JP2017130427A - Switch and connector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a switch dealing with high voltage and DC current.SOLUTION: A switch has a movable plate provided with a fixed contact and a movable contact, and a movable spring. The movable plate is in contact with the bent in the movable spring, and is attached to a card. By moving the card, the movable plate moves while keeping the contact state with the movable spring at the bent. The fixed contact and the movable contact are switched from the contact state to the non-contact state, or vice versa.SELECTED DRAWING: Figure 8

Description

  The present invention relates to a switch and a connector.

  When the electric device receives power from the power source, the power is supplied from the power source to the electric device via the connector. The connector used at this time is electrically connected by fitting a convex male connector and a concave female connector.

  On the other hand, in recent years, as one of the countermeasures against global warming and the like, supply of high voltage power with direct current, which has little power loss in voltage conversion, power transmission, etc. and does not need to increase the thickness of the cable, has been studied. . In particular, information devices such as servers consume a large amount of power, and such power supply is desirable.

  By the way, regarding the electric power supplied to the electric equipment, if the voltage is high, the human body may be affected or the operation of the electronic component may be affected. When such high-voltage power is used for information equipment such as a server, since the work is performed by a person during installation and maintenance of the apparatus, a connector that is an electrically connected part is a normal connector. It must be different from the connector used for AC commercial power. Some of these connectors incorporate a switch.

JP-A-5-82208 JP 2003-31301 A JP 2012-104448 A

  In a connector with a built-in switch, when the power supplied from the power source is high voltage and direct current, the currently used switch cannot be used as it is. For example, when the power supplied from the power source is 400V DC, the switch used for AC 100V does not ensure sufficient safety and reliability when using DC 400V, so it is used for DC 400V as it is. It is dangerous to do.

  Therefore, the present invention has been made in view of the above, and an object of the present invention is to provide a switch capable of safely supplying high-voltage power.

  According to one aspect of the present embodiment, it has a fixed contact, a movable plate on which a movable contact is installed, and a movable spring, and the movable plate is in contact at a bent portion of the movable spring. The movable plate is attached to the card, and by moving the card, the movable plate moves while maintaining contact with the movable spring and the bent portion, and the fixed contact and the movable contact are in contact with each other. It is characterized in that it is changed from a contacted state to a non-contacted state and from a non-contacted state to a contacted state.

  According to the disclosed switch, high-voltage power can be safely supplied.

The perspective view of the plug connector used for this Embodiment The perspective view of the plug connector in this Embodiment The perspective view before a plug connector and a jack connector are connected Sectional view before plug connector and jack connector are connected (1) Sectional view before the plug connector and jack connector are connected (2) Sectional view before the plug connector and jack connector are connected (3) The perspective view of the internal structure of the plug connector in this Embodiment Structure of switch part (OFF state) Structure of switch (ON state) Perspective view of fixing spring Perspective view of moving part Perspective view of movable plate Perspective view of movable spring Perspective view of holding spring A perspective view of the button on the switch Cross-sectional perspective view of the internal structure of the plug connector in the present embodiment Perspective view of slide part (1) Perspective view of slide part (2) Sectional view during connection of plug connector and jack connector (1) Sectional view during connection of plug connector and jack connector (2) Sectional view during connection of plug connector and jack connector (3) Sectional view where plug connector and jack connector are connected (1) Sectional view where the plug connector and jack connector are connected (2) Sectional view where plug connector and jack connector are connected (3) Sectional view in the middle of separation of plug connector and jack connector (1) Sectional view in the middle of separation of plug connector and jack connector (2) Sectional view in the middle of separation of plug connector and jack connector (3)

  The form for implementing this invention is demonstrated below. In addition, about the same member etc., the same code | symbol is attached | subjected and description is abbreviate | omitted.

(Connector structure)
The structure of the connector in this embodiment will be described. FIG. 1 is a perspective view of the plug connector 100, and FIG. 2 is a perspective view of the jack connector. 3 is a perspective view before the plug connector and the jack connector are fitted together, and FIGS. 4 to 6 are cross-sectional perspective views of different sections before the plug connector and the jack connector are fitted together. It is. FIG. 7 is a perspective view showing the internal structure of the jack connector.

  The connector in the present embodiment is connected to the plug connector 100, which is another connector shown in FIG. 1, and is the jack connector 200 having the structure shown in FIG. The plug connector 100 is provided with a plurality of plug terminals serving as other connection terminals, and the jack connector 200 is provided with a plurality of jack terminals serving as connection terminals connected to the plug terminals.

