JP5955727B2 - Lighting equipment for saddle riding type vehicles - Google Patents

Description

  The present invention relates to a lighting device in a saddle riding type vehicle that prevents erroneous lighting due to leakage current.

  In Patent Document 1 shown below, a voltage from a battery is applied to a plurality of LEDs of an auxiliary stop lamp, and a transistor as a switching element is connected downstream of the plurality of LEDs. When the switch connected to the battery is turned on, the voltage from the battery is applied to the base of the transistor through the diode and the resistor, so that the transistor is turned on. A circuit configuration is disclosed.

JP-A-62-61853

  However, if moisture such as rain adheres to the switch without sharing the ground of the switch and the ground of the switching element, the voltage applied to the base of the transistor that is the switching element is large due to the ground level. As a result, the transistor is turned on and a plurality of LEDs are lit. On the other hand, if the switch is a waterproof switch, the problem can be solved, but a seal structure or the like is required, and the switch itself becomes large, resulting in a problem that the degree of freedom of layout is limited, or the cost is high Also occurs.

  Therefore, an object of the present invention is to provide a lighting device in a saddle riding type vehicle that prevents erroneous lighting of the lighting device due to the influence of leakage current even if a non-waterproof switch is used.

  The lighting device (100) in the saddle riding type vehicle (10) according to the present invention has the following features.

1st characteristic; it is connected to the battery (102) which is a power supply, the said battery (102), and the lighting device (76) which light-emits light, and the said lighting device (76), and a predetermined voltage is applied. conduction with that, the lighting device and the first semiconductor switch for lighting the (76) (116 a), which is connected to the battery (102), said first conducting a voltage of a predetermined value or more is applied The second semiconductor which stops applying the voltage to the semiconductor switch (116a) and becomes non-conductive when a voltage less than the predetermined value is applied, and applies the predetermined voltage to the first semiconductor switch (116a). a switch (116 b), connected to said battery (102), when turned on in response to a user operation, the application of a voltage to the second semiconductor switch (116 b) is stopped, off in response to operation of the user That when the switch unit for applying a predetermined value or more voltage to the second semiconductor switch (116 b) and (106), provided with, and the second semiconductor switch (116 b) and the switch unit (106) It features a common ground.

Second Feature: The second semiconductor switch (116b) is a transistor, and the switch unit (106) is connected to the base or gate of the transistor.

Third feature: The switch unit (106) and the connection point between the switch unit (106) and the ground and the connection point between the second semiconductor switch (116b) and the ground are close to each other. The second semiconductor switch (116b) is connected to the ground.

Fourth feature: The first semiconductor switch (116a) and the second semiconductor switch (116b) are provided on a substrate (109), and the substrate (109) is a meter panel of the saddle riding type vehicle (10). (68) and the switch (106) is provided on the handle (12).

  Fifth feature: the substrate (109) is arranged on the back side of the meter panel (68).

According to the first feature of the present invention, since the ground of the second semiconductor switch and the switch unit is made common, when the switch unit is realized by a non-waterproof switch, moisture such as raindrops adheres and leakage current is generated. Even if it occurs, it is possible to prevent the first semiconductor switch from becoming conductive due to excessive leakage current (voltage), and it is possible to prevent erroneous lighting of the lamp. Further, the cost can be reduced.

According to the second feature of the present invention, the cost can be further suppressed by using an inexpensive component called a transistor as the second semiconductor switch.

According to the third feature of the present invention, by disposing the connection point between the ground of the switch unit and the ground of the second semiconductor switch close to each other, the distance can be shortened and the resistance to noise can be reduced. Can also be improved.

According to the fourth feature of the present invention, since the board on which the first semiconductor switch and the second semiconductor switch are provided is provided on the meter panel, the waterproofness of the board can be further improved.

  According to the fifth feature of the present invention, since the substrate is disposed on the back side of the meter panel, the dead space can be effectively utilized while maintaining waterproofness.

1 is a left side view of a scooter type motorcycle that is a kind of saddle riding type vehicle. FIG. 2 is a diagram showing an example of a circuit configuration of a lighting device mounted on the motorcycle of FIG. 1. It is a time chart which shows the circuit operation | movement of the lighting device shown in FIG. It is a circuit block diagram of the lighting device of the modification 1.

  DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A lighting device in a saddle riding type vehicle according to the present invention will be described in detail below with reference to the accompanying drawings.

