JP5079053B2 - Power supply connector and power supply plug - Google Patents

Description

  The present invention relates to a power supply connector and a power supply plug.

  In order to prevent arc discharge that occurs when the power supply plug is inserted into the power supply connector, an outlet that starts power supply after the male terminal of the plug is inserted has been proposed (for example, see Patent Document 1). This outlet includes a pushbutton switch that relays power to a power supply female terminal, and the pushbutton switch has a male terminal of a plug inserted into a control female terminal used for power supply control. And pushed down by the inserted male terminal.

JP 2010-56055 A

  Here, in the technique disclosed in Patent Literature 1, since an object inserted through the female terminal starts to supply power to the female terminal for power supply as long as the push button switch is pushed down, power supply to the female terminal for power supply is started. There was a problem that sufficient safety could not be secured.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a power supply connector (outlet) and a power supply plug that can ensure safety at the time of insertion of the plug as compared with the conventional case.

In order to achieve the above object, a power feeding connector according to the first aspect of the present invention includes:
A female terminal into which the male terminal of the power supply plug is inserted;
A coupling portion electromagnetically coupled to the power supply plug;
When the coupling portion is coupled to the power supply plug, the female terminal electrically connected to the DC power supply for supplying power to the female terminal, and is coupled with the power supply plug and the coupling portion are eliminated A semiconductor switch for electrically disconnecting the female terminal and the DC power source supplying power to the female terminal;
When detecting the electromagnetic coupling between the feeding plug and the coupling portion, Bei example and a driving circuit for driving the semiconductor switches so as to electrically connect a line between the female terminal power supply,
The coupling portion is electromagnetically coupled to the power supply plug after the male terminal of the power supply plug is inserted into the female terminal.
It is characterized by that.

In order to achieve the above object, a power supply plug according to a second aspect of the present invention includes:
A male terminal inserted into the female terminal of the power supply connector;
A slide member that slides in the insertion direction of the male terminal;
A coupling portion for non-contact coupling with the power feeding connector at a position moved by the slide member;
It is characterized by that.

  According to the power supply connector and the power supply plug according to the present invention, safety at the time of insertion of the plug can be ensured as compared with the related art.

FIG. 1A is a diagram illustrating an example of a side cross section of a power supply connector and a side cross section of a power supply plug according to the first embodiment of the present invention before electromagnetic coupling. FIG.1 (b) is the elements on larger scale of the area | region A shown to Fig.1 (a). It is a figure showing an example of the circuit structure of the connector for electric power feeding. FIG. 3A is a diagram illustrating an example of signals communicated between the power supply connector and the power supply plug before and after the start of power supply. FIG. 3B is a diagram illustrating an example of signals communicated between the power supply connector and the power supply plug before and after the end of electromagnetic coupling. FIG. 4A is a front view illustrating an example of a power feeding connector according to the first embodiment. FIG. 4B is a front view illustrating an example of a power feeding connector according to the second modification of the first embodiment. FIG. 4C is a front view illustrating an example of a power feeding connector according to the third modification of the second embodiment. FIG. 4D is a perspective view illustrating an example of a power supply plug according to the first embodiment. FIG. 4E is a perspective view illustrating an example of a main body portion included in the power supply plug according to the first embodiment. It is a figure showing an example of the circuit structure of the plug for electric power feeding. It is a perspective view showing an example of a resin module. FIG. 7A is a diagram illustrating an example of a side cross section of the power supply connector and a side cross section of the power supply plug according to the first embodiment at the time of electromagnetic coupling. FIG.7 (b) is the elements on larger scale of the area | region B shown to Fig.7 (a). FIG. 8A is a diagram illustrating an example of a side cross section of a power supply connector and a side cross section of a power supply plug according to the second embodiment before electromagnetic coupling. FIG. 8B is a diagram illustrating an example of a side cross section of the power feeding connector and a side cross section of the power feeding plug according to the second embodiment at the time of electromagnetic coupling. FIG. 9A is a front view illustrating an example of a power feeding connector according to the second embodiment. FIG. 9B is a front view illustrating an example of the power feeding connector according to the first modification of the first embodiment. FIG. 9C is a front view illustrating an example of a power feeding connector according to the second modification of the second embodiment. FIG. 9D is a front view illustrating an example of a power feeding connector according to a combination of Modification 1 and Modification 2 of the second embodiment. FIG. 9E is a perspective view illustrating an example of a power supply plug according to the second embodiment.

<First Embodiment>
Hereinafter, a power supply connector and a power supply plug according to a first embodiment of the present invention will be described with reference to the accompanying drawings.

  When the power supply connector 100 according to the embodiment of the present invention shown in FIG. 1A is non-contact coupled to the power supply plug 200 after the power supply plug 200 according to the embodiment of the present invention is inserted, the power supply plug 200 The power supply to 200 is started.

