JP2005269883A - Power unit and ac connector used therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power unit which can reduce constant power consumption in a charging resistor, while being equipped with the charging resistor for the purpose of preventing electric shock in an AC inlet (input part). <P>SOLUTION: The power unit is provided with the charging resistor 5 which can be connected in parallel with X capacitors 3a, 3b (line across capacitor) by a control switch 6, and a fitting detection means 7 for detecting whether or not an AC connector 18 is fitted in the AC inlet 4 in a prescribed fitting state. When the prescribed fitting state between the AC inlet 4 (AC input part) and the AC cable connector 18 (AC connector) is detected by the fitting detection means 7, the control switch 6 electrically shuts off the charging resistor 5 from an N line. While, when the fitting state between the AC inlet 4 and the connector 18 is detected as not being in the prescribed state by the fitting detection means 7, the control switch 6 connects the charging resistor 5 to both the L line 1 and N line 2. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to suppression of power loss caused by a residual voltage discharge resistor in a power supply device including a line across capacitor (X capacitor) used for a line filter.

  First, FIGS. 5 and 6 show circuit diagrams of a conventional power supply device including a line filter (noise filter).

  As shown in FIG. 5, the power supply device 100 includes an AC inlet 40, a Live line (hereinafter referred to as L line) 10, a neutral line (hereinafter referred to as N line) 20, an earth line (hereinafter referred to as E line) 90, and a bridge diode. 120 is provided. One end of each line (L line 10, N line 20, E line 90) is provided in the AC inlet 40 as an L terminal 80a, an N terminal 80b, and an E terminal 80c. The other end of the line 20 is connected to each input terminal of the bridge diode 120, and the E line 90 is grounded.

  Between the L terminal of the L line 10 and the input terminal of the bridge diode 120, a fuse 160 and a coil 110a are arranged in series from the L terminal side. Also, the N terminal of the N line 20 and the input terminal of the bridge diode 120 are arranged. The coil 110b is arranged in series between the two. The coils 110a and 110b are wound around the same core. Further, a smoothing electrolytic capacitor 130 is disposed between the output terminals of the bridge diode 120, and an alternating current supplied from an AC power source or the like connected via the AC inlet 40 passes through each line. Rectified by 120 and the electrolytic capacitor 130 is charged.

  Here, between the L line 10 and the N line 20, two line across capacitors (X capacitors) 30a and 30b for normal mode noise are connected in parallel. That is, one electrode of the X capacitor 30a is connected between the fuse 160 and the coil 110a in the L line 10, and the other electrode is connected between the N terminal 80b and the coil 110b in the N line 20. . One electrode of the X capacitor 30b is connected between the coil 110a and the bridge diode 120 in the L line 10, and the other electrode is connected between the coil 110b and the bridge diode 120 in the N line 20. Yes.

  A Y capacitor 140 for common mode noise is disposed between the N line 20 and the E line 90. That is, one electrode of the Y capacitor 140 is connected between the coil 110b in the N line 20 and one electrode of the X capacitor 30b, and the other electrode is connected to the N line 20 (ground line).

  In this way, in devices equipped with an AC power supply circuit such as the power supply device 100, a line is formed by combining the X capacitors 30a and 30b, the Y capacitor 140, the coils 110a and 110b (normal mode coil and common mode coil), and the like. By configuring the filter, it is possible to remove or reduce noise generated between the lines (L line 10, N line 20, E line 90) (between AC lines). Note that, as shown in FIG. 6, such a line filter has the configuration shown in FIG. 5, in which the coil 110 c is arranged in series with the L line 10, the coil 110 d is arranged in series with the N line 20, and It is also possible to adopt a configuration in which an X capacitor 30c is additionally arranged between the L line 10 and the N line 20 (in parallel with the X capacitors 30a and 30b).

  Here, between the L line 10 and the N line 20, a discharging resistor 50 is connected in parallel to the X capacitors 30a and 30b. That is, one terminal of the discharging resistor 50 is connected between one electrode of the X capacitor 30b in the L line 10 and one input terminal of the bridge diode 120, and the other terminal of the discharging resistor 50. Is connected between one electrode of the X capacitor 30 b in the N line 20 and one input terminal of the bridge diode 120.

  In this way, by disposing the discharging resistor 50 between the L line 10 and the N line 20 in parallel with the X capacitors 30a and 30b, the AC inlet 40 is mistakenly connected to the AC cable 40 while the power supply device 100 is turned on. Even when the connector is disconnected from the connector, the electric charge remaining in the X capacitors 30a and 30b can be discharged through the discharge resistor 50, and the voltage of the terminal 80 of each line is kept within a specified time (for example, 1 second). (In addition, for devices such as switching power supplies equipped with a power circuit, a “plug discharge test” is defined by safety standards such as the Electrical Appliance and Material Safety Law. If the AC plug is accidentally unplugged from the outlet while using electrical equipment, the voltage remaining on the plug is reduced within 1 second. Voltage as drops below are required to be designed).

