JP2004178045A - Alarm system, power supply device and its method, and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To allow a user to set a sensor unit and a battery unit more suitably. <P>SOLUTION: A cigar power source plug 11 for the battery unit 1 is connected to a cigar lighter socket, which is mounted in a vehicle not shown in the figure, to get electric power fed from the vehicle side. A battery box 12 feeds the electric power fed from the cigar power source plug 11 to the electrically connected sensor unit 2 via a cable 3, uses the electric power fed from the cigar power source plug 11 to charge a built-in secondary battery 14, or uses the charged secondary battery 14 to feed electric power to the sensor unit 2 if no electric power is fed from the cigar power source plug 11. The sensor unit 2 is installed in the vehicle to monitor the condition inside the vehicle. This constitution is applicable to a vehicle antitheft system. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an alarm system, a power supply device and method, and a program, and more particularly, to an alarm system, a power supply device and method, and a user that can more appropriately install a sensor unit and a battery unit. About the program.
[0002]
[Prior art]
In recent years, in order to prevent theft of a vehicle, a vehicle antitheft device that detects a glass breakage, opening and closing of a door, and the like by using a sensor such as an ultrasonic wave or an infrared ray and warns of an abnormality has become widespread.
[0003]
2. Description of the Related Art Conventionally, in a vehicle anti-theft device, there is a simple vehicle anti-theft device in which a dedicated power plug is attached to a cigarette lighter socket and a main body is installed on a dashboard in a vehicle or on a sun visor. Such a vehicle anti-theft device has a simple installation method, and can be easily installed by a general user who does not have specialized knowledge.
[0004]
Power supplied through the cigarette lighter socket (hereinafter referred to as cigarette power) is generated by the vehicle engine or supplied from a car battery, and is in a normal parking state in which the vehicle anti-theft device operates. That is, the power is not supplied when the engine is stopped and the power supply from the car battery is stopped.
[0005]
Therefore, in a state where a secondary battery is built in and cigarette power is supplied (in a state where the engine is operating and power is being generated or power is being supplied from a car battery), the secondary battery is There is a vehicle anti-theft device that operates by supplying power from the secondary battery in the above-described parking state.
[0006]
Also, for example, the power cord is connected to the fuse box so that the power is always supplied from the car battery, and if the power supply from the car battery is stopped due to disconnection of the power cord, the There is a vehicle anti-theft device that operates by power supply from a built-in secondary battery (for example, see Patent Document 1).
[0007]
[Patent Document 1]
JP-A-9-223278 (page 4-6, FIG. 1)
[0008]
[Problems to be solved by the invention]
However, since the above-described vehicle anti-theft device has a built-in secondary battery, the size of the housing is increased and the weight is increased, so that the place where the anti-theft device can be installed is limited. There were challenges.
[0009]
For example, considering the position and direction of the sensor and the condition after installation of the device, even if the user specifies the optimum installation location, the vehicle anti-theft device is too large for that location and cannot be installed There was a possibility that such a case might occur.
[0010]
In addition, since the vehicle anti-theft device is large and heavy, the method of fixing the device must be more robust for safety, so that not only the user cannot easily mount the device but also a mounting member and the like. There was also a problem that the cost of this increased.
[0011]
Furthermore, when the vehicle anti-theft device is operated using a secondary battery, the continuous operation time has a limit. Therefore, the user must periodically start the engine in order to charge the secondary battery, which may be inconvenient for users who use the vehicle less frequently.
[0012]
The present invention has been made in view of such a situation, realizes a vehicle anti-theft device that is smaller and lighter, can be installed more safely and easily, and while suppressing an increase in cost, It is intended to increase the capacity of a battery and improve convenience.
[0013]
[Means for Solving the Problems]
The alarm system of the present invention is an alarm system including an alarm device that detects an abnormality in the surroundings, and a power supply device that is detachably connected to the alarm device and supplies power to the alarm device. When the device operates with the power supplied from the power supply device, monitors the surroundings of the alarm device and detects an abnormality, and operates with the power supplied from the power supply device and detects an abnormality with the detection device. The power supply device includes an acquisition unit that acquires power from another device, and a power storage element, and the acquisition unit acquires the power. First power storage means for storing the obtained power, first power supply means for supplying the power acquired by the acquisition means or the power stored by the first power storage means to the alarm device, Controls power storage unit and the first power supply means, characterized in that it comprises a second control means for controlling the supply of power to the alarm device.
[0014]
The alarm device is configured with, for example, a sensor unit, the power supply device is configured with, for example, a battery unit, the detection unit is configured with, for example, a sensor, and the alarm unit is configured with, for example, a speaker or an LED. The first control unit is configured by, for example, a CPU, the acquisition unit is configured by, for example, a cigarette power plug, the first power storage unit is configured by, for example, a secondary battery, and the first power supply unit is configured by: The second control means is constituted by, for example, a power supply control unit.