  As shown in FIG. 2, the power supply connector 100 includes power supply female terminals 111 and 112, a ground female terminal 113, a relay power supply 120, relay devices 131 and 132, a semiconductor switch 140, an oscillation circuit 151, a first circuit. A drive circuit 152, a second drive circuit 153, an ON / OFF control circuit 154, and a coil 190 are provided.

  As shown in FIG. 1A, the male terminal 211 of the power supply plug 200 is inserted into the female terminal 111. Further, as shown in FIG. 2, the female terminal 111 is connected to a positive terminal of a DC (Direct Current) power supply 10 via a relay device 131. Similarly, the male terminal 212 of the power supply plug 200 to be described later is inserted into the female terminal 112 and connected to the negative terminal of the DC power supply 10 that is a DC power supply source via the relay device 132. Therefore, when the relay devices 131 and 132 simultaneously close (that is, drive) the main electric circuit MR that returns from the DC power supply 10 to the relay devices 131 and 132 and the power supply plug through the power supply plug, the female terminal 111 is connected. And 112 supply power to the power supply plug 200. The female terminal 113 is inserted with a male terminal 213 of a power supply plug 200 described later, and provides a reference potential to the power supply plug 200.

  The relay power supply 120 includes a power supply circuit such as a DC-DC (Direct Current-Direct Current) converter, and generates a power supply for driving the relay devices 131 and 132 and the oscillation circuit 151. The first drive circuit 152, the second drive circuit 153, and the ON / OFF control circuit 154 may also use the relay power supply 120 as a power supply.

  When the semiconductor switch 140 is driven by the second drive circuit, the relay circuit RR that returns from the relay power supply 120 to the relay power supply 120 through the relay devices 131 and 132 is closed. Open the electric circuit RR. The oscillation circuit 151 oscillates at an arbitrary period over a predetermined period at intervals specified by the ON / OFF control circuit 154.

  The first drive circuit 152 drives the coil 190 based on the oscillation of the oscillation circuit 151. The driven coil 190 is electromagnetically coupled to the power supply plug 200 by transmitting a predetermined signal to the power supply plug 200 of FIG. In addition, the coil 190 receives a request signal for power supply from the power supply plug during a period in which the coil 190 is not driven by the first drive circuit 152 (hereinafter referred to as an oscillation period). According to this configuration, the power supply connector 100 can perform both power transmission by electromagnetic coupling to the power supply plug 200 and signal communication with the power supply plug 200.

  The second drive circuit 153 is a receiving circuit that acquires the signal received by the coil 190 during the oscillation period of the oscillation circuit 151 based on the transmission / reception switching signal output from the ON / OFF control circuit 154. The transmission / reception switching signal is a signal indicating whether or not the oscillation circuit 151 controlled by the ON / OFF control circuit 154 is oscillating (that is, during signal transmission).

  Further, as shown in FIG. 3A, the second drive circuit 153 is predetermined at a predetermined cycle in a reception state where a request signal is received (that is, a state where the power supply plug 200 is not detected by receiving the request signal). When the request signal is continuously acquired a number of times (four times in FIG. 3A), it is determined that the non-contact coupling with the power supply plug 200 is started, and the semiconductor switch 140 in FIG. 2 is driven. When the semiconductor switch 140 is driven, the relay electric circuit RR is closed, so that the relay devices 131 and 132 close the main electric circuit MR. Therefore, since the power supply from the DC power supply 10 is relayed by the relay devices 131 and 132 in the female terminals 111 and 112, the state of the power supply connector 100 is changed to a power supply state in which power supply is performed.

  According to these configurations, when the power supply connector 100 is coupled to the power supply plug 200 in a non-contact manner, power supply to the female terminals 111 and 112 is started. For this reason, for example, even if an object other than the male terminals 211 to 213 of the power supply plug 200 is inserted into any of the female terminals 111 to 113, the power supply connector 100 is not connected to the power supply plug 200 in a non-contact manner. Since power supply is not started, safety can be ensured more than in the past.

  In addition, according to these configurations, the power supply connector 100 is electromagnetically coupled to the power supply plug 200, so that power is supplied to the power supply plug 200 before supplying power from the female terminals 111 and 112 to the power supply plug 200. Can supply.

  Furthermore, according to these configurations, the power supply connector 100 starts power supply upon receiving a request signal from the combined power supply plug 200. For this reason, for example, even if there is an object that happens to be coupled to the power feeding connector 100, the power feeding connector 100 does not start power feeding unless a request signal is received. Therefore, the power feeding connector 100 can prevent malfunction.

  In addition, according to these configurations, for example, an interface for detecting insertion and removal of the power supply plug 200 such as a control terminal is unnecessary, and thus the number of terminals included in the power supply connector 100 and the power supply plug 200 is controlled. The number of terminals can be reduced. For this reason, since the distance between terminals can be widened, it is difficult for dust to collect in the connection portions of the female terminals 111 to 113 and the male terminals 211 to 213.

