JP3190270U - Information output device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an information output device used in a vehicle, which eliminates wiring for power supply and signal transmission, is easy to handle and has a good appearance, and a base station of the information output device. An information output device 1 includes a main body 10 and a base station 30. The main body has a first battery 11 and an output unit. The first battery is a rechargeable battery. The output unit outputs information. The base station is fixed to the vehicle and holds the main body in a detachable state. The base station has a power generation unit 31 that converts at least one of light, heat, wind, and vibration into electrical energy. The first battery is charged based on the electric energy obtained by the power generation unit without using the electric energy charged in the vehicle battery. The main body does not use the electric energy charged in the battery of the vehicle, but drives based on the electric energy obtained in the power generation unit or the electric energy charged in the first battery. [Selection diagram] Fig. 3

Description

  The present invention relates to an information output device.

Information output devices such as a car navigation system that displays the position of the vehicle and the route to the destination on a map have been proposed.
There are two types of car navigation systems from the perspective of mounting the part that includes the monitor. One is an in-dash mounting type that is installed in a dashboard to which a car audio is normally mounted. The other is an on-dash installation type that is installed on the dashboard.
In either case, to supply power to the car navigation system, at least the battery line through which current always flows and the accessory power line through which current flows only when the vehicle accessory switch is turned on It is necessary to wire a power line including one side and a ground line.
Patent Document 1 discloses an on-dash mounting type car navigation system.

JP 2007-69828 A

However, when the on-dash mounting type car navigation system shown in Patent Document 1 is mounted on a vehicle, it is necessary to route and wire the wire for power supply from the inside of the engine room or the dashboard. Skill is required.
In order to simplify the wiring process, it is conceivable to route these wires from the cigarette lighter socket, but in this case, the wire from the cigarette lighter socket to the car navigation system is visible and the wiring must be done neatly. I can not.

  Therefore, an object of the present invention is to provide an information output device or a base station of the information output device.

An information output device according to the present invention includes a main body having a rechargeable first battery, an output unit for outputting information, and a base station that is fixed to the vehicle and holds the main body in a detachable state. The base station has a power generation unit that converts at least one of light, heat, wind, and vibration into electric energy, and charging the first battery does not use the electric energy charged in the vehicle battery. The main body is charged with the electric energy supplied from the base station or the first battery without using the electric energy charged in the battery of the vehicle. It is driven based on electrical energy, and the main unit is the base station as a means for confirming the connection between the main unit and the base station. Switch turned on when mounted is provided on the side of the base station, the power supply from the base station to the main part is performed after confirming the connection state by the confirmation means, and conducted via a magnetic coupling.
Preferably, the vehicle further includes a first detection unit that detects an on / off state of an accessory power supply of a vehicle in which the base station is installed, and a transmission unit that transmits a detection result by the first detection unit as first information, the base station and the main body unit At least one has a receiving unit that receives the first information from the transmitting unit, and the main unit has a control unit that controls the on / off state of the main unit based on the first information, and the first detecting unit Is attached to a cigarette lighter socket provided in the vehicle, and detects a power supply state to the cigarette lighter socket as an on / off state of the accessory power supply.
The base station of the information output device according to the present invention includes a power generation unit that converts at least one of light, heat, wind, and vibration into electric energy, and the base station is attached to the vehicle and is detachable. The main body has a rechargeable first battery and an output unit for outputting information. Charging to the first battery uses electric energy charged in the vehicle battery. The main body is not used with the electric energy charged in the battery of the vehicle, but is charged with the electric energy supplied from the base station or the first battery. It is driven based on the electrical energy, and the body portion is used as a means for confirming the connection state between the body portion and the base station. A switch that is turned on when attached to the station is provided on the base station side, and power supply from the base station to the main body is performed after confirmation of the connection state by the confirmation means, and is performed via magnetic coupling. Is called.

The objects and advantages of the present invention will be better understood from the following description with reference to the accompanying drawings.
It is a perspective view of the information output device in the state where the main-body part and base station in 1st-4th embodiment left | separated. It is a perspective view of the information output device in the state where the main-body part in the 1st-4th embodiment was attached to the base station. It is a block diagram of the main-body part and base station in 1st Embodiment. It is a flowchart which shows the operation | movement procedure of the electric power supply control of a 1st control part. It is a flowchart which shows the operation | movement procedure of the electric power supply control of a 2nd control part. It is a block diagram of the main-body part and base station in 2nd Embodiment. It is a block diagram of the main-body part and base station in 3rd Embodiment. It is a block diagram of the main-body part and base station in 4th Embodiment. It is a block diagram of the base station containing the main-body part and transformer in 1st Embodiment.