However, the discharge resistor 50 generally has a resistance value of several MΩ to several hundred KΩ, and as the total capacity of the X capacitors 30a and 30b and the voltage applied to the AC inlet 40 increase, A small resistance value is required, and power consumption by the discharge resistor 50 is P = V ² / R (P is power consumption at the discharge resistor 50, V is a potential difference between the L line 10 and the N line 20, and R is for discharge. It will increase according to the resistance value of the resistor 50).

That is, the discharging resistor 50 causes a power loss of P = V ² / R when energized, and is an impediment to realizing standby power saving.

As a conventional technique related to this problem, there is a power supply device described in Patent Document 1 (Japanese Patent Laid-Open No. 2002-95247). This Patent Document 1 includes first and second power supply units each including a line filter (including a hot line, a neutral line, an X capacitor, and a discharge resistor), and the first power supply unit is in an OFF state. There is disclosed a power supply device configured such that a discharge resistor provided in a line filter of a second power supply unit is cut off from each line during a power saving mode (cut off from a commercial power supply).
JP 2002-95247 A (publication date: March 29, 2002)

  However, in the configuration described in Patent Document 1, the discharging resistors of both the first and second power supply units are connected to each line during energization and standby mode in which the supplied voltage increases. That is, although the power consumption of the second power supply unit in the power saving mode can be reduced, the discharge resistance of the first and second power supply units can be reduced during operation (during printing) and standby when the supplied voltage increases. As a result, power is constantly wasted.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a discharge resistor for preventing an electric shock in an AC inlet (AC input unit) and to constantly consume power at the discharge resistor. It is an object of the present invention to provide a power supply device that can eliminate the problem.

  In order to solve the above-described problem, the power supply device of the present invention has an AC input unit, first and second lines connected to the AC input unit, and one electrode connected to the first line. And a line-across capacitor having the other electrode connected to the second line, a discharge resistor that can be connected to the first and second lines in parallel with the line-across capacitor by a control switch, and the AC input Fitting detecting means for detecting whether or not the AC connector is fitted in a predetermined fitting state, and the fitting detecting means detects a predetermined fitting state between the AC input portion and the AC connector. When detected, the discharge resistor is electrically disconnected from the first or second line by the control switch, while the fitting detection means connects the AC input unit and the AC connector. If the focus state is detected to be not a predetermined fitting state, it is characterized by being configured to use the discharge resistor is connected to the first and second lines by the control switch.

  The power supply device generates noise (mainly normal mode noise) generated between the first and second lines when energized with an AC power supply such as a commercial power supply through an AC connector. ). The discharging resistor is for discharging the residual charge of the line across capacitor.

  According to the above configuration, when the predetermined fitting state between the AC input unit and the AC connector is detected by the fitting detection means, the discharge resistor is electrically connected from the first or second line by the control switch. Is blocked. That is, when the AC connector is fitted to the AC input portion of the power supply device in a predetermined fitting state and the power supply device is energized (when the AC input portion and the AC connector are not in the predetermined fitting state, the line across The discharging resistor 5 (connected in parallel with the capacitor) is electrically disconnected from the first or second line.

  As a result, the steady power consumption (waste power) at the discharging resistor during energization can be made substantially zero, and power saving of the power supply device is realized.

  On the other hand, the fitting detection means detects that the fitting state between the AC input unit and the AC connector is not a predetermined fitting state (for example, the AC connector is disconnected from or disconnected from the AC input unit). In this case, the discharging resistor is connected to the first and second lines by the control switch. That is, when the AC connector and the AC input portion are not in a predetermined fitting state due to pulling out or loosening of the AC connector (when the AC input portion and the AC connector are in the predetermined fitting state, the first and second A discharging resistor (which is electrically disconnected from the line) is connected to the first line and the second line so as to be in parallel with the line across capacitor.

  As a result, the electric charge accumulated in the line across capacitor during energization is instantaneously discharged through the discharging resistor. That is, even when the AC connector is accidentally pulled out from the energized power supply device, each line potential in the AC input unit can be lowered to a safe voltage or less within a predetermined time, so that an electric shock in the AC input unit can be reduced. The danger can be avoided reliably.

  Further, in the power supply device, the fitting detection means is a mechanical detection structure supported by the AC input section so that the fitting detection means can be moved by inserting or pulling out an AC connector, and the control switch has the mechanical detection structure. It is preferable to be interlocked with the movement of the structure.