  Further, the second drive circuit 153 of FIG. 2 outputs a receiving signal indicating that the request signal is being received to the ON / OFF control circuit 154. When the ON / OFF control circuit 154 acquires the receiving signal, the ON / OFF control circuit 154 changes the oscillation interval Ab of the oscillation circuit 151 to Af shorter than the oscillation interval Ab as shown in FIG. For example, when the response of the power supply plug 200 is interrupted by the removal of the power supply plug 200, the response interruption is detected at an early stage.

  On the contrary, as shown in FIG. 3B, the second drive circuit 153 supplies power unless it acquires the request signal continuously for a predetermined number of times (four times in FIG. 3B) in the reception state. It is determined that the non-contact coupling with the plug 200 has been completed, and the driving of the semiconductor switch 140 in FIG. 2 is stopped (that is, stopped). When the driving of the semiconductor switch 140 is stopped, the relay electric circuit RR is opened, so that the relay devices 131 and 132 open the main electric circuit MR. Therefore, since the female terminals 111 and 112 are interrupted by the relay devices 131 and 132 from the power supply from the DC power supply 10, the state of the power supply connector 100 is returned to the reception state.

  Further, the second drive circuit 153 in FIG. 2 ends the output of the receiving signal to the ON / OFF control circuit 154. Therefore, the ON / OFF control circuit 154 changes the oscillation interval Af of the oscillation circuit 151 to Ab longer than the oscillation interval Af, as shown in FIG. This is to reduce the power consumed by the power supply connector 100.

  The ON / OFF control circuit 154 controls the oscillation of the oscillation circuit 151 as described above based on the signal acquired from the second drive circuit 153. As shown in FIG. 1B, the coil 190 is stored in a storage space 163 formed inside the power supply connector 100 with the central axis of the coil 190 facing the front direction of the power supply connector 100.

  As shown in FIG. 4A, openings 164 and 170 to 173 are formed on the front surface of the power supply connector 100. The openings 164 and 170 will be described later. Openings 171 to 173 are openings that respectively communicate with the female terminals 111 to 113, and the male terminals 211 to 213 of the power supply plug 200 are respectively inserted therethrough.

  The circuit configuration of the power supply plug 200 includes male terminals 211 to 213, a rectifying element 251, a regulator 252, an ON / OFF control circuit 253, an oscillation circuit 254, a drive circuit 255, and a coil 290, as shown in FIG.

  As shown in FIG. 1A, the male terminal 211 is inserted into the female terminal 111 that is a plus terminal of the power feeding connector 200. The male terminal 212 and the male terminal 213 are inserted into the female terminal 112 that is a minus terminal and the female terminal 113 that is a ground terminal, respectively, of the power feeding connector 200. The male terminal 211 to the male terminal 213 are respectively connected to the electronic device through a conducting wire in the electric cord.

  The rectifying element 251 generates a current generated by electromagnetic coupling between the coil 290 and the coil 190 of the power feeding connector 100 among the current flowing through the electric circuit connecting the drive circuit 255 and the coil 290, and the regulator 252 and the ON / OFF. Flow to control circuit 253.

  The regulator 252 forms a constant voltage circuit that charges a capacitor (not shown) supplied with power supplied via the rectifying element 251, and supplies power to the oscillation circuit 254. Note that the constant voltage circuit may also supply power to the ON / OFF control circuit 253 and the drive circuit 255. The power supply plug 200 further includes a small power source such as a rechargeable battery or a battery, and the power source supplies power to the oscillation circuit 254, the ON / OFF control circuit 253, and the drive circuit 255. May be.

  The ON / OFF control circuit 253 acquires the charge level of the capacitor and determines whether or not the acquired charge level has reached a predetermined value. When the ON / OFF control circuit 253 determines that the charge level has reached a predetermined value, it determines that the power supply connector 100 is electromagnetically coupled. When the ON / OFF control circuit 253 determines that the electromagnetic coupling is performed, the oscillation circuit is configured to oscillate at a predetermined frequency with a predetermined period Af over a predetermined period with reference to a timing at which a signal is received from the power supply connector 100. 254 is controlled. Conversely, if the ON / OFF control circuit 253 determines that the acquired charge level has fallen below a predetermined value, it determines that electromagnetic coupling has ended, and controls the oscillation circuit 254 to end oscillation.

  The drive circuit 255 drives the coil 290 based on the oscillation of the oscillation circuit 254. The driven coil 290 transmits a request signal to the power feeding connector 100.

  According to these configurations, even if the power supply plug 200 does not store electricity in advance, or before the power storage amount of the power supply plug 200 is supplied at least from the female terminals 211 to 213, the power supply connector 100 is electromagnetically coupled. The request signal can be transmitted using the supplied power. In addition, according to these configurations, the power supply plug 200 starts transmission of a power supply signal using electric power supplied by electromagnetic coupling with the power supply connector 100, so that the power supply plug 200 is not connected to the power supply connector 100. It is possible to reduce power consumption of the power supply plug 200 when the contact coupling is not performed.

Next, the external configuration of the power supply plug 200 will be described.
As shown in FIG. 4D, the power supply plug 200 includes a main body 260 having the circuit of FIG. 5 and male terminals 211 to 213, and a slide cover 270 that covers the upper surface 260t and both side surfaces 260s of the main body 260. Further prepare.

