JP2012235060A - Printed wiring board and printed circuit board and device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent failure of a circuit due to incorrect combination by making a product, e.g. a lighting fixture, to be assembled in correct combination even when the components, e.g. a power supply and a load device, do not come into direct contact with each other.SOLUTION: Printed wiring boards 140, 240 are used in common in two or more kinds of electric circuits. Connectors are mounted on connector mounting parts 150, 250. The connector has a plurality of terminals. A plurality of terminal connection conductor patterns (print wiring 141-143, 241-243) are connected electrically with the plurality of terminals of the connector, respectively. Electric circuits (power supply circuit, load circuit) are configured by mounting the elements on the printed wiring boards 140, 240. Connection select sections 160, 260 can electrically connect the electric circuits and the plurality of terminal connection conductor patterns, respectively.

Description

  The present invention relates to a printed wiring board used in common for an electric circuit having a plurality of types of variations.

In electrical products such as lighting devices, there may be multiple variants (variations, lineups) that share the same external appearance and have different specifications such as the number of light sources and emission colors to meet the diverse needs of users. . In these variants, manufacturing costs can be reduced by using as many common parts as possible.
When there are a plurality of parts having a plurality of variants corresponding to product variants, it is necessary to use the components in the correct combination when assembling the product. When multiple parts are in direct contact with each other, by changing the shape of the contact part for each variant, the product can be assembled only in the correct combination, and the product cannot be assembled in the wrong combination There is. In addition, there is a technique for providing a protection circuit so that the circuit does not fail when an incorrect combination is made.

JP 2010-55824 A JP 2008-103461 A

However, when a plurality of components do not directly contact each other, such as when connecting a plurality of components using a connection component such as a harness, the shape of the contact portion cannot be changed. When the shape of the connector that connects the component and the connection component is changed, it is necessary to change the connection component for each type of product.
The present invention has been made to solve the above-described problems, for example. Even when components such as a power supply device and a load device are not in direct contact with each other, a product such as a lighting device can be assembled with a correct combination. In this way, the object is to prevent a circuit failure due to an incorrect combination.

  A printed wiring board according to the present invention is a connector mounting portion for mounting a connector having a plurality of terminals in a printed wiring board commonly used for two or more types of electric circuits, and the plurality of terminals of the mounted connector A connector mounting portion having a plurality of terminal connection conductor patterns that are electrically connected to each other, an electric circuit configured by mounting elements on the printed wiring board, and each of the plurality of terminal connection conductor patterns can be electrically connected And a connection selection unit.

  According to the printed wiring board concerning this invention, according to the kind of electric circuit mounted, the terminal connection conductor pattern connected with an electric circuit via a connection selection part can be changed. For this reason, even when a plurality of components are connected using a connection component such as a harness, if the combination of the plurality of components is not correct, the electrical circuits are not properly electrically connected and cannot be operated. For this reason, it can be found by an operation test that the combination of a plurality of circuits is not correct. Further, if a closed circuit is not formed by an incorrect combination, an overvoltage or an overcurrent due to an incorrect combination does not occur, and a circuit failure can be prevented.

FIG. 3 shows an entire configuration of a lighting device 800 in Embodiment 1. FIG. 6 shows a detailed configuration of a first variant of lighting apparatus 800 in the first embodiment. FIG. 6 shows a detailed configuration of a second variant of the lighting device 800 in the first embodiment. FIG. 6 shows a detailed configuration of a third variant of lighting apparatus 800 in the first embodiment. FIG. 3 is a diagram showing a printed pattern of the printed wiring board 140 and the printed wiring board 240 in the first embodiment. FIG. 6 shows a printed pattern of a printed wiring board 240 in the second embodiment. FIG. 6 shows a printed pattern of a printed wiring board 140 in the third embodiment.

Embodiment 1 FIG.
The first embodiment will be described with reference to FIGS.

FIG. 1 is a diagram showing an overall configuration of an illumination device 800 according to this embodiment.
Lighting device 800 (LED lighting device) includes power supply device 100, load device 200, and harness 300. The power supply device 100 (DC power supply circuit unit) converts power supplied from an AC power supply AC such as a commercial power supply into power (DC power) supplied to the load device 200. The load device 200 (LED module unit) has a light source such as an LED. The light source of the load device 200 is turned on by the power supplied from the power supply device 100. The harness 300 (connection harness part) connects between the power supply device 100 and the load device 200 and electrically connects them.

  The lighting device 800 has a plurality of variants. Each variation of the lighting device 800 differs in, for example, the brightness of the light source and the emission color. In the following description, different parts in each variation of the lighting device 800 may be distinguished by adding a lower case alphabet after the reference numeral.

