JPS63300599A - Electromagnetic shielding structure of communication equipment - Google Patents

Abstract

PURPOSE:To enable effective electromagnetic shielding with less number of steps by providing a conductive elastic sheet pattern which can prevent a solder from bonding on an earth pattern. CONSTITUTION:Earth patterns of the same pattern shape as those of the end face of a shielding wall 24a are formed on the front and rear faces of a printed wiring substrate 21, and a plurality of through holes 23 for electrically connecting the patterns 22 of the front and rear faces are arranged and formed through the substrate 21 at a desired interval. A conductive elastic sheet pattern 25 for preventing a solder from bonding is formed on the pattern 22, and obtained by printing silicon mixed with carbon fiber, drying and polymerizing it. A strip 24f is press-contacted with the pattern 25 to further effectively electrically contact the wall 24a with the pattern 25. The pattern 25 is utilized to be interposed between the end face of the wall 24a and the pattern 22 to effectively electrically connect a shielding case 24 to the pattern 22.

Description

[Detailed Description of the Invention] [Summary] A functional circuit configured on a printed wiring board is electromagnetically connected by a ground pattern and through holes provided on the printed wiring board, and a shield case having a shield wall along the ground pattern. In the electromagnetic shielding structure of communication equipment that is shielded by shielding, we prevent solder from adhering to the ground pattern in order to achieve a structure that ensures electrical connection between the shield wall of the shield case and the ground pattern with a small number of steps. A conductive elastic sheet pattern is provided.

[Industrial application field]

The present invention relates to an electromagnetic shielding structure for communication equipment, and more specifically, an improvement in a structure in which a functional circuit configured on a printed wiring board is electromagnetically shielded by a ground pattern, a through hole, and a shield case provided on the printed wiring board. Regarding.

Wireless communication devices such as car phones, mobile phones, cordless phones, and personal radios tend to use high frequency bands called quasi-microwave bands due to mutual use of radio waves and multi-access communication. . Therefore, it is necessary to prevent electromagnetic interference between functional circuits in wireless communication equipment. In addition, with the digitalization of the social environment, there is a need to prevent electromagnetic interference between electronic devices such as various communication and information devices, and for this reason, it is necessary to regulate radiated radio waves through electromagnetic shielding of wireless communication devices. ing.

[Conventional technology]

FIGS. 4 and 5 show electromagnetic shielding structures of conventional wireless communication equipment. Referring to these figures, on the front and back surfaces of the printed wiring board l of the wireless communication device, there is a ground pattern 2 having the same pattern shape as the end surface of the shield wall 4d of the shield case 4 surrounding each functional circuit area 1a+lb, lc.
A plurality of through holes 3 are formed in the ground pattern 2, and a plurality of through holes 3 are formed in the functional circuit areas la and l, penetrating the printed wiring board 1 and electrically connecting the ground patterns 2 on the front and back sides.
Although not shown, each functional circuit area 1a, lb of the printed wiring board l is arranged at a desired interval sufficiently shorter than the wavelength of the high-frequency signal used in the
, lc are equipped with functional circuit components.

Since each functional circuit on the printed wiring board 1 needs to be shielded spatially and electromagnetically, shield cases 4 are attached to the front and back surfaces of the printed wiring board 1, respectively. The shield case 4 includes a shield wall 4d along the ground pattern 2 of the printed wiring board l, and the shield wall 4d covers each functional circuit area 1a, l on the printed wiring board 1.
b.

Functional circuit component storage chamber 4 that accommodates functional circuit components in the IC
It separates a, 4b, and 4c. Shield wall 4d of shield case 4 and earth pattern 2 on printed wiring board 1
Each functional circuit area 1a, lb, l
The functional circuit within c is electromagnetically shielded.

[Problem that the invention seeks to solve]

In the above-mentioned wireless communication equipment with electromagnetic shielding structure,
Shield wall 4d of shield case 4 and printed wiring board 1
Although it is necessary to ensure electrical connection with the upper ground pattern 2, functional circuit components may be placed on each functional circuit area 1a, lb, lc of the printed wiring board 1 on which the ground pattern 2 is formed by dipping method or floating method. When fixed with adhesive by soldering method, due to the adhesion of solder on the ground pattern 2,
There is a risk that the smoothness of the ground pattern 2 will be impaired and the electrical contact with the shield wall 4d of the shield case 4 will become insufficient.