  FIG. 1 is a left side view of a scooter type motorcycle (hereinafter referred to as a motorcycle) 10 which is a kind of saddle riding type vehicle. In addition, regarding the mechanisms or components provided symmetrically one by one on the left and right of the vehicle body, “L” is attached to the reference symbol on the left, and “R” is attached to the reference symbol on the right. Further, unless otherwise specified, in FIG. 1, the front and rear and up and down directions will be described with reference to the arrow direction shown in FIG. .

  The motorcycle 10 includes a front wheel WF that is a steering wheel, a handle 12 that operates the front wheel WF, a body frame 14 that constitutes a vehicle body, a unit swing engine 16 that is a drive source, a rear wheel WR that is a drive wheel, and a seat 18. Have.

  The front wheel WF is provided in front of the vehicle body and is rotatably supported by a pair of front forks 22L and 22R extending from the lower end side of the steering shaft 20. A front fender 24 covering the front wheel WF is attached to the front forks 22L and 22R. The steering shaft 20 has a handle 12 connected to an upper end portion thereof, and a substantially intermediate portion thereof is rotatably held by a head pipe 26 provided on the vehicle body frame 14.

  The handle 12 extends symmetrically in the vehicle width direction with the connection portion with the steering shaft 20 as the center. Grips 28L and 28R gripped by the driver are attached to both ends of the handle 12, and a pair of left and right brake levers 30L and 30R are provided in front of the pair of left and right grips 28L and 28R. The handle 12 is operated by the driver to change the direction of the front wheel WF connected via the steering shaft 20 and the front forks 22L and 22R.

  The body frame 14 extends downward and downward from the head pipe 26 to the bottom of the vehicle body, and also has a front frame 34 that is curved from the bottom of the vehicle body and extends to the support shaft 32 at a substantially middle portion in the longitudinal direction of the vehicle body. The rear frame 36 is supported by 32 and extends to the upper rear side of the vehicle body. A unit swing engine 16 is supported on the vehicle body frame 14 so as to be swingable up and down at a substantially middle portion in the vehicle longitudinal direction. A fuel tank 38 that supplies fuel (gasoline) to the unit swing engine 16 is held by the vehicle body frame 14 at the rear portion of the vehicle body.

  The unit swing engine 16 includes a water-cooled engine 40 with a cylinder axis substantially horizontal, and a belt type that continuously transmits the output of the engine 40 to a rear wheel WR by a transmission belt and a movable pulley (not shown). The continuously variable transmission 42 is configured. The continuously variable transmission 42 drives a movable pulley in accordance with the operation of an electric motor for shifting (not shown) to change the gear ratio steplessly.

  The rear wheel WR is rotatably supported by a rear cushion 44 and a swing arm 46 at the rear of the continuously variable transmission 42, and is rotated and driven by the rotational driving force transmitted from the continuously variable transmission 42. The body is propelled as a wheel.

  The seat 18 is provided from a substantially middle part in the front-rear direction of the vehicle body to the rear of the vehicle body. The seat 18 employs a so-called tandem type seat including a front seat 18a on which a driver is seated and a rear seat 18b on which a passenger sits behind the front seat 18a. A storage box 48 for storing articles is provided below the sheet 18. The storage box 48 also serves as a lid that covers the upper surface of the sheet 18, and the internal space is exposed by pulling the sheet 18 forward.

  A fuel tank 38 is disposed behind the storage box 48, and an air cleaner 50 for cleaning the exhaust gas of the engine 40 is disposed below the storage box 48.

  In the motorcycle 10, a main stand 52 is rotatably supported on the vehicle body frame 14 below the unit swing engine 16. The main stand 52 is stored so as to be substantially parallel to the road surface during traveling, and is erected so as to be substantially orthogonal to the road surface during parking so as to float the rear wheel WR and to make the motorcycle 10 independent.

  In the motorcycle 10, a vehicle body cover 54 that constitutes a design surface (appearance) of the vehicle body in the longitudinal direction of the vehicle body is attached to the vehicle body frame 14, the steering shaft 20, and the like. The vehicle body cover 54 is formed of, for example, a polymer material such as acrylonitrile, butadiene, styrene (ABS), fiber reinforced plastic (FRP), or polypropylene (PP). Each part of the vehicle body such as the fuel tank 38 is covered.

  The vehicle body cover 54 forms a step floor 60 a behind the front cover 56 that covers the front portion of the steering shaft 20 and the top of the front wheel WF, a handle cover 58 that covers the handle 12 above the front cover 56, and the front cover 56. A floor center cover 60, a body cover 62 disposed below the seat 18 and connected to the floor center cover 60 and extending rearward, and a rear cover 64 connected to the rear of the body cover 62 are provided. The front cover 56 is provided with a pair of front blinkers 66L and 66R having a blinking direction indicating function.