FIG. 2 is a diagram showing a detailed configuration of the first variant of the lighting device 800 according to this embodiment.
The harness 300 (connection component) has two connectors 311 and 312 and three wirings 321 to 323 (electric wires). The connector 311 has three terminals (pins). The three terminals of the connector 311 are electrically connected to the three wires 321 to 323, respectively. The connector 312 has three terminals (pins). The three terminals of the wiring 321 are electrically connected to the three wirings 321 to 323, respectively. Connector 311 is coupled to connector 110 of power supply device 100. Connector 312 is coupled to connector 210 of load device 200. Thereby, harness 300 connects between power supply device 100 and load device 200.
The load device 200a (printed circuit board) includes a load circuit 230a, a connector 210, and an electrical connection unit 220. The load circuit 230a (light source circuit, electric circuit) is a circuit in which a plurality of light sources 231 that are lit by DC power, such as LEDs, are electrically connected in series. The connector 210 (LED module side connector) has three terminals (pins). Connector 210 engages with connector 312 of harness 300. The three terminals of the connector 210 are in contact with and electrically connected to the terminals of the combined connector 312 respectively. The electrical connection unit 220 is interposed between the connector 210 and the load circuit 230a, and connects the wiring of the harness 300 connected to the connector 210 and the load circuit 230a. The connector 210 and the electrical connection part 220 are electrically connected by three printed wirings 241 to 243. The electrical connection unit 220 and the load circuit 230a are electrically connected by two printed wirings 246 and 247. The electrical connection unit 220 includes two jumper elements 221 and 222 (a conductive component, a jumper resistor, and a jumper wire). The jumper element 221 electrically connects the printed wiring 241 electrically connected to the wiring 321 of the harness 300 and the printed wiring 246 electrically connected to the input (high potential side input terminal) of the load circuit 230a. The jumper element 222 is electrically connected between the printed wiring 242 that is electrically connected to the wiring 322 of the harness 300 and the printed wiring 247 that is electrically connected to the input (low potential side input terminal) of the load circuit 230a.
The power supply apparatus 100a (printed circuit board) includes a power supply circuit 130a, a connector 110, and an electrical connection unit 120. The power supply circuit 130a (electric circuit) converts AC power input from the AC power supply AC into DC power supplied to the load circuit 230a. The power supply circuit 130a includes, for example, a filter circuit, a full-wave rectifier circuit, and a flyback converter circuit. The output characteristics of the power supply circuit 130a are set according to the electrical characteristics of the load circuit 230a. Examples of output characteristics of the power supply circuit 130a include a maximum output voltage, a rated output voltage, a maximum output current, and a rated output current. The electrical characteristics of the load circuit 230a include, for example, a maximum input voltage, a rated input voltage, a maximum input current, a rated input current, and the like. For example, the power supply circuit 130a is a constant current power supply that attempts to make the output current coincide with the target current value. The target current value is set based on the current that should be passed to turn on the light source 231 of the load circuit 230a with a desired brightness. Further, a maximum output voltage value is set in the power supply circuit 130a. Since no current flows when there is no load, the power supply circuit 130a attempts to flow current by increasing the output voltage. When the output voltage reaches the set maximum output voltage value, the power supply circuit 130a determines that there is no load and stops its operation, thereby preventing the output voltage from becoming too high. The maximum output voltage value has a margin more than the maximum value of the voltage across the load circuit 230 when the current of the target current value is passed in consideration of the variation in the voltage across the light source 231 (forward voltage drop). Value is set.
The connector 110 (power supply side connector) has three terminals (pins). The connector 110 is coupled and connected to the connector 311 of the harness 300. The three terminals of the connector 110 are in electrical contact with the terminals of the combined connector 311 respectively. The electrical connection unit 120 is interposed between the connector 110 and the power supply circuit 130a, and connects the wiring of the harness 300 connected to the connector 110 and the power supply circuit 130a. The connector 110 and the electrical connection part 120 are electrically connected by three printed wirings 141 to 143. The electrical connection unit 120 and the power supply circuit 130a are electrically connected by two printed wirings 146 and 147. The electrical connection unit 120 includes two jumper elements 121 and 122. The jumper element 121 is electrically connected between the printed wiring 141 electrically connected to the wiring 321 of the harness 300 and the printed wiring 146 electrically connected to the output (high potential side output terminal) of the power supply circuit 130a. The jumper element 122 electrically connects the printed wiring 142 electrically connected to the wiring 322 of the harness 300 and the printed wiring 147 electrically connected to the output (low potential side output terminal) of the power supply circuit 130a.
Therefore, the power supply circuit 130a and the load circuit 230a are electrically connected through two paths. The first route is a route of the printed wiring 146, the jumper element 121, the printed wiring 141, the wiring 321, the printed wiring 241, the jumper element 221, and the printed wiring 246. The second route is a route of the printed wiring 147, the jumper element 122, the printed wiring 142, the wiring 322, the printed wiring 242, the jumper element 222, and the printed wiring 247. The power output from the power supply circuit 130a is supplied to the load circuit 230a via these two paths.
Of the three wires 321 to 323 of the harness 300, the wire 323 is not electrically connected to the power circuit 130a or the load circuit 230a, is in an electrically floating state, and is in a non-energized state. It does not contribute to the connection between the power supply circuit 130a and the load circuit 230a.