  According to the above configuration, the mechanical detection structure is moved by insertion or withdrawal of the AC connector, and the control switch is operated in conjunction with the movement of the mechanical detection structure. In other words, the fitting detection means can be configured simply by interlocking the control switch with the movement of the mechanical detection structure. As a result, the configuration of the power supply device can be simplified and the manufacturing cost can be reduced.

  Further, in the power supply device, the fitting detection means is an optical detection structure provided in an AC input unit so as to sense light from the AC connector in response to insertion or extraction of the AC connector, and the control It is preferable that the switch is interlocked with the sensing of light by the optical detection structure.

  According to the above configuration, the amount of light sensed by the optical detection structure from the AC connector changes due to insertion or withdrawal of the AC connector, and the control switch operates in conjunction with the change in the amount of light. In other words, the fitting detection means can be configured simply by interlocking the light sensing in the optical detection structure with the control switch. As a result, the configuration of the power supply device can be simplified and the manufacturing cost can be reduced.

  Moreover, the AC connector of the present invention is used for connection to the power supply device, and has a protruding portion for moving the mechanical detection structure. When the AC connector is connected to the power supply apparatus, the mechanical detection structure is moved by the protruding portion, and the control switch is interlocked with the movement. Thereby, the fitting state of the AC input part of the power supply device and the AC connector can be easily detected.

  The AC connector of the present invention is used for connection to the power supply device, and has a light emitting section that emits light to the optical detection structure. When the AC connector is connected to the power supply device, the optical detection structure receives the light from the light emitting unit, and the control switch is linked to the detection of the light. Thereby, the fitting state of the AC input part of the power supply device and the AC connector can be easily detected.

  Further, in order to solve the above problems, the power supply device of the present invention is based on an AC input section, a filter section, discharge means for discharging the filter section, and a fitting state of the connector in the AC input section. A discharge control means for controlling the discharge means, wherein the discharge control means brings the discharge means and the filter portion into a disconnected state when the AC input portion and the connector are in a predetermined fitting state, If the AC input unit and the connector are not in a predetermined fitting state, the discharging unit and the filter unit are connected to discharge the filter unit.

  According to the above configuration, when the AC input unit and the connector are in a predetermined fitting state, the discharge unit and the filter unit are electrically disconnected by the discharge control unit. As a result, it is possible to greatly suppress the power consumption in the discharging means during energization, and to realize power saving of the power supply device.

  On the other hand, when the AC input unit and the connector are not in a predetermined fitted state (for example, when the connector is disconnected from or is almost disconnected from the AC input unit), the discharge control unit electrically connects the discharge unit to the filter. Connected to. That is, when the connector is pulled out or loosened, the discharging means (which was cut off from the filter portion when the AC input portion and the connector are in a predetermined fitting state) is connected to the filter portion.

  Thereby, the electric charge which accumulated in the filter part (for example, X capacitor | condenser of a line filter) at the time of electricity supply is discharged by the discharge means. As a result, even when the connector is accidentally pulled out from the energized power supply device, the potential in the AC input section can be lowered to a safe potential or less, and the risk of electric shock or the like in the AC input section can be eliminated.

  As described above, according to the present invention, the steady power consumption at the discharging resistor during energization can be made almost zero, and the power saving of the power supply apparatus can be realized. Moreover, even when the AC connector is accidentally pulled out from the energized power supply device, each line potential in the AC input section can be lowered to a safe voltage or less within a predetermined time, resulting in a risk of electric shock or the like in the AC input section. Can be avoided.

  An embodiment of the present invention will be described below with reference to FIGS.

  FIG. 1A is a block diagram showing a configuration of a power supply device according to the present invention. As shown in FIG. 1A, the power supply device 17 includes an AC inlet 4 (AC input unit) having a fitting detection means 7 (discharge control means), a Live line (first line, hereinafter referred to as L line). ) 1, a neutral line (second line, hereinafter referred to as N line) 2, a ground line (hereinafter referred to as E line) 9, and a bridge diode 12. One end of each line (L line 1, N line 2, E line 9) is provided in the AC inlet 4 as an L terminal 8a, an N terminal 8b, and an E terminal 8c. The other end of the line 2 is connected to each input terminal of the bridge diode 12, and the E line 9 is grounded.

  Between the L terminal in the L line 1 and the input terminal of the bridge diode 12, a fuse 16 and a coil 11a are arranged in series from the L terminal side, and the N terminal in the N line 2 and the input terminal of the bridge diode 12 are connected. The coil 11b is arranged in series between the two. The coils 11a and 11b are wound around the same core. These coils 11a and 11b mainly correspond to common mode noise. Further, an electrolytic capacitor 13 for smoothing is disposed between the output terminals of the bridge diode 12, and AC supplied from an AC power source or the like connected via the AC inlet 4 is bridged through each line. Rectified by the diode 12 and charged to the electrolytic capacitor 13.