  The handle cover 58 covers the upper part of the steering shaft 20 and the central part of the handle 12, and a meter panel 68 is provided on the rear upper surface thereof for displaying the speed and the like. An opening 70 is formed in front of the handle cover 58, and a headlight 72 is attached to the opening 70.

  The step floor 60a of the floor center cover 60 is formed in a flat shape so that the driver's legs can be put on the vehicle while traveling. The rear cover 64 is attached with a rear fender 74 that covers the rear wheel WR from the rear and on which a license plate and the like are disposed. Behind the rear cover 64, a tail lamp 76, which is a light emitting diode, and a pair of rear blinkers 78L and 78R are disposed. The tail lamp 76 functioning as a lighting device is turned on and off in response to a driver's brake operation. On the other hand, the pair of rear winkers 78L and 78R has a blinking direction indicating function like the pair of front winkers 66L and 66R.

  FIG. 2 is a circuit configuration diagram of the lighting device 100 mounted on the motorcycle 10 of FIG. The lighting device 100 includes a battery 102 as a power source, an ignition switch 104, a switch unit 106 that is turned on when the brake levers 30L and 30R are operated, and a control unit circuit 108. When the switch unit 106 is turned on, the control unit circuit 108 uses the power from the battery 102 that is a power source to light the tail lamp 76 that is a load. The ignition switch 104 is interposed between the battery 102 and the control unit circuit 108. The switch unit 106 is provided on the handle 12.

  The control unit circuit 108 is formed on a substrate 109, and the substrate 109 is disposed on the back side of the meter panel 68 (see FIG. 1). The substrate 109 may be provided inside the meter panel 68 or inside the meter panel 68 and inside the handle cover 58. The control unit circuit 108, the battery 102, the ignition switch 104, the switch unit 106, and the tail lamp 76 are connected via a coupler (not shown).

  The control unit circuit 108 includes a power supply circuit 110, a first resistor 112, a second resistor 114, a first semiconductor switch 116 a, a second semiconductor switch (semiconductor switch) 116 b, and a microcomputer 118. Is provided. The first semiconductor switch 116a and the second semiconductor switch 116b are NPN bipolar transistors.

  The power supply circuit 110 is connected to the battery 102 via the ignition switch 104. The power supply circuit 110 removes noise and stabilizes the voltage supplied from the battery 102. A first resistor 112 and a switch unit 106 connected in series are interposed between the power supply circuit 110 and the first ground GND1, and the first resistor 112 is on the power supply circuit 110 side, and the switch unit 106 is One ground is connected to GND1 side.

  A second resistor 114 and a second semiconductor switch 116b are interposed between the power supply circuit 110 and the first ground GND1, and the second resistor 114 is provided on the power supply circuit 110 side, and the second semiconductor switch 116b is provided. It is connected to the first ground GND1 side. The collector of the second semiconductor switch 116b is connected to the second resistor 114, the emitter is connected to the first ground GND1, and the base is connected to the switch section 106 side of the first resistor 112. The first ground GND1 is connected to the control unit circuit 108 via the coupler. In addition, the switch unit 106 and the second semiconductor switch 116b are arranged such that the connection point between the switch unit 106 and the first ground GND1 and the connection point between the second semiconductor switch 116b and the first ground GND1 are close to each other. It is connected to the ground GND1.

  The power supply circuit 110 and the first semiconductor switch 116a are connected via a tail lamp 76, and the first semiconductor switch 116a is connected to the second ground GND2. The collector of the first semiconductor switch 116a is connected to the cathode of the tail lamp 76, the emitter is connected to the second ground GND2, and the base is connected to the collector of the second semiconductor switch 116b via the microcomputer 118. Note that the anode of the tail lamp 76 is connected to the power supply circuit 110.

  FIG. 3 is a time chart showing the circuit operation of the lighting apparatus 100 shown in FIG. 3 indicates the current flowing through the switch unit 106, the second base potential indicates the base potential of the second semiconductor switch 116b, and the first base potential indicates the base of the first semiconductor switch 116a. The load current indicates the current flowing through the tail lamp 76.

