KR20190131092A - Wiring conversion adapter - Google Patents

Abstract

A wiring conversion adapter comprising a connector between a first printed wiring board, a second printed wiring board, and a printed wiring board for connecting both printed wiring boards, the wiring portion being common to a plurality of wiring patterns in the first printed wiring board and the second printed wiring board. Pattern design is carried out by dividing the wiring into individual wiring parts, and the common wiring parts of both printed wiring boards are always connected, and the mounting positions of the connectors between the printed wiring boards are connected so that the individual wiring parts of both printed wiring boards are connected according to a desired wiring connection pattern. It is provided with a configuration that can vary.

Description

 Wiring conversion adapter

The present invention is, for example, when replacing a programmable controller (hereinafter referred to as "PLC") that is a control device from an old model to a new model, an electric wire wired thereon including a connector, a terminal block, or the like used in the old model. The present invention relates to a wiring conversion adapter for enabling connection to a new model (hereinafter referred to as "wiring group").

When an existing control device replaces a device, such as nearing the useful life, or a failure occurs, the old control device is a different type from the old control device. The situation of substitution can be considered. Moreover, especially when it is necessary to update a control function, the situation which replaces the old model which is an existing control apparatus by the new model with a new function can be considered.

When performing such a substitution, if existing wiring used in the old model can be used for a new model, the wiring time can be shortened and the wiring miss can be reduced.

As a conventional technique for easily changing the electrical connection pattern, there is a FPC (Flexisible Printed Circuit) repeater (see Patent Document 1, for example). According to this patent document 1, the guide part which can insert each FPC is provided in the both ends of an FPC repeater, and this guide part is provided with the structure which can shift.

By providing such a structure, the electrical connection pattern between two FPCs can be easily changed by shifting a guide part suitably.

Japanese Patent Laid-Open No. 2004-363001

However, the prior art has the following problems.

For example, consider a case where the control device to which the model is to be changed is a PLC. In this case, it is required to use the wiring group connected to each module of the existing PLC as it is. Therefore, when implementing such a wiring group, FPC converter like patent document 1 cannot be used.

Therefore, in order to use the wiring group and to perform wiring switching, a first printed wiring board on which a connector to which an existing wiring group can be connected is mounted, and a second printed wiring board on which a connector that can be connected to a new model is mounted are connected to a connector between printed wiring boards. It is possible to consider applying the wiring conversion adapter connected by this.

When using such a wiring conversion adapter, the wiring patterns of a 1st printed wiring board and a 2nd printed wiring board can be devised, and it becomes possible to switch wiring of the existing wiring group so that it may be suitable for a new model connector.

However, for example, when replacing a PLC from an old model to a new one, it is common that a plurality of different modules are assembled in a control system using the PLC. In addition, it can be considered that the wiring switching pattern is different for each module. Therefore, in order to cope with such different patterns, the following two methods have been used conventionally.

(Method 1) According to each module, a 1st printed wiring board and a 2nd printed wiring board are designed and manufactured individually, and a wiring conversion adapter is produced for every module.

(Method 2) Each of the first printed wiring boards and the second printed wiring boards in which the wiring pattern is shared so as to be suitable for a plurality of modules is manufactured, and each of the components on the printed wiring board is selected and unmounted. Enable wiring switching by module.

However, in the case of employing Method 1, it is necessary to manufacture and stock individual wiring conversion adapters corresponding to the respective modules, so that the development cost and the increase in component cost become a problem.

In addition, in order to employ Method 2, it is necessary to mount components for circuit switching on a printed wiring board in order to achieve common use among a plurality of modules. Therefore, with the increase of the parts score, the increase of the parts cost becomes a problem. In addition, since it is necessary to secure a space for component mounting, the enlargement of the printed wiring board becomes a problem.

This invention is made | formed in order to solve the above subjects, and an object of this invention is to obtain the wiring conversion adapter which can suppress the increase of a printed wiring board size and a component score, and can respond to a some switching pattern within a limited pattern wiring area.

The wiring conversion adapter according to the present invention includes a first printed wiring board, a second printed wiring board, and a connector between the printed wiring boards for electrically connecting the first printed wiring board and the second printed wiring board, and when the replacement device is replaced with a new device, A wiring conversion adapter for making a wiring group used in an old device useful, wherein the first printed wiring board should be inserted into a first connector to which a wiring group of the old device can be connected and a first printed wiring board of a connector between the printed wiring boards. The second printed wiring board is configured to include a first through-hole group into which the pin is inserted, and the second printed wiring board includes a second connector connectable to a connector of the new device, and a second inserting pin to be inserted into the second printed wiring board of the connector between the printed wiring boards. The through-hole group is comprised, The 1st through-hole group is the number of pins with which the connector between printed wiring boards is equipped. It is formed with a large number of through holes, and the first common which can be mounted at a plurality of different positions in the connector between the printed wiring boards, and commonly used in any position when the connector between the printed wiring boards is mounted at different positions. The through-hole group is provided, and the 2nd through-hole group is formed with the through-hole which consists of more than the number of pins with which the connector between printed wiring boards is equipped, The connector between printed wiring boards can be mounted in several different positions, and it prints in a different position. A first through-hole group is provided when a connector between wiring boards is mounted, and when it is mounted in any position, when it connects a 1st printed wiring board and a 2nd printed wiring board with the connector between printed wiring boards, it is provided. And printed wiring boards for each of the second through-hole groups. By changing the mounting position of the pin of a connector, it is provided with the structure which can switch the wiring connection pattern of a 1st connector and a 2nd connector.