  Between the L line 1 and the N line 2, two X capacitors 3a and 3b (line across capacitors) for normal mode noise are connected in parallel. That is, one electrode of the X capacitor 3a is connected between the fuse 16 and the coil 11a in the L line 1, and the other electrode is connected between the N terminal 8b and the coil 11b in the N line 2. . One electrode of the X capacitor 3b is connected between the coil 11a and the bridge diode 12 (input terminal) in the L line 1, and the other electrode is connected between the coil 11b and the bridge diode 12 (input terminal). It is connected to the.

  Thereby, in the L line 1, the fuse 16 is arranged between the L terminal and one electrode (L line side electrode) of the X capacitor 3a, and the L line side electrode of the X capacitor 3a and one end of the coil 11a are connected to each other. The other end of the coil 11a, one electrode (L line side electrode) of the X capacitor 3b, and the L line side input terminal of the bridge diode 12 are connected. On the other hand, in the N line 2, the N terminal, the other electrode of the X capacitor 3a (N line side electrode), and one end of the coil 11b are connected, and the other end of the coil 11b and the X capacitor 3b The other electrode (N line side electrode) and the input terminal on the N line side of the bridge diode 12 are connected.

  Further, a Y capacitor 14 for common mode noise is disposed between the N line 2 and the E line 9. That is, one electrode (N line side electrode) of the Y capacitor 14 is connected between the coil 11b in the N line 2 and one electrode of the X capacitor 3b, and the other electrode (E line side electrode) is E. It is connected to line 9 (ground line).

  As described above, in the devices including the AC power supply circuit such as the power supply device 17, the X capacitors 3a and 3b, the Y capacitor 14 (for common mode noise), the coils 11a and 11b (common mode coils), etc. By configuring a line filter (filter unit) by combining the above, noise generated between the lines (L line 1, N line 2, E line 9) (between AC lines) can be removed or reduced.

  Here, between the L line 1 and the N line 2, a discharge resistor 5 (discharge means) is arranged in parallel with the X capacitors 3a and 3b, and a control switch 6 (discharge) is connected in series with the discharge resistor 5. Control means) is arranged. That is, one terminal of the discharging resistor 5 is connected between one electrode of the X capacitor 3 b in the L line 1 and one input terminal of the bridge diode 12 and the other terminal of the discharging resistor 5. Is connected to one terminal of the control switch 6, and the other terminal of the control switch 6 is connected between one electrode of the X capacitor 3b in the N line 2 and one input terminal of the bridge diode 12. Yes.

  Thereby, one terminal (L line side terminal) of the discharge resistor 5 is connected to the L line side electrode of the X capacitor 3b. Further, the other terminal (N line side terminal) of the discharging resistor 5 can be connected to the N line side electrode of the X capacitor 3 b and the N line side electrode of the Y capacitor 14 via the control switch 6.

  FIG. 1B is a block diagram showing the relationship between the power supply device 17 of FIG. 1A and the AC cable. As shown in FIG. 1B, an AC cable terminal corresponding to each terminal 8a, 8b, 8c of the AC inlet 4 in the power supply device 17 is provided on the connector portion (AC connector) 18 of the AC cable 15. 28a, 28b, and 28c are provided.

  When the terminals (8a, 8b, 8c) of the AC inlet 4 and the AC cable terminals (28a, 28b, 28c) in the power supply device 17 are fitted in a predetermined fitting state, this fitting state is determined. The fitting detection means 7 detects, and in conjunction with this, the control switch 6 (see FIG. 1A) is turned off. As a result, one terminal of the discharging resistor 5 is electrically disconnected from the N line 2. When the terminals (8a, 8b, 8c) of the AC inlet 4 and the AC cable terminals (28a, 28b, 28c) are not in the predetermined fitting state, the fitting detecting means 7 detects this, In conjunction with this, the control switch 6 (see FIG. 1A) is turned on. Thereby, one terminal of the discharging resistor 5 is connected to the L line 1 and the other terminal is connected to the N line 2.

  The control switch 6 is preferably a mechanical switch such as a limit switch, an electrical switch such as a relay switch, or an optical switch such as a photo interrupter.

  As described above, when the AC cable 15 and the AC inlet 4 are fitted in a predetermined fitting state and the power supply device 17 is energized (when not in the predetermined fitting state, they are connected in parallel with the X capacitors 3a and 3b. The discharging resistor 5 is electrically disconnected from the N line 2. That is, the wasted power in the discharging resistor 5 during energization is almost zero, and power saving in the power supply device 17 is possible.