  As shown in FIG. 4E, a guide hole 261 and a convex portion 262 are formed on the upper surface of the main body portion 260, and the male terminals 211 to 213 protrude from the front surface, and an opening portion 264 is formed on the front surface.

  The rib 271 of the slide cover 270 shown in FIG. 1B is inserted into the guide hole 261, and the guide cover 261 guides the slide cover 270 to slide in the front-rear direction of the power supply plug 200. That is, the width of the guide hole 261 in the front-rear direction is longer than the width of the rib 271 in the front-rear direction. Further, the width in the left-right direction of the guide hole 261 is substantially the same as the width of the rib 271. Therefore, the rib 271 of the slide cover 270 is slidably fitted into the guide hole 261.

  Here, as shown in FIG. 1B, a storage space 263 for storing the coil 290 is formed inside the main body 260. The length (that is, the thickness) from the ceiling of the storage space 263 to the upper surface 260t of the main body 260 is shorter than the length of the rib 271 in the vertical direction. Therefore, the rib 271 of the slide cover 270 is inserted through the guide hole 261 and protrudes from the upper surface of the storage space 263.

  In the storage space 263, a resin module 280 containing a coil is stored. The resin module 280 includes a plate-shaped main body 281, a hook 282, and a support shaft 283 as shown in FIG. 6.

  The main body 281 of the resin module 280 has a support shaft 283 formed below the main body 281. As shown in FIG. 1B, the support shaft 283 is inserted into a bearing 289 formed in the main body 260 of the power supply plug 200, and supports the main body 281 and the hook 282 in a swingable manner. As shown in FIG. 6, the support shaft 283 has one end locked to the main body 281 and the other end locked to a front wall 269 (see FIG. 1B) that defines the storage space 263. Is installed.

  The torsion spring 284 presses the resin module 280 with a restoring force, and pushes the resin module 280 back to the position as shown in FIG. In the position shown in FIG. 1B, the resin module 280 starts from a substantially upright state (hereinafter referred to as an upright state) with the front direction of the power supply plug 200 as the front side (hereinafter referred to as an upright state). In this state, it is tilted to the rear of the power supply plug 200 (hereinafter referred to as a rearward state). Here, since the resin module 280 incorporates the coil 290 so that the center axis of the coil 290 faces the front of the resin module 280 in the upright state, the center axis of the coil 290 is the power plug 200 in the rearward state. It deviates diagonally upward from the front direction. In addition, since the central axis of the coil 190 of the power supply connector 100 faces the front direction of the power supply connector 100 (that is, the back surface direction of the power supply plug 200), the coil 190 of the power supply connector 100 and the power supply plug The 200 coils 290 cannot be sufficiently electromagnetically coupled.

  Next, for example, when the user picks the slide cover 270 and performs an insertion operation of inserting the power supply plug 200 into the power supply connector 100, first, the male terminals 211 to 213 of the power supply plug 200 are connected to the female connector 100. Inserted into terminals 111 to 113. Next, when the insertion operation is continued, the slide cover 270 slides relatively in the front direction with respect to the main body 260 by the frictional resistance between the female terminals 111 to 113 and the male terminals 211 to 213. As shown in FIG. 7A, the tip of the slide cover 270 that has slid enters the opening 170 provided on the front surface of the power supply connector 100. This is because the position and shape of the opening 170 with respect to the female terminals 111 and 112 substantially coincide with the position and shape of the slide cover 270 with respect to the male terminals 211 and 212. For this reason, the slide cover 270 covers not only the main body portion 260 but also the male terminals 211 to 213.

  According to these configurations, the slide cover 270 covers the male terminals 211 to 213 when slid in the insertion direction of the male terminals 211 to 213, so that an electric shock or the like through the male terminals 211 to 213 can be prevented. Therefore, the power supply plug 200 can improve the safety at the time of insertion or removal. In addition, dust accumulation on the male terminals 211 to 213 protruding from the main body 260 can be prevented, so that the occurrence of tracking is prevented and the safety when using the power supply plug 200 is improved.

  When the slide cover 270 slides in the front direction, the rib 271 of the slide cover 270 protruding from the ceiling of the storage space 263 moves the resin module 280 to the position shown in FIGS. 7A and 7B. Since the moved resin module 280 is in an upright state, the central axis of the coil 290 of the resin module 280 faces the front direction of the power supply plug 200. That is, since the coil 190 and the coil 290 are facing each other, electromagnetic coupling can be started. Thereafter, the power supply connector 100 detects the start of electromagnetic coupling and starts power supply to the power supply plug 200.

  According to these configurations, when the male terminals 211 to 213 of the power supply plug 200 are inserted into the power supply connector 100, the slide cover 270 slides in the insertion direction of the male terminals 211 to 213. For this reason, when the power supply plug 200 is inserted into the power supply connector 100, non-contact coupling with the power supply connector 100 can be started.