According to the present invention, in the first printed wiring board and the second printed wiring board, the pattern design is executed by dividing the wiring parts common to the plurality of wiring patterns and the individual wiring parts, and the common wiring parts of both printed wiring boards are always connected. It is equipped with the structure which can change the mounting position of the connector between printed wiring boards so that the individual wiring parts of both printed wiring boards may be connected according to a desired wiring connection pattern. As a result, within the limited pattern wiring area, an increase in the printed wiring board size and the part score can be suppressed, and a wiring conversion adapter capable of responding to a plurality of switching patterns can be obtained.

BRIEF DESCRIPTION OF THE DRAWINGS It is explanatory drawing which showed each component structure which comprises the wiring conversion adapter which concerns on Embodiment 1 of this invention.
2 is an explanatory diagram for realizing two wiring switching patterns according to the mounting position of the connector between printed wiring boards in the wiring conversion adapter according to the first embodiment of the present invention.
Fig. 3 is a diagram showing a first example of the wiring conversion adapter in the first embodiment of the present invention.
Fig. 4 is a diagram showing a second example of the wire conversion adapter in the first embodiment of the present invention.
Fig. 5 is a diagram showing a third example of the wire conversion adapter in the first embodiment of the present invention.
Fig. 6 is a diagram showing a fourth example of the wiring conversion adapter in the first embodiment of the present invention.
Fig. 7 is a diagram showing a fifth example of the wiring conversion adapter in the first embodiment of the present invention.
FIG. 8 is a diagram showing the actual through-hole arrangement of the first printed wiring board for realizing the fifth example of the wiring conversion adapter in Embodiment 1 of the present invention.
FIG. 9 is a diagram showing a sixth example of the wire conversion adapter according to the first embodiment of the present invention. FIG.
Fig. 10 is a diagram showing a seventh example of the wiring conversion adapter in the first embodiment of the present invention.
It is explanatory drawing which implements two wiring switching patterns according to the mounting position of the connector between printed wiring boards in the wiring conversion adapter in Embodiment 2 of this invention.
It is explanatory drawing which implements two wiring switching patterns according to the mounting position of the connector between printed wiring boards by the structure different from the previous FIG. 11 in the wiring conversion adapter in Embodiment 2 of this invention.

EMBODIMENT OF THE INVENTION Hereinafter, preferred embodiment of the wiring conversion adapter of this invention is described using drawing.

Embodiment 1

BRIEF DESCRIPTION OF THE DRAWINGS It is explanatory drawing which showed each component structure which comprises the wiring conversion adapter which concerns on Embodiment 1 of this invention. The wiring conversion adapter in this Embodiment 1 is comprised including the 1st printed wiring board 10, the 2nd printed wiring board 20, and the connector 30 between printed wiring boards. The wiring conversion adapter is formed by connecting the first printed wiring board 10 and the second printed wiring board 20 with the connector 30 between the printed wiring boards interposed therebetween.

The 1st printed wiring board 10 is the 1st connector 11 which can connect the existing wiring group used by an old model, and the through-hole group 12a for connecting with the some pin of the connector 30 between printed wiring boards. It is comprised including the 1st through-hole area | region 12 provided.

On the other hand, the second printed wiring board 20 is a second through hole provided with a second connector 21 that can be connected to a new type of module, and a through hole group 22a for connecting with a plurality of pins of the connector 30 between the printed wiring boards. The area 22 is comprised. The through hole group 12 or the through hole group 22 may be substituted as a pad for using a connector between printed wiring boards of a surface mount type.

The printed wiring board connector 30 has a plurality of pins for connecting the through hole group 12a provided in the first through hole region 12 and the through hole group 22a provided in the second through hole region 22. These pins protrude from both sides of the front and back surfaces.

Then, the first printed wiring board 10 and the second printed wiring board are inserted by inserting a plurality of pins on the surface into the through hole group 12a, and inserting a plurality of pins on the back surface into the through hole group 22a, and soldering them respectively. (20), the wiring conversion adapter comprised of the connector 30 between printed wiring boards is completed.

Although not shown, a wiring pattern on the first printed wiring board 10 connecting the first connector 11 and the through hole group 12a, and a second connecting the second connector 21 and the through hole group 22a. By devising a wiring pattern on the printed wiring board 20, desired wiring switching can be realized between the first connector 11 and the second connector 21.

Here, in the present invention, the number of through holes provided in the through hole group 12a and the through hole group 22a is provided more than the number of pins provided in the connector 30 between the printed wiring boards, and the mounting of the connector 30 between the printed wiring boards is provided. The wiring switching pattern between the first connector 11 and the second connector 21 can be changed depending on the position. Thus, this feature will be described in detail below.

2 is an explanatory diagram for realizing two wiring switching patterns in accordance with the mounting position of the connector 30 between printed wiring boards in the wiring conversion adapter according to the first embodiment of the present invention. More specifically, FIG. 2A illustrates a mounting position of the printed wiring board connector 30 for realizing the first wiring pattern, and FIG. 2B shows a print for realizing the second wiring pattern. The mounting position of the connector 30 between wiring boards is illustrated. In addition, the connector 30 between printed wiring boards is implemented by the same component in the mounting position which connects a 1st wiring pattern, and the mounting position which connects a 2nd wiring pattern, in any case.

In addition, in FIG. 2, in order to simplify illustration and description, each through-hole which comprises the through-hole group 12a and each through-hole which comprises the through-hole group 22a are arranged in a vertical line and 12 pieces are comprised. The case is illustrated.

The through-hole group 12a provided on the 1st printed wiring board 10 is comprised with three types of through-holes, the through-hole 12a1, the through-hole 12a2, and the through-hole 12a3. Here, the through-hole 12a2 provided in the center part of the through-hole group 12a in FIG. 2 is corresponded to the through-hole with which the common wiring pattern was connected by the 1st wiring pattern and the 2nd wiring pattern.

