JP4033406B2 - Structure of solder land - Google Patents

Description

  The present invention relates to the structure of a solder land portion for connecting signal lines. Specifically, when soldering a plurality of signal lines to a solder land portion provided on a substrate or the like, the soldered signal lines are disconnected or disconnected. The present invention relates to a structure of a solder land portion that is hard to be peeled off.

In earphone cables, etc. in audio devices such as portable type MD players, CD players, MP3 players, etc., an extremely thin signal line is soldered to a solder land portion of a substrate or the like on the player body or earphone side to We are communicating.
Some of these devices include a remote control device that can adjust the volume between the main body and the earphone. In the apparatus equipped with this remote control device, the number of signal lines increases, and in some cases, the signal lines are constituted by coaxial cables composed of a plurality of core wires, or the signal lines are constituted by a plurality of electric wires and coaxial cables. There is a case.

And the example conventionally performed which connects a signal wire | line with an audio apparatus, an earphone, or a remote control apparatus is given.
FIG. 3 shows a conventional example of the remote control device A1 portion provided in the portable audio device A, and FIG. 4 is an explanatory diagram showing a soldering state between the remote control device A1 and the signal line L.
At the other end of the signal line L, a mini-plug L1 having four contacts that can be connected to the portable audio device A is attached as shown in FIG. In addition, a signal line l is connected to the earphone Y and extends, and a stereo mini plug l1 for connecting to the remote control device A1 is integrally attached to the tip. Therefore, the remote control device A1 has a built-in stereo mini jack (not shown) for connecting to the signal line l extending from the earphone Y, and can be connected to the stereo mini plug l1, and the audio signal is transmitted to the earphone. Transmission to the horn Y is possible.

The remote control device A1 includes various switches for controlling the portable audio device A1, a liquid crystal display unit, and the like. When manufactured, the remote control device A1 has a built-in small printed wiring board P as shown in FIG. A solder land portion P1 for soldering each line of the signal line L is provided. As shown in FIG. 4, the solder land portions P <b> 1 are generally provided so as to be arranged side by side so that a soldering operation of a cable having a plurality of signal lines can be easily performed collectively. This is an example.
On the other hand, the signal line L to be soldered to the solder land portion P1 is a four-core signal line. The ear is worn on the ear from the portable audio device A1 in a bag or the like or in a pocket. Since it is provided between the horns Y, a wire that is as light and thin as possible and that has sufficient signal transmission capability and mechanical strength is required, so a thin 4-core wire is used.

  When the signal line L is manufactured, the stereo minipla L1 is integrally formed in advance on an end portion different from the end portion to be soldered. And, the length of each wire is aligned at the tip part to be soldered, and the wire is generally supplied as a manufactured part in a state where the coating of the tip of each wire is peeled off and the solder is placed.

When the portable audio device A1 has a radio function, the signal line L and the signal line l may be used as radio receiving antenna lines.
In this case, three lines L2 and a common line L3 to the right and left earphones Y for transmitting audio signals to the left and right earphones, and four lines of the antenna line L4 are used. When the signal line L and the signal line l are used as antennas, the common line L3 is used as the antenna GND line L5.
When the antenna is also used, the GND line L5 and the antenna line L4 that are the common lines L3 may use the coaxial cable L6, the core line may be the antenna line L4, and the GND line L5 may be used as the shield line.
Further, even in the configuration of the signal line L as shown in FIG. 5, a line thinner than the other lines may be used in the plurality of lines (L2, L3, L4).
The signal line L and the signal line l are used in a state where a force is applied in a direction that is always pulled between the audio device A1 and the earphone Y.

  However, since the signal line L is supplied in advance as a component, the end of the signal line L to which the mini plug L1 is not attached is aligned in advance, stripped of the coating, and loaded with solder. In this case, when one of a plurality of wires as in the conventional example is thin, or when the core wire L4 of the coaxial cable L6 is thinner than the shield wire of the coaxial cable L6 (thinner than other wires). When these thin lines and the core line L4 are soldered to the solder land part P1 of the printed wiring board P provided in the horizontal direction, the tension and the manufacturing process that are actually used during the use of the audio device A1 It cannot withstand external forces such as tension applied in the process, and the thin wire or the core wire L4 is cut or the solder is peeled off, resulting in an electrically disconnected state.

  Therefore, the inventor cannot easily cause disconnection or solder peeling even when soldered to the solder land portion using a signal line that has been cut with the end portions aligned in advance and peeled off. Invent and provide the structure.