  On the other hand, when the AC cable 15 and the AC inlet 4 are not in the predetermined fitting state, the discharging resistor 5 (which is electrically disconnected from the lines 1 and 2 in the predetermined fitting state) is connected to the X capacitor 3a. 3b in parallel with the L line 1 and the N line 2. As a result, the charges accumulated in the X capacitors 3 a and 3 b are instantaneously discharged through the discharge resistor 5. That is, even if the AC power supply (AC cable 15 or the like) is accidentally pulled out from the energized power supply device 17, the voltage of each terminal 8 (8a, 8b, 8c) of the AC inlet 4 is set to a safe voltage within a predetermined time. Since it can be reduced to the following, dangers such as electric shock can be reliably avoided.

  Next, the fitting detection means 7 and the AC inlet 4 will be described more specifically.

  2 and 3 are sectional views showing the relationship between the fitting state of the AC cable and the AC inlet and the mechanical detection structure (fitting detection means), and FIG. 4 shows the fitting state of the AC cable and the AC inlet. It is sectional drawing which shows the relationship with an optical detection structure (fitting detection means).

[Embodiment 1]
As shown in FIG. 2, the AC inlet 4 includes a housing shaped to cover a space portion into which the connector portion 18 of the AC cable 15 is inserted, and the housing is configured to insert the AC cable 15. A back wall 4a perpendicular to the (fitting) direction and a side wall 4b along the insertion direction are provided. In the space portion, the terminals 8 (8a, 8b, 8c) of the AC inlet 4 protrude from the back wall 4a along the insertion (fitting) direction of the AC cable 15.

  The mechanical detection structure 7a is supported on the side wall 4b by an elastic force that can move at the fulcrum P. This mechanical detection structure 7a is a portion 7a ′ that protrudes from a portion (the space portion) into which the connector portion 18 of the AC cable 15 is inserted in a state where the AC cable 15 is not fitted (inserted) into the AC inlet 4. When the AC cable 15 is inserted into the AC inlet 4 to a predetermined depth (fitted in a predetermined fitting state), the protruding portion 7a ′ becomes a connector portion 18 in the AC cable 15. The mechanical detection structure 7a is rotated about the fulcrum P as it is pushed by the (cable housing 18 '). Then, the control switch 6 is turned off in conjunction with the rotational movement of the mechanical detection structure 7a (see FIG. 1B). When the AC cable 15 is pulled out to a predetermined position in the AC inlet 4 (the AC cable 15 and the AC inlet 4 are not in a predetermined fitted state), the mechanical detection structure 7a is centered on the fulcrum P by the elastic force. To return to the state (the original state) having the portion 7a ′ protruding into the space. Then, the control switch 6 is turned on in conjunction with the reverse rotation of the mechanical detection structure 7a (see FIG. 1B). Here, it is preferable that the control switch 6 is composed of a mechanical switch such as a limit switch or an electrical switch such as a relay switch.

  By adjusting the position of the supporting fulcrum P of the mechanical detection structure 7a and the size of the portion 7a 'protruding to the space, the insertion or extraction position of the AC cable 15 (the fitting of the AC cable 15 and the AC inlet 4 is performed). And the rotation state of the mechanical detection structure 7a (that is, the ON / OFF state of the control switch 6) can be adjusted.

  As shown in FIG. 2, the AC cable 15 includes an AC cable terminal 28 (28 a, 28 b, 28 c) along the insertion direction into the AC inlet 4 at the connector portion 18 that is an end portion thereof. The AC cable terminal 28 is structured to be divided into two portions 28x and 28y facing each other from the base end portion, and the AC inlet 4 of the AC inlet 4 is interposed between the two portions 28x and 28y separated from the base end portion. Each terminal 8 (8a, 8b, 8c) is configured to be inserted.

[Embodiment 2]
Further, the AC inlet 4 and the fitting detection means 7 and the AC cable 15 may be configured as shown in FIG.

  That is, the AC inlet 4 includes a housing shaped to cover the space portion into which the connector portion 18 of the AC cable 15 is inserted, and the housing is in the insertion (fitting) direction of the AC cable 15. A vertical back wall 4a and a side wall 4b along the insertion direction are provided. In the space portion, each terminal 8 (8a, 8b, 8c) of the AC inlet 4 protrudes from the back wall 4a along the insertion direction of the AC cable 15.