In contrast, the through hole 12a1 provided in the upper end portion of the through hole group 12a in FIG. 2 corresponds to a through hole in which a wiring pattern inherent to the first wiring pattern is connected. In addition, the through hole 12a3 provided in the lower end part of the through hole group 12a in FIG. 2 is corresponded to the through hole in which the wiring pattern peculiar to the 2nd wiring pattern was connected.

Similarly, the through hole group 22a provided on the second printed wiring board 20 is composed of three types of through holes: through hole 22a1, through hole 22a2, and through hole 22a3. Here, the through hole 22a2 provided in the center part of the through hole group 22a in FIG. 2 corresponds to the through hole to which the common wiring pattern was connected by the 1st wiring pattern and the 2nd wiring pattern.

On the other hand, the through hole 22a1 provided in the upper end part of the through hole group 22a in FIG. 2 is corresponded to the through hole in which the wiring pattern peculiar to the 1st wiring pattern was connected. In addition, the through hole 22a3 provided in the lower end part of the through hole group 22a in FIG. 2 is corresponded to the through hole in which the wiring pattern peculiar to the 2nd wiring pattern was connected.

In FIG. 2A, a through hole 12a2 and a through hole 22a2, which are common parts, are connected, and a through hole 12a1 and a through hole 22a1 inherent to the first wiring pattern are connected. The connector 30 between printed wiring boards is connected to the position where the through hole 12a3 and the through hole 22a3 unique to the wiring pattern are not connected. As a result, wiring switching according to the first wiring pattern can be realized by the connection configuration of Fig. 2A.

On the other hand, in Fig. 2B, through holes 12a2 and through holes 22a2 which are common parts are connected, through holes 12a3 and through holes 22a3 inherent to the second wiring pattern are connected. On the other hand, the connector 30 between printed wiring boards is connected in the position where the through hole 12a1 and the through hole 22a1 unique to the first wiring pattern are not connected. As a result, wiring switching according to the second wiring pattern can be realized by the connection configuration of FIG.

In other words, a rotary switch or a jumper pin is placed on the printed wiring board by changing the connection position of the connector 30 between the printed wiring boards by using one type of the first printed wiring board and the second printed wiring board, respectively. The 1st wiring pattern and the 2nd wiring pattern can be switched easily, without providing components for circuit switching, such as these.

In addition, the present invention has been devised as follows in order to respond to a plurality of wiring patterns by changing the mounting positions of the connectors between the printed wiring boards. First, a part common to the plurality of wiring patterns is extracted. And the wiring pattern of the 1st printed wiring board 10 and the 2nd printed wiring board 20 is designed so that the extracted common part may be arrange | positioned in the center part of the 1st through-hole area | region 12 and the 2nd through-hole area | region 22. FIG.

Next, a unique portion is extracted from each wiring pattern. Then, the wiring patterns of the first printed wiring board 10 and the second printed wiring board 20 are designed so that the extracted unique portions are collectively arranged at the ends of the first through hole region 12 and the second through hole region 22. do.

And silk printing is performed on the 1st printed wiring board 10 and the 2nd printed wiring board 20 so that the connection position of the connector 30 between the printed wiring boards corresponding to each wiring pattern may be specified. The method of specifying the connection position is not limited to silk printing. For example, the display by soldering resist, the printer printing, and the copper foil may be used.

A more specific embodiment of the wiring conversion adapter according to the present invention produced by implementing the above-described design will be described with reference to the drawings.

Fig. 3 is a diagram showing a first example of the wiring conversion adapter in the first embodiment of the present invention. Specifically, this Fig. 3 corresponds to an explanatory diagram of pin arrangement and silk printing of the first printed wiring board for coping with the change in the mounting position of the connector 30 between the printed wiring boards.

Unlike the previous FIG. 2, FIG. 3 illustrates a case where a plurality of pins provided in the connector 30 between printed wiring boards are arranged in a column shape of 2 × 6. In addition, in FIG. 3, the through-hole group 12a is shown taking the 1st printed wiring board 10 as an example, Although the same structure can be employ | adopted also about the 2nd printed wiring board 20, the 2nd printed wiring board 20 is shown. ), The illustration is omitted.

In FIG. 3, the through-hole group 12a provided on the 1st printed wiring board 10 is comprised with the three types of through-holes of the through hole 12a1, the through hole 12a2, and the through hole 12a3. Here, the through-hole 12a2 provided in the center part of the through-hole group 12a in FIG. 3 is corresponded to the through-hole with which the common wiring pattern was connected in the 1st wiring pattern and the 2nd wiring pattern.

On the other hand, the through hole 12a1 provided in the left end part of the through hole group 12a in FIG. 3 is corresponded to the through hole in which the wiring pattern peculiar to the 1st wiring pattern was connected. In addition, the through hole 12a3 provided in the right end part of the through hole group 12a in FIG. 3 is corresponded to the through hole in which the wiring pattern peculiar to the 2nd wiring pattern was connected.

In addition, on the first printed wiring board 10, the external silk printed portion 101 for the first wiring pattern specifying the mounting position of the connector 30 between the printed wiring boards for realizing the first wiring pattern, and the second wiring pattern. The outer silk printed part 102 for the 2nd wiring pattern which specifies the mounting position of the connector 30 between printed wiring boards for implementing this is provided.

Thus, the mounting position of the connector 30 between printed wiring boards is arrange | positioned by gathering and arrange | positioning the through-hole 12a1 and through-hole 12a3 which are intrinsic parts which need wiring switching for every module at the edge part of the through-hole group 12a. Only by changing, the wiring pattern can be switched without changing the wiring on the printed wiring board.