The present invention will be described with reference to the following embodiments and drawings.
A first embodiment will be described. The car navigation system (information output device) 1 according to the first embodiment includes a main body 10 and a base station (cradle) 30 (see FIG. 1).
The base station 30 is fixed on the dashboard of the vehicle, and holds the main body 10 in a detachable state via a fixture (not shown) (see FIG. 2).

  In addition, the attachment position of the base station 30 will not be restricted on a dashboard, if the electric power generation part 31 mentioned later can be arrange | positioned in the position which can receive sunlight via a windshield. For example, the base station 30 may be attached to a windshield, a sun visor, a rearview mirror, and an air conditioner vent.

  The main body 10 includes a first battery 11, a vehicle position detector 13, a monitor 17, and a first control unit 29. The base station 30 includes a second battery 33, a power generation unit 31, and a cooling unit. (Cooler) 35 and a second control unit 39 (see FIG. 3).

The configuration of the main body unit 10 will be described.
The first battery 11 is a rechargeable storage battery, and charging to the first battery 11 is performed based on electrical energy obtained by the power generation unit 31 described later or electrical energy charged in the second battery 33. .
The navigation system 1 including the main operation of the main body 10 such as the display of the monitor 17 when the main body 10 is not attached to the base station 30 or the like. Used for electrical operation). The driving of the main body 10 refers to the electrical operation of the car navigation system 1 including the main operation of the main body 10 such as the display on the monitor 17.
The first battery 11 may be charged from an AC power source (not shown) while being removed from the base station 30.

The own vehicle position detection unit 13 uses latitude-longitude information such as cell-based positioning based on radio wave information from a single mobile phone base station, multi-base station positioning based on radio wave information from a plurality of mobile phone base stations, and GPS positioning. It is a device that acquires.
The monitor 17 displays a map including the position of the vehicle including the car navigation system 1 and the route to the destination. The position of the vehicle is specified based on the latitude / longitude information provided from the vehicle position detection unit 13.

The first control unit 29 is a control device such as a CPU, and controls each unit constituting the main body unit 10.
In particular, the first control unit 29 checks whether or not power is supplied from the base station 30 (see step S11 in FIG. 4).
When electric power is supplied from the base station 30 to the main body 10, each part of the main body 10 is driven by the electric power supplied from the base station 30 (see step S <b> 12 in FIG. 4).
When power is not supplied from the base station 30 to the main body 10, each part of the main body 10 is driven by the power supplied from the first battery 11 (see step S <b> 13 in FIG. 4).
In addition, when power is supplied from the base station 30 to the main body unit 10, the first control unit 29 confirms the charging state of the first battery 11.
When the first battery 11 needs to be charged, the first control unit 29 charges the first battery 11 based on the electric energy obtained by the power generation unit 31 or the electric energy charged in the second battery 33. I do.

Next, the configuration of the base station 30 will be described.
The power generation unit 31 is a solar cell that uses the photovoltaic effect to convert light energy into electrical energy (performs solar power generation). The power generation unit 31 is provided on the upper surface of the base station 30 (see FIG. 1) or at a position where sunlight can be received through the windshield. For example, the power generation unit 31 may be provided on the surface opposite to the position where the main body 10 of the base station 30 is attached.
For this reason, the power generation unit 31 generates electromotive force based on the received light (receives power) while receiving sunlight such as daytime. That is, the power generation unit 31 converts light energy into electrical energy during the daytime.

When the main body 10 is attached to the base station 30, the electrical energy converted by the power generation unit 31 is preferentially used for charging the first battery 11 of the main body 10 and driving the main body 10. (See step S33 in FIG. 5), and is also used for charging the second battery 33 of the base station 30.
Moreover, when the main-body part 10 is not attached to the base station 30, the electrical energy converted by the electric power generation part 31 is used for the charge to the 2nd battery 33 (refer FIG.5 S34).