  The back wall 4a supports the mechanical detection structure 7b with an elastic force that can move. This mechanical detection structure 7b is a portion 7b ′ protruding from a portion (the space portion) where the connector portion 18 of the AC cable 15 is inserted in a state where the AC cable 15 is not fitted (inserted) into the AC inlet 4. When the AC cable 15 is inserted into the AC inlet 4 to a predetermined depth (the AC cable 15 and the AC inlet 4 are fitted in a predetermined fitting state), the protruding portion 7b 'Is pushed by the connector portion 18 (cable housing 18') of the AC cable 15, and the mechanical detection structure 7b moves accordingly. Then, the control switch 6 is turned off in conjunction with the movement of the mechanical detection structure 7b (see FIG. 1B). When the AC cable 15 is pulled out to a predetermined position in the AC inlet 4 (the AC cable 15 and the AC inlet 4 are not in a predetermined fitting state), the mechanical detection structure 7b is moved into the space portion by the elastic force. The original state having the protruding portion 7b ′ is restored. Then, the control switch 6 is turned on in conjunction with the movement of the mechanical detection structure 7b (see FIG. 1B). Here, it is preferable that the control switch 6 is composed of a mechanical switch such as a limit switch or an electrical switch such as a relay switch.

  By adjusting the size (width) of the portion 7b 'that protrudes into the space, the AC cable 15 is inserted or pulled out (fitted state between the AC cable 15 and the AC inlet 4), and the mechanical detection structure. The relationship with the movement state of 7b (that is, the ON / OFF state of the control switch 6) can be adjusted.

  Here, as shown in FIG. 3, the AC cable 15 is connected to an AC cable terminal 28 (28a, 28b, 28c) along the direction of insertion into the AC inlet 4 at the connector portion 18 serving as an end thereof. And a cable housing 18 'that covers. The AC cable terminal 28 has a structure divided into two portions 28x and 28y facing each other from the base end portion, and the AC inlet 4 of the AC inlet 4 is between the two portions 28x and 28y separated from the base end portion. Each terminal 8 (8a, 8b, 8c) is configured to be inserted. Further, a projection 23 for pushing out the mechanical detection structure 7b at the time of insertion into the AC inlet 4 is formed in the cable housing 18 'corresponding to the tip of the connector portion 18. By adjusting the size of the protrusion 23 (width in the insertion direction), the AC cable 15 is inserted or pulled out (fitted state between the AC cable 15 and the AC inlet 4) and the mechanical detection structure 7b. It is possible to adjust the relationship with the movement state (that is, the ON / OFF state of the control switch 6).

[Embodiment 3]
Further, the AC inlet 4, the fitting detection means 7, and the AC cable 15 may have a configuration as shown in FIG.

  That is, the AC inlet 4 includes a housing shaped to cover the space portion into which the connector portion 18 of the AC cable 15 is inserted, and the housing is in the insertion (fitting) direction of the AC cable 15. A vertical back wall 4a and a side wall 4b along the insertion direction are provided. In the space portion, each terminal 8 (8a, 8b, 8c) of the AC inlet 4 protrudes from the back wall 4a along the insertion direction of the AC cable 15.

  The back wall 4a is provided with an optical detection structure 7c, and the AC cable 15 is inserted into the AC inlet 4 to a predetermined depth (when the AC cable 15 and the AC inlet 4 are in a predetermined fitting state). And the light from a light emitting element (described later) 24 provided in the connector portion 18 (cable housing 18 ′) of the AC cable 15 is detected. Then, the control switch 6 is turned off in conjunction with the light detection by the optical detection structure 7c (see FIG. 1B). When the AC cable 15 is pulled out to a predetermined position in the AC inlet 4 (the AC cable 15 and the AC inlet 4 are not in a predetermined fitting state), the optical detection structure 7c causes the light from the light emitting element 24 to pass. It will not be detected. Then, the control switch 6 is turned on in conjunction with the non-detection of light in the optical detection structure 7c (see FIG. 1B). Here, the control switch 6 is preferably composed of an optical switch such as a photo interrupter.

  By adjusting the relationship between the amount of light detected by the optical detection structure 7 c and the ON / OFF state of the control switch 6, the AC cable 15 insertion or extraction position (fitting between the AC cable 15 and the AC inlet 4 can be performed. State) and the ON / OFF state of the control switch 6 can be adjusted.

  Here, as shown in FIG. 4, the AC cable 15 has an AC cable terminal 28 (28 a, 28 b, 28 c) along the direction of insertion into the AC inlet 4 and this at the connector 18 that is the end of the AC cable 15. And a cable housing 18 'that covers. The AC cable terminal 28 has a structure divided into two portions 28x and 28y facing each other from the base end portion, and the AC inlet 4 of the AC inlet 4 is between the two portions 28x and 28y separated from the base end portion. Each terminal 8 (8a, 8b, 8c) is configured to be inserted.

  Further, the cable housing 18 ′ corresponding to the tip of the connector portion 18 is provided with a light emitting element 24 that applies light to the optical detection structure 7 c of the AC inlet 4 when inserted into the AC inlet 4. The light emitting element 24 emits light when each terminal 28 (28a, 28b, 28c) of the AC cable 15 and each terminal 8 (8a, 8b, 8c) of the AC inlet 4 are fitted (connected). It is preferable. The relationship between the insertion or extraction position of the AC cable 15 (fitted state between the AC cable 15 and the AC inlet 4) and the ON / OFF state of the control switch 6 by adjusting the light emission amount of the light emitting element 24. Can be adjusted.

