plurality of strip-shaped workpieces, wherein the clamping assembly can be used for completely exposing the processing surface of the strip-shaped workpieces successively in a position adjusting state;

The clamping assembly comprises a first clamping plate (1) and a second clamping plate (2), clamping grooves (1 a) embedded into the strip-shaped workpieces and having a step structure are formed in the first clamping plate (1) at intervals, one end of each clamping groove (1 a) is communicated, and the lengths and the widths of the clamping grooves (1 a) are smaller than the corresponding sizes of the strip-shaped workpieces;

The second clamping plate (2) is of a grid-shaped structure and comprises an upper beam (21) and a lower beam (22), pressing beams (23) are vertically and alternately connected between the upper beam (21) and the lower beam (22), and fastening bolts (3) connected with the first clamping plate (1) are uniformly distributed on the upper beam (21) and the lower beam (22).

2. The synchronous processing tool according to claim 1, wherein: waist-shaped holes (2 a) for adjusting the dislocation of the pressing positions of the pressing beams (23) are formed in the upper beam (21) and the lower beam (22).