In a plurality of solder land portions to which the signal lines in the cable formed in parallel on the printed wiring board and soldered in advance at the end portions are soldered,
When arranging each solder land part side by side, pull out the cable from the other solder land part to the solder land part to which the signal line with low mechanical strength is soldered among the multiple signal lines whose ends have been cut out in advance. The structure of the solder land, characterized by being located on the side,

I will provide a. Therefore, in a printed wiring board or the like constituting the solder land portion, the solder land portion for soldering the signal line having low mechanical strength is configured to be lowered to the signal line side from the solder land portion for soldering other signal lines. The signal line with weak mechanical strength is soldered to the solder land, which is shifted to the signal line side, and the signal line is long enough to be disconnected or peeled off before the signal line with high mechanical strength. Hard to wake up.
Furthermore, in this invention,

In a plurality of solder land portions to which the signal lines in the cable formed in parallel on the printed wiring board and soldered in advance at the end portions are soldered,
When the solder land portions are arranged side by side, the solder land portion to which the signal line having a low mechanical strength is soldered among the plurality of signal wires having the end portions aligned in advance is closer to the center of the plurality of solder land portions. Solder land structure, characterized in that it is located

I will provide a. Therefore, among the solder land portions arranged in parallel, the solder land portion to which the signal line having low mechanical strength is connected is located on the center side, and the signal lines connected to this solder land portion are arranged on both end sides. The signal line connected to the solder land part of the cable has a margin in length, so when the cable is pulled, the force pulled by the margin of the length is a signal line with strong mechanical strength at both ends. Therefore, disconnection or solder peeling is unlikely to occur prior to a signal line having high mechanical strength.
The structure of the solder land is
In a plurality of solder land portions that are formed side by side on a printed wiring board and to which signal lines are soldered, signal wires with low mechanical strength are soldered when the solder land portions are arranged in parallel. Providing the solder land part closer to the center of the other solder land parts and providing the solder land part on the cable drawing side.
This makes it possible to give more slack to signal lines with weak mechanical strength, and even if the signal lines are moved by being pulled to the side where the solder lands are arranged side by side, the mechanical strength The movement of the weak signal lines is maintained by the mechanical strength of the signal lines arranged on either side, which is compared to the case where there are multiple signal lines with weak mechanical strength at the end of the solder land. In addition, the signal line with low mechanical strength is less likely to break or peel off before the signal line with high mechanical strength.

Therefore, according to the present invention, a signal line having a low mechanical strength among a plurality of signal lines is soldered to a solder land portion provided to be shifted from a solder land portion to which other signal lines are soldered. Since mechanical external force such as pulling force acting on the wire can be made difficult to be applied to the signal wire with weak mechanical strength, the signal wire with low mechanical strength among the signal wires supplied as parts with the ends aligned. It is possible to prevent the concentration of mechanical external force and to prevent solder peeling and disconnection.
Therefore, it is possible to supply a product that is less prone to solder peeling and disconnection than in the past by using signal lines configured in the same manner as in the past.

  In particular, in a composite cable configured by inserting coaxial cables into a plurality of signal wires, the core wire of the coaxial cable is thinner than other wires and the mechanical strength is weakened. Therefore, the core wire of the coaxial cable is soldered to the other signal wires. By soldering to a solder land portion that is shifted from the solder land portion, it is effective to prevent the core wire of the coaxial cable from being peeled off or disconnected.

Hereinafter, a description will be given based on FIG.
As shown in FIG. 1, the solder lands 2 provided on the substrate 1 are provided with four locations of land portions 2 a to 2 d that match the number of signal lines 3 connected to the portable audio device A.
As shown in FIG. 1, the signal lines 3 to be soldered to the solder lands 2 are an audio signal right channel signal line 3a and left channel signal line 3b, an antenna line 3c, and the right channel signal line 3a and The antenna line 3c is a coaxial cable core line, and the common line 3d is a coaxial cable network line (in some cases, a foil-like line). These four lines are formed as one line by the same insulating skin 3e.

The solder land 2 is provided with the land portions 2a to 2d arranged in parallel, but only the land portion 2c for soldering the antenna wire 3c having the weakest mechanical strength of the core wire of the coaxial cable among the signal wires 3 is provided. The antenna wire 3c can be soldered by shifting it in the direction in which the signal line 3 is attached, that is, on the right side in FIG. 1 with respect to the other land portions 2a, 2b, 2d.
Thus, by providing the land portion 2c to the side where the signal line 3 is installed somewhat from the other land portions 2a, 2b, 2d, the other signal lines 3a, 3b are connected to the soldered antenna wire 3c. As a result, the antenna line 3c is not subjected to a mechanical force more than the other signal lines 3a, 3b, 3d even if the signal line 3 is pulled in the direction in which the signal line 3 is installed. To.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an explanatory plan view showing an embodiment of the present invention, and FIG. 2 is an explanatory view showing the entire apparatus in which the present invention is implemented.