The second battery 33 is a rechargeable storage battery, and charging to the second battery 33 is performed based on electrical energy obtained by the power generation unit 31 described later.
The electric energy charged in the second battery 33 is used for charging the first battery 11 and driving the main body 10 when the power generation unit 31 does not generate electromotive force without receiving sunlight, such as at night. The

When the vehicle including the car navigation system 1 is not driven, the car navigation system 1 is not used, and the main body 10 is made removable from the base station 30 to prevent theft.
In this case, the electric energy obtained by the power generation unit 31 cannot be used for charging the first battery 11 of the main body unit 10, but is used for charging the second battery 33 provided in the base station 30. I can do it.
From the viewpoint of reducing the weight and size of the main body 10, it is desirable that the first battery 11 mounted on the main body 10 is as light and small as possible.
As the first battery 11 becomes smaller, the storage capacity of the first battery 11 becomes smaller. However, since the second battery 33 provided in the base station 30 can also be used to drive the main body 10, it is difficult for the battery to run out.
The second battery 33 is provided in the base station 30 fixed on the dashboard and does not need to be carried. Therefore, a battery having a larger storage capacity than the first battery 11 can be used.

The cooling unit 35 is a cooling device such as an air cooling fan or a Peltier element, and is driven based on the electric energy converted by the power generation unit 31 to cool the second battery 33.
The main body 10 can be removed from the base station 30. Therefore, when the main body 10 is detached from the base station 30, the first battery 11 included in the main body 10 can be cooled.
On the other hand, the base station 30 including the second battery 33 is fixed on the dashboard of the vehicle, receives sunlight, and the second battery 33 may become high temperature.
However, in the first embodiment, the second battery 33 can be cooled by the cooling unit 35, and deterioration of the second battery 33 due to high temperature can be prevented.
In addition, although electric power is required for the drive of the cooling unit 35, the situation where cooling by the cooling unit 35 is necessary occurs when sunlight is received for a long time.
In this case, since sufficient electric energy is obtained by the power generation unit 31, it is not necessary to consume electric power based on the electric energy charged in the second battery 33 for driving the cooling unit 35.

The second control unit 39 is a control device such as a CPU, and controls each unit constituting the base station 30.
In particular, the second control unit 39 controls power supply to the main unit 10 when the main unit 10 is connected to the base station 30 (see steps S33 and S38 in FIG. 5).
Moreover, the 2nd control part 39 drives the cooling part 35, when the 2nd battery 33 is a high temperature state (refer step S36 of FIG. 5).
In addition, when power generation by the power generation unit 31 is performed, the second control unit 39 confirms the charging state of the second battery 33.
When the second battery 33 needs to be charged, the second control unit 39 charges the second battery 33 based on the electric energy obtained by the power generation unit 31 (see step S34 in FIG. 5).

Next, the operation procedure of the power supply control of the first control unit 29 will be described using the flowchart of FIG.
This control is performed for a certain period of time (for example, 1 ms) while the first control unit 29 is driven based on the electric energy charged in the first battery 11 or the second battery 33 or the electric energy generated by the power generation unit 31. Done every time.
In step S <b> 11, the first control unit 29 determines whether power is being supplied from the base station 30 to the main body unit 10.

The determination as to whether or not power is being supplied from the base station 30 to the main body 10 is made based on, for example, determination as to whether or not current is flowing through a terminal connecting the main body 10 and the base station 30.
When the main body 10 is not held by the base station 30, no current flows through the connection terminal.
When the power generation unit 31 of the base station 30 is not generating power and the second battery 33 is not charged (empty), no current flows through the connection terminal.

When the first control unit 29 determines that power is supplied from the base station 30 to the main body unit 10, the process proceeds to step S12. When it is determined that power is not supplied, the process proceeds to step S13.
In step S <b> 12, the first control unit 29 supplies power to each unit of the main body unit 10 based on the electrical energy generated by the power generation unit 31 or the electrical energy charged in the second battery 33.
Further, the first control unit 29 charges the first battery 11 in accordance with the operation state of the main body unit 10 and the charging state of the first battery 11.
In step S <b> 13, the first control unit 29 supplies power to each unit of the main body unit 10 based on the electrical energy charged in the first battery 11.

The power supply from the base station 30 to the main body 10 is performed via the first terminal of the concave portion 10 a provided in the main body 10 and the second terminal of the convex portion 30 a provided in the base station 30.
When the main body 10 is attached to the base station 30, the concave portion 10a and the convex portion 30a are engaged with each other, and the terminals contact each other, whereby the first terminal of the concave portion 10a and the second terminal of the convex portion 30a are electrically connected. Are connected to each other, and power can be supplied from the base station 30 to the main body 10 via the concave portion 10a and the convex portion 30a.
When the main body 10 is attached to the base station 30 by the engagement between the concave portion 10a and the convex portion 30a, electrical contact is reliably performed.