[0015]
The power supply device that supplies power to the alarm device acquires power from another device, charges a built-in secondary battery, and supplies power to the alarm device. The alarm device supplied with electric power monitors the state in the vehicle where the alarm device is installed by using a sensor. When an abnormality is detected, the CPU of the alarm device performs an alarm process by outputting an alarm sound from a speaker or causing an LED to emit light.
[0016]
As described above, by configuring the power supply device that supplies power to the alarm device and has a secondary battery separately from the alarm device, the size and weight of the alarm device can be reduced. Thus, the alarm device can be installed in a narrower place, and the mounting method can be simplified, so that the user can easily install the alarm device at a suitable position. Further, the cost of the mounting member can be reduced. In particular, when the installation location is limited, such as in a car, the number of locations that cannot be installed due to the size and weight of the alarm device can be reduced, and the alarm device can be installed at an optimal position desired by the user. The possibilities increase.
[0017]
For example, the user installs a power supply device storing a heavy secondary battery in a low position in the vehicle, for example, under a seat, and an alarm device lighter than the power supply device, for example, on a sun visor or a dashboard. In general, since the sensor can be installed at a high position in the vehicle where an abnormality can be easily detected, each unit can be easily and more suitably arranged.
[0018]
Further, by configuring the power supply device having the secondary battery separately from the alarm device, it is possible to increase the capacity of the secondary battery of the power supply device without changing the size and weight of the alarm device. Therefore, the continuous operation time of the alarm device can be easily extended.
[0019]
The obtaining means may obtain power from a power supply device of a vehicle in which the alarm device is installed or a commercial power supply.
[0020]
The power supply device obtains power from a cigarette lighter socket in the vehicle where the alarm device is installed using a cigarette power plug, or obtains power from a commercial power source or the like using an AC adapter.
[0021]
With the above-described configuration, power is obtained not only in a vehicle but also from a commercial power supply or the like wired to a general household, and the secondary battery is charged or the alarm device is supplied with power. be able to.
[0022]
The first power storage means may be detachable from a power supply device.
[0023]
With the above-described configuration, for example, in the case of a user having two power supply devices, one of the power supply devices is used to operate the alarm device in the vehicle, while the other power supply device is operated at home. It is also possible to charge a secondary battery.
[0024]
The second control means controls the first supply means when the acquisition means can acquire the power, supplies the power acquired by the acquisition means to the alarm device, and when the acquisition means cannot acquire the power, The first power supply means may be controlled to supply the electric power stored by the first power storage means to the alarm device.
[0025]
When power is supplied through the cigarette power plug, the power control unit of the power supply device supplies the power to the alarm device and operates the alarm device, but the power is supplied through the cigarette power plug. If not, the power stored in the secondary battery stored in the power supply device is supplied to the alarm device to operate the alarm device.
[0026]
For example, when the user is driving a car, the power supply of the alarm system installed in the car supplies the power supplied from the generator or the battery on the vehicle side to the alarm device, and operates the secondary device. When the battery is charged and the vehicle is stopped and power is not supplied from the vehicle side, the power supply device supplies the power stored in the secondary battery to the alarm device to operate.
[0027]
By doing so, the alarm system can operate even with a configuration including only the alarm device and the power supply device including the sufficiently charged secondary battery.
[0028]
The second control means may control the first power storage means to store the power obtained by the obtaining means when the output voltage of the first power storage means is equal to or less than a predetermined threshold. it can.
[0029]
When the output voltage of the secondary battery is equal to or less than a predetermined threshold, that is, when the secondary battery is not in a fully charged state, the power supply control unit of the power supply device controls the power supplied through the cigarette power plug to the secondary power. Charge the battery. Thus, the secondary battery stored in the power supply device can be charged even if the user does not perform any special operation.
[0030]
The power supply device further includes a temperature measurement unit that measures a temperature around the first power storage unit, and the second control unit performs a first operation when the measurement result by the temperature measurement unit is within a predetermined temperature range. Can be controlled to store the electric power acquired by the acquiring means.
[0031]
The temperature measurement unit is, for example, a power supply control unit that controls a thermometer provided near the secondary battery. The power control unit measures and monitors the ambient temperature of the secondary battery. Then, only when the ambient temperature of the secondary battery is within a predetermined temperature range (for example, 0 degrees to 40 degrees), power can be stored in the secondary battery. To store electricity. In this way, when the temperature is too high (for example, 40 degrees or more) or too low (for example, 0 degrees or less), the power storage process to the secondary battery can be stopped. Thus, efficient power storage can be performed without receiving a special instruction from the user.