Reference numeral 1 denotes a printed wiring board on which the present invention is implemented. As shown in FIG. 1, the printed wiring board 1 is configured such that a solder land 2 for soldering a wire from the outside to a printed wiring is provided at an end, and the signal line 3 can be soldered. The An electronic component 4 such as a capacitor is mounted on the printed wiring board 1.
As shown in FIG. 2, this printed wiring board 1 is attached to an audio device A such as a portable MD player, CD player, MP3 player, etc. that can be carried in a pocket or a bag. It is provided in the middle of A and installed in a remote control device A1 for controlling the audio device A and controlling the volume of the earphone Y, and enables these controls.
Therefore, details of the portable audio apparatus A in which the present embodiment is implemented will be described.
In this embodiment, the portable audio device A is an MD player having an AM / FM radio function, and is provided with a connection jack A2 to which a remote control device A1 can be connected. In the remote control device A1, a connection plug A11 that can be connected to the connection jack A2 is connected by a signal line 3. That is, the connection plug A11 is connected to the distal end of the signal line 3, and the base end portion of the signal line 3 is soldered to the solder land 2 shown in FIG. The remote control device A1 includes an earphone jack A12 that can be connected to the earphone Y, and an earphone plug Y2 provided at the tip of the earphone signal line Y1 whose base end is connected to the earphone Y body. Connectable.

The earphone Y configured as described above requires at least three signal lines, that is, left and right channel lines and a common line for transmitting a stereo audio signal, so the earphone signal line Y1 is a three-core signal line. It is composed of The earphone signal line Y1 also has a function as an antenna line for the portable audio device A to receive radio. Therefore, the audio signal and the antenna reception signal are exchanged with the remote control device A1 through the earphone signal line Y1.
On the other hand, the signal line 3 from the main body of the portable audio device A to the remote control device A1 can transmit and receive the control signal controlled by the remote control device A1 and the audio signal of the left and right channels, and can be received by the antenna wire for radio reception. Therefore, the signal line 3 is provided with four lines of three lines for voice and one line for antenna. These signal lines 3 are connected to the portable audio device A through the connection jack A2 and the connection plug A11.
In the apparatus configured as described above, in the remote control apparatus A1, an electronic circuit is configured by the printed wiring board 1, and audio signals are exchanged between the portable audio apparatus A and the earphone Y, and antenna reception signals are exchanged and portable. Control of the audio device A is performed.

Hereinafter, the remote control device A1 will be described in detail.
In the remote control device A1, a capacitor 4 which is an electronic component is mounted in accordance with the printed wiring applied to the printed wiring board 1. Further, a solder land 2 for electrically connecting the signal line 3 by soldering or the like is provided on the right side of the printed wiring board 1 in FIG. The solder land 2 is composed of four land portions 2a to 2d corresponding to the number of the signal lines 3, and the end of the printed wiring board 1 (that is, in accordance with the arrangement of the signal lines 3) It is provided on the right side in FIG.
As shown in FIG. 1, the signal lines 3 to be soldered to the solder lands 2 are an audio signal right channel signal line 3a and left channel signal line 3b, an antenna line 3c, and the right channel signal line 3a and The left channel signal line 3b is paired with a common line 3d, and these four lines are formed as one signal line 3 by the same insulating sheath 3e. The right channel signal line 3a and the left channel signal line 3b are formed of a coated single core wire. Further, the antenna line 3c and the common line 3d are constituted by coaxial cables so that the length of the antenna line 3c does not contribute to reception, the antenna line 3c is a core line, and the common line 3d is a net line (in some cases, a foil-like shape). Line). The signal line 3 has a connection plug A11 connected to the tip in advance, and the base end portion soldered to the solder land 2 is trimmed in advance, and the coating is peeled off and soldered to the solder land 2 Supplied as a possible component. The antenna line 3c, which is a core line when a coaxial cable is used for the signal line 3 as in the present embodiment, or a plurality of single-core twisted lines although not described in detail.

