TWM573884U - Copper coil structure - Google Patents

Abstract

The present invention relates to a copper coil structure, wherein the processing method fixedly positions the thick copper foil of more than 100[mu]m in thickness by a mounting fixture and presses to flatten the copper foil. Next, use the UV laser in the spiral winding method to cut the copper coil from the thick copper foil. At the same time, the connecting bridges and a plurality of grooves existing on bother sides of the connecting bridges, which are not completely cut through and off by the UV laser, remain. Last, use the VU laser to cut off the connecting bridges and copper coils in a spiral shape are produced.

Description

Copper coil structure

This creation is related to a copper coil structure; more specifically, it relates to a copper coil structure cut on thick copper using a UV laser.

Generally, a radio frequency coil having a coil diameter of 40 mm or less is manufactured by using a copper wire to be wound around a spiral, and the RF coil of this size cannot be cut by a laser processing machine because the laser is During the process of cutting copper, some of the laser energy is absorbed by the copper material, which causes the copper material to swell and produce copper deformation, which causes a significant deviation in the position and size of the cut copper wire, and finally leads to the completion of the cutting. The RF coil is not presented in a complete spiral.

In view of this, the applicant of this case has been engaged in research and development experience in related fields for many years, and has conducted in-depth discussions on the above-mentioned shortcomings, and actively sought solutions according to the above-mentioned needs. After a long period of hard work and many tests, the applicant finally completed this book. creation.

The main purpose of this creation is to use a UV laser to cut a copper coil having a diameter of 40 mm or less on a thick copper of 100 μm or more.

For the above purposes, the UV laser processing method for copper coils is made by the following steps:

A. Positioning step: Fix the thick copper with a thickness of 100 μm or more to the position and flatten it with a fixed jig.

B. Cutting step: cutting the copper wire on the thick copper through the UV laser by means of a spiral, and leaving the connecting bridge not cut by the UV laser on the thick copper after the cutting is completed and at the connecting bridge Multiple grooves on the side.

C. Cutting step: the connecting bridge is cut off by UV laser, and the grooves on both sides of the connecting bridge are connected to each other to form a complete spiral groove, thereby obtaining a spiral copper with a diameter of 40 mm or less. Coil.

The copper coil structure of the present invention is provided with a connecting bridge and a groove on a thick copper having a thickness of 100 μm or more, and the diameter of the copper coil is 40 mm or less.

The connecting bridge is located on thick copper and has a certain width.

The grooves are disposed on both sides of the joint bridge and are presented in an arc shape.

This creation has the following advantages:

1. Using a laser to directly process thick copper into a copper coil.

2. Thick copper does not deform during the cutting process to cause dimensional deviation.

1‧‧‧Solar coil UV laser processing method

11‧‧‧ Positioning steps

12‧‧‧ Cutting steps

13‧‧‧cutting steps

2‧‧‧ copper coil structure

21‧‧‧ thick copper

211‧‧‧ Linked Bridge

212‧‧‧ trench

31, 32, 33‧ ‧ steps

Figure 1: Schematic diagram of the UV laser processing flow of the copper coil; Figure 2: Schematic diagram of the copper coil structure of the present invention; Figure 3: Partial enlarged schematic view of the copper coil structure of the present invention; Figure 4: Schematic diagram of the implementation process of the UV laser processing method of the copper coil.

The purpose, function, features and structure of the present invention can be understood in a more detailed manner, and the preferred embodiment will be described in conjunction with the drawings.

First, please refer to FIG. 1 , FIG. 2 and FIG. 3 . FIG. 1 is a schematic diagram of a UV laser processing flow of a copper coil, FIG. 2 is a schematic diagram of a copper coil structure, and FIG. 3 is a partially enlarged schematic view of the copper coil structure.

The UV laser processing method 1 of the copper coil is made by the following steps:

A. Positioning Step 11: The thick copper 21 having a thickness of 100 μm or more is fixed to the position and flattened by a fixing jig.