FIG. 3 is a diagram showing a detailed configuration of the second variant of the lighting device 800 according to this embodiment.
The second variant of the lighting device 800 is different from the first variant in that the load circuit 230b, the power supply circuit 130b, and the jumper elements 121, 122, 221, and 222 in the electrical connection unit 120 and the electrical connection unit 220 are different. It is an arrangement.
The load circuit 230b (electric circuit) is different from the load circuit 230a in the number and type of the light sources 231. For this reason, the electrical characteristics of the load circuit 230b are different from those of the load circuit 230a.
The output characteristics of the power supply circuit 130b (electric circuit) are set according to the electrical characteristics of the load circuit 230b. Since the electrical characteristics of the load circuit 230b are different from those of the load circuit 230a, the output characteristics of the power supply circuit 130b are different from those of the power supply circuit 130a. For example, since the current to be supplied to the light source 231 varies depending on the type of the light source 231, the target current value of the power supply circuit 130b is set to a different value. Further, since the voltage across the load circuit 230 changes depending on the number and type of the light sources 231, the maximum output voltage value of the power supply circuit 130b is set to a different value.
In the electrical connection section 220, the jumper element 221 is electrically connected to the printed wiring 241 that is electrically connected to the wiring 321 of the harness 300 and the input (high potential side input terminal) of the load circuit 230b, as in the first variant. The printed wiring 246 is electrically connected. However, unlike the first variant, the jumper element 222 includes a printed wiring 243 that is electrically connected to the wiring 323 of the harness 300 and a printed wiring 247 that is electrically connected to the input (low potential side input terminal) of the load circuit 230b. Are electrically connected.
Further, in the electrical connection unit 120, the jumper element 121 is electrically connected to the printed wiring 241 electrically connected to the wiring 321 of the harness 300 and the output (high potential side output terminal) of the power supply circuit 130b, as in the first variant. The printed wiring 146 is electrically connected. However, unlike the first variant, the jumper element 122 includes a printed wiring 143 that is electrically connected to the wiring 323 of the harness 300, and a printed wiring 147 that is electrically connected to the output (low potential side output terminal) of the power supply circuit 130b. Are electrically connected.
Therefore, the power supply circuit 130b and the load circuit 230b are electrically connected through two paths. The first route is a route of the printed wiring 146, the jumper element 121, the printed wiring 141, the wiring 321, the printed wiring 241, the jumper element 221, and the printed wiring 246, as in the first variant. Unlike the first variant, the second path is a path of the printed wiring 147, the jumper element 122, the printed wiring 143, the wiring 323, the printed wiring 243, the jumper element 222, and the printed wiring 247. The power output from the power supply circuit 130b is supplied to the load circuit 230b via these two paths. Of the three wires 321 to 323 of the harness 300, the wire 322 is not electrically connected to the power circuit 130b and the load circuit 230b, is in an electrically floating state, is in a non-energized state, It does not contribute to the connection between 130b and the load circuit 230b.

FIG. 4 is a diagram showing a detailed configuration of the third variant of the lighting device 800 according to this embodiment.
The third variant of the lighting device 800 is different from the first and second variants in that the load circuit 230c, the power supply circuit 130c, and the jumper elements 121, 122, 221 and 222 are arranged.
The load circuit 230c (electric circuit) is different from the load circuit 230a and the load circuit 230b in the number and type of the light sources 231. For this reason, the electrical characteristics of the load circuit 230c are different from those of the load circuits 230a and 230b.
The output characteristics of the power supply circuit 130c (electric circuit) are set according to the electrical characteristics of the load circuit 230c. For this reason, the output characteristics of the power supply circuit 130c are different from those of the power supply circuits 130a and 130b.
In the electrical connection part 220, the jumper element 221 electrically connects the printed wiring 242 electrically connected to the wiring 322 of the harness 300 and the printed wiring 246 electrically connected to the input (high potential side input) of the load circuit 230c. Connected. Similar to the second variant, the jumper element 222 is connected between the printed wiring 243 electrically connected to the wiring 323 of the harness 300 and the printed wiring 247 electrically connected to the input (low potential side input) of the load circuit 230c. Electrical connection.
In the electrical connection unit 120, the jumper element 121 is connected between the printed wiring 242 that is electrically connected to the wiring 322 of the harness 300 and the printed wiring 146 that is electrically connected to the output (high potential side output) of the power supply circuit 130c. Are electrically connected. Similar to the second variant, the jumper element 122 is connected between the printed wiring 143 electrically connected to the wiring 323 of the harness 300 and the printed wiring 147 electrically connected to the output (low potential side output) of the power supply circuit 130c. Electrical connection.
Therefore, the power supply circuit 130c and the load circuit 230c are electrically connected through two paths. The first route is a route of the printed wiring 146, the jumper element 121, the printed wiring 142, the wiring 322, the printed wiring 242, the jumper element 221, and the printed wiring 246. Similar to the second variant, the second path is a path of the printed wiring 147, the jumper element 122, the printed wiring 143, the wiring 323, the printed wiring 243, the jumper element 222, and the printed wiring 247. The power output from the power supply circuit 130c is supplied to the load circuit 230c via these two paths. Of the three wires 321 to 323 of the harness 300, the wire 321 is not electrically connected to the power circuit 130c or the load circuit 230c, is in an electrically floating state, is in a non-energized state, It does not contribute to the connection between 130c and the load circuit 230c.