  When the ignition switch 104 is turned on, the voltage of the battery 102 is applied to the base of the second semiconductor switch 116b, and the second semiconductor switch 116b is turned on (conductive state). When the second semiconductor switch 116b is turned on, a current flows through the route of the battery 102 → the ignition switch 104 → the power supply circuit 110 → the second resistor 114 → the second semiconductor switch 116b → the first ground GND1. Therefore, the voltage of the battery 102 is not applied to the base of the first semiconductor switch 116a, the first semiconductor switch 116a is turned off, and no current flows through the tail lamp 76 (the tail lamp 76 is not lit).

  Thereafter, when the switch unit 106 is turned on by the driver's operation of the brake levers 30L and 30R, the route of the battery 102 → the ignition switch 104 → the power supply circuit 110 → the first resistor 112 → the switch unit 106 → the first ground GND1. Current flows. Therefore, the voltage of the battery 102 is not applied to the base of the second semiconductor switch 116b, and the second semiconductor switch 116b is turned off. When the second semiconductor switch 116b is turned off, the voltage of the battery 102 is applied to the base of the first semiconductor switch 116a, the first semiconductor switch 116a is turned on (conductive state), a current flows through the tail lamp 76, and the tail lamp 76 is turned on. Light.

  The microcomputer 118 provided between the base of the first semiconductor switch 116a and the collector of the second semiconductor switch 116b has a function as a filter, and the base of the first semiconductor switch 116a is provided at a predetermined cycle. When the potential, that is, the potential of the collector of the second semiconductor switch 116b is read and it is determined that the potential is larger than the threshold value continuously (three times), the input potential is converted into the base of the first semiconductor switch 116a. To output the first semiconductor switch 116a. Thereby, noise resistance performance improves.

  Thereafter, when the driver releases the operation of the brake levers 30L and 30R and the switch unit 106 is turned off, the voltage of the battery 102 is applied to the base of the second semiconductor switch 116b, and the second semiconductor switch 116b is turned on. . When the second semiconductor switch 116b is turned on, a current flows through the route of the battery 102 → the ignition switch 104 → the power supply circuit 110 → the second resistor 114 → the second semiconductor switch 116b → the first ground GND1. Therefore, the voltage of the battery 102 is not applied to the base of the first semiconductor switch 116a, the first semiconductor switch 116a is turned off, and no current flows through the tail lamp 76 (lighting of the tail lamp 76 ends). When the ignition switch 104 is turned off, the voltage supply from the battery 102 to the control unit circuit 108 ends.

  Here, when the switch unit 106 is turned off and a leak current is generated due to moisture such as raindrops adhering to the switch unit 106, the second semiconductor switch 116b is turned off by the leak current, and the tail lamp 76 is turned off. May light up. However, in the present embodiment, the ground connected to the switch unit 106 and the ground connected to the second semiconductor switch 116b are shared, that is, the switch unit 106 and the second ground are connected to the same first ground GND1. Since the two semiconductor switches 116b are connected, it is possible to prevent the second semiconductor switch 116b from being turned on even when a leakage current is generated in the switch unit 106.

  More specifically, the second semiconductor switch 116b has a characteristic that it is turned on when the potential difference (voltage) between the base and the emitter is equal to or greater than a predetermined value, and is turned off when the potential difference (voltage) is less than the predetermined value. Thus, since the voltage applied to the base of the second semiconductor switch 116b is clamped to the potential difference between the base and the emitter, the base voltage cannot exceed a predetermined value even when a leakage current occurs. Absent.

  On the other hand, when the ground connected to the switch unit 106 and the ground connected to the second semiconductor switch 116b are different, the ground level is different, so the voltage applied to the base of the second semiconductor switch 116b is It cannot be clamped to the potential difference between the base and the emitter. When a leak current occurs, an excessive voltage (a voltage equal to or higher than a predetermined value) is applied to the base of the second semiconductor switch 116b, and the second semiconductor switch 116b is turned on.

  As described above, since the ground of the second semiconductor switch 116b and the switch unit 106 is made common, when the switch unit 106 is realized by a non-waterproof switch, moisture such as raindrops adheres and leak current is generated. However, it is possible to prevent the first semiconductor switch 116a from conducting due to an excessive voltage due to the leakage current, and it is possible to prevent the tail lamp 76 from being erroneously turned on. Moreover, the cost can be reduced by providing a non-waterproof switch.

  Since inexpensive components such as transistors are used as the first semiconductor switch 116a and the second semiconductor switch 116b, the cost can be further reduced. Since the connection point between the switch unit 106 and the first ground GND1 and the connection point between the second semiconductor switch 116b and the first ground GND1 can be arranged close to each other, the distance can be shortened. Can also be improved.