  First, the plug connector 100 will be described with reference to FIG. Plug connector 100 is provided with plug terminals 121, 122, and 123 to be inserted into jack connector 200 described later in plug housing portion 110. A power cable 130 for supplying power is connected to the side of the plug housing 110 opposite to the side where the plug terminals 121, 122, 123 are provided. An edge 111 is formed in the plug connector 100 so as to surround the periphery of the plug terminals 121, 122, and 123. The plug terminal 121 is a GND terminal and is longer than the plug terminals 122 and 123. The plug casing 110 is made of an insulating material such as a resin material, and the edge 111 is formed as a part of the plug casing 110.

  Next, the jack connector 200 will be described with reference to FIGS. The jack connector 200 has a jack housing part 210. The jack housing part 210 is provided with jack openings 221, 222, and 223. In the jack connector 200, jack terminals 231, 232, 233 connected to the plug terminals 121, 122, 123 of the plug connector 100 are provided inside the jack openings 221, 222, 223 as shown in FIG. Is provided.

  The plug terminal 121 is connected to a jack terminal 231 provided inside the jack opening 221, the plug terminal 122 is connected to a jack terminal 232 provided inside the jack opening 222, and the plug terminal 123 is connected to the jack opening 223. Is connected to a jack terminal 233 provided inside the terminal. In addition, a groove portion 211 into which the edge portion 111 of the plug connector 100 can enter is formed around the jack openings 221, 222, and 223. The jack terminal 231 provided inside the jack opening 221 is a GND terminal.

  Moreover, the jack connector 200 in this Embodiment has the switch part 300 shown by FIG.8 and FIG.9 mentioned later inside the jack housing | casing part 210. FIG. The switch unit 300 is provided with a connection terminal connected to the jack terminal 232 of the jack connector 200 and a connection terminal connected to the jack terminal 233. By closing the contact of the switch in the switch unit 300, the jack terminal Power is supplied to the plug connector 100 via the H.232 and the jack terminal 233. Further, when the switch in the switch unit 300 is opened, the supply of power to the plug connector 100 via the jack terminal 232 and the jack terminal 233 is stopped.

  In this embodiment, when the button 360 of the switch unit 300 shown in FIGS. 7 to 9 is pressed, the switch in the switch unit 300 is closed and power is supplied. At this time, the slide portion 250 provided inside the jack connector 200 slides, whereby the button 360 is pushed downward by the slide portion 250, the switch of the switch portion 300 is closed, and the jack terminals 232 and 233 are connected. Electric power is supplied to the plug connector 100. Details of the operations of the slide unit 250 and the button 360 will be described later.

(Switch part)
Next, based on FIG.8 and FIG.9, the switch part 300 provided in the jack connector 200 is demonstrated. Switch unit 300 in the present embodiment is a switch for controlling power supply, and is also referred to as a power switch.

  As shown in FIGS. 8 and 9, the switch unit 300 includes a fixed unit 310 and a movable unit 320, and whether or not the fixed contact 311 in the fixed unit 310 and the movable contact 321 in the movable unit 320 are in contact with each other. Thus, on / off control of power supply can be performed. The switch unit 300 is provided with two pairs of a fixed unit 310 and a movable unit 320, and each set corresponds to one of the jack terminals 232 and 233.

  The fixed portion 310 has a fixed spring 312 formed entirely of a conductive material such as metal, and a fixed contact 311 that contacts the movable contact 321 of the movable portion 320 is provided at one end of the fixed spring 312. It is of the structure that has been. The fixed contact 311 is formed of an alloy of silver and copper, and the fixed spring 312 is formed by bending a metal plate or the like made of copper or an alloy containing copper.

  FIG. 10 shows a fixing spring 312 according to this embodiment. In the present embodiment, the fixing spring 312 is formed by processing and bending a copper plate having a thickness of about 0.5 mm and a width of about 5 mm. A fixed contact installation hole 312a for installing the fixed contact 311 is formed near one end of the fixed spring 312, and an external connection terminal 312b is provided at the other end of the fixed spring 312. . The other end of the fixing spring 312 is fixed to the base block 330 with the external connection terminal 312b protruding outside the base block main body 331.