  The harness 300 is common in all variants of the lighting device 800. That is, one type of harness 300 is used for manufacturing all variants of the lighting device 800. Since it is not necessary to prepare a different harness 300 for each variant, it is possible to reduce the cost for inventory management of parts.

The shapes of the connectors 110 of the power supply apparatuses 100 a to 100 c are all the same, and can be connected to the connector 311 of the same harness 300. Further, the shapes of the connectors 210 of the load devices 200a to 200c are all the same, and can be connected to the connector 312 of the same harness 300.
For this reason, when the lighting device 800 is assembled, there is a possibility that the combination of the power supply device 100 and the load device 200 is wrongly connected.

For example, it is assumed that the power supply device 100a and the load device 200b are connected by mistake. In that case, the path connecting the power supply circuit 130a and the load circuit 230 is only the path of the printed wiring 146, the jumper element 121, the electrical connection unit 120, the wiring 321, the printed wiring 241, the jumper element 221, and the printed wiring 246. Yes, another path is not formed. For this reason, the power output from the power supply circuit 130a is not supplied to the load circuit 230b. For this reason, it is possible to prevent the load circuit 230b from failing due to overvoltage, overcurrent, etc., and it is possible to find an erroneous connection by a lighting test.
Similarly, when the connection is made in another wrong combination, the power output from the power supply circuit 130 is not supplied to the load circuit 230, so that a failure of the load circuit 230b can be prevented and an erroneous connection can be found.

The wiring of the harness 300 is not limited to three and may be four or more. Moreover, the structure which uses wiring other than two wiring used in order to supply electric power from the power supply device 100 to the load apparatus 200 for other uses, such as transmission of a control signal, may be sufficient.
In addition, when there are only two types of the lighting device 800, one jumper element may be used for each of the electrical connection unit 120 and the electrical connection unit 220. For example, in the electrical connection unit 120, the printed wiring 141 and the printed wiring 146 are directly connected, and the printed wiring 142 or the printed wiring 143 and the printed wiring 147 are electrically connected by the jumper element 122. Similarly, the printed wiring 241 and the printed wiring 246 are directly connected in the electrical connection unit 220, and the printed wiring 242 or the printed wiring 243 and the printed wiring 247 are electrically connected by the jumper element 222.

FIG. 5 is a diagram showing a printed pattern of the printed wiring board 140 and the printed wiring board 240 in this embodiment.
The power supply apparatus 100 is configured by mounting components on a printed wiring board 140 (DC power supply board). The output characteristics of the power supply circuit 130 can be changed by changing circuit constants (for example, resistance values of resistors) of components to be mounted. For this reason, the power supply apparatuses 100a to 100c are configured using the same printed wiring board 140.
The load device 200 is configured by mounting components on a printed wiring board 240 (LED module substrate). When changing the number of light sources of the load circuit 230, for example, a portion (jumper mounting portion) where a jumper element (chip jumper) can be mounted in parallel with a mounting position (LED mounting portion) of each light source is provided, and a light source that is not mounted Instead of this, a jumper element may be mounted. In this way, the load devices 200a to 200c can be configured using the same printed wiring board 240.

  The printed wiring board 140 and the printed wiring board 240 have printed wiring and lands (pads). The printed wiring is composed of, for example, the remaining copper foil by etching a copper foil or the like covering the surface of the printed wiring board to peel a part of the copper foil. A land is a part for mounting, for example, a surface-mounted component and electrically connecting with a printed wiring. For example, the land is formed by providing an exposed portion that is not covered with a resist on a part of the printed wiring.