  Since the substrate 109 provided with the first semiconductor switch 116a and the second semiconductor switch 116b is provided on the meter panel 68, the waterproof property of the substrate 109 can be further improved. Further, by disposing the substrate 109 on the back side of the meter panel 68, it is possible to effectively use the dead space while maintaining waterproofness.

(Modification) The above embodiment may be modified as follows.
(Modification 1) In the above embodiment, the ground to which the second semiconductor switch 116b is connected and the ground to which the switch unit 106 is connected are used as the first ground GND1, and is connected to the first semiconductor switch 116a. The second ground GND2 is different from the first ground GND1, but in the first modification, the first semiconductor switch 116a, the second semiconductor switch 116b, and the switch unit 106 are connected as shown in FIG. A common ground may be used. That is, the first semiconductor switch 116a, the second semiconductor switch 116b, and the switch unit 106 may be connected to one ground GND.

  (Modification 2) In the above embodiment and Modification 1, the tail lamp 76 has been described as an example of the lighting device. The headlight 72 may be used. In short, any device having a light emitting element that emits light may be used.

  (Modification 3) In the above embodiment and Modification 1 or 2, NPN bipolar transistors are used as the first semiconductor switch 116a and the second semiconductor switch 116b, but an FET (Field Effect Transistor) or the like is used. A transistor may be used. In the case of using an FET, the emitters of the first semiconductor switch 116a and the second semiconductor switch 116b are the source, the collector is the drain, and the base is the gate.

  As mentioned above, although this invention was demonstrated using suitable embodiment, the technical scope of this invention is not limited to the range of description of the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above embodiment. It is apparent from the description of the scope of claims that embodiments with such changes or improvements can be included in the technical scope of the present invention. In addition, the reference numerals in parentheses described in the claims are appended to the reference numerals in the accompanying drawings for easy understanding of the present invention. It should not be construed as limited.

DESCRIPTION OF SYMBOLS 10 ... Scooter type motorcycle 12 ... Handle 14 ... Body frame 68 ... Meter panel 100 ... Lighting device 102 ... Battery 104 ... Ignition switch 106 ... Switch part 108 ... Control unit circuit 109 ... Board | substrate 110 ... Power supply circuit 112 ... 1st resistance 114: second resistor 116a: first semiconductor switch 116b: second semiconductor switch 118: microcomputer

Claims (5)

A battery (102) as a power source;
A lamp (76) connected to the battery (102) and emitting light;
Connected to said lighting device (76), conducts a predetermined voltage is applied, a first semiconductor switch for lighting the lighting device of (76) (116 a),
When connected to the battery (102) and applied with a voltage equal to or higher than a predetermined value, it is turned on to stop applying voltage to the first semiconductor switch (116a), and when a voltage lower than the predetermined value is applied. A second semiconductor switch (116b) that becomes non-conductive and applies the predetermined voltage to the first semiconductor switch (116a);
When connected to the battery (102) and turned on in response to a user operation, the application of voltage to the second semiconductor switch (116b) is stopped, and when turned off in response to a user operation, the second semiconductor A switch unit (106) for applying a voltage equal to or higher than the predetermined value to the switch (116b);
Equipped with a,
Before SL lighting apparatus apparatus in a saddle-ride type vehicle (10), characterized in that the switch unit and the second semiconductor switch (116 b) of the ground (106) in common (100). In the lighting device (100) of the saddle riding type vehicle (10) according to claim 1,
The second semiconductor switch (116b) is a transistor, and the switch unit (106) is connected to a base or a gate of the transistor. ). In the lighting device (100) in the saddle riding type vehicle (10) according to claim 1 or 2,
As the connection point between the ground of the second semiconductor switch and the connection point between the ground of the switch unit (106) (116 b) is, toward each other, the switch unit (106) and said second semiconductor switch (116b) is connected to the ground. The lighting device (100) in the saddle riding type vehicle (10). In the lighting device (100) in the saddle riding type vehicle (10) according to any one of claims 1 to 3,
The first semiconductor switch (116a) and the second semiconductor switch (116b) are provided on a substrate (109), and the substrate (109) is provided on a meter panel (68) of the saddle riding type vehicle (10). In addition, the lighting device (100) in the saddle riding type vehicle (10), wherein the switch portion (106) is provided on the handle (12). In the lighting device (100) in the saddle riding type vehicle (10) according to claim 4,
The board (109) is disposed on the back side of the meter panel (68). The lighting device (100) in the saddle riding type vehicle (10).

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