  FIG. 11 is a perspective view of the movable portion 320 in a state where the movable plate 322 is attached to the movable spring 323. As shown in FIG. 11, the movable portion 320 includes a movable plate 322 and a movable spring 323 that are formed of a conductive material such as metal. At one end of the movable plate 322, a movable contact 321 that contacts the fixed contact 311 of the fixed portion 310 is provided. As shown in FIGS. 8 and 9, the movable plate 322 is attached to the card 340 in a state of being attached to the pressing spring 324, and the movable spring 323 is attached to the base block main body 331. . The movable plate 322 is in contact with a bent portion 323 a formed by a bent shape provided in the vicinity of one end portion of the movable spring 323 in the vicinity of the other end portion of the movable plate 322. The movable plate 322 is in contact with the mountain side of the bent portion 323a. When the movable plate 322 moves, the contact state between the mountain side of the bent portion 323a and the movable plate 322 moves on the mountain side of the bent portion 323a. Kept. The movable contact 321 is made of an alloy of silver and copper. The movable plate 322 is formed by processing a metal plate or the like made of copper or an alloy containing copper, and the movable spring 323 is formed by bending a metal plate or the like made of copper or an alloy containing copper. Yes.

  FIG. 12 shows the movable plate 322. The movable plate 322 is formed by processing a copper plate having a thickness of about 0.5 mm and a width of about 5 mm. A movable contact 321 is provided in the vicinity of one end of the movable plate 322 for installing a movable contact 321. A contact installation hole 322a is formed. The movable plate 322 is provided with a recess 322b and a recess 322c to which the holding spring 324 is attached in the vicinity of one end and the other end.

  FIG. 13 shows the movable spring 323. The movable spring 323 is formed by processing and bending a copper plate having a thickness of about 0.5 mm and a width of about 5 mm. Near one end of the movable spring 323, a bent portion 323a that is bent into a curved shape in contact with the movable plate 322 is formed, and an external connection terminal 323b is provided at the other end of the movable spring 323. ing. The other end of the movable spring 323 is fixed to the base block 330 with the external connection terminal 323 b protruding outside the base block main body 331.

  In the present embodiment, as shown in FIG. 12, the movable plate 322 has an opening 322d in the vicinity of the other end. An end contact portion 322e is formed on the other end side of the opening 322d of the movable plate 322. The opening width of the end contact portion 322e in the short direction of the movable plate 322 is formed to be narrower than the opening width of the opening 322d. The movable spring 323 and the movable plate 322 are installed in a state where the opening 322 d enters the movable spring 323 and the bent portion 323 a of the movable spring 323 and the movable plate 322 are in contact with each other. In the present embodiment, one of the external connection terminal 312b and the external connection terminal 323b is connected to the jack terminal 232 or the jack terminal 233, and the other is connected to a power source (not shown).

  In the present embodiment, the movable plate 322 is not fixed to the movable spring 323. Further, in this embodiment, the side of the movable plate 322 where the end contact portion 322e is formed is not fixed to the movable spring 323, and the end contact portion 322e is movable using the mountain of the bent portion 323a as a fulcrum. The spring 323 can be displaced in the vertical direction. With such a configuration, the movable plate 322 can be operated even if the spring properties of the movable plate 322 and the movable spring 323 are low.

  FIG. 14 shows the holding spring 324. The holding spring 324 is formed by processing a stainless steel plate having a thickness of about 0.2 mm, and has conductivity as well as springiness. One end and the other end of the holding spring 324 are bent to form hook portions 324a and 324b. The holding spring 324 is attached to the movable plate 322 as shown in FIG. When attaching the holding spring 324 to the movable plate 322, the hooking portion 324 a formed at one end of the holding spring 324 is hooked into the recess 322 b at one end of the moving plate 322, and the other end of the holding spring 324. The hook 324b formed in the hook is attached to the other end of the movable plate 322 by hooking it into the recess 322c.

  As shown in FIGS. 8 and 9, the central portion of the upper portion of the holding spring 324 is in contact with the lower portion of the card body 345 of the card 340, and the lower portion of the movable plate 322 is in contact with the lower contact portion 342 of the card 340. The movable plate 322 to which the holding spring 324 is attached is attached to the card 340. In this state, the movable plate 322 is pushed toward the lower contact portion 342 of the card 340 by the spring force of the holding spring 324. When the movable plate 322 to which the pressing spring 324 is attached is attached to the card 340, the central portion of the pressing spring 324 may be fixed to the card body 345.

  In the present embodiment, the fixed spring 312, the movable plate 322, and the movable spring 323 through which current flows are formed thicker than those of the conventional structure in order to flow a large amount of current.