In the printed wiring board 140, the land 151 and the land 161 are electrically connected to each other via the printed wiring 141 (terminal connection conductor pattern). The land 152 and the land 162 are electrically connected to each other via a printed wiring 142 (terminal connection conductor pattern). The land 153 and the land 163 are electrically connected to each other via a printed wiring 143 (terminal connection conductor pattern). The land 166 is electrically connected to the printed wiring 146 (input terminal). The land 167 is electrically connected to the printed wiring 147 (input terminal).
The three lands 151, 152, and 153 constitute a connector mounting unit 150. The connector mounting part 150 is a part for mounting the connector 110 on the printed wiring board 140. The lands 151 to 153 are electrically connected to terminals of the connector 110 mounted on the connector mounting portion 150, respectively. A terminal to which the land 151 is connected is electrically connected to the wiring 321 of the harness 300. A terminal to which the land 152 is connected is electrically connected to the wiring 322 of the harness 300. A terminal to which the land 153 is connected is electrically connected to the wiring 323 of the harness 300.
The five lands 161, 162, 163, 166, and 167 constitute a connection selection unit 160. The connection selection unit 160 (power supply side connection route selection pattern) configures the above-described electrical connection unit 120 by mounting the jumper elements 121 and 122, and outputs the power circuit 130 according to the output characteristics of the power circuit 130. This is a part for selecting the wiring of the harness 300 to be connected.
The land 166 is provided between the land 161 and the land 162 at a position where the jumper element 121 can be mounted. By mounting the jumper element 121 between the land 166 and the land 161 (conductive component mounting portion), the printed wiring 146 and the printed wiring 141 are electrically connected, and between the land 166 and the land 162 (conductive component mounting portion). ), The printed wiring 146 and the printed wiring 142 are electrically connected.
The land 167 is provided at a position where the jumper element 122 can be mounted between the land 162 and the land 163. By mounting the jumper element 122 between the land 167 and the land 162 (conductive component mounting portion), the printed wiring 147 and the printed wiring 142 are electrically connected, and between the land 167 and the land 163 (conductive component mounting portion). ), The printed wiring 147 and the printed wiring 143 are electrically connected.
As described above, by changing the positions where the jumper elements 121 and 122 are mounted, the printed wiring connected to the power supply circuit 130 can be changed, and the wiring of the harness 300 connected to the power supply circuit 130 can be changed.

In the printed wiring board 240, the land 251 and the land 261 are electrically connected to each other via the printed wiring 241 (terminal connection conductor pattern). The land 252 and the land 262 are electrically connected to each other via a printed wiring 242 (terminal connection conductor pattern). The land 253 and the land 263 are electrically connected to each other via a printed wiring 243 (terminal connection conductor pattern). The land 266 is electrically connected to the printed wiring 246 (output terminal). The land 267 is electrically connected to the printed wiring 247 (output terminal).
The three lands 251, 252 and 253 constitute a connector mounting portion 250. The connector mounting part 250 is a part for mounting the connector 210 on the printed wiring board 240. The lands 251 to 253 are electrically connected to terminals of the connector 210 mounted on the connector mounting portion 250, respectively. A terminal connected to the land 251 is electrically connected to the wiring 321 of the harness 300. A terminal connected to the land 252 is electrically connected to the wiring 322 of the harness 300. A terminal connected to the land 253 is electrically connected to the wiring 323 of the harness 300.
The five lands 261, 262, 263, 266, 267 constitute a connection selection unit 260. The connection selection unit 260 (module-side connection path selection pattern) configures the above-described electrical connection unit 220 by mounting the jumper elements 221 and 222, and the load circuit 230 has an electrical characteristic according to the electrical characteristics of the load circuit 230. This is a part for selecting the wiring of the harness 300 to be connected to the input.
The land 266 is provided between the land 261 and the land 262 at a position where the jumper element 221 can be mounted. By mounting the jumper element 221 between the land 266 and the land 261 (conductive component mounting portion), the printed wiring 246 and the printed wiring 241 are electrically connected, and between the land 266 and the land 262 (conductive component mounting portion). The printed wiring 246 and the printed wiring 242 are electrically connected to each other by mounting the jumper element 222 in FIG.
The land 267 is provided at a position where the jumper element 222 can be mounted between the land 262 and the land 263. By mounting the jumper element 222 between the land 267 and the land 262 (conductive component mounting portion), the printed wiring 247 and the printed wiring 242 are electrically connected, and between the land 267 and the land 263 (conductive component mounting portion). The printed wiring 247 and the printed wiring 243 are electrically connected to each other by mounting the jumper element 222 on the above.

As described above, by changing the positions where the jumper elements 221 and 222 are mounted, the printed wiring connected to the load circuit 230 can be changed, and the wiring of the harness 300 connected to the load circuit 230 can be changed.
The wiring of the harness 300 is not used for one of the three types of connections, but is used for the remaining two types of connections. Since one wiring is used for two types of connections, the number of used poles of the connector can be reduced as compared with the case where the connection terminals used are divided in the connector.