Thereby, a pair of printed wiring boards which consist of the 1st printed wiring board 10 and the 2nd printed wiring board 20 are shared, and the mounting position of the connector 30 between printed wiring boards is changed, and it switches to several wiring patterns. It becomes possible. Moreover, when manufacturing the wiring conversion adapter of this invention, based on silk printing, the mounting position of the connector 30 between printed wiring boards for realizing a necessary wiring pattern can be easily specified, and the connector between printed wiring boards was set in the wrong position. Misinsertion which mounts (30) can be prevented beforehand.

Fig. 4 is a diagram showing a second example of the wire conversion adapter in the first embodiment of the present invention. Specifically, this Fig. 4 corresponds to an explanatory diagram of pin arrangement and silk printing of the first printed wiring board for coping with the change in the mounting position of the connector 30 between the printed wiring boards.

The layout of the through hole group 12a on the first printed wiring board 10 in FIG. 4 is the same as that of the first embodiment in FIG. 3. However, in the second embodiment shown in FIG. 4, after mounting the connector 30 between printed wiring boards, a method is provided which can easily identify which wiring pattern corresponds to.

As shown in FIG.4 (b), the connector 30 between printed wiring boards in 2nd Example has the extension shape part 31 which the one end part in which the pin is not provided extended. In this second embodiment, the extension part 31 is provided so as to extend by 2 x 2 pin areas, and the size of this area is the connector between the printed wiring boards in order to switch between the first wiring pattern and the second wiring pattern. It corresponds to the amount which shifts (30).

Compared with the first embodiment shown in FIG. 3, in the second embodiment shown in FIG. 4A, the first wiring is formed at the right end of the first through hole region 12 of the first printed wiring board 10. The silk printing part 111 for specifying a pattern is further provided, and the silk printing part 112 for specifying a 2nd wiring pattern is further provided in the left end part.

As shown in FIG. 4C, the silk printed portion 112 is covered with the silk printed portion 111 by mounting the connector 30 between the printed wiring boards at a position to realize the first wiring pattern. ) Can only be identified. On the contrary, as shown in FIG. 4D, the silk printed portion 111 is covered with the silk printed portion 112 by mounting the connector 30 between the printed wiring boards at a position to realize the second wiring pattern. ) Can only be identified.

In addition, in FIG.4 (d), it is necessary to make the extension part 31 turn to the right side. Therefore, in FIG. 4C for implementing the first wiring pattern and FIG. 4D for realizing the second wiring pattern, the connector 30 between the printed wiring boards is rotated 180 degrees to be mounted.

As a result, according to the second embodiment, when specifying the mounting position of the connector 30 between printed wiring boards, the outline silk printing portions 101 and 102 which display the outline positions when mounting the connector 30 between the printed wiring boards are displayed. In addition to the reference numerals), the silk printing portions 111 and 112 which display information for identifying the wiring pattern can be referred to, and thus, erroneous insertion can be prevented.

In addition, the position, the size of the extension part 31 in FIG. 4, and the position of the silk printing parts 111 and 112 are an example to the last, and it is also possible to design and change the position and size suitably.

Fig. 5 is a diagram showing a third example of the wire conversion adapter in the first embodiment of the present invention. Specifically, in FIG. 5, a portion where no through hole is formed on the first printed wiring board 10 side is provided for the purpose of preventing misinsertion, and a portion where no pin is placed on the connector 30a side between the printed wiring boards is provided. It corresponds to explanatory drawing of a case.

As shown in Fig. 5A, the first printed wiring board 10 side is provided with a through hole between the through hole 12a2 and the through hole 12a1 and between the through hole 12a2 and the through hole 12a3, respectively. A free area 12b, which is not provided, is provided.

Moreover, on the 1st printed wiring board 10, the external form silk printing part 103 for the 1st wiring pattern which specifies the mounting position of the connector 30a between printed wiring boards for implementing a 1st wiring pattern, and 2nd wiring An external silk printing section 104 for a second wiring pattern that specifies the mounting position of the connector 30a between printed wiring boards for realizing a pattern is provided.

On the other hand, as shown in Fig. 5B, the toothed region 32 which does not erect the pin at a position corresponding to the toothed region 12b without providing the through hole is provided on the connector 30a side between the printed wiring boards. It is prepared.

Thus, by providing the toothed area | region 12b which does not provide a through-hole, and the toothed area | region 32 which does not raise a pin, the connector 30a between printed wiring boards has the outer silk printed part 103 or the outer silk. It can only be inserted at a position that matches the printing unit 104.

In the first embodiment in FIG. 3 or the second embodiment in FIG. 4, it was possible to insert the connector 30 between printed wiring boards even when the position was not matched with the position of the outer silk printed portion. On the other hand, according to the third embodiment in Fig. 5, the connector 30a between the printed wiring boards cannot be inserted unless the position is matched with the position of the outer silk printed portion, so that the erroneous insertion prevention can be enhanced.

In the above first to third embodiments, explanation has been made mainly on the prevention of misinsertion of the connectors 30 and 30a between the printed wiring boards. Next, in the following fourth to seventh embodiments, variations of the arrangement method of through-holes and pins for realizing switching of a plurality of wiring patterns will be described.

Fig. 6 is a diagram showing a fourth example of the wiring conversion adapter in the first embodiment of the present invention. Specifically, this FIG. 6 corresponds to the arrangement method of through holes and fins of the first to third embodiments described above with reference to FIGS. 3 to 5.

According to this fourth embodiment, when the one type of printed wiring board connector 30 is mounted in the through-hole group arranged in a column shape, the two types of wiring patterns can be switched by shifting in the horizontal direction. .

Fig. 7 is a diagram showing a fifth example of the wiring conversion adapter in the first embodiment of the present invention. Specifically, FIG. 7 corresponds to a combination of the through hole and pin arrangement method of the first embodiment described with reference to FIG. 3 and the through hole and pin arrangement method of the third embodiment described with reference to FIG. .