[0032]
The second control means controls the first power storage means when a predetermined time has elapsed from the power storage start time of the first power storage means, and terminates the power storage of the power acquired by the acquisition means. can do.
[0033]
For example, when one hour has elapsed from the time when the storage of the secondary battery is started, the power supply control unit stops the storage of the secondary battery. This makes it possible to suppress overcharge of the secondary battery without receiving a special instruction from the user.
[0034]
The power supply device may further include a display unit that displays information regarding power storage by the first power storage unit.
[0035]
The power supply device includes an LED, and the power control unit controls light emission by the LED. Then, when power storage in the secondary battery is started, the power supply control unit causes the LED to emit light. Further, when the secondary battery is removed from the power control unit and power cannot be stored in the secondary battery, the power control unit blinks the LED. By doing so, the user can easily grasp the state of power storage of the secondary battery.
[0036]
The detecting means may detect at least one of a pressure change around the alarm device, a vibration of the alarm device, a temperature change around the alarm device, and a tilt of the alarm device.
[0037]
For example, the sensor of the alarm device includes a pressure sensor, a vibration sensor, a pyroelectric sensor, an inclination sensor, and the like, and detects opening / closing of a door, breakage of glass, intrusion into a vehicle, theft of a tire, and the like. Thus, the alarm device can detect more than various states, and can warn of the possibility of vehicle theft.
[0038]
The warning means may include at least one of a sound output unit that outputs a warning sound and a light emitting unit that includes a light emitting element, and the warning unit may be configured to warn by voice or light.
[0039]
For example, the alarm device is provided with a speaker that outputs an alarm sound and an LED that emits light or blinks when an abnormality occurs, and can issue an alarm by sound (alarm sound) and light (light emission). Thereby, the user can easily recognize the warning issued by the warning device.
[0040]
The first control unit sets the operation mode of the alarm device to one of a first mode in which the detection unit and the alarm unit are operated, and a second mode in which the detection unit and the alarm unit are not operated. You can make it.
[0041]
The CPU of the alarm device controls a sensor that detects an abnormality, a speaker that outputs an alarm sound, and the like, and selects one of a warning mode in which the operation mode of the alarm device is operated as an alarm system and a normal mode in which no alarm is issued. Set. The alarm device detects an abnormality in the vehicle when in the alert mode, and issues a warning by detecting it with a sensor. However, in the normal mode, the sensor is stopped and does not detect the abnormality.
[0042]
With the above configuration, the CPU of the alarm device sets the operation mode of the alarm device to the normal mode when the authorized user uses the car, and operates the alarm device when the authorized user leaves the vehicle. The mode can be set to the alert mode.
[0043]
The alarm device further includes a power failure detection unit that detects a stop of power supply from a power supply device, and a second power supply unit that supplies power. The first control unit includes a power failure detection unit. When an abnormality is detected, the alarm device operates using the electric power supplied by the second electric power supply device. Further, when the operation mode of the alarm device is the first mode, the alarm device is controlled to generate an alarm. Can be
[0044]
The power supply abnormality detection means is constituted by, for example, a disconnection detection circuit section, and the second power supply means is constituted by, for example, an internal battery. For example, when the power supply cable connecting the power supply device and the alarm device is disconnected, each part of the alarm device operates using the electric power stored in the primary battery or the secondary battery built in the alarm device. Then, in the alert mode, the disconnection detection circuit unit notifies the CPU of the abnormality, and the CPU controls a speaker, an LED, and the like to issue an alarm. With the configuration described above, the alarm device can output an alarm even when power is not supplied from the power supply device to the alarm device.
[0045]
The second power supply means may be composed of a primary battery.
[0046]
By using, for example, a commercially available primary battery as the built-in battery, the manufacturing cost of the alarm device can be reduced. It is needless to say that a dedicated primary battery may be used.
[0047]
The second power supply unit may include a power storage element, and may include a second power storage unit that stores power supplied from a power supply device.
[0048]
The second power storage means is constituted by, for example, a secondary battery. With this configuration, unlike in the case of the primary battery, the power supplied from the power supply device is stored in the secondary battery even if the battery is not replaced. Can be reduced.
[0049]
The alarm device may further include a receiving unit that receives an instruction from a user.
[0050]
The accepting means includes, for example, a detection level setting switch and an alarm sound setting switch. The user can operate the switches provided on the alarm device to change the settings of the alarm device.
[0051]
The receiving means may be configured separately from the alarm device, and may supply the received instruction from the user to the alarm device via wireless communication using infrared rays or radio waves.