B. Cutting step 12: cutting the copper wire on the thick copper 21 by means of a UV laser by means of a spiral, and leaving the connecting bridge 211 not cut by the UV laser on the thick copper 21 after the cutting is completed and A plurality of grooves 212 are located on both sides of the connecting bridge.

C. Cutting step 13: The connecting bridge 211 is cut off by UV laser, and the grooves 212 on both sides of the connecting bridge are connected to each other to form a complete spiral groove 212, thereby obtaining a spiral copper coil.

Further, in the copper coil structure 2 of the present invention, the connection bridge 211 and the groove 212 are provided on the thick copper 21 having a thickness of 100 μm or more.

The joint bridge 211 is located on the thick copper 21 and has a certain width. The joint bridge 211 refers to a specific block that is not cut by UV laser on the thick copper 21.

The grooves 212 are disposed on both sides of the connecting bridge 211 and are presented in an arc shape, and the grooves 212 are processed by UV laser processing.

The details of the implementation of this creation and related reference drawings are as follows:

Please refer to FIG. 4 and FIG. 2 and FIG. 3 together. FIG. 4 is a schematic diagram of the implementation process of the UV laser processing method of the copper coil.

As shown in step 31, the thick copper 21 to be cut is first fixed by a fixing jig and simultaneously flattened by a fixing jig, thereby preventing the thick copper 21 from being uneven due to surface irregularity. The necessary error.

As shown in step 32, the fixed jig is then placed in the laser cutting machine, and the UV laser is cut into a plurality of copper wires on the thick copper 21 in a spiral manner, in order to avoid copper during the cutting process. The position of the line is offset and the size is deviated. Therefore, at least one or more of the connecting bridges 211 that are not cut by the UV laser are reserved on the thick copper 21, so that the thick copper 21 after the cutting is completed has multiple passes. The grooves 212 are connected to each other.

The forming method of the connecting bridge 211 may be to block the laser beam by using a fixed fixture, so that the laser beam cannot make energy on the thick copper 21 to form the uncut bridge 211, or through setting the laser cutting machine. The software is operated to control the energy of the laser beam so that the energy of the laser beam cannot be cut through the thick copper 21 when passing through a specific path. In addition, the shape of the bridge 211 is not limited to the radiation shown in FIG. The main purpose of the reserved bridge 211 is to avoid offset and size deviation of the copper wire position. Therefore, the bridge 211 can be arbitrarily adjusted as long as it is calculated by calculation that the copper wire is not deformed during cutting. The location and number of settings.

As shown in step 33, finally, the connecting bridge 211 is cut by the UV laser, so that the grooves 212 on both sides of the connecting bridge 211 are connected to each other, and when all the grooves 212 are joined into one long groove 212, a Copper coils made of spiral copper wire.

In summary, the advantages of the copper coil structure of the present creation are:

1. Using a UV laser to directly process thick copper having a thickness of 100 μm or more into a spiral copper coil having a diameter of 40 mm or less.

2. The connection bridge can maintain the fixed line width of the cut copper wire, and can avoid the copper material from absorbing too much laser energy to cause thermal deformation, which causes the position and size of the copper wire to deviate.

Therefore, this creation has excellent progress and practicality in similar products. At the same time, after checking the technical literature on such structures at home and abroad, it has not been found that the same or similar structure exists before the application of this case, so this case It should meet the patent requirements of "creative", "combined with industrial use" and "progressive", and apply in accordance with the law.

It is to be understood that the above-mentioned preferred embodiments of the present invention are intended to be included in the scope of the present invention.

Claims (3)

A copper coil structure is provided with a connecting bridge and a groove on a thick copper having a thickness of 100 μm or more; the connecting bridge is located on a thick copper and has a certain width, and the connecting bridge refers to a thick copper. a specific block cut by the beam; the groove is disposed on both sides of the connecting bridge and is represented by an arc shape, and the groove is cut by a laser beam. The copper coil structure of claim 1, wherein the copper coil has a diameter of 40 mm or less. The copper coil structure according to claim 1, wherein the number of the bridges is one or more.