  The thickness of the conventional fixed spring or the like is about 0.15 mm as an example, but the thickness of the fixed spring or the like according to the present embodiment is about 0.5 mm, which is thicker than the conventional one. If the thickness of the fixing spring or the like is thin, the electrical conductivity is low and the resistance is high, so that the fixing spring or the like generates heat when a large current is passed. However, by increasing the conductivity and lowering the resistance by increasing the thickness of the fixed spring or the like, heat generation of the fixed spring or the like can be suppressed even when a large current flows, and a large current (for example, about 26 A) flows. It becomes possible.

  In addition, by setting the thickness of the fixed spring 312, the movable plate 322, and the movable spring 323 to 0.3 mm, for example, it is possible to pass a current about twice that of the conventional one, and by setting these thicknesses to 0.45 mm. About three times as much current as before can be passed.

  By the way, when the thickness of the fixed spring 312 or the movable spring 323 is increased, the elasticity of the fixed spring 312 or the movable spring 323 is lowered, and the function as a spring is weakened. Therefore, in the present embodiment, the movable portion 320 is divided into the movable spring 323 and the movable plate 322, and when the movable contact 321 contacts the fixed contact 311, the movable plate 322 is a bent portion 323a of the movable spring 323. The movable plate 322 is configured to move so that the movable contact 321 approaches and comes into contact with the fixed contact 311 while being in contact with. Therefore, when the movable contact 321 comes into contact with the fixed contact 311, the movable plate 322 moves, so that the necessity for deforming the movable spring 323 is small. Therefore, even if the elasticity of the movable spring 323 is low and the spring property is small, it can function as a switch by moving the movable plate 322. On the other hand, since the function as a spring is not so required for the movable spring 323, even if the plate thickness of the movable spring 323 is increased, the operation of the switch is not hindered, and the current flowing through the switch can be increased. Become. In the present embodiment, when the movable contact 321 contacts the fixed contact 311, the movable plate 322 moves, so that the end contact portion 322 e of the movable plate 322 contacts the movable spring 323. Thereby, the contact part with the movable plate 322 of the movable spring 323 becomes two places including the bending part 323a. Therefore, when the movable contact 321 comes into contact with the fixed contact 311, the resistance between the movable spring 323 and the movable plate 322 can be reduced as compared with the case where only the bent portion 323 a is in contact with the movable plate 322. . For example, pure copper may be used as a material for forming the fixed spring 312 and the movable spring 323.

  The movable spring 323 is formed by bending a metal plate or the like, and thus has a certain degree of flexibility although its elasticity is slightly reduced. Therefore, when the movable contact 321 provided at one end of the movable plate 322 is moved in the vertical direction, the bending portion 323a is pushed by the movable plate 322 by moving the position of the movable plate 322. The movable spring 323 is slightly deformed downward while the bent portion 323a of the movable spring 323 is in contact with the bent portion 323a. That is, when the movable spring 323 is further pushed by the card in a state where the end contact portion 322e is moved upward as shown in FIG. 9, the contact position between the end contact portion 322e and the movable spring 323 acts as a fulcrum. The movable spring 323 is pushed by the movable plate 322 and is slightly deformed. Due to the downward deformation of the movable spring 323, an upward restoring force is generated in the movable spring 323. This restoring force also contributes to maintaining the contact between the movable plate 322 and the bent portion 323a.

  Insulation made of a flame-retardant resin material or the like between the portion where the other end of the fixed spring 312 of the base block 330 is connected and the portion where the other end of the movable spring 323 is connected A wall 333 is provided, and the movable spring 323 is bent in a shape that wraps around a part of the periphery of the insulating wall 333 from the other end.

  In this embodiment, since the holding spring 324 is attached to the card 340 and the movable plate 322 is attached to the holding spring 324, the movable plate 322 is rotated by rotating the card 340 around the rotation shaft 343. Can move the movable plate 322 while being in contact with the bent portion 323a of the movable spring 323, and the movable contact 321 can be moved in the vertical direction.

  The holding spring 324 attached to the card 340 exerts a restoring force toward the movable spring 323 in a state where the movable spring 323 and the movable plate 322 are in contact with each other. When the movable plate 322 is moved by the operation of the card 340, the movable plate 322 is pushed to the movable spring 323 side by the pressing spring 324. Therefore, the movable plate 322 is maintained while maintaining the contact state between the movable plate 322 and the movable spring 323. 322 can be moved.

  After the movable contact 321 comes into contact with the fixed contact 311, when the card 340 is further rotated downward about the rotation shaft 343, the fixed spring 312 and the holding spring 324 are deformed. In the present embodiment, the holding spring 324 is more easily deformed than the fixed spring 312.