In addition, a door (flapper) 10b is provided in front of the recess 10a. The door part 10b opens by insertion of the convex part 30a when the concave part 10a engages with the convex part 30a, and closes when not engaged.
At the time of non-engagement, the first terminal provided inside the recess 10a is hidden by the closed door portion 10b, so that it is possible to prevent entry of dust or the like that causes contact failure.

Next, the operation procedure of the power supply control of the second control unit 39 will be described using the flowchart of FIG.
This control is performed at regular intervals (for example, 1 ms) while the second control unit 29 is driven based on the electrical energy charged in the second battery 33 or the electrical energy generated by the power generation unit 31.
In step S31, the second control unit 39 determines whether power generation by the power generation unit 31 is being performed.
When the second control unit 39 determines that power generation by the power generation unit 31 is being performed, the process proceeds to step S32, and when it is determined that power generation by the power generation unit 31 is not being performed, the process proceeds to step S37. .

In step S <b> 32, the second control unit 39 determines whether the main body unit 10 is attached to the base station 30.
The determination of whether or not the main body 10 is attached to the base station 30 is, for example, the determination of whether or not current is flowing through the first terminal and the second terminal that connect the main body 10 and the base station 30. Based on.
If the second control unit 39 determines that the main body unit 10 is attached to the base station 30, the process proceeds to step S33. If the second control unit 39 determines that the main body unit 10 is not attached to the base station 30, the step S34 is performed. Proceed to
In step S <b> 33, the second control unit 39 supplies power to the main body unit 10 based on the electric energy generated by the power generation unit 31.
At this time, the second battery 33 may be charged according to the operating state of the main body 10 and the charged state of the second battery 33.

In step S <b> 34, the second control unit 39 confirms the state of charge of the second battery 33.
When the second battery 33 needs to be charged, the second control unit 39 charges the second battery based on the electric energy generated by the power generation unit 31.

In step S35, the second control unit 39 determines whether or not the second battery 33 is in a high temperature state based on information from a temperature sensor (not shown) or the like.
If the second control unit 39 determines that the second battery 33 is in a high temperature state, the process proceeds to step S36. If the second control unit 39 determines that the second battery 33 is not in a high temperature state, the procedure ends.
In step S <b> 36, the second control unit 39 drives the cooling unit 35 to cool the second battery 33.

In step S <b> 37, the second control unit 39 determines whether the main body unit 10 is attached to the base station 30.
If the second control unit 39 determines that the main unit 10 is attached to the base station 30, the process proceeds to step S38. If the second control unit 39 determines that the main unit 10 is not attached to the base station 30, the procedure is performed. finish.
In step S <b> 38, the second control unit 39 supplies power to the main body unit 10 based on the electric energy charged in the second battery 33.

In the first embodiment, the main body 10 is driven based on the electrical energy generated by the power generation unit 31, the electrical energy charged in the second battery 33, or the electrical energy charged in the first battery 11.
Electric energy charged in the vehicle battery is not required for driving the main body 10.
For this reason, the possibility that the power consumed by the navigation system 1 affects the electric system of the vehicle can be reduced.
Further, it is not necessary to route the power line from the vehicle battery or the like to the dashboard and to connect to the main body 10 or the base station 30. The power line here includes a battery line through which current always flows and an accessory power line through which current flows only when the accessory switch of the vehicle is turned on.
For this reason, the installation of the navigation system 1 can be simplified.
In addition, the number of wire rods related to the navigation system 1 can be reduced on the dashboard, and the appearance after the navigation system 1 is attached can be improved as compared with the form in which a plurality of wire rods are visible on the dashboard.

Further, the circuit of the navigation system 1 can be configured without considering the voltage from the vehicle battery.
Specifically, an electronic component such as a DC-DC converter that transforms the voltage 24V or 12V of the vehicle battery into a voltage (about 3 to 5V) suitable for driving the navigation system 1 is omitted, and the main body 10 In addition, the configuration of the base station 30 can be simplified.