For this reason, conventionally, as shown in FIG. 6, between the printed wiring board manufacturing process 11 and the mounting process 13 of electronic components such as functional circuit components on the printed wiring board, the earth pattern of the printed wiring board is Printing solder resist on (Step 12)
was carried out to prevent solder from adhering to the ground pattern during soldering by the dip method or flow method, but in this case, the cleaning step 1 after the soldering step 14
5 and assembly process 17 of printed wiring board and shield case
Since a step 16 for peeling off the solder resist from the ground pattern is required, a problem arises in that the number of steps from manufacturing the printed wiring board to assembling the shield case increases.

Furthermore, in conventional wireless communication equipment, in order to absorb variations in the smoothness of the end face of the shield wall 4d of the shield case 4, a groove is formed on the end face of the shield wall 4d as shown in FIGS. 4 and 5. An electromagnetic shielding gasket 5 made of conductive rubber or the like is attached to the groove, and the shielding wall 4d of the shielding case 4 and the earth pattern 2 on the printed wiring board 1 are electrically connected via the electromagnetic shielding gasket 5. However, as shown in FIG. 6, a step 18 for assembling the electromagnetic shielding packing into the shield case is required before the assembly step 17, resulting in an increase in the number of man-hours.

[Means for solving problems]

According to the present invention, a communication device electromagnetically shields a functional circuit configured on a printed wiring board by a ground pattern and a through hole provided on the printed wiring board, and a shield case having a shield wall along the ground pattern. Provided is an electromagnetic shielding structure for a communication device characterized in that the electromagnetic shielding structure includes a conductive elastic sheet pattern that can prevent solder adhesion on a ground pattern.

As a material for the conductive elastic sheet pattern, for example, silicone rubber mixed with carbon powder can be used.

A conductive elastic sheet pattern can be obtained by printing silicone rubber mixed with carbon powder on a ground pattern by silk printing or the like, and drying and polymerizing it.

[For production]

In the electromagnetic shielding structure for communication equipment according to the present invention,
The conductive elastic sheet pattern on the ground pattern can prevent solder from adhering, and the conductive elastic sheet pattern on the ground pattern can be used as is to be interposed between the shield wall end face of the shield case and the ground pattern. By doing so, variations in the smoothness of the end face of the shield wall can be absorbed and the shield case and the earth pattern can be reliably electrically connected. therefore,
According to the electromagnetic shielding structure according to the present invention, there is no need to peel off the conductive elastic sheet pattern from the ground pattern, and there is no need to incorporate the electromagnetic shielding packing into the shielding case. The number of man-hours required for assembly can be reduced.

〔Example〕

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 and 2 show one embodiment of the present invention. Referring to these figures, each functional circuit area 21a, 21b,
A ground pattern 22 having the same pattern shape as the end face of the shield wall 24a of the shield case 24 surrounding the shield case 21c is formed, and the ground pattern 22 is electrically connected to the front and back ground patterns 22 by penetrating the printed wiring board 21 at the location of the ground pattern 22. A plurality of connecting through holes 23 are connected to the functional circuit area 2.
They are arranged at desired intervals that are sufficiently shorter than the wavelength of the high frequency signals used in 1a, 21b, and 21c. Although not shown, each functional circuit area 213.21b of the printed wiring board 21.

Functional circuit components are respectively mounted in 21C.

Since each functional circuit on the printed wiring vi21 needs to be shielded spatially and electromagnetically, shield cases 24 are attached to the front and back surfaces of the printed wiring board 21, respectively. Shield case 24 is printed wiring board 2
The shield wall 24d is provided with a shield wall 24d along the ground pattern 22 of No. 1, and the shield wall 24d serves as a functional circuit component storage chamber 24a, 24b for accommodating the functional circuit components in each functional circuit area 21a, 21b, 21c on the printed wiring board 21. , 24c
is in charge of

The shield case 24 can be made of a conductive metal, but it may also be made of a plastic case with a conductive metal film formed on the surface by plating or the like.

A conductive elastic sheet pattern 25 that can prevent solder from adhering is provided on the ground pattern 22 of the printed wiring board 21. As the material of the conductive elastic sheet pattern 25, for example, silicon mixed with carbon powder can be used. The conductive elastic sheet pattern 25 can be obtained by printing silicon mixed with carbon powder on the ground pattern 22 by silk printing or the like, and drying and polymerizing it.