8 is a diagram showing the actual through-hole arrangement of the first printed wiring board 10 for realizing the fifth example of the wiring conversion adapter in Embodiment 1 of the present invention. In addition, in FIG. 8, 2 x 16 through-holes 12a2 of the common part provided in the center part of the through-hole group 12a are comprised, and the through-holes 12a1, 12a2, and 12a4 inherent in each wiring pattern are 2x. It consists of 16 pieces.

According to this fifth embodiment, a pair of printed wiring boards composed of the first printed wiring board 10 and the second printed wiring board 20 are shared, and the connector 30 between the printed wiring boards is shifted in one direction, or the printed wiring board is used. By using the inter connector 30a, switching of three types of wiring patterns corresponding to the outer silk printing sections 101, 102 and 104 can be realized.

FIG. 9 is a diagram showing a sixth example of the wire conversion adapter according to the first embodiment of the present invention. FIG. Specifically, this FIG. 9 corresponds to the case where the arrangement method of the through hole and the pin of the first embodiment described in FIG. 3 is shifted in two directions, longitudinal and transverse. In other words, not only the shift in the lateral direction but also the shift in the horizontal and vertical directions, the shift of the four wiring patterns in total can be performed.

According to the sixth embodiment, four types of wirings are provided depending on the outer silk printed portions 101, 102, 105, and 106 by shifting the connector 30 between one type of printed wiring board in the up-down direction or the left-right direction. Switching of patterns can be realized.

Fig. 10 is a diagram showing a seventh example of the wiring conversion adapter in the first embodiment of the present invention. Specifically, this FIG. 10 applies the through-hole and pin arrangement | positioning method of 1st Example demonstrated previously in FIG. 3, and rotates the connector 30 between printed wiring boards 90 degrees, and it connects to the wiring pattern of two directions. It corresponds to the case corresponding.

According to the seventh embodiment, the external silk printed portions 107 and 108 are switched by switching between the case where one type of printed wiring board connector 30 is used in the horizontal direction and the case where it is rotated by 90 degrees and used in the longitudinal direction. Accordingly, switching between two types of wiring patterns can be realized.

In the sixth and seventh embodiments described above, in particular, when the wiring of the common portion is small, many inherent through holes can be provided in the wiring pattern, so that design freedom can be provided.

As described above, according to the first embodiment, in the first printed wiring board and the second printed wiring board, the pattern design is executed by dividing the wiring parts common to the plurality of wiring patterns and the individual wiring parts, and the common wiring parts of both printed wiring boards. They are always connected, and the structure which can change the mounting position of the connector between printed wiring boards so that the individual wiring parts of both printed wiring boards may be connected according to a switching pattern.

By providing such a structure, it becomes possible to share a pair of printed wiring boards for switching of several wiring patterns, without switching the wiring on a printed wiring board. As a result, within the limited pattern wiring area, an increase in the printed wiring board size and the part score can be suppressed, and a wiring conversion adapter capable of responding to a plurality of switching patterns can be obtained.

Embodiment 2

In the above Embodiment 1, the case where the through hole which consists of more than the number of pins with which the connector between printed wiring boards is equipped is provided in both of a pair of printed wiring boards, and the pair of printed wiring boards was illustrated. However, the present invention is not limited to such a configuration.

Only one printed wiring board of a pair of printed wiring boards is provided with common through-holes which are larger than the number of pins provided by the connector between the printed wiring boards, and the other printed wiring board of the pair of printed wiring boards is provided with a connector between the printed wiring boards. A configuration in which the same number of through holes as the number of pins to be provided is provided in different arrangements (shifted positions) and individualized in accordance with a desired wiring connection pattern may be adopted.

11 is an explanatory diagram for realizing two wiring switching patterns according to the mounting position of the connector 30 between printed wiring boards in the wiring conversion adapter according to the second embodiment of the present invention. More specifically, FIG. 11A illustrates a mounting position of the connector 30 between printed wiring boards for realizing the first wiring pattern, and FIG. 11B illustrates printing for realizing the second wiring pattern. The mounting position of the connector 30 between wiring boards is illustrated. In addition, the connector 30 between printed wiring boards is implemented by the same component in the mounting position which connects a 1st wiring pattern, and the mounting position which connects a 2nd wiring pattern, in either case.

In addition, in FIG. 11, in order to simplify illustration and description, each through-hole which comprises the through-hole group 12a is comprised in a line and 12 pieces, and each through-hole which comprises the through-hole group 22a is vertically. The case where it is comprised by ten pieces in a row is illustrated.

The through-hole group 12a provided on the 1st printed wiring board 10 is comprised with three types of through-holes, the through-hole 12a1, the through-hole 12a2, and the through-hole 12a3. Here, in the through hole 12a2 provided in the center portion of the through hole group 12a in FIGS. 11A and 11B, a common wiring pattern is connected between the first wiring pattern and the second wiring pattern. It corresponds to a through hole.

On the other hand, the through hole 12a1 provided in the upper end part of the through hole group 12a in FIGS. 11A and 11B corresponds to a through hole in which a unique wiring pattern is connected to the first wiring pattern. In addition, the through-hole 12a3 provided in the lower end part of the through-hole group 12a in FIGS. 11A and 11B is corresponded to the through-hole with which the intrinsic wiring pattern was connected to the 2nd wiring pattern.

On the other hand, the through-hole group 22a provided on the 2nd printed wiring board 20 (1) shown to Fig.11 (a) is comprised by the two types of through-holes of the through hole 22a1 and the through hole 22a2. . In addition, the through-hole group 22a provided on the 2nd printed wiring board 20 (2) shown to FIG. 11B is comprised by the two types of through-holes, the through-hole 22a2 and the through-hole 22a3. .

Here, the through hole 22a2 provided in common in FIGS. 11A and 11B corresponds to a through hole to which a common wiring pattern is connected in the first wiring pattern and the second wiring pattern.