  As described above, as shown in FIG. 2, when the cable housing 18 ′ is inserted into the AC inlet 4 (AC inlet housing), the mechanical detection structure 7 a is pushed out of the housing of the AC inlet 4 around the fulcrum P. . At this time, by interlocking so that the control switch 6 (see FIGS. 1A and 1B) is turned OFF, it can be detected that the AC cable 15 is correctly inserted into the AC inlet 4, and at the same time, the discharge resistance 5 (see FIGS. 1A and 1B) can be electrically cut off from the lines 1 and 2, so that the power loss due to the discharging resistor 5 can be made zero.

  Further, when the cable housing 18 ′ is disconnected from the AC inlet 4, the mechanical detection structure 7 a is pulled back into the housing. In conjunction with this, the control switch 6 is turned on, and the discharging resistor 5 arranged in series with the control switch 6 is connected to the lines 1 and 2. As a result, the residual voltage of the X capacitors 3a and 3b is instantaneously discharged, and the requirement “below the safe voltage within the specified time” required by the “plug discharge test” can be satisfied.

  As described above, as shown in FIG. 3, when the cable housing 18 ′ is inserted into the AC inlet 4 (AC inlet housing), the protruding portion 23 arranged in the cable housing 18 ′ is arranged in the housing of the AC inlet 4. The mechanical detection structure 7b is pushed out. At this time, by interlocking so that the control switch 6 is turned off, it can be detected that the AC cable 15 is correctly inserted into the AC inlet 4, and at the same time, the discharging resistor 5 is electrically connected to the lines 1 and 2. Since it can be made into a cutoff state, it becomes possible to make the power loss by the discharge resistor 5 zero.

  Further, when the cable housing 18 ′ is disconnected from the AC inlet 4, the protruding portion 23 disposed in the cable housing 18 ′ does not press the mechanical detection structure 7 b disposed in the AC inlet 4. It is pulled back inside the AC inlet 4. In conjunction with this, the control switch 6 is turned on, and the discharging resistor 5 arranged in series with the control switch 6 is connected to the lines 1 and 2. As a result, the residual voltage of the X capacitors 3a and 3b is instantaneously discharged, and the requirement “below the safe voltage within the specified time” required by the “plug discharge test” can be satisfied.

  As described above, as shown in FIG. 4, when the cable housing 18 ′ is inserted into the AC inlet 4 (AC inlet housing), the light emitting element 24 disposed in the cable housing 18 ′ emits light, and this is transmitted to the AC inlet 4. The optical detection structure 7c disposed in the housing receives light. By interlocking the light reception of the optical detection structure 7c and the switching of the control switch 6 to the OFF state, it can be detected that the AC cable 15 is correctly inserted into the AC inlet 4, and at the same time, the discharge resistor 5 is Since the lines 1 and 2 can be electrically cut off, the power loss due to the discharge resistor 5 can be made zero.

  Further, when the cable housing 18 ′ is detached from the housing of the AC inlet 4, the light emitting element 24 disposed in the cable housing 18 ′ is turned off, and the optical detection structure 7c disposed in the AC inlet 4 does not receive light. . In conjunction with this, the control switch 6 is turned on, and the discharging resistor 5 arranged in series with the control switch 6 is connected to the lines 1 and 2. As a result, the residual voltage of the X capacitors 3a and 3b is instantaneously discharged, and the requirement “below the safe voltage within the specified time” required by the “plug discharge test” can be satisfied.

  The configuration of the present invention includes a single-layer two-wire or single-layer three-wire AC input section, a capacitor disposed between the two lines connected to the AC input section for the purpose of reducing noise, and an AC input voltage. A resistor arranged in parallel with the capacitor for discharging the residual voltage of the capacitor at the time of shutoff, a detection means for detecting whether the AC input unit is correctly fitted, and ON / OFF in conjunction with the detection means A switch unit that performs an OFF operation, and when the AC cable is correctly inserted into the AC input unit, the resistor is electrically disconnected by the switch unit, and when the AC input voltage is interrupted, the resistor is connected It can also be expressed as a power saving circuit characterized by this.

  In the power supply device 17 in the above embodiments (1-3), the X capacitor 3a is provided on the L / N terminals 8a and 8b side of the coils 11a and 11b, and the X capacitor 3b is provided on the bridge diode 12 side of the coils 11a and 11b. However, the present invention is not limited to this (see FIG. 1A). For example, as a modification of the above embodiment, the X capacitor 3b may be omitted and only the X capacitor 3a may be provided, or the X capacitor 3a may be omitted and only the X capacitor 3b may be provided. Is possible.