  The fixed part 310 and the movable part 320 are installed inside a region surrounded by the base block 330 and the switch part case 350. The card 340 includes a protrusion 344 having a shape protruding from the switch opening 351 provided in the switch case 350, and a card main body located inside a region surrounded by the base block 330 and the switch case 350. 345, and a lower contact portion 342 is provided under the card main body portion 345. The card 340, the base block 330, and the switch case 350 are made of an insulating material made of a resin material or the like.

  A button 360 that is pressed to rotate the card 340 about the rotation shaft 343 is provided outside the switch unit case 350. The card 340 and the button 360 are connected in a state where the card 340 can rotate around the rotation shaft 343, and the card 340 can be pulled up by the button 360 when the button 360 moves upward. ing. The card 340 is in contact with the inner wall portion 361 of the button 360 at a contact portion 344 a provided on the upper portion of the projection portion 344. Since the contact portion 344a slides on the surface of the inner wall portion 361, a surface layer formed of a fluororesin or the like may be provided on the surface of the inner wall portion 361 in order to reduce frictional resistance. . In addition, a release spring 370 having one end connected to the switch unit case 350 and the other end connected to the button 360 is provided outside the switch unit case 350.

  FIG. 15 is a perspective view of the button 360. In the present embodiment, a button protrusion 365 shown in FIG. 15 is formed on the upper side of the button 360. The button protrusion 365 has a structure that protrudes upward from the lower flat part 369 in FIG. 15, and the upper part of the button protrusion 365 is an upper flat part 366 formed flat. In the button projection portion 365, a steeply inclined portion 367 having a steep slope and a gently inclined portion 368 having a gentle slope are formed on a side surface from the upper flat portion 366 toward the lower flat portion 369.

(Slide part)
Next, the slide part 250 will be described with reference to FIGS. 7, 16, 17, and 18. 16 is a cross-sectional perspective view showing the internal structure of the jack connector, and FIGS. 17 and 18 are perspective views of the slide portion 250. FIG. FIG. 17 illustrates the lower surface of the slide portion, and FIG. 18 illustrates the upper surface of the slide portion.

  In the present embodiment, the slide part 250 provided in the jack connector 200 is slid by the insertion of the plug connector, whereby the button 360 is pressed and the switch part 300 is turned on.

  An upper protrusion 251 is formed on one surface of the slide portion 250 (the upper surface shown in FIG. 7 and the surface shown in FIG. 18). A flat upper surface 252 is formed at the upper end of the upper protrusion 251, and a slide inclined portion 253 that is inclined downward from the end of the upper surface 252 is formed. The slide inclined portion 253 is formed up to the inclined end portion 254 at the lower end. Further, a lower protrusion 256 is formed on the other surface (the surface shown in FIG. 17) of the slide portion 250. As shown in FIG. 17, the lower protrusion 256 is formed in a substantially circular shape, and an overhanging portion 257 that protrudes partly from the substantially circular portion is formed. The lower protrusion 256 and the overhang 257 are formed so that the top portions have the same height.

  In the present embodiment, when the plug connector 100 is inserted into the jack connector 200 in the state shown in FIGS. 7 and 16, the edge 111 of the plug connector 100 contacts the slide inclined portion 253, and the slide portion The slide slope 253 at 250 is pushed by the edge 111. Thus, when the slide portion 250 slides in the right direction in FIG. 7 and the slide portion 250 slides until the edge portion 111 and the inclined end portion 254 of the slide portion 250 come into contact with each other, the slide of the slide portion 250 ends.

  In addition, according to the slide of the slide part 250, the button 360 is pressed by the slide part 250, and thereby the card 340 rotates downward. Thereafter, the edge portion 111 of the plug connector 100 enters the inside of the jack connector 200 together with the plug terminals 121, 122, and 123, whereby the switch of the switch portion 300 is turned on and power is supplied to the plug connector 100. The

  Specifically, by inserting the plug connector 100 into the jack connector 200, the lower projection 256 of the slide portion 250 and the button projection 365 of the button 360 are in contact with each other, and the slide portion 250 slides to the right. In response, the lower protrusion 256 pushes the button protrusion 365. Since the button protrusion 365 has a slope, the button 360 is pressed downward. As a result, the card 340 in contact with the button 360 rotates downward in accordance with the downward movement of the button 360.