  Further, according to these configurations, after the male terminals 211 and 212 are inserted into the power feeding female terminals 111 and 112, the slide cover 270 slides to move the coil 290 to a position where it can be non-contact coupled. For this reason, when the power feeding connector 100 determines that the non-contact coupling with the power feeding plug 200 is started after the female terminals 111 and 112 and the male terminals 211 and 212 are connected, power feeding to the female terminals 111 and 112 is performed. Therefore, when the power supply plug 200 is inserted, for example, a spark discharge due to an inrush current can be prevented. In addition, since the power supply plug 200 prevents the inrush current from occurring, the female terminals 111 and 112 and the male terminals 211 and 212 can be prevented from deteriorating, electric shock, and fire.

  As shown in FIG. 7A, when the resin module 280 is in an upright state, the front surface of the resin module 280 is in contact with the front wall 269 of the storage space 263. The hook 282 of the resin module 280 protrudes from the resin module 280 in front of the power supply plug 200. Therefore, the hook 282 protrudes from the opening 264 formed in the front surface 280f of the main body 281.

  Here, the position and range of the opening 164 formed on the front surface of the power supply connector 100 with respect to the female terminals 111 and 112 of the power supply connector 100 are based on the male terminals 211 and 212 of the power supply plug 200. The position and range of the opening 264 are substantially the same. For this reason, the hook 282 protruding from the opening 264 of the power supply plug 200 enters the storage space 163 from the opening 164 formed on the front surface of the power supply connector 100 and is caught by the front wall 169 that defines the storage space 163.

  According to these configurations, when the male terminals 211 to 213 of the power supply plug 200 are inserted into the power supply connector 100, the hook 282 as the engaging portion is moved by the slide of the slide cover 270, and the position after the movement is moved. Is engaged with the opening 164 of the power supply connector 100. This makes it difficult for the power supply plug 200 to be detached from the power supply connector 100. For example, the power supply plug 200 can be prevented from being pulled out without operating the slide cover 270, such as by pulling a cord extending from the power supply plug 200. For this reason, it is possible to prevent the power supply plug 200 from being pulled out from the power supply connector 100 before the non-contact coupling with the power supply connector 100 is finished by sliding the slide cover 270 (that is, during power supply). Therefore, the safety at the time of removing the power supply plug 200 can be improved.

  Further, according to these configurations, once the hook 282 is caught by the opening 164 of the power supply connector 100, the gap between the power supply connector 100 and the power supply plug 200 is not easily widened unless the slide cover 270 is operated. Therefore, it is difficult for foreign matter and dust to accumulate in the gap. Therefore, the safety when using the power supply connector 100 and the power supply plug 200 can be improved. Further, if the slide cover 270 is slid, not only the power supply by the power supply connector 100 can be terminated, but also the power supply plug 200 can be easily removed from the power supply connector 100 even in the event of an emergency, for example. I can leave.

  Note that the hook 282 is moved by the rib 271 and caught by the opening 164. Here, since the hook 282, the rib 271 and the opening 164 are not composed of electrical parts, according to these structures, for example, the rectifying element 251, the regulator 252, the ON / OFF control circuit 253, and the oscillation circuit of FIG. It is possible to prevent foreign matter and dust from entering the H.254 and the drive circuit 255 from the outside.

  After that, for example, when the user picks the slide cover 270 and performs an extraction operation of extracting the power supply plug 200 from the power supply connector 100, first, friction generated between the female terminals 111 to 113 and the male terminals 211 to 213 is performed. Due to the resistance, the slide cover 270 slides in the rear surface direction (that is, the removal direction) relatively with respect to the main body 260. When the slide cover 270 slides in the rear direction, the rib 271 of the slide cover 270 protruding from the ceiling of the storage space 263 returns to the position shown in FIGS. 1 (a) and 1 (b). Next, since the resin module 280 is returned to the backward state by the torsion spring 284 in FIG. 6, the coil 190 of the power supply connector 100 and the coil 290 of the power supply plug 200 end electromagnetic coupling. Next, the power supply connector 100 ends the power supply to the power supply plug 200 when the electromagnetic coupling is completed.

  According to these configurations, since the slide cover 270 covers the main body 260, the user grips the slide cover 270 and inserts the power supply plug 200 into the power supply connector 100. For this reason, the slide cover 270 surely slides in the insertion direction of the male terminal 211 to 213 in accordance with the insertion operation. On the contrary, since the slide cover surely slides in the direction opposite to the insertion direction of the male terminal 211 from the male terminal 211 in accordance with the extraction operation (that is, the extraction direction), the non-contact coupling and power supply are performed before the power supply plug 200 is extracted. Can be terminated. For this reason, the safety at the time of insertion and removal of the power supply plug 200 can be improved.

  In addition, according to these configurations, the user can start power supply to the power supply connector 100 by an insertion operation of inserting the power supply plug 200 into the power supply connector 100 and can perform an extraction operation to remove the power supply plug 200. Thus, since the power supply to the power supply connector 100 can be terminated, the convenience of the power supply connector 100 and the power supply plug 200 is improved.