In contrast, the through hole 22a1 provided in the upper end portion of the through hole group 22a in FIG. 11A corresponds to a through hole in which a unique wiring pattern is connected to the first wiring pattern. In addition, in FIG. 11A, the lower end part of the through-hole group 22a is provided with the wiringable area | region 23 (1) corresponding to the area | region which can remove a through hole and can design a wiring pattern. In other words, the second printed wiring board 20 (1) for realizing the first wiring pattern is configured to include a wiring possible region 23 (1) instead of the through hole 22 a 3.

On the other hand, the through hole 22a3 provided in the lower end of the through hole group 22a in FIG. 11B corresponds to a through hole in which a wiring pattern inherent to the second wiring pattern is connected. In FIG. 11B, an upper end portion of the through hole group 22 a is provided with a wiring possible region 23 (2) corresponding to a region where the through hole can be eliminated and the wiring pattern can be designed. In other words, the second printed wiring board 20 (2) for realizing the second wiring pattern is configured to include a wiring possible region 23 (2) instead of the through hole 22 a 1.

In Fig. 11A, through holes 12a2 and through holes 22a2, which are common parts, are connected, through holes 12a1 and through holes 22a1 inherent to the first wiring pattern are connected. The connector 30 between printed wiring boards is connected to the position which is not connected to the through hole 12a3 peculiar to 2 wiring patterns. As a result, wiring switching according to the first wiring pattern can be realized by the connection configuration of FIG. 11A.

On the other hand, in Fig. 11B, the through hole 12a2 and the through hole 22a2, which are common parts, are connected, and the through hole 12a3 and the through hole 22a3 unique to the second wiring pattern are connected. On the other hand, the connector 30 between printed wiring boards is connected in the position which is not connected to the through hole 12a1 peculiar to a 1st wiring pattern. As a result, wiring switching according to the second wiring pattern can be realized by the connection configuration of FIG. 11B.

In other words, in FIG. 11, the 1st printed wiring board is shared by one type, and the 2nd printed wiring board is employ | adopted as a separate printed wiring board provided with a wiring possible area | region. As a result, by changing the connection position of the connector 30 between printed wiring boards, a 1st wiring pattern and a 2nd wiring do not provide components for circuit switching, such as a rotary switch or a jumper pin, on a printed wiring board. The pattern can be easily switched, and the same effect as in the first embodiment can be realized.

In addition, instead of sharing the second printed wiring board, a wiring possible area is provided, and the degree of freedom in design for manufacturing the second printed wiring board according to each wiring pattern can be improved.

Next, the case where switching of a wiring pattern is performed using the structure different from 2nd printed wiring board 20 (1) and 20 (2) shown in FIG. 11 is demonstrated. FIG. 12 is an explanatory diagram for realizing two wiring switching patterns according to the mounting position of the connector 30 between printed wiring boards in the wiring conversion adapter according to the second embodiment of the present invention according to a configuration different from that of FIG. 11. to be.

The structure of FIG. 12 differs from the following two points compared with the structure of previous FIG.

The second printed wiring board 20 (3) used to form the first wiring pattern does not include the wiring possible region 23 (1) as compared with the second printed wiring board 20 (1). It is formed so that the size of a longitudinal direction may become small by that much.

The second printed wiring board 20 (4) used to form the second wiring pattern does not include the wiring possible region 23 (2) as compared with the second printed wiring board 20 (2). It is formed so that the size of a longitudinal direction may become small by that much.

According to such a structure of FIG. 12, although there is no wiring area | region, the size of a printed wiring board can be miniaturized more and manufacturing cost can be reduced.

11 and 12 collectively, in the second embodiment, the first printed wiring board is used as one type, and the second printed wiring board is provided with a wiring enable area or the size is made smaller. It is set as a separate printed wiring board according to a pattern, and changes the connection position of the connector 30 between printed wiring boards.

Also in such a configuration, by inserting the connector between the printed wiring boards in accordance with the through-hole position of the other printed wiring board, the increase in the size of the printed wiring board and the number of parts is suppressed within the limited pattern wiring area, and the plurality of switching The wiring conversion adapter corresponding to a pattern can be obtained. Moreover, according to each wiring pattern, the design freedom of the other printed wiring board of a pair of printed wiring board can be increased.

In addition, the structure demonstrated by Embodiment 1 and the structure demonstrated by FIG. 11 of Embodiment 2 used the pair of printed wiring boards with the same maximum length of the long side and short side of a printed wiring board. In contrast, in the configuration described in FIG. 12 of Embodiment 2, the shapes of the first printed wiring board and the second printed wiring board are not the same.

When each printed wiring board which comprises a pair of printed wiring board is made the same size, it can be efficiently integrated in the same housing, and according to the structure demonstrated in Embodiment 1, a 2nd printed wiring board can be shared. However, as described with reference to FIG. 12, the maximum length of the long side and short side of a pair of printed wiring boards does not need to be the same.

Also, by making the size of the second printed wiring board smaller than the size of the first printed wiring board, a wiring conversion adapter capable of suppressing an increase in the printed wiring board size and the part score and corresponding to a plurality of switching patterns within a limited pattern wiring area can be obtained. It is possible to obtain the effect of the present invention.

In addition, the structure shown in FIG. 11 and FIG. 12 can also reverse the structure of the 1st printed wiring board 10, and the structure of the 2nd printed wiring board 20, and can implement | achieve the same effect.

In addition, by devising the pattern design of the individual wiring portions, the pins which do not mount the connectors 30 and 30a between the printed wiring boards can be designed so as not to be short-circuited in the first printed wiring board 10. That is, on the first printed wiring board 10, the wiring pattern between the two pins is avoided, and the through-holes of the individual wiring portions are increased so as to short-circuit between these pins on the second printed wiring board 20 side, thereby forming a wiring pattern. Can be designed.

