CN211465531U - Efficient batch positioning and processing device for radiating fins - Google Patents

Abstract

The utility model relates to a high-efficiency batch positioning and processing device for radiating fins, which comprises a mounting seat, a limiting component and a clamping component, wherein the limiting component comprises a limiting column and two rotary pressing cylinders, the clamping component comprises a placing table, a clamping piece and a locking screw, a plurality of accommodating grooves are arranged on the top surface of the placing table, the clamping piece is arranged on the side surface of the placing table, the clamping piece is arranged corresponding to the accommodating grooves and is used for supporting against a workpiece, so that the workpiece is tightly pressed between the accommodating grooves and the clamping piece, the clamping piece is locked on the side surface of the placing table through the locking screw, and further the workpiece is tightly clamped between the inner side wall of the accommodating groove and the side wall of the clamping piece, thus, the radiating fins to be processed are fixed through the set position, the positioning accuracy of the radiating fins to be processed can be effectively improved, the processing error is reduced, and the product yield, and realize the processing operation of the batch of work piece through setting up a plurality of storage tanks, and then can effectively improve production efficiency.

Description

Efficient batch positioning and processing device for radiating fins

Technical Field

The utility model relates to a novel mechanical production technical field, in particular to high-efficient location processing in batches of fin device.

Background

The mechanical processing mainly comprises two types of manual processing and numerical control processing. Manual machining refers to a method in which a machinist manually operates mechanical equipment such as a milling machine, a lathe, a drilling machine, and a sawing machine to machine various materials. The manual machining is suitable for small-batch and simple part production. Numerical control machining refers to machining performed by a mechanical worker by using numerical control equipment, wherein the numerical control equipment comprises a machining center, a turning and milling center, wire electric discharge machining equipment, a thread cutting machine and the like. Most machining workshops adopt numerical control machining technology.

CNC is a Computer Numerical Control (CNC) machine, and is an automated machine equipped with a program control system that can logically process a program having control codes or other symbolic instructions, which are decoded by a computer to operate the machine and machine a part, such as a blank to a semi-finished part by cutting with a tool.

CNC machining (CNCMachining) refers to machining with a numerically controlled machining tool. CNC numerically controlled machines are programmed by a numerically controlled machining language, typically G-code. The numerical control machining G code tells the machining tool of the numerical control machine tool which Cartesian position coordinate is adopted, and controls the feeding speed and the main shaft rotating speed of the tool, the functions of a tool converter, a coolant and the like. Numerical control machining has great advantages over manual machining, and parts produced by numerical control machining are very accurate and have repeatability; numerical control machining can produce parts with complex shapes which cannot be finished by manual machining. The numerical control machining technology is widely popularized, most machining workshops have numerical control machining capacity, and the most common numerical control machining modes in a typical machining workshop comprise numerical control milling, numerical control turning and numerical control EDM wire cutting (wire cut electrical discharge machining). The tool for carrying out numerical control milling is called a numerical control milling machine or a numerical control machining center. The lathe for performing numerical control turning is called a numerical control turning center. The G-code of the numerical control machining can be programmed manually, but usually, a machining shop automatically reads a CAD (computer aided design) file by CAM (computer aided manufacturing) software and generates a G-code program to control the numerical control machine tool.

Along with the rapid development of the mobile phone industry, more and more mobile phone metal parts need to be processed by CNC (computer numerical control), and the fixture clamp jig cannot be removed in CNC processing, so that the good fixture clamp jig can greatly improve the production efficiency, and the improvement and the optimization of the fixture clamp jig are particularly important.

However, the existing part of the processed workpieces are processed individually, which easily causes the situation of high processing cost and low production efficiency of products. When the volume of some machined workpieces is small, the positioning accuracy of the workpieces is difficult to control when the machined workpieces are machined, large errors are easy to occur in machining engineering, and the yield of the machined workpieces is greatly influenced.

SUMMERY OF THE UTILITY MODEL

Therefore, the efficient batch positioning processing device for the radiating fins is needed to be designed, wherein the production efficiency can be effectively improved, the positioning accuracy can be effectively improved, the processing error is reduced, and the product yield is improved.