(On / off operation in the switch section)
When the switch is turned on in the switch unit 300, the plug connector 100 is inserted into the jack connector 200. Accordingly, the button 360 is pushed downward by the operation described above, and the card 340 in which the contact portion 344a is in contact with the inner wall portion 361 of the button 360 is rotated downward from the state of FIG. Then, the holding spring 324 is pushed downward by the card 340. Since the holding spring 324 is pushed downward by the card 340, the movable plate 322 attached to the holding spring 324 moves downward in FIG. 8, and the movable contact 321 and the fixed contact 311 come into contact with each other. FIG. 9 shows a state where the movable contact 321 and the fixed contact 311 are in contact with each other. When the movable contact 321 and the fixed contact 311 come into contact with each other, power from the power source is supplied to the plug connector 100 side.

  When the switch is turned off, by removing the plug connector 100 from the jack connector 200, the slide portion 250 returns to the original position, and the force pressing the button 360 is lost. As a result, the button 360 moves upward by the restoring force of the release spring 370, and the button 360 returns to the off state. When the button 360 moves upward, the card 340 connected to the button 360 is pulled up by the button 360, so that the card 340 rotates upward about the rotation shaft 343. In accordance with the operation of the card 340, the holding spring 324 attached to the card 340 is pulled upward, and the movable plate 322 attached to the holding spring 324 moves upward. By moving the movable plate 322 upward in this manner, the contact between the movable contact 321 and the fixed contact 311 can be released, and the supply of power from the power source can be stopped.

  When the contact between the movable contact 321 and the fixed contact 311 is released, an arc may be generated between the movable contact 321 and the fixed contact 311. Therefore, the movable contact 321 can be blown by a magnetic field force. A permanent magnet 380 that generates a magnetic field substantially perpendicular to the direction in which the arc is generated is provided in the vicinity of the contact position between the contact point 311 and the fixed contact 311.

  Thus, when the button 360 is lifted up by returning the button 360 to the original state by the restoring force of the release spring 370, the card 340 connected to the button 360 is also lifted up in conjunction with the button 360. Since the holding spring 324 is pulled upward by the card 340, the movable contact 321 is separated from the fixed contact 311.

  The base block 330 is provided with an insulating wall 333 between a portion where the other end of the fixed spring 312 is connected and a portion where the other end of the movable spring 323 is connected. . Thereby, even when melting of the fixed portion 310 and the movable portion 320 progresses due to heat, the fixed portion 310 and the movable portion 320 are separated by the insulating wall 333. Therefore, it is possible to prevent the current from continuing to flow while the fixed portion 310 and the movable portion 320 are in contact with each other due to melting.

(Connector connection method)
Next, a connector connection method in the present embodiment will be described. Specifically, as shown in FIGS. 3 to 6, the plug connector 100 and the jack connector 200 are fitted and electrically connected from the state where the plug connector 100 and the jack connector 200 are separated from each other. The process until the state is reached will be described in order. In the following, the plug terminal 121 and jack terminal 231 and the plug terminal 123 and jack terminal 233 shown in FIGS. 19 to 27 will be described. Since the state of the plug terminal 122 and the jack terminal 232 (not shown in FIGS. 19 to 27) is the same as the state of the plug terminal 123 and the jack terminal 233, the description thereof will be omitted.

  19 to 21 are cross-sectional perspective views of the plug terminals 121, 122, and 123 inserted into the jack openings 221, 222, and 223, respectively. 19 is a cross section corresponding to FIG. 4, FIG. 20 is a cross section corresponding to FIG. 5, and FIG. 21 is a cross section corresponding to FIG.

  First, the plug terminals 121, 122, 123 of the plug connector 100 are inserted into the jack openings 221, 222, 223 of the jack connector 200 from the state shown in FIGS. It becomes a state.

  Thereby, the plug terminal 121 of the plug connector 100 and the jack terminal 231 in the jack opening 221 come into contact with each other, and the plug terminal 123 of the plug connector 100 and the jack terminal 233 in the jack opening 223 come into contact with each other. At this time, the edge portion 111 of the plug connector 100 enters the groove portion 211 of the jack connector 200, and the slide inclined portion formed on the upper projection 251 of the slide portion 250 provided in the jack connector 200 as shown in FIG. In contact with H.253. However, in the state of FIGS. 19 to 21, the slide inclined portion 253 of the upper protrusion 251 is only in contact with the tip of the edge 111, and the slide portion 250 does not slide in the right direction in the figure. . 7 and FIGS. 19 to 21 are applied to the slide portion 250 by an elastic body such as a spring so that the original state (position of FIGS. 3 to 7) is maintained if no force is applied from the outside. It is biased to the left in the figure.