As a result, as long as the 1st printed wiring board 10 and the 2nd printed wiring board 20 are not connected by the connector between printed wiring boards 30 and 30a, a short circuit is not carried out between both pins. On the other hand, the first printed wiring board 10 and the second printed wiring board 20 are connected by the connectors 30 and 30a between the printed wiring boards, so that both pins can be shorted on the second printed wiring board 20 side. Therefore, the short circuit at the time of not mounting a connector between printed wiring boards can be eliminated.

10: first printed wiring board 11: first connector
12: first through hole region 12a: first through hole group
12a1, 12a2, 12a3, 12a4: through hole 12b: toothless area
20: second printed wiring board 21: second connector
22: second through hole region 22a: second through hole group
22a1, 22a2, 22a3, 22a4: through hole
30, 30a: Connector between printed wiring board 31: Extension part
32: toothed area
101 to 108: outline silk printing section 111, 112: silk printing section

Claims (10)

A first printed wiring board, a second printed wiring board, and a connector between the printed wiring board for electrically connecting the first printed wiring board and the second printed wiring board, wherein the connector is used in the old device when the old device is replaced with the new device. In the wiring conversion adapter which allows a wiring group to be connected to new equipment,
The first printed wiring board includes a first connector to which the wiring group of the old device is connectable, and a first through hole group into which pins to be inserted into the first printed wiring board of the connector between the printed wiring boards are inserted.
The second printed wiring board includes a second connector connectable to the connector of the new device, and a second through hole group into which pins to be inserted into the second printed wiring board of the connector between the printed wiring boards are inserted.
The first through hole group,
It is formed of a through hole consisting of a larger number of pins than the connector between the printed wiring board, the connector between the printed wiring board can be mounted at a plurality of different positions,
Moreover, when mounting the said connector between printed wiring boards in a different position, it is equipped with the 1st common through-hole group commonly used even when mounted in any position,
The second through hole group,
It is formed of a through hole consisting of a larger number of pins than the connector between the printed wiring board, the connector between the printed wiring board can be mounted at a plurality of different positions,
Moreover, when mounting the said connector between printed wiring boards in a different position, it is equipped with the 2nd common through-hole group commonly used even when mounted in any position,
When the first printed wiring board and the second printed wiring board are connected by the connector between the printed wiring boards, the mounting positions of the pins of the connector between the printed wiring boards with respect to each of the first through hole group and the second through hole group are changed. Thereby, the structure which can switch the wiring connection pattern of a said 1st connector and a said 2nd connector is provided.
Wiring conversion adapter. The method of claim 1,
The wiring connection pattern to be switched includes two kinds of a first wiring connection pattern and a second wiring connection pattern,
The first through hole group,
Through holes are arranged in a column shape, the first common through hole group is formed in the central portion of the column shape, and a through hole group for the first wiring connection pattern is formed at one end of the first common through hole group, A through hole group for the second wiring connection pattern is formed on the other end side of the first common through hole group,
The second through hole group,
Through holes are arranged in a column shape, the second common through hole group is formed in the central portion of the column shape, and a through hole group for the first wiring connection pattern is formed at one end of the second common through hole group, A through hole group for the second wiring connection pattern is formed on the other end side of the second common through hole group,
By connecting the said 1st printed wiring board and the said 2nd printed wiring board in the mounting position which shifted the connector between the said printed wiring boards to the horizontal direction, switching of the said 1st wiring connection pattern and the said 2nd wiring connection pattern is possible. doing
Wiring conversion adapter. The method of claim 2,
The first through-hole group is not provided with a through hole in both the first common through-hole group and the through-hole group for the first wiring connection pattern, and between the first common through-hole group and the through-hole group for the second wiring connection pattern. Has a first toothed area,
The second through hole group is not provided with a through hole in both the second common through hole group and the through hole group for the first wiring connection pattern, and between the second common through hole group and the through hole group for the second wiring connection pattern. Has a second toothed area,
The connector between the printed wiring boards is disposed at a position opposite to the first toothed region at a first mounting position for forming the first wiring connection pattern and at a second mounting position for forming the second wiring connection pattern. A third toothed region in which pins are not erected on both sides of the position opposite to the second toothed region, except for the first mounting position and the second mounting position, the first printed wiring board and the second print. With the structure which makes connection of a wiring board impossible
Wiring conversion adapter. The method of claim 2,
In the first through hole group, a third wiring connection pattern is further provided on the side opposite to the side where the through hole group for the second wiring connection pattern is adjacent to the first common through hole group, through a first toothed region where no through hole is provided. Through-hole group of dragon is formed,
In the second through hole group, a third wiring connection pattern is further provided on the side opposite to the side where the through hole group for the second wiring connection pattern is adjacent to the second common through hole group, through a first toothed region where no through hole is provided. Through-hole group of dragon is formed,
The connector between the printed wiring board,
A second printed wiring board connector having a third toothed region in which pins are not erected at a position opposite to the first toothed region in a third mounting position for forming a third wiring connection pattern, or
A connector between the first printed wiring boards without the third toothed region and capable of being mounted at a first mounting position for forming the first wiring connection pattern and a second mounting position for forming the second wiring connection pattern
One of which is used,
When the said 1st printed wiring board connector is used, the said 1st printed wiring board and a said 2nd printed wiring board are connected by the said 1st printed wiring board in the mounting position which shifted the said 1st printed wiring board connector in the horizontal direction. Enable switching of the wiring connection pattern and the second wiring connection pattern,
When the connector between the second printed wiring boards is used, the third wiring by mounting the connector between the second printed wiring boards at the third mounting position and connecting the first printed wiring board and the second printed wiring board. I enable the change over to a connection pattern
Wiring conversion adapter. The method of claim 2,