  The electrical connection unit 120 is not limited to a configuration using a jumper element, and may have another configuration. For example, the printed wiring board 140 may be provided with a printed wiring in which five printed wirings 141, 146, 142, 147, 143 are electrically connected, and scraped off unnecessary printed wiring. Or the structure which mounts switches, such as a dip switch, in the printed wiring board 140, and changes a connection by switching a switch may be sufficient. Alternatively, a configuration may be employed in which a plurality of types of printed wiring boards 140 with different printed wiring connections are prepared, and different types of printed wiring boards 140 are used according to variations of the power supply device 100 to be manufactured. The same applies to the electrical connection part 220. Moreover, the structure of the electrical connection part 120 and the structure of the electrical connection part 220 may be different.

Embodiment 2. FIG.
The second embodiment will be described with reference to FIG.
In addition, about the part which is common in Embodiment 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 6 is a diagram showing a printed pattern of the printed wiring board 240 in this embodiment.
The printed wiring board 240 has seven printed wirings 241 to 243 and 271 to 274 and 15 lands 251 to 253, 261, 268 and 286 to 295. The printed wiring 241 (terminal connection conductor pattern) is between the lands 251 and 261, the printed wiring 242 (terminal connection conductor pattern) is between the lands 252 and 286, and the printed wiring 243 (terminal connection conductor pattern) is the land. 253 and 288, the printed wiring 271 is between the lands 287 and 290, the printed wiring 272 is between the lands 291 and 294, and the printed wiring 273 is between the lands 268, 295 and 293. 274 electrically connects the lands 292 and 289, respectively. The lands 251 to 253 are the connector mounting portion 250, the lands 286 and 287 are the light source mounting portion 281, the lands 288 and 289 are the light source mounting portion 282, the lands 290 and 291 are the light source mounting portion 283, and the land 292. 293 and 293 constitute a light source mounting portion 284, and the lands 294 and 295 constitute a light source mounting portion 285, respectively. A light source 231 is mounted between the lands of the light source mounting portions 281 to 285. In addition, the six lands 261, 268, 286 to 289 constitute a connection selection unit 260. That is, the lands 286 to 289 are not only the light source mounting unit but also the connection selection unit 260. A jumper element (conductive component) can be mounted between the lands 261 and 268 (conductive component mounting portion).

The printed wiring board 240 is commonly used for manufacturing three types of variations of the load device 200. The three types of load devices 200a to 200c differ in the number of light sources 231.
The load device 200a includes three light sources 231. The load device 200a is manufactured by mounting the three light sources 231 on the light source mounting portions 281, 283, and 285, respectively, and mounting the jumper element 221 between the lands 261 and 268. Thereby, a series circuit of the jumper element 221 and the three light sources 231 is formed between the lands 251 and 252. The land 253 is not electrically connected anywhere in this circuit. The load device 200a is connected to the power supply device 100a described in the first embodiment via the harness 300.
The load device 200b includes two light sources 231. The load device 200b is manufactured by mounting the two light sources 231 on the light source mounting portions 282 and 284, respectively, and mounting the jumper element 221 between the lands 261 and 268. Thereby, a series circuit of the jumper element 221 and the two light sources 231 is formed between the lands 251 and 253. The land 252 is not electrically connected anywhere in this circuit. Load device 200b is connected to power supply device 100b described in the first embodiment via harness 300.
The load device 200c has five light sources 231. The load device 200c is manufactured by mounting the five light sources 231 on the light source mounting portions 281 to 285, respectively. Thereby, a series circuit of five light sources 231 is formed between the lands 252 and 253. The land 251 is not electrically connected anywhere in this circuit. The load device 200c is connected to the power supply device 100c described in the first embodiment via the harness 300.
That is, by not mounting the light source 231 (conductive component) on the light source mounting unit 281 (conductive component mounting unit), the land 252 is disconnected from the load circuit 230, and the light source 231 (conductive) is connected to the light source mounting unit 282 (conductive component mounting unit). The land 253 is disconnected from the load circuit 230 by not mounting the component.

As described above, the light source 231 mounted on the light source mounting portions 281 and 282 is used in place of the jumper element 222. Thereby, since the number of the jumper elements 222 mounted on the printed wiring board 240 can be reduced, the manufacturing cost of the load device 200 and thus the lighting device 800 can be suppressed.
Note that an element (conductive component) used as a substitute for the jumper element is not limited to the light source 231, but may be an element that changes whether to be mounted or not depending on the type of the load device 200. Similarly, the power supply apparatus 100 may be configured to use an element that changes depending on the type of the power supply apparatus 100 as a replacement for the jumper element.

Embodiment 3 FIG.
The third embodiment will be described with reference to FIG.
Note that portions common to Embodiment 1 or Embodiment 2 are denoted by the same reference numerals and description thereof is omitted.