In addition, since the power generation unit 31 is disposed in the base station 30 that is separate from the main body unit 10, the main body unit 10 is not increased by providing the power generation unit 31.
In addition, since the first battery 11 is provided in the main body 10, the main body 10 can be used even if the main body 10 is detached from the base station 30.
Accordingly, the main body unit 10 includes the first battery 11 and outputs information upon receiving power supply from the base station 30 when connected, and outputs information based on electric energy charged in the first battery when disconnected. Any form may be used.
For this reason, not only a navigation system but also a portable music player that outputs sound such as music, a monitor that outputs video from a TV, a radar detector, and the like may be used.

The power supply from the base station 30 to the main body 10 may be performed by magnetic coupling via transformers Tr1 and Tr2 (see FIG. 9) provided on both sides.
In this case, confirmation means for confirming the connection state between the main body 10 and the base station 30 and control means for supplying power after confirming the connection state are required. However, electrical connection terminals (first terminal and second terminal) are not required between the main body 10 and the base station 30.
For example, as the confirmation means, a switch SW1 that is turned on when the main body 10 is attached to the base station 30 is provided in the base station 30. When the switch SW1 is in the ON state, the second control unit 39 supplies power to the transformer Tr2 of the base station 30 as the control means.

Next, a second embodiment will be described.
In the second embodiment, the main body unit 10 is further provided with a vibration detection unit (second detection unit) 12. On / off control of the main body 10 is performed based on an output signal from the vibration detector 12. Hereinafter, a description will be given focusing on differences from the first embodiment (see FIG. 6).

The vibration detection unit 12 in the second embodiment is an acceleration sensor, and detects gravitational acceleration components in two or three directions orthogonal to each other.
The first control unit 29 determines the driving state of the vehicle based on the gravitational acceleration component in each direction.
Specifically, when the engine is operating, the vehicle vibrates based on the operation of the engine, so that the output value of the gravitational acceleration component in each direction varies with time.
For this reason, the 1st control part 29 judges that the engine has stopped when the fluctuation range per unit time of the output value regarding the gravitational acceleration in each direction is small.
In this case, the first control unit 29 turns off the main operation of the main body unit 10 such as display on the monitor 17.
The first control unit 29 determines that the engine is operating when the fluctuation range per unit time of the output value related to gravity acceleration in at least one direction is large.
In this case, the first control unit 29 turns on the main operation of the main body unit 10.
Note that operations that are always performed, such as the clock function and the power supply control illustrated in FIG. 4, are maintained in the on state regardless of the output from the vibration detection unit 12.

When the main body 10 is held by a user, vibration due to camera shake is transmitted to the main body 10, and the fluctuation range per unit time of the output value related to gravitational acceleration increases.
However, the vibration pattern due to camera shake is different from the vibration pattern of the vehicle due to the operation of the engine.
For this reason, if the first control unit 29 stores the fluctuation range per unit time corresponding to these vibration patterns, the difference between vibration due to camera shake and vibration due to engine operation can be specified. Therefore, the first control unit 29 can determine the on / off state of the engine by distinguishing it from vibrations caused by engine operation and other vibrations such as camera shake.

In the first embodiment, the main body 10 and the base station 30 are not electrically connected to the vehicle battery and do not use the electrical energy charged in the vehicle battery. For this reason, the main body 10 and the base station 30 cannot electrically detect the on / off state of the engine. Therefore, in addition to the on / off control of the engine, the user needs to manually perform the on / off control of the main body 10 separately.
In the second embodiment, the vibration detection unit 12 detects the vibration state of the vehicle, and the first control unit 29 grasps the on / off state of the engine. For this reason, it becomes possible to automatically perform on / off control of the main operation of the main body 10 in accordance with the on / off state of the engine.

  The vibration detection unit 12 is not limited to an acceleration sensor, and may be any sensor that can detect the vibration state of the engine. For example, the vibration detection unit 12 may be an angular velocity sensor that detects angular velocities about two or three orthogonal axes. In this case, the 1st control part 29 grasps | ascertains the on-off state of an engine based on the fluctuation range per unit time of the output value regarding angular velocity.

In the second embodiment, the vibration detection unit 12 is provided in the main body unit 10, but the vibration detection unit 12 is provided in the base station 30, and the second control unit 39 vibrates in the first control unit 29. The form which transmits the information regarding the gravity acceleration obtained by the detection part 12 may be sufficient.
In this case, the line connecting the main unit 10 and the base station 30 is not only a power supply line for supplying power, but also a signal for transmitting information on gravitational acceleration from the second control unit 39 to the first control unit 29. A line is also provided.