Next, the solder land 2 will be described in detail.
The solder land 2 is composed of land portions 2a to 2d according to the number of signal lines 3 to be soldered as described above. Solder lands 2 are soldered in order of the right channel signal line 3a, the left channel signal line 3b, the antenna line 3c (coaxial cable core), and the common line 3d (coaxial cable twisted line) from bottom to top in FIG. Attached. The land portions 2a to 2d are arranged side by side so as to intersect the direction in which the signal line 3 extends at the end of the printed wiring board 1 on the side where the signal line 3 extends. Among them, the land portion 2c to which the antenna line 3c (core wire of the coaxial cable) is soldered is provided on the signal line 3 by about 0.5 mm as compared with the other land portions 2a, 2b, and 2d.

  Then, the right channel signal line 3a, the left channel signal line 3b, the antenna line 3c, and the common line 3d are soldered to each of the land portions 2a to 2d provided on the solder land 2 either automatically or manually. 3 is electrically connected to the remote control device A1.

  As described above, the land portion 2c to which the antenna wire 3c (core wire of the coaxial cable) having weak mechanical strength compared to other wires is soldered is shifted to the signal wire 3 side. Even when pulled, the antenna wire 3c having the weakest mechanical strength is provided by shifting the land portion 2c soldered to the antenna wire 3c from the other land portions 2a, 2b, and 2d as compared to the other wires. Since there is a slack, the pulling force is not applied or reduced. Further, when the assembled remote control device A1 is connected to the portable audio device A and the earphone signal line Y1 is connected to the remote control device A1, the signal line 3 is pulled by the movement of the user or the like. Even if there is nothing, the pulling force on the antenna wire 3c (core wire of the coaxial cable) is similarly not applied or reduced.

As described above, according to the present invention, a land portion that connects a signal line having a low mechanical strength among a plurality of signal lines that are bundled together and connected to each land portion is connected to a land that connects another line. Since the external force is applied to the signal lines assembled in one set, the external force does not act on the signal lines with low mechanical strength or other signal lines. It can be made to work less.
In the present invention, the signal line is an audio signal line and the antenna line, but the embodiment has been described. However, the line is composed of a plurality of lines, and there is a line having low mechanical strength in the plurality of lines. If it is the structure of the land part which connects such a set of electric wires, it will not be specifically limited to the said Example. Of course, as shown in FIG. 4 of the conventional example, even when the coaxial cable is not used, the same operation and effect as in the above-described embodiment can be obtained by shifting the land portion connecting the line having weak mechanical strength.
Furthermore, in the above description, the example in which the line having the weakest mechanical strength is connected to the land portion provided on the center side has been described, but the line having the weakest mechanical strength is connected to the land portion provided at the end. Alternatively, it may be configured to be connected to a land portion at any position. Furthermore, the number of signal lines 3 collected as a set is not limited to four, but can be more or less, and is not limited to the number of lines. In this case, a line with weak mechanical strength is used. The sag formed on the line having a low mechanical strength can be most effectively acted by positioning the land portion connecting the lands to the center side of each land portion, or preferably at the center.

  The present invention is not limited to electrically connecting a signal line extending from a remote control device such as a portable audio device as described above, but can also be used for connection between an earphone signal line and an earphone, Since it can be used when electrically connecting and fixing a plurality of wires bundled in a set to a printed wiring board provided in an electronic device such as a portable audio device by soldering or the like, It can be used in all situations where the electric wire is electrically fixedly connected to a printed wiring board or the like.

Plane explanatory drawing showing the embodiment of this invention Explanatory drawing showing the whole apparatus in which this invention is implemented Explanatory drawing showing the entire apparatus in which the conventional example is implemented Plane explanatory diagram showing a conventional example Plan view showing another conventional example

Explanation of symbols

A Portable audio device A1 Remote control device A11 Connection plug A12 Earphone jack A2 Connection jack A3
Y ear horn Y1 ear horn signal line Y2 ear horn plug 1 printed wiring board 2 solder land 2a to 2d land 3 cable 3a right channel signal line 3b left channel signal line 3c antenna line (coaxial cable core line)
3d common wire (coaxial cable network wire)
4 Electronic components (capacitors)

Claims (2)

In a plurality of solder land portions to which the signal lines in the cable formed in parallel on the printed wiring board and soldered in advance at the end portions are soldered,
When arranging each solder land part side by side, pull out the cable from the other solder land part to the solder land part to which the signal line with low mechanical strength is soldered among the multiple signal lines whose ends have been cut out in advance. A structure of a solder land portion, which is provided on the side. In a plurality of solder land portions to which the signal lines in the cable formed in parallel on the printed wiring board and soldered in advance at the end portions are soldered,
When the solder land portions are arranged side by side, the solder land portion to which the signal line having a low mechanical strength is soldered among the plurality of signal wires having the end portions aligned in advance is closer to the center of the plurality of solder land portions. A structure of a solder land part, wherein the solder land part is provided.

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