The wiring connection pattern to be switched further includes two kinds of a third wiring connection pattern and a fourth wiring connection pattern,
Through holes are formed in the first through hole group and the second through hole group so that the connectors between the printed wiring boards can be mounted in a vertical shift state in a vertical shift in a vertical direction perpendicular to the horizontal direction.
In the first through hole group, the through hole group for the third wiring connection pattern is further formed on one end side of the first common through hole group in the vertical shift state, and the first through hole group is formed on the other end side of the first common through hole group. 4 Through-hole group for wiring connection pattern is further formed,
In the second through hole group, the through hole group for the third wiring connection pattern is further formed on one end side of the second common through hole group in the vertical shift state, and the second through hole group is formed on the other end side of the second common through hole group. 4 Through-hole group for wiring connection pattern is further formed,
In the vertical shift state, the third wiring connection pattern and the fourth wiring are connected by connecting the first printed wiring board and the second printed wiring board at a mounting position in which the connectors between the printed wiring boards are shifted in the horizontal direction. To further enable the switching of the connection pattern
Wiring conversion adapter. The method of claim 1,
The wiring connection pattern to be switched includes two kinds of a first wiring connection pattern and a second wiring connection pattern,
The first through hole group,
Through holes are arranged in a cross shape in the transverse direction and the longitudinal direction, and the first common through hole group is formed in the center portion of the cross shape, and the first wirings are provided at both ends of the first common through hole group in the transverse direction. Through-hole groups for connection patterns are formed, Through-hole groups for second wiring connection patterns are formed at both ends of the first common through-hole group in the longitudinal direction,
The second through hole group,
Through holes are arranged in a cross shape in the transverse direction and the longitudinal direction, and the second common through hole group is formed in the center portion of the cross shape, and the first wirings are formed at both ends of the second common through hole group in the transverse direction. Through-hole groups for connection patterns are formed, Through-hole groups for second wiring connection patterns are formed at both ends of the second common through-hole group in the longitudinal direction,
The first wiring connection pattern and the second wiring connection are connected by connecting the first printed wiring board and the second printed wiring board to the connector between the printed wiring boards in any one of the lateral or longitudinal directions. Which enables the switching of patterns
Wiring conversion adapter. The method according to any one of claims 1 to 6,
The printed wiring board connector extends to cover a specific silk printed portion on the first printed wiring board and the second printed wiring board in a printed wiring board mounted state, and includes an extended shape portion where pins are not disposed.
Wiring conversion adapter. A first printed wiring board, a second printed wiring board, and a connector between the printed wiring board for electrically connecting the first printed wiring board and the second printed wiring board, wherein the connector is used in the old device when the old device is replaced with the new device. In the wiring conversion adapter which allows a wiring group to be connected to new equipment,
The first printed wiring board includes a first connector to which the wiring group of the old device can be connected, and a first through hole group into which a pin to be inserted into the first printed wiring board of the connector between the printed wiring boards is inserted, and which is to be switched. Each wiring connection pattern is configured in common,
The second printed wiring board includes a second connector connectable to a connector of the new device, and a second through hole group into which a pin to be inserted into the second printed wiring board of the connector between the printed wiring boards is inserted, wherein the respective wirings Individually configured for the connection pattern,
The first through hole group,
It is formed of a through hole consisting of a larger number of pins than the connector between the printed wiring board, the connector between the printed wiring board can be mounted at a plurality of different positions,
Moreover, when mounting the said connector between printed wiring boards in a different position, it is equipped with the 1st common through-hole group commonly used even when mounted in any position,
The second through hole group,
It is formed of a through hole made of the same number of pins that the connector between the printed wiring boards,
Moreover, the 2nd common through-hole group used commonly for each said wiring connection pattern is provided,
When the first printed wiring board and the second printed wiring board are connected with the connector between the printed wiring boards, the mounting position of the pins of the connector between the printed wiring boards with respect to the first through hole group is changed, so that the first connector and the Having a structure which can switch the wiring connection pattern of a 2nd connector
Wiring conversion adapter. A first printed wiring board, a second printed wiring board, and a connector between the printed wiring board for electrically connecting the first printed wiring board and the second printed wiring board, wherein the connector is used in the old device when the old device is replaced with the new device. In the wiring conversion adapter which allows a wiring group to be connected to new equipment,
The first printed wiring board includes a first connector to which the wiring group of the new device can be connected, and a first through hole group into which pins to be inserted into the first printed wiring board of the connector between the printed wiring boards are inserted, and which are to be switched. Each wiring connection pattern is configured in common,
The second printed wiring board includes a second connector connectable to the connector of the old device, and a second through hole group into which a pin to be inserted into the second printed wiring board of the connector between the printed wiring boards is inserted, wherein the respective wirings are inserted. Individually configured for the connection pattern,
The first through hole group,
It is formed of a through hole consisting of a larger number of pins than the connector between the printed wiring board, the connector between the printed wiring board can be mounted at a plurality of different positions,
Moreover, when mounting the said connector between printed wiring boards in a different position, it is equipped with the 1st common through-hole group commonly used even when mounted in any position,
The second through hole group,
It is formed of a through hole made of the same number of pins that the connector between the printed wiring boards,
Moreover, the 2nd common through-hole group used commonly for each said wiring connection pattern is provided,
When the first printed wiring board and the second printed wiring board are connected with the connector between the printed wiring boards, the mounting position of the pins of the connector between the printed wiring boards with respect to the first through hole group is changed, so that the first connector and the Having a structure which can switch the wiring connection pattern of a 2nd connector
Wiring conversion adapter. The method according to claim 8 or 9,
The second printed wiring board is smaller in size than the first printed wiring board.
Wiring conversion adapter.

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