  Next, a third embodiment will be described. In 3rd Embodiment, it replaces with the vibration detection part (2nd detection part) 12 provided in the main-body part 10, and the electric current detection part (1st detection part) 40 is used for the detection of an engine on-off state (FIG. 7). Hereinafter, a description will be given focusing on differences from the second embodiment.

The current detection unit 40 according to the third embodiment is attached to a cigarette lighter socket of a vehicle and detects a current flowing through the cigarette lighter socket (whether power is supplied through the cigarette lighter socket).
When the current detection unit 40 detects the current flowing through the cigarette lighter socket, the transmitter 41 provided adjacently sends a constant signal to the receiver 16 provided in the main body 10. Send as information.
Bluetooth (registered trademark) or the like can be considered as a communication means from the transmission unit 41 to the reception unit 16.
When the current detector 40 does not detect the current flowing through the cigarette lighter socket, the transmitter 41 does not perform signal transmission.

  Note that both the current detection unit 40 that performs current detection and the transmission unit 41 that performs first information transmission are driven based on electric power supplied from the battery of the vehicle via the cigarette lighter socket. Therefore, when power is not supplied through the cigarette lighter socket, neither the current detection unit 40 nor the transmission unit 41 consumes power.

While the receiving unit 16 is not receiving the first information, the first control unit 29 determines that the accessory power supply of the vehicle is turned off, and performs the main operation of the main body unit 10 such as display on the monitor 17. Turn off.
Note that operations that are always performed, such as the reception of the first information, the clock function, and the power supply control illustrated in FIG. 4, are turned on regardless of the detection result in the current detection unit 40.

The current flowing through the cigarette lighter socket usually corresponds to the current flowing through the accessory power line of the vehicle. Specifically, when the accessory power supply is off, power is not supplied through the cigarette lighter socket, and when the accessory power supply is on, power is supplied through the cigarette lighter socket.
For this reason, by detecting the power supply state to the cigarette lighter socket as the on / off state of the accessory power source, it is possible to perform on / off control of the main body unit 10 in conjunction with the on / off state of the accessory power source.

  Note that the power supply via the cigarette lighter socket is not always linked to the on / off state of the accessory power supply, and is always performed in some vehicles. In this case, the effect of the third embodiment cannot be obtained.

  Next, a fourth embodiment will be described. In 4th Embodiment, the structure of the electric current detection part 40 differs from 3rd Embodiment. Hereinafter, a description will be given focusing on differences from the third embodiment.

The electric current detection part 40 in 4th Embodiment is provided near ECU (engine control unit) of a vehicle (refer FIG. 8). The current detection unit 40 is connected to the ECU via an accessory power supply line or a vehicle speed signal line.
The current detection unit 40 detects a current flowing from the accessory power source to the ECU (whether or not power is supplied from the accessory power source to the ECU).
Moreover, the electric current detection part 40 detects a vehicle speed signal pulse via a vehicle speed signal line.
When the current detection unit 40 detects the current flowing through the ECU, the transmitter 41 provided adjacent to the reception unit 16 provided in the main body unit 10 outputs a signal including information related to the vehicle speed to the first. Send as information.
When the current detection unit 40 does not detect the current flowing through the ECU, the transmission unit 41 does not perform signal transmission.

  The current detection unit 40 that performs current detection and the transmission unit 41 that performs first information transmission are all driven based on electric power supplied from the accessory power supply to the ECU. Therefore, when the accessory power supply is in the off state, neither the current detection unit 40 nor the transmission unit 41 consumes power.

While the receiving unit 16 is not receiving the first information, the first control unit 29 determines that the accessory power supply of the vehicle is turned off, and performs the main operation of the main body unit 10 such as display on the monitor 17. Turn off.
Note that operations that are always performed, such as the reception of the first information, the clock function, and the power supply control illustrated in FIG. 4, are turned on regardless of the detection result in the current detection unit 40.