An efficient batch positioning and processing device for radiating fins comprises

The mounting seat is provided with a mounting area;

the limiting assembly comprises a limiting column and two rotary pressing cylinders, the limiting column is arranged in the mounting area, the two rotary pressing cylinders are respectively arranged on the mounting seat, the mounting area is positioned between the two rotary pressing cylinders, and the rotary pressing cylinders are provided with pressing blocks; and

the clamping assembly comprises a placing table, a clamping piece and a locking screw, a containing groove is formed in the top surface of the placing table, the accommodating groove is used for accommodating a workpiece, the clamping piece is arranged on the side surface of the placing table, the clamping piece is arranged corresponding to the accommodating groove, the clamping piece is used for being propped against the workpiece, so that the workpiece is tightly pressed between the accommodating groove and the clamping piece, a locking hole is arranged on the side surface of the placing table, the inner side wall of the locking hole is provided with an internal thread, the clamping piece is provided with a through hole, the locking screw penetrates through the through hole, the end part of the locking screw is in threaded connection with the internal thread, the bottom surface of the placing table is provided with a limiting hole, the limiting column is embedded in the limiting hole, and the rotary pressing cylinder is used for pressing and holding the pressing block on the placing table during movement.

In one embodiment, the clamping assembly comprises a plurality of clamping pieces and a plurality of locking screws, a plurality of accommodating grooves are formed in the top surface of the placing table, the clamping pieces are respectively arranged on the side surface of the placing table, and the clamping pieces are arranged corresponding to the accommodating grooves one by one;

the side surface of the placing table is provided with a plurality of locking holes, inner threads are correspondingly formed in the inner side wall of each locking hole, through holes are respectively formed in the clamping pieces, the locking screws penetrate through the through holes in a one-to-one correspondence mode, and the end portions of the locking screws are in one-to-one correspondence with the inner threads.

In one embodiment, a space is arranged between the accommodating grooves.

In one embodiment, the locking screw includes a screw body and a screw post disposed on the screw body.

In one embodiment, the clamping piece is provided with an alignment convex strip, the side surface of the placing table is provided with an alignment groove, and the alignment convex strip is embedded in the alignment groove.

In one embodiment, the placing table is provided with two pressing areas, and the two rotary pressing cylinders are respectively used for rotary pressing to press and hold the two pressing areas.

In one embodiment, the standing platform has a rectangular parallelepiped structure.

In one embodiment, the accommodating groove is a rectangular accommodating groove.

Compared with the prior art, the utility model discloses following beneficial technological effect has:

the efficient batch positioning and processing device for the radiating fins comprises a mounting seat, a limiting component and a clamping component, wherein the clamping component comprises a placing table, a clamping piece and a locking screw, a containing groove is formed in the top surface of the placing table, the containing groove is provided with a plurality of parts, the clamping piece is locked on the side surface of the placing table through the locking screw, and further the workpiece is clamped between the inner side wall of the containing groove and the side wall of the clamping piece, so that the radiating fins to be processed are fixed through the set positions, the positioning accuracy of the radiating fins to be processed can be effectively improved, machining errors are reduced, the product yield is improved, batch processing operation of the workpiece is achieved through the plurality of containing grooves, and the production efficiency can be effectively improved.

Drawings

Fig. 1 is a schematic structural diagram of a batch positioning and processing device for high-efficiency cooling fins according to an embodiment of the present invention.

Fig. 2 is an enlarged view of the efficient batch alignment processing apparatus for heat sinks shown in fig. 1 at a.

The drawings are for illustrative purposes only and are not to be construed as limiting the patent; for the purpose of better illustrating the embodiments, certain features of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted; the same or similar reference numerals correspond to the same or similar parts; the terms describing positional relationships in the drawings are for illustrative purposes only and are not to be construed as limiting the patent.

Detailed Description

The following detailed description of the preferred embodiments of the present invention is provided to enable those skilled in the art to better understand the advantages and features of the present invention, and to define the scope of the present invention more clearly.

Please refer to fig. 1, which is a schematic structural diagram of an efficient batch positioning and processing device 10 for heat dissipation fins according to an embodiment of the present invention. High-efficient processing device 10 that fixes a position in batches of fin includes mount pad 100, spacing subassembly 200 and centre gripping subassembly 300, mount pad 100 is used for the installation and fixes, promptly, spacing subassembly 200 reaches centre gripping subassembly 300 set up respectively in on the mount pad 100, spacing subassembly 200 be used for right centre gripping subassembly 300 plays the installation and fixed effect, centre gripping subassembly 300 is used for the centre gripping work piece, plays centre gripping, fixed effect to the work piece.

Referring to fig. 1, the mounting base 100 is provided with a mounting area 110, and the limiting assembly 200 and the clamping assembly 300 are respectively disposed on the mounting area 110.