  As shown in FIGS. 1A and 7A, a concave portion 272a and a concave portion 272b into which the convex portion 262 formed on the upper surface 260t of the main body portion 260 is fitted are formed on the lower surface of the slide cover 270. Is formed. When the slide cover 270 is in the position of FIG. 1A, the concave portion 272a of the slide cover 270 and the convex portion 262 of the main body portion 260 are fitted. Therefore, the slide cover 270 does not slide forward unless a predetermined force or more is applied to the slide cover 270 in the forward direction. In addition, when the slide cover 270 is in the position of FIG. 7A, the concave portion 272 b formed behind the concave portion 272 a of the slide cover 270 and the convex portion 262 of the main body portion 260 are fitted. For this reason, the slide cover 270 does not slide backward unless a predetermined force or more is applied to the slide cover 270 in the backward direction.

  According to these configurations, the slide cover 270 does not start sliding unless a predetermined force or more is applied, so that it is possible to prevent malfunctions related to the power supply of the power supply connector 100.

<Modification 1>
In the present embodiment, the power supply connector 100 and the power supply plug 200 have coils 190 and 290, respectively. Power supply starts when the coils 190 and 290 start electromagnetic coupling, and power supply ends when the electromagnetic coupling ends. As explained. However, the present invention is not limited to this. For example, the power supply plug 200 includes a permanent magnet, the power supply connector 100 includes a Hall element, and power supply starts when the Hall element detects magnetism. It is also good. According to this configuration, since the configuration of the power supply connector 100 and the power supply plug 200 can be simplified, the manufacturing cost can be reduced.

<Modification 2>
In the present embodiment, the front surface of the power feeding connector 100 has been described on the assumption that the openings 164 and 170 to 173 are formed as shown in FIG. Here, as shown in FIG. 7A, the opening 170 is fitted with the slide cover 270 of the power supply plug 200. Therefore, the slide cover 270 covers the male terminals 211 to 213 of the power supply plug 200 without generating a gap with the power supply connector 100 when viewed from the upper surface and both side surfaces. For this reason, the slide cover 270 has foreign matters such as dust from the upper surface and both side surfaces of the connecting portion between the female terminals 111 to 113 and the male terminals 211 to 213 in the gap between the power feeding connector 100 and the power feeding plug 200. Prevent entry.

  However, the present invention is not limited to this. For example, as shown in FIG. 4B, even if the power supply connector 100 does not have the opening 170, the front surface of the power supply connector 100 is connected to the power supply connector 100. What is necessary is just to install so that it may become a back side rather than the surface of the panel 180 surrounding the circumference | surroundings. According to this configuration, since the front surface of the power supply connector 100 is in a position recessed from the surface of the panel 180, the slide cover 270 creates a gap with the surface of the panel 180 when viewed from the upper surface and both side surfaces. The male terminals 211 to 213 of the power supply plug 200 are covered. For this reason, even if there is no opening 170 into which the slide cover 270 is fitted, the slide cover 270 has a foreign substance such as dust from the upper surface and both side surfaces of the connection portion between the female terminals 111 to 113 and the male terminals 211 to 213. Can prevent entry.

<Modification 3>
Further, for example, as shown in FIG. 4C, the power supply connector 100 has an opening 170 and may be installed so that the front surface of the power supply connector 100 is behind the surface of the panel 180. good. According to this configuration, foreign matters such as dust can be more reliably prevented from entering the gap between the power supply connector 100 and the power supply plug 200.

Second Embodiment
Hereinafter, a power supply connector and a power supply plug according to a second embodiment of the present invention will be described with reference to the accompanying drawings.

  The power supply connector 300 according to the embodiment of the present invention shown in FIG. 8A is inserted with the power supply male terminal 411 of the power supply plug 400 according to the embodiment of the present invention, as in the first embodiment. After that, when non-contact coupling with the power supply plug 400 is performed, supply of power to the power supply plug 400 is started. Hereinafter, description of the configuration common to the first embodiment will be omitted.

  The power feeding connector 300 has a circuit configuration similar to that shown in FIG. As shown in FIG. 8A, openings 370 to 373 are formed on the front surface of the power feeding connector 300. The openings 371 to 373 are the same as the openings 171 to 173 of the first embodiment. Note that the front surface of the power feeding connector 300 is not formed with an opening corresponding to the opening 164 of the first embodiment. This is because the power supply plug 400 does not have the hook 282 of the first embodiment, as will be described later.

  As shown in FIG. 9E, the opening 370 is inserted with the tip of a slide cover 470 included in the power supply plug 400. Here, since the slide cover 470 has a flat plate shape, the opening 370 is formed in a throttle shape. As shown in FIG. 8A, a lateral hole defined by a bottom surface, an upper surface, and both side surfaces parallel to the sliding direction of the slide cover 470 is formed on the back side of the opening 370 of the power supply connector 300. Yes.