FIG. 7 is a diagram showing a printed pattern of the printed wiring board 140 in this embodiment.
The printed wiring board 140 has six printed wirings 141 to 144, 146, 147 and ten lands 151-154, 161-164, 166, 167. The printed wiring 141 is between the lands 151 and 161, the printed wiring 142 is between the lands 152 and 162, the printed wiring 143 is between the lands 153 and 163, and the printed wiring 144 is between the lands 154 and 164. Are electrically connected to each other. The land 166 is electrically connected to the printed wiring 146 connected to the output (high potential side output) of the power supply circuit 130. The land 167 is electrically connected to a printed wiring 147 connected to the output (low potential side output) of the power supply circuit 130.
The four lands 151 to 154 constitute a connector mounting portion 150. The harness 300 in this embodiment has four wires 321 to 324 (not shown). The four lands 151 to 154 are electrically connected to the wirings 321 to 324 of the harness 300 connected to the connector 110 via the connector 110 mounted on the connector mounting unit 150.
The six lands 161 to 164, 166, and 167 constitute a connection selection unit 160. Jumper element 121 (not shown) is mounted between land 166 and land 161 or land 162 or land 163. Jumper element 122 (not shown) is mounted between land 167 and land 162 or land 163 or land 164. The lands 162, 163, 166, and 167 are divided into two so that the jumper elements can be mounted in directions different by 90 degrees.

The printed wiring board 140 is used in common for manufacturing six types of variants of the power supply device 100.
In the first variation of the power supply device 100, the jumper element 121 is mounted between the lands 166 and 161, and the jumper element 122 is mounted between the lands 167 and 162. As a result, the power output from the power supply circuit 130 is supplied to the load device 200 via the wiring 321 of the harness 300 connected to the land 151 and the wiring 322 of the harness 300 connected to the land 152.
In the second variant of the power supply device 100, the jumper element 121 is mounted between the lands 166 and 161, and the jumper element 122 is mounted between the lands 167 and 163. As a result, the power output from the power supply circuit 130 is supplied to the load device 200 via the wiring 321 and the wiring 323 of the harness 300 connected to the land 153.
In the third variation of the power supply device 100, the jumper element 121 is mounted between the lands 166 and 161, and the jumper element 122 is mounted between the lands 167 and 164. As a result, the power output from the power supply circuit 130 is supplied to the load device 200 via the wiring 321 and the wiring 324 of the harness 300 connected to the land 154.
In the fourth variation of the power supply apparatus 100, the jumper element 121 is mounted between the lands 166 and 162, and the jumper element 122 is mounted between the lands 167 and 163. As a result, the power output from the power supply circuit 130 is supplied to the load device 200 via the wiring 322 and the wiring 323.
In the fifth variation of the power supply device 100, the jumper element 121 is mounted between the lands 166 and 162, and the jumper element 122 is mounted between the lands 167 and 164. As a result, the power output from the power supply circuit 130 is supplied to the load device 200 via the wiring 322 and the wiring 324.
In the sixth variation of the power supply device 100, the jumper element 121 is mounted between the lands 166 and 163, and the jumper element 122 is mounted between the lands 167 and 164. As a result, the power output from the power supply circuit 130 is supplied to the load device 200 via the wiring 323 and the wiring 324.

  There are also six types of variations in the load device 200. Each variant of the load device 200 corresponds to one of the variants of the power supply device 100. Although detailed description is omitted, the load device 200 is configured so that the power supplied from the two wires connected to the power supply circuit 130 in the corresponding power supply device 100 among the four wires 321 to 324 of the harness 300 is the load circuit. 230 to be supplied.

  It is possible to connect the jumper element 121 between the lands 166 and 163 and the jumper element 122 between the lands 167 and 162, but this connection is not used. This is because if the load device 200 corresponding to the fourth variant of the power supply device 100 is mistakenly connected to the power supply device 100 using the connection, a reverse voltage is applied to the load circuit 230.

  Thus, by increasing the number of wirings of the harness 300, the number of variants of the power supply device 100 and the load device 200 that are connected using the same harness 300 can be increased.

Assuming that the number of wirings of the harness 300 is n, the number of combinations for selecting two is _n C ₂ = n · (n−1) / 2. Therefore, if the harness 300 having n wires is used, n · (n−1) / 2 types of variants of the power supply device 100 and the load device 200 can be connected. For example, when the harness 300 has five wires, ten kinds of variations of the power supply device 100 and the load device 200 can be connected.

  If the load device 200 is provided with a protection circuit against reverse voltage, and power is not supplied to the load circuit 230 and the light source 231 is not turned on when the reverse voltage is applied, the same two wires are used. Since the connection which supplies electric power of reverse polarity using can also be used, the number of the variants of the power supply device 100 and the load device 200 which can be connected using the same harness 300 is doubled. That is, n · (n−1) types of variants of the power supply device 100 and the load device 200 can be connected using the harness 300 having n wirings.