Referring to fig. 1, the limiting assembly 200 includes a limiting column 210 and two rotary pressing cylinders 220, the limiting column 210 is disposed in the mounting area 110, the two rotary pressing cylinders 220 are respectively disposed on the mounting base 100, the mounting area 110 is located between the two rotary pressing cylinders 220, the two rotary pressing cylinders 220 are respectively configured to rotate toward the mounting area 110, and the rotary pressing cylinders are provided with pressing blocks 221.

Referring to fig. 1, the clamping assembly 300 includes a placing table 310, a clamping member 320 and a locking screw 330, wherein a receiving groove 311 is formed on a top surface of the placing table 310, the receiving groove 311 is used for receiving a workpiece, the workpiece is a heat sink to be processed, that is, a three-sided ring groove with one side of the receiving groove 311 open, and an open end of the receiving groove 311 is disposed toward the clamping member 320. The clamping member 320 is disposed on a side surface of the placing table 310, the clamping member 320 is disposed corresponding to the receiving groove 311, that is, the clamping member 320 is disposed corresponding to an opening end of the receiving groove 311, the clamping member 320 is configured to be supported against a workpiece, that is, a clamping area is formed between an inner side wall of the receiving groove 311 and a side wall of the clamping member 320, the workpiece is embedded in the clamping area so as to be tightly pressed between the receiving groove 311 and the clamping member 320, a locking hole 312 is formed on the side surface of the placing table 310, an inner thread is formed on an inner side wall of the locking hole 312, a through hole 321 is formed on the clamping member 320, the locking screw 330 penetrates through the through hole 321, an end portion of the locking screw 330 is in threaded connection with the inner thread, and the clamping member 320 is locked on the side surface of the placing table 310 by the locking screw 330, thereby clamping the workpiece between the inner side wall of the receiving groove 311 and the side wall of the clamping member 320. A limiting hole (not shown) is formed in the bottom surface of the placing table 310, the limiting post 210 is used for being embedded in the limiting hole, the rotating pressing cylinder 220 is used for pressing and holding the pressing block 221 on the placing table 310 during movement, that is, when the rotating shaft which rotates and presses down is rotated and pressed down, the pressing block can synchronously rotate and press down, after the workpiece is clamped on the placing table 310, the limiting post 210 is aligned with the limiting hole to realize the pre-positioning of the placing table 310, then when the two rotating pressing cylinders 220 at the two ends of the placing table 310 are started, the two rotating pressing cylinders 220 respectively rotate towards the placing table 310 and then press down on the placing table 310, and further the placing table 310 is fixed on the mounting base 100.

What need explain is, change traditional single one and treat one by one and process the heating plate and process, through the mount pad spacing subassembly reaches the centre gripping subassembly, the centre gripping subassembly is including placing platform, holder and locking screw, place and seted up the storage tank on the top surface of platform, the storage tank is provided with a plurality ofly, the holder passes through locking screw locks on placing the side of platform, and then will the work piece presss from both sides tightly the inside wall of storage tank with between the lateral wall of holder, like this, treat the fin of processing through the position of setting for and fix, can effectively improve the location precision of the fin of treating processing to reduce machining error, improve the product yields, and through setting up a plurality ofly the storage tank realizes the batch processing operation of work piece, and then can effectively improve production efficiency.

Furthermore, the clamping assembly comprises a plurality of clamping pieces and a plurality of locking screws, a plurality of accommodating grooves are formed in the top surface of the placing table, the clamping pieces are respectively arranged on the side surface of the placing table and are arranged corresponding to the accommodating grooves one by one, and each accommodating groove and each corresponding clamping piece are matched with each other to clamp a cooling fin to be machined, so that batch operation of workpieces is realized. For another example, a space is arranged between the accommodating grooves, so that the processing operation of each workpiece is convenient. The side surface of the placing table is provided with a plurality of locking holes, inner threads are correspondingly formed in the inner side wall of each locking hole, through holes are respectively formed in the clamping pieces, the locking screws penetrate through the through holes in a one-to-one correspondence mode, and the end portions of the locking screws are in one-to-one correspondence with the inner threads. For another example, referring to fig. 2, the locking screw 330 includes a screw body 331 and a screwing column 332, the screwing column 332 is disposed on the screw body 331, and the screwing column facilitates people to screw the locking screw on the placing table. For another example, the receiving groove is a rectangular receiving groove, the receiving groove may be a polygonal or other receiving groove, and the shape of the receiving groove may be set according to the shape of the heat sink to be processed.