Holes 24e and 21d for screw fixing to shield wall 24d of shield case 24 and printed wiring board 21 at appropriate locations.
, 22d are provided. Furthermore, a protrusion 24f extending along the conductive elastic sheet pattern 25 is formed on the end face of the shield wall 24d. By pressing the protrusion 24f against the conductive elastic sheet pattern 25, the electrical contact between the shield wall 24d and the conductive elastic sheet pattern 25 becomes more reliable.

In the above-mentioned electromagnetic shielding structure for communication equipment, the conductive elastic sheet pattern 25 on the ground pattern 22 can prevent solder from adhering, and moreover, the four-conductor elastic sheet pattern 25 on the ground pattern 22 can be used as is. By interposing it between the end face of the shield wall 24d of the shield case 24 and the ground pattern 22, variations in the smoothness of the end face of the shield wall 24d are absorbed and the shield case 24 and the ground pattern 22 are reliably connected to each other. can be connected.

FIG. 3 shows an example of the flow of the manufacturing and assembly process for the electromagnetic shielding structure of the communication device described above.

Referring to FIG. 3, manufacturing process 3 of printed wiring board 21
1 and the step 33 of mounting electronic components such as functional circuit components onto the printed wiring board 21, a conductive elastic sheet pattern 25 is formed on the ground pattern 22 of the printed wiring board 21 (step 32). . Therefore, during the soldering process 34 using the dip method or the flow method, adhesion of solder to the ground pattern 22 and the conductive elastic sheet pattern 25 covering it is prevented. Since the conductive elastic sheet pattern 25 is used as it is as an electromagnetic shielding packing, there is no need for a peeling process after the cleaning process 35 after the soldering process 34. The assembly process 36 can be proceeded to.

Also, the shield wall 24d of the shield case 24 is formed by the conductive elastic sheet pattern 25 on the ground pattern 22.
Since it is possible to absorb variations in the smoothness of the end face of the shield case 24, after manufacturing the shield case 24 (step 37), it is possible to proceed to the assembly step 36 without having to incorporate the electromagnetic shield packing into the shield case 24. .

Therefore, printed wiring board 21 and shield case 2
4. The number of man-hours from manufacturing to assembly can be reduced.

Although the illustrated embodiments have been described above, the present invention is not limited to the embodiments described above; for example, the shape of the ground pattern on the printed wiring board, the number and size of functional circuit areas, etc. may be changed as necessary. It can be changed accordingly.

〔Effect of the invention〕

As is clear from the above description, according to the present invention, a conductive elastic sheet pattern formed on a ground pattern on a printed wiring board is used as a solder resist, and the conductive elastic sheet pattern is directly used as an elastic electromagnetic material. It can be used as a shield packing to ensure electrical connection between the ground pattern and the shield wall of the shield case through the conductive elastic sheet pattern, making it ideal for communication equipment that can achieve reliable electromagnetic shielding with a small number of steps. An electromagnetic shielding structure can be provided.

[Brief explanation of drawings]

Fig. 1 is an exploded perspective view of a main part of an electromagnetic shielding structure of a communication device showing an embodiment of the present invention; Fig. 2 is an exploded sectional view of a main part of an electromagnetic shielding structure shown in Fig. 1; Figure 4 is an exploded perspective view of the main part of the conventional electromagnetic shield structure, Figure 5 is an exploded sectional view of the main part of the electromagnetic shield structure shown in Figure 4. , Fig. 6 is a diagram showing the flow of the manufacturing process of the electromagnetic shield structure shown in Fig. 4. In the figure, 21 is a printed wiring board, 22 is a ground pattern, 23 is a through hole, 24 is a shield case, 2
4d represents a shield wall, and 25 represents a conductive elastic sheet pattern.

Claims (1)

[Claims] 1. A functional circuit configured on a printed wiring board (21) is connected to a ground pattern (22) provided on the printed wiring board, a through hole (23), and a shield wall (24d) along the ground pattern. ) in an electromagnetic shield structure for communication equipment that is electromagnetically shielded by a shield case (24) having a conductive elastic sheet pattern (25) that can prevent solder from adhering to the ground pattern (22). Electromagnetic shielding structure for communication equipment. 2. The electromagnetic shielding structure for communication equipment according to claim 1, wherein the conductive elastic sheet pattern (25) is made of silicone rubber mixed with carbon powder.