  The configuration described above is an example, and other configurations may be used. For example, the structure which combined the structure demonstrated in different embodiment may be sufficient, and the structure which replaced the structure of the non-essential part with the other structure may be sufficient.

  DESCRIPTION OF SYMBOLS 100 Power supply device, 110,210,311,312 connector, 120,220 Electrical connection part, 121,122,221,222 Jumper element, 130 Power supply circuit, 140,240 Printed wiring board, 141-147,241-247,271 274 printed wiring, 150, 250 connector mounting part, 151-154, 161-167, 251-253, 261-268, 286-295 land, 160, 260 connection selection part, 200 load device, 230 load circuit, 231 light source 281-285 Light source mounting part, 300 harness, 321-324 wiring, 800 lighting device, AC AC power supply.

Claims (12)

In printed wiring boards used in common for two or more types of electrical circuits,
A connector mounting portion for mounting a connector having a plurality of terminals, the connector mounting portion having a plurality of terminal connection conductor patterns respectively electrically connected to the plurality of terminals of the mounted connector;
A printed wiring board comprising: an electric circuit configured by mounting an element on the printed wiring board; and a connection selection unit capable of electrically connecting each of the plurality of terminal connection conductor patterns.   The connection selection unit has a plurality of conductive component mounting units capable of mounting conductive components, and when the conductive component is mounted on any one of the plurality of conductive component mounting units, the electrical circuit, The printed wiring board according to claim 1, wherein any one of the plurality of terminal connection conductor patterns is electrically connected.   The printed wiring board according to claim 1, wherein the connector mounting portion has three or more terminal connection conductor patterns. The printed wiring board according to any one of claims 1 to 3,
A connector mounted on the connector mounting portion of the printed wiring board;
An element mounted on the printed wiring board and constituting an electric circuit selected from two or more types of electric circuits;
The terminal connection conductor pattern selected from the plurality of terminal connection conductor patterns according to the type of the electric circuit and the electric circuit are electrically connected via the connection selection unit. Printed circuit board. The connection selection unit has a plurality of conductive component mounting units capable of mounting conductive components,
The printed circuit board according to claim 4, wherein the printed circuit board includes a conductive component mounted on any one of the plurality of conductive component mounting portions. The connector mounting portion has three or more terminal connection conductor patterns,
Two terminal connection conductor patterns selected from among the three or more terminal connection conductor patterns according to the type of the electric circuit and two connection points of the electric circuit are respectively connected via the connection selector. The printed circuit board according to claim 4, wherein the printed circuit board is electrically connected to each other. The electric circuit is a power supply circuit or a load circuit,
At least one of the maximum output voltage, the rated output voltage, the maximum output current, and the rated output current of the power circuit, or at least one of the maximum input voltage, the rated input voltage, the maximum input current, and the rated input current of the load circuit. Accordingly, the terminal connection conductor pattern selected from among the plurality of terminal connection conductor patterns and the output terminal of the power supply circuit or the input terminal of the load circuit are electrically connected via the connection selection unit. The printed circuit board according to claim 4, wherein the printed circuit board is provided.   The printed circuit board according to any one of claims 4 to 7, wherein the connector is a connector capable of connecting connection parts having the same shape regardless of the type of the electric circuit. A plurality of printed circuit boards according to claim 4;
An apparatus comprising: a connecting component coupled to a connector of the plurality of printed circuit boards to electrically connect the plurality of printed circuit boards. One of the plurality of printed circuit boards is a power circuit in which the electrical circuit is selected from two or more types of power circuits.
Another one of the plurality of printed circuit boards is a load circuit in which the electrical circuit is selected from two or more types of load circuits,
The apparatus according to claim 9, wherein the connection component transmits power supplied from the power supply circuit to the load circuit when a combination of the power supply circuit and the load circuit is correct. The connecting part has three or more wires,
Each of the plurality of printed circuit boards is
The connector has three or more terminals each electrically connected to three or more wires of the connecting component;
The connector mounting portion has three or more terminal connection conductor patterns electrically connected to three or more terminals of the connector, respectively;
The printed circuit board in which the electric circuit is a power supply circuit includes two terminal connection conductor patterns selected from among the three or more terminal connection conductor patterns according to the type of the power supply circuit, and two of the power supply circuits. The output terminals are electrically connected through the connection selection unit,
The printed circuit board in which the electric circuit is a load circuit is connected to the three or more terminals in a printed circuit board in which the combination of two input terminals of the load circuit and the electric circuit is a correct power circuit. Two terminal connection conductor patterns respectively electrically connected to the two wirings of the connection component that are electrically connected to the two terminal connection conductor patterns selected from among the conductor patterns, respectively, via the connection selection unit The device according to claim 10, wherein the device is electrically connected.   The apparatus according to claim 10 or 11, wherein the load circuit is a light source circuit having a light source that is turned on by electric power supplied from the power supply circuit.

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