In an embodiment, referring to fig. 2, the clamping member 320 is provided with an alignment protrusion 322, the side surface of the placing table 310 is provided with an alignment groove 313, and the alignment protrusion 322 is embedded in the alignment groove 313, so that the clamping member 320 is convenient to mount, and thus when the locking screw 330 locks the clamping member 320 on the placing table 310, alignment can be more accurate and operation is simpler.

In one embodiment, referring to fig. 1, two pressing areas 314 are disposed on the placing table 310, that is, two pressing areas 314 are disposed on two ends of the placing table 310 respectively close to the two rotary pressing cylinders 220, and the two rotary pressing cylinders 220 are respectively used for rotating and pressing down to press and hold on the two pressing areas 314. As another example, the placing table 310 has a rectangular parallelepiped structure.

Compared with the prior art, the utility model discloses following beneficial technological effect has:

the efficient batch positioning and processing device 10 for the radiating fins passes through the mounting seat 100, the limiting component 200 reaches the clamping component 300, the clamping component 300 comprises a placing table 310, a clamping piece 320 and locking screws 330, a containing groove 311 is formed in the top surface of the placing table 310, the containing groove is provided with a plurality of clamping pieces, the clamping piece 320 passes through the locking screws 330 are locked on the side surface of the placing table 310, the workpiece is clamped tightly between the inner side wall of the containing groove and the side wall of the clamping piece, and therefore the radiating fins to be processed are fixed through the set positions, the positioning accuracy of the radiating fins to be processed can be effectively improved, machining errors are reduced, the product yield is improved, batch processing operation of the workpiece is achieved through the plurality of containing grooves, and further the production efficiency can be effectively improved.

It is obvious that the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not limitations to the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (8)

1. An efficient batch positioning and processing device for radiating fins is characterized by comprising

The mounting seat is provided with a mounting area;

the limiting assembly comprises a limiting column and two rotary pressing cylinders, the limiting column is arranged in the mounting area, the two rotary pressing cylinders are respectively arranged on the mounting seat, the mounting area is positioned between the two rotary pressing cylinders, and the rotary pressing cylinders are provided with pressing blocks; and

the clamping assembly comprises a placing table, a clamping piece and a locking screw, a containing groove is formed in the top surface of the placing table, the accommodating groove is used for accommodating a workpiece, the clamping piece is arranged on the side surface of the placing table, the clamping piece is arranged corresponding to the accommodating groove, the clamping piece is used for being propped against the workpiece, so that the workpiece is tightly pressed between the accommodating groove and the clamping piece, a locking hole is arranged on the side surface of the placing table, the inner side wall of the locking hole is provided with an internal thread, the clamping piece is provided with a through hole, the locking screw penetrates through the through hole, the end part of the locking screw is in threaded connection with the internal thread, the bottom surface of the placing table is provided with a limiting hole, the limiting column is embedded in the limiting hole, and the rotary pressing cylinder is used for pressing and holding the pressing block on the placing table during movement.

2. The efficient batch positioning and processing device for cooling fins according to claim 1, wherein the clamping assembly comprises a plurality of clamping pieces and a plurality of locking screws, a plurality of accommodating grooves are formed in the top surface of the placing table, the clamping pieces are respectively arranged on the side surfaces of the placing table, and the clamping pieces are arranged corresponding to the accommodating grooves one by one;

the side surface of the placing table is provided with a plurality of locking holes, inner threads are correspondingly formed in the inner side wall of each locking hole, through holes are respectively formed in the clamping pieces, the locking screws penetrate through the through holes in a one-to-one correspondence mode, and the end portions of the locking screws are in one-to-one correspondence with the inner threads.

3. The efficient batch positioning and processing device for cooling fins according to claim 2, wherein a space is provided between each accommodating groove.

4. The efficient batch positioning and processing device for heat sinks as claimed in claim 1 or 2, wherein said locking screw comprises a screw body and a screwing column, and said screwing column is disposed on said screw body.

5. The efficient batch positioning and processing device for heat dissipation fins according to claim 1, wherein the clamping member is provided with an alignment rib, the side surface of the placing table is provided with an alignment groove, and the alignment rib is embedded in the alignment groove.

6. The efficient batch positioning and processing device for cooling fins as claimed in claim 1, wherein said placing table is provided with two pressing areas, and said two rotary hold-down cylinders are respectively used for rotary hold-down to press and hold on said two pressing areas.

7. The efficient batch-positioning and processing device for heat sinks as claimed in claim 1, wherein said placing table has a rectangular parallelepiped structure.

8. The efficient batch positioning and processing device for heat dissipation plates as recited in claim 1, wherein the receiving groove is a rectangular receiving groove.

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