  The power supply apparatus according to the present invention includes an AC input unit, a filter unit, a discharge unit that discharges the filter unit, and a discharge control that controls the discharge unit based on a fitting state of the connector in the AC input unit. And the discharge control means disconnects the discharge means and the filter portion from each other when the AC input portion and the connector are in a predetermined fitting state, while the AC input portion and the connector are in a predetermined state. If it is not in the fitting state, it can be expressed that the discharge means and the filter portion are connected to cause the filter portion to discharge. Here, the filter unit is, for example, the X capacitors 3a and 3b in the above embodiment. The discharge means is, for example, the discharge resistor 5 in the above embodiment. The discharge control means is, for example, the control switch 6 and the fitting detection means 7 (the mechanical detection structure 7a, the mechanical detection structure 7b, or the optical detection structure 7c) in the above embodiment.

  Further, the present invention is not limited to the above-described embodiments, and various modifications are possible within the scope shown in the claims, and different embodiments or means are appropriately combined with technical means disclosed respectively. The obtained embodiment or means are also included in the technical scope of the present invention.

  In the power supply device according to the present invention, when the AC inlet and the AC cable are fitted, the discharging resistor connected in parallel to the line across capacitor is electrically cut off, and when not fitted, the discharge is performed. By connecting the resistors for use, both power saving and safety can be realized. Therefore, the present invention can be widely applied to electric products (for example, a copy machine, a television, and the like) equipped with a power supply device including a line across capacitor (X capacitor).

(A) is a block diagram which shows the structure of the power supply device of this invention, (b) is a block diagram which shows the relationship between the power supply device of (a), and an AC cable. It is sectional drawing which shows the relationship between the fitting state of an AC cable and AC inlet based on Embodiment 1, and a mechanical detection structure. It is sectional drawing which shows the relationship between the fitting state of an AC cable and AC inlet and mechanical detection structure based on Embodiment 2. FIG. It is sectional drawing which shows the relationship between the fitting state of an AC cable and AC inlet based on Embodiment 3, and an optical detection structure. It is a circuit diagram of the conventional power supply device. It is a circuit diagram of the conventional power supply device.

Explanation of symbols

1 L line (first line)
2 N line (second line)
4 AC inlet (AC input section)
5 Discharge resistance (discharge means)
6 Control switch (discharge control means)
7a, 7b Mechanical detection structure (fitting detection means, discharge control means)
7c Optical detection structure (fitting detection means, discharge control means)
8a to 8c AC inlet terminals 3a and 3b X capacitors (line across capacitors)
11a / 11b Coil 12 Bridge diode 13 Electrolytic capacitor 15 AC cable 17 Power supply 18 Connector (AC connector)
23 Protruding part 24 Light emitting element (light emitting part)
28a-28c AC cable terminal

Claims (6)

AC input section, first and second lines connected to the AC input section, and a line across one electrode connected to the first line and the other electrode connected to the second line A capacitor, a control switch, a discharging resistor that can be connected to the first and second lines in parallel with the line-across capacitor by the control switch, and a predetermined fitting state of the AC connector at the AC input section And a fitting detection means for detecting whether or not it is fitted with,
When the predetermined detection state between the AC input portion and the AC connector is detected by the fitting detection means, the discharge resistor is electrically disconnected from the first or second line by the control switch. When the fitting detection means detects that the fitting state between the AC input portion and the AC connector is not a predetermined fitting state, the discharging resistor is set to the first and second lines by the control switch. A power supply device configured to be connected.   The fitting detection means is a mechanical detection structure supported by the AC input section so as to be movable by insertion or extraction of an AC connector, and the control switch is interlocked with the movement of the mechanical detection structure. The power supply device according to claim 1, wherein the power supply device is provided.   The fitting detection means is an optical detection structure provided in the AC input unit so as to sense light from the AC connector in response to insertion or extraction of the AC connector, and the control switch is provided with the optical detection structure. The power supply apparatus according to claim 1, wherein the power supply apparatus is interlocked with sensing of light at a light source.   An AC connector that is used for connection to the power supply device according to claim 2 and has a fitting detection protrusion.   An AC connector, which is used for connection to the power supply device according to claim 3 and has a light-emitting part for fitting detection. An AC input unit, a filter unit, a discharge unit for discharging the filter unit, and a discharge control unit for controlling the discharge unit based on a fitting state of the connector in the AC input unit,
When the AC input unit and the connector are in a predetermined fitting state, the discharge control unit disconnects the discharging unit and the filter unit, while the AC input unit and the connector are in a predetermined fitting state. Otherwise, the discharge means and the filter unit are connected to cause the filter unit to discharge.

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