  In the power supply connector 300, a storage space 363 for storing a coil 390 used for electromagnetic coupling with the power supply plug 400 is formed above a lateral hole having an opening 370. The coil 390 is stored in the storage space 363 such that the central axis of the coil 390 is substantially perpendicular to the bottom surface and the top surface of the horizontal hole.

  The power supply plug 400 has a circuit configuration similar to that shown in FIG. As shown in FIG. 9 (e), the power supply plug 400 further includes a main body 460 having the circuit of FIG. 5 and a slide cover 470 that covers only the upper surface 460 t of the main body 460.

  Guide grooves 461r and 461l are formed on the upper surface 460t of the main body 460, and a male terminal 411 protrudes from the front. Note that the front surface of the main body 460 is not formed with an opening corresponding to the opening 264 of the first embodiment. This is because the main body 460 does not have the hook 282 of the first embodiment, as will be described later.

  An upper surface 460t of the main body 460 is inclined downward. Guide grooves 461r and 461l provided on the upper surface 460t are fitted into both ends of the slide cover 470, and guide the slide cover 470 to slide in the front-rear direction of the power supply plug 400 along the gradient of the upper surface 460t. .

  According to these configurations, the upper surface 460t of the main body portion 460 included in the power supply plug 400 has a gradient that decreases in the insertion direction of the male terminal 411 and the like, so that the weight of the slide cover 470 is increased with the upper surface 460t facing upward. The slide cover 470 can easily slide in the insertion direction of the male terminal 411 and the like.

  As shown in FIG. 8A, the main body 460 does not have a storage space for storing the coil 490. Therefore, the resin module 280 including the coil 290 of the first embodiment and having the hook 282 is not provided.

  A storage space 463 for storing the coil 490 is formed at the tip of the slide cover 470. In the storage space 463, the central axis of the coil 490 is installed so as to be substantially perpendicular to the upper surface and the lower surface of the slide cover 470.

  Here, for example, when the user performs an insertion operation of inserting the power supply plug 400 into the power supply connector 300, first, the power supply male terminal 411 of the power supply plug 400 becomes the female terminal 311 of the power supply connector 300. Inserted. Next, the slide cover 470 slides forward along the upper surface 460t of the main body 460 by a user operation or by inertial force and gravity. As shown in FIG. 8 (b), the sliding slide cover 470 enters the lateral hole formed at the back of the opening 370 provided on the front surface of the power supply connector 300 as shown in FIG. This is because the position and shape of the opening 370 with respect to the female terminal 311 and the like substantially coincide with the position and shape of the slide cover 470 with respect to the male terminal 411 and the like. For this reason, the slide cover 470 covers not only the upper surface 460t of the main body 460 but also the upper surfaces of the male terminals 411 and the like.

  Further, when the distal end portion of the slide cover 470 is fitted into the lateral hole having the opening 370, the slide cover 470 is accommodated in the central axis of the coil 490 accommodated in the distal end portion of the slide cover 470 and the accommodating space 363 formed above the lateral hole. The center axis of the formed coil 390 substantially matches. For this reason, the coil 390 and the coil 490 facing each other start electromagnetic coupling. Next, the power feeding connector 300 detects the start of electromagnetic coupling and starts power feeding to the power feeding plug 400.

  Further, as shown in FIG. 8B, the bottom surface of the horizontal hole having the opening 370 is the guide direction of the guide grooves 461r and 461l with respect to the slide cover 470 when the power supply plug 400 is inserted into the power supply connector 300. It is almost parallel to. Here, since the guide directions of the guide grooves 461r and 461l substantially coincide with the gradient of the upper surface 460t of the main body 460, the guide grooves 461r and 461l form a predetermined angle with the extraction direction of the male terminals 411 and the like. For this reason, when only the main body 460 is moved in the removal direction (that is, rearward), the bottom surface of the slide cover 470 fitted in the horizontal hole is caught by the bottom surface of the horizontal hole.

  Therefore, according to these configurations, even if the hook 282 of the first embodiment is not provided, the power supply plug 400 is not easily detached from the power supply connector 300 during electromagnetic coupling (that is, during power supply). For this reason, according to the power supply connector 300 and the power supply plug 400, it is possible to prevent the power supply plug 400 from being pulled out without operating the slide cover 470.

  Further, according to these configurations, since the gap between the power supply connector 300 and the power supply plug 400 does not easily widen unless the slide cover 470 is operated, it is difficult for foreign matter and dust to accumulate in the gap. Further, as long as the slide cover 470 is slid, not only the power supply by the power supply connector 300 can be terminated, but also the power supply plug 400 can be easily removed from the power supply connector 300.

  Thereafter, for example, when the user pushes up the slide cover 470 to the position of FIG. 8A, the central axis of the coil 390 and the central axis of the coil 490 are separated beyond a predetermined distance. For this reason, the coil 390 of the power supply connector 300 and the coil 490 of the power supply plug 400 end electromagnetic coupling. Next, the power supply connector 300 ends the power supply to the power supply plug 400 when the electromagnetic coupling ends.