  19 to FIG. 21, the plug terminal 121 and the jack terminal 231 are in contact with each other, and the plug terminal 123 and the jack terminal 233 are in contact with each other. However, since the movable contact 321 and the fixed contact 311 of the switch unit 300 are not in contact, the switch unit 300 is off and no power is supplied to the plug connector 100 side. In this state, the end of the lower projection 256 of the slide portion 250 is in contact with the lower flat portion 369 of the button 360 as shown in FIG.

  Thereafter, when the plug connector 100 is further inserted into the jack connector 200 from the state shown in FIGS. 19 to 21, the state shown in FIGS. 22 to 24 is obtained. 22 to 24 are cross-sectional perspective views of different cross sections of the plug connector and the jack connector in this state. 22 is a cross section corresponding to FIG. 4, FIG. 23 is a cross section corresponding to FIG. 5, and FIG. 24 is a cross section corresponding to FIG.

  Accordingly, the plug terminal 121 enters the back of the jack terminal 231 while maintaining contact with the jack terminal 231. In addition, the plug terminal 123 enters the back of the jack terminal 233 while maintaining contact with the jack terminal 233.

  At this time, the edge portion 111 of the plug connector 100 also enters further into the groove portion 211 of the jack connector 200, and the slide inclined portion 253 of the slide portion 250 is pushed by the tip portion of the edge portion 111 by pushing the plug connector 100. The slide inclined portion 253 is pushed by the tip end portion of the edge portion 111 in this way, so that the slide portion 250 is slid to the right side in the drawing until the tip end portion of the edge portion 111 reaches the position of the inclined end portion 254 of the slide portion 250. . FIG. 23 shows a state in which the edge portion 111 reaches the inclined end portion 254 and the slide portion 250 is slid rightward in the drawing.

  As a result, the overhanging portion 257 of the slide portion 250 comes into contact with the steeply inclined portion 367 of the button 360, and the slide portion 250 further slides to the right in the drawing, thereby causing the lower protrusion 256 to contact the gently inclined portion 368. Since a force in the right direction in the figure is applied to the gently inclined portion 368, a force is applied in the downward direction to the button 360, and the button 360 is lowered. Accordingly, when the card 340 is pushed by the button 360 and rotates, the holding spring 324 is pushed by the card 340 and the movable plate 322 moves, and the movable contact 321 moves toward the fixed contact 311. When the movable plate 322 moves, the contact state between the movable plate 322 and the bent portion 323a is maintained. By such an operation, the movable contact 321 and the fixed contact 311 of the switch unit 300 come into contact with each other.

  Note that the plug terminal 123 has already been in contact with the jack terminal 233 before the movable contact 321 and the fixed contact 311 are in contact with each other, and the movable contact 321 and the fixed contact 311 of the switch unit come into contact with each other from the jack connector 200. Electric power is supplied to the plug connector 100 side. In addition, the slide part 250 slides further to the right in the state where the button 360 is lowered, and the lower protrusion 256 and the overhang part 257 move on the upper flat part 366 of the button 360 as shown in FIG. For this reason, the upward movement of the button 360 is restricted by the lower protrusion 256 that contacts the upper flat portion 366, and the contact state between the movable contact 321 and the fixed contact 311 is maintained until the slide portion 250 moves to the left in the drawing. Is done.

  Next, a case where power supply is stopped, that is, a case where the plug connector 100 is disconnected from the jack connector 200 will be described. First, when the plug connector 100 is slightly separated from the jack connector 200 from the state shown in FIGS. 22 to 24, the state shown in FIGS. 25 to 27 is obtained. 25 to 27 are cross-sectional perspective views of different sections of the plug connector 100 and the jack connector 200 in a state in which the plug connector 100 is slightly removed from the jack connector 200. FIG. 25 is a cross section corresponding to FIG. 4, FIG. 26 is a cross section corresponding to FIG. 5, and FIG. 27 is a cross section corresponding to FIG. 25 and 26 show a state where the inside of the switch unit 300 is transmitted.

  25 to 27, the plug connector 100 and the jack connector 200 are slightly separated from each other, but the contact between the plug terminal 121 and the jack terminal 231 is maintained, and similarly, the plug terminal 123 and the jack terminal 233 are not contacted with each other. Contact is maintained.

  In this state, as shown in FIG. 26, the front end and the outer portion of the edge portion 111 are in contact with the inclined end portion 254 of the slide portion 250, and the slide portion 250 is at the right side in the drawing. For this reason, the button 360 is in a state of being pressed by the slide portion 250, and the contact between the movable contact 321 and the fixed contact 311 of the switch portion 300 is maintained. Therefore, in the state of FIG. 26 in which the contact between the plug terminal 121 and the jack terminal 231 is maintained and the contact between the plug terminal 123 and the jack terminal 233 is maintained, power is supplied to the plug connector 100 side.