In 4th Embodiment, the 1st control part 29 can obtain the information regarding the vehicle speed from a vehicle speed signal pulse not only the information which shows that an accessory power supply is an ON state.
The first control unit 29 specifies the vehicle position based on the information on the vehicle speed, the information from the vehicle position detection unit 13, and the information from the angular velocity sensor 14 provided in the main body unit 10.
As a result, the first control unit 29 can specify the own vehicle position with higher accuracy than the case where only the information from the own vehicle position detection unit 13 is used.
Further, the first control unit 29 performs control for restricting (prohibiting) the operation of the main body unit 10 from the safety aspect when it is determined that the traveling speed (vehicle speed) of the vehicle is equal to or higher than the threshold value based on the information on the vehicle speed. It may be provided.

In the third and fourth embodiments, the configuration in which the receiving unit 16 is provided in the main body unit 10 has been described. However, the receiving unit 16 is provided in the base station 30 and the second control unit 39 sends the first information to the first control unit 29. The form which transmits may be sufficient.
In this case, the line connecting the main unit 10 and the base station 30 is not only a power supply line for supplying power, but also a signal line for transmitting the first information from the second control unit 39 to the first control unit 29. Is also provided.

Moreover, in 1st-4th embodiment, although the electric power generation part 31 demonstrated as a solar cell, it is not restricted to a solar cell, The apparatus which converts energy, such as a heat | fever, a wind, a vibration, into an electrical energy. It may be.
Since thermal energy is obtained from sunlight incident through the windshield of the vehicle, it can be converted into electrical energy during the day regardless of the operating state of the engine of the vehicle.
Since wind energy is obtained from air-conditioner air blown from the dashboard toward the windshield (or wind from the air-conditioner outlet), it can be converted into electrical energy during operation of the air-conditioner.
Since the vibration energy is obtained from the vibration of the vehicle due to the operation of the engine, it can be converted into electric energy during the operation of the engine using a piezoelectric element or the like.

Although the embodiments according to the present invention have been described with reference to the drawings, many improvements and modifications may be made by those skilled in the art without departing from the scope of the present invention.
The present disclosure relates to the subject matter included in Japanese Patent Application No. 2009-037157 (filed on Feb. 19, 2009), and is incorporated herein by reference.

1 Information output device (navigation system)
DESCRIPTION OF SYMBOLS 10 Main-body part 10a Recessed part 10b Door part 11 1st battery 12 Vibration detection part (2nd detection part)
DESCRIPTION OF SYMBOLS 13 Own vehicle position detection part 14 Angular velocity sensor 16 Reception part 17 Monitor 29 1st control part 30 Base station 30a Convex part 31 Power generation part 33 2nd battery 35 Cooling part 40 Current detection part (1st detection part)
41 Transmitter

Claims (3)

A main body having a rechargeable first battery and an output for outputting information;
A base station fixed to a vehicle and holding the main body in a detachable state,
The base station includes a power generation unit that converts at least one of light, heat, wind, and vibration into electrical energy,
Charging the first battery is performed based on the electric energy supplied from the base station without using the electric energy charged in the vehicle battery,
The main body portion is driven based on the electric energy supplied from the base station or the electric energy charged in the first battery, without using the electric energy charged in the battery of the vehicle.
As a means for confirming the connection state between the main body and the base station, a switch that is turned on when the main body is attached to the base station is provided on the base station side,
The power supply from the base station to the main body is performed after the confirmation of the connection state by the confirmation unit, and is performed via magnetic coupling. A first detector for detecting an on / off state of an accessory power source of a vehicle in which the base station is installed;
A transmission unit that transmits the detection result of the first detection unit as first information;
At least one of the base station and the main body has a receiver that receives the first information from the transmitter,
The main body has a controller that controls an on / off state of the main body based on the first information,
The said 1st detection part is attached to the cigarette lighter socket provided in the said vehicle, The electric power supply state to the said cigarette lighter socket is detected as an ON / OFF state of the said accessory power supply. Information output device. A base station of an information output device including a power generation unit that converts at least one of light, heat, wind, and vibration into electrical energy,
The base station is attached to a vehicle and holds the main body in a removable state.
The main body has a rechargeable first battery and an output unit for outputting information,
Charging the first battery is performed based on the electric energy supplied from the base station without using the electric energy charged in the vehicle battery,
The main body portion is driven based on the electric energy supplied from the base station or the electric energy charged in the first battery, without using the electric energy charged in the battery of the vehicle.
As a means for confirming the connection state between the main body and the base station, a switch that is turned on when the main body is attached to the base station is provided on the base station side,
The power supply from the base station to the main body is performed after the connection state is confirmed by the confirmation unit, and is performed through magnetic coupling.

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