<Modification 1>
In this embodiment, as shown in FIG. 9B, the opening 370 is not formed on the front surface of the power supply connector 300, and the opening 370 is formed on the surface of the panel 380 installed around the power supply connector 300. An opening corresponding to may be formed. Further, a hole corresponding to a horizontal hole formed on the back side of the opening 370 may be formed on the back side of the opening of the panel 380. Furthermore, the power supply connector 300 may form a storage space for storing the coil 390 below the lateral hole.

  According to this configuration, even if the opening 370 is not formed on the front surface of the power supply connector 300, if the opening corresponding to the opening 370 is formed on the surface of the panel 380, the power supply connector 300 during power supply is formed. Can be prevented from being removed.

<Modification 2>
In the present embodiment, as shown in FIG. 9C, the power feeding connector 300 may be installed such that the front surface in which the opening 370 is formed is behind the surface of the panel 380. According to this configuration, foreign matters such as dust can be more reliably prevented from entering the gap between the power supply connector 300 and the power supply plug 400. In addition, as shown in FIG.9 (d), you may combine the modification 2 and the modification 3 of this embodiment.

  Various embodiments and modifications can be made to the present invention without departing from the broad spirit and scope of the present invention. Further, the above-described embodiment is for explaining the present invention, and does not limit the scope of the present invention. That is, the scope of the present invention is shown not by the embodiments but by the claims. Various modifications within the scope of the claims and within the scope of the equivalent invention are considered to be within the scope of the present invention.

DC power supply 10
Power supply connector 100,300
Female terminals 111 to 113, 311 to 313
Relay power supply 120
Relay device 131,132
Semiconductor switch 140
Oscillation circuit 151
First drive circuit 152
Second driving circuit (receiving circuit) 153
ON / OFF control circuit 154
Storage space 163,363
Openings 164, 170-173, 370-373
Panel 180, 380
Coil 190
Power supply plug 200,400
Male terminal 211-213,411
Rectifier element 251
Regulator 252
ON / OFF control circuit 253
Oscillator circuit 254
Drive circuit 255
Upper surface 260t, 460t
Side 260s
Main body 260, 460
Guide hole 261
Storage space 263
Opening 264
Slide cover 270, 470
Rib 271
Resin module 280
Body part 281
Hook 282
Support shaft 283
Torsion spring 284
Bearing 289
Coil 190, 290, 390, 490
Guide groove 461r, 461l

Claims (11)

A female terminal into which the male terminal of the power supply plug is inserted;
A coupling portion electromagnetically coupled to the power supply plug;
When the coupling portion is coupled to the power supply plug, the female terminal electrically connected to the DC power supply for supplying power to the female terminal, and is coupled with the power supply plug and the coupling portion are eliminated A semiconductor switch for electrically disconnecting the female terminal and the DC power source supplying power to the female terminal;
When detecting the electromagnetic coupling between the feeding plug and the coupling portion, Bei example and a driving circuit for driving the semiconductor switches so as to electrically connect a line between the female terminal power supply,
The coupling portion is electromagnetically coupled to the power supply plug after the male terminal of the power supply plug is inserted into the female terminal.
A power supply connector characterized by that.   The coupling portion eliminates electromagnetic coupling with the power supply plug while the male terminal of the power supply plug is inserted into the female terminal.
  The power feeding connector according to claim 1. The coupling unit receives a request signal for requesting power feeding from the coupled power feeding plug,
The driving circuit drives the semiconductor switch when the coupling unit receives the request signal.
The power supply connector according to claim 1 , wherein the power supply connector is a power supply connector. When the coupling unit does not receive the request signal for a certain period, the drive circuit stops driving the semiconductor switch;
The power feeding connector according to claim 3. A male terminal inserted into the female terminal of the power supply connector;
A slide member that slides in the insertion direction of the male terminal;
A coupling portion for non-contact coupling with the power feeding connector at a position moved by the slide member;
A power supply plug characterized by that. The coupling portion is electromagnetically coupled to the power feeding connector;
A driving circuit for driving the coupling unit to transmit a request signal for requesting start of power feeding to the power feeding connector using an electromotive force generated by electromagnetic coupling between the coupling unit and the power feeding connector; In addition,
The power supply plug according to claim 5. The slide member is a slide cover that covers a main body having the male terminal.
The power supply plug according to claim 5 or 6. The covering surface covered with the slide member of the main body has a gradient that descends in the insertion direction of the male terminal with the covering surface facing up,
The main body has a guide groove for guiding the slide of the slide member in a direction along the gradient.
The power supply plug according to claim 7. The male terminal protrudes from the main body,
The slide cover covers the male terminal when sliding in the insertion direction of the male terminal,
The power supply plug according to claim 7 or 8. An engaging portion that engages with the opening of the power feeding connector at a position moved by the slide member;
The power supply plug according to claim 7, wherein the power supply plug is a power supply plug. The slide member is fitted into the opening of the power feeding connector.
The power supply plug according to claim 8.

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