  Thereafter, when the plug connector 100 is further removed from the jack connector 200, the state shown in FIGS. When the edge portion 111 does not come into contact with the inclined end portion 254 by pulling out the plug connector 100, the slide portion 250 starts to return and slide in the left direction in the figure by the spring force. At this time, the protruding portion 257 of the slide portion 250 moves so as to slide on the steeply inclined portion 367 of the button 360. That is, in accordance with the movement of the slide part 250 in the left direction in the figure, first, the state in which the lower protrusion 256 is in contact with the upper flat part 366 is released. However, the state in which the overhanging portion 257 is in contact with the upper flat portion 366 is maintained, and the upward movement of the button 360 remains restricted, so that the button 360 remains on. Thereafter, when the slide portion 250 further moves leftward in the figure, the contact state between the overhang portion 257 and the upper flat portion 366 is also released. Since the steeply inclined portion 367 has a steep slope, when the contact state between the overhang portion 257 and the upper flat portion 366 is released, the button 360 that has been pushed by the overhang portion 257 instantaneously moves upward. To do. As a result, the force that the lower protrusion 256 and the overhanging portion 257 are pushing the button 360 is released, so that the button 360 moves upward and returns to its original position.

  Thus, when the button 360 returns to the original position, the movable contact 321 and the fixed contact 311 of the switch unit 300 are separated. Therefore, although the contact between the plug terminal 123 and the jack terminal 233 is maintained, the supply of electric power to the plug connector 100 side is interrupted.

  Thereafter, when the plug connector 100 and the jack connector 200 are further separated, the state shown in FIGS. 3 to 6 is obtained, and the contact between the plug terminal 121 and the jack terminal 231 and the contact between the plug terminal 123 and the jack terminal 233 are performed. Leave. At this time, before the plug terminal 121 and the jack terminal 231 are disconnected and the plug terminal 123 and the jack terminal 233 are disconnected, the movable contact 321 and the fixed contact 311 in the switch unit 300 are already separated from each other. Therefore, power supply to the plug connector 100 is interrupted. Therefore, no arc is generated when the plug terminal and the jack terminal are disconnected.

  In the present embodiment, since the overhang portion 257 of the slide portion 250 moves the steeply inclined portion 367 of the button 360, when the contact state between the overhang portion 257 and the steeply inclined portion 367 is released, The button 360 is instantaneously moved upward. Since the card 360 is pulled up by the button 360 in response to the button 360 being raised instantaneously, the movable contact 321 is instantly separated from the fixed contact 311 and the supply of power can be cut off instantaneously. In the present embodiment, by changing the inclination angle of the steeply inclined portion 367, the speed at which the power supply is cut off can be adjusted.

  As mentioned above, although the form which concerns on implementation of this invention was demonstrated, the said content does not limit the content of invention.

DESCRIPTION OF SYMBOLS 100 Plug connector 110 Plug housing part 121,122,123 Plug terminal 200 Jack connector 210 Jack housing part 211 Groove parts 231,232,233 Jack terminal 250 Slide part 300 Switch part 310 Fixed part 311 Fixed contact 312 Fixed spring 320 Movable part 321 Movable contact 322 Movable plate 322b, 322c Recessed part 323 Movable spring 323a Bending part 324 Pressing spring 324a, 324b Hook part 330 Base block 340 Card 343 Rotating shaft 344 Protruding part 360 Button 370 Release spring

Claims (4)

A fixed contact;
A movable plate on which movable contacts are installed;
A movable spring,
Have
The movable plate is in contact with a bent portion of the movable spring;
The movable plate is attached to a card;
By moving the card, the movable plate moves while maintaining the state in contact with the movable spring and the bent portion, the state where the fixed contact and the movable contact are in contact with each other, In addition, the switch is characterized by changing from a non-contact state to a contact state. The movable contact is provided near one end of the movable plate,
The switch according to claim 1, wherein the movable plate is in contact with the bent portion in the vicinity of the other end of the movable plate. The card is provided with a holding spring to which the movable plate is attached,
By hooking one end of the movable plate on one end of the pressing spring and hooking the other end of the movable plate on the other end of the pressing spring, the movable plate is attached to the pressing spring. The switch according to claim 1, wherein the switch is attached. A connector comprising the switch according to any one of claims 1 to 3, wherein a connection terminal connected to another connector is provided,
By fitting the connector and the other connector, the card moves, and the fixed contact and the movable contact come into contact with each other.

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