[0052]
The receiving means is constituted by, for example, a remote controller that outputs infrared rays or radio waves. When a user operates a button or the like provided on the remote controller, a radio signal corresponding to the operation (user's instruction) is transmitted from the remote controller. It is output and received by the receiver of the alarm device. Then, when information related to a user's instruction is extracted from the received wireless signal and supplied to the CPU, the CPU controls each unit based on the information.
[0053]
With the above-described configuration, for example, even when the user is outside the vehicle in which the alarm device is installed, the user can instruct the operation of the alarm device or change the setting.
[0054]
The alarm unit further includes a wireless communication unit that performs wireless communication using radio waves, and when an abnormality is detected by the detection unit, alarm information for alarming the abnormality is transmitted to the user by wireless communication using the wireless communication unit. The data can be transmitted to a portable wireless receiving device.
[0055]
The wireless communication unit is configured by, for example, a wireless transmission unit, and the wireless reception device is configured by, for example, a remote controller. For example, when the sensor detects an abnormality, the CPU outputs an alarm sound, emits an LED, and controls the wireless transmission unit to transmit alarm information for alarming the abnormality to the remote controller. Upon receiving the alarm information, the remote controller issues an alarm by voice or light. Thus, if the user carries the remote controller, the user can be alerted by the alarm output from the remote controller even if the user cannot hear the alarm sound output in the vehicle or is in a position where the emission of the LED cannot be confirmed. An alarm from the device can be recognized.
[0056]
The power supply device of the present invention is a power supply device that is detachably connected to a first other device and supplies power to the first other device, and acquires power from the second other device. Means for storing the power obtained by the obtaining means, and a power supply for supplying the power obtained by the obtaining means or the power stored by the power storing means to the first other device. Means, and control means for controlling the power storage means and the power supply means and for controlling the supply of power to the first other device.
[0057]
The power supply device is configured by, for example, a battery unit, the acquisition unit is configured by, for example, a cigarette power plug, the power storage unit is configured by, for example, a secondary battery, and the power supply unit is configured by, for example, an output terminal. The second control means is constituted by, for example, a power supply control unit.
[0058]
The power supply control unit of the power supply device obtains power from the cigarette power plug, stores the power in the secondary battery, and supplies the power to the first other device via a cable connected to the output terminal. . If power cannot be obtained from the cigarette power plug, the power control unit supplies the power stored in the secondary battery to the first other device via the cable connected to the output terminal.
[0059]
With the above configuration, the power supply device can store power in the secondary battery, and supply power to the first other device even when power is not supplied to the power supply device. Can be.
[0060]
Also, by configuring the power supply device having the secondary battery separately from the first other device, the secondary battery of the power supply device can be enlarged without changing the size and weight of the first other device. The capacity can be increased.
[0061]
The obtaining means may obtain power from a power supply device of a vehicle in which the first other device is installed or from a commercial power supply.
[0062]
With the configuration described above, the power supply device can acquire power through the cigarette lighter socket of the vehicle using the cigarette power plug, or use the AC adapter to supply power from the commercial power supply. It is also possible to obtain.
[0063]
The power storage means may be detachable from a power supply device.
[0064]
Thereby, the user can replace the secondary battery stored in the power supply device. For example, when the secondary battery becomes old and the storable capacity decreases, the user can replace the new secondary battery with the old secondary battery. In addition, the secondary battery can be shared with another device.
[0065]
The control unit controls the power supply unit when the acquisition unit can acquire the power, supplies the power acquired by the acquisition unit to the first other device, and supplies the power supply when the acquisition unit cannot acquire the power. The means can be controlled to supply the electric power stored by the power storage means to the first device.
[0066]
The control means may control the power storage means to store the power obtained by the obtaining means when the output voltage of the power storage means is equal to or lower than a predetermined threshold value.
[0067]
As described above, the power supply control unit controls power storage to the secondary battery and supply of power to the first other device.
[0068]
The power supply device further includes a temperature measurement unit that measures a temperature around the power storage unit, and the control unit controls the power storage unit when the measurement result by the temperature measurement unit is within a predetermined temperature range to obtain The electric power acquired by the means can be stored.
[0069]
The control means may control the power storage means to terminate the power storage of the power acquired by the acquisition means when a predetermined time has elapsed from the power storage start time of the power storage means.
[0070]
Accordingly, the power supply control unit can suppress unnecessary power storage processing for the secondary battery, and can perform efficient power storage processing.
[0071]
The power supply device may further include a display unit that displays information regarding power storage by the power storage unit.
[0072]
The display means is constituted by, for example, an LED. The power control unit turns on or blinks an LED according to the state of storage of the secondary battery. The user can know the storage state of the secondary battery by the light emission of the LED.
[0073]
A power supply according to the present invention, which includes a power storage unit including a power storage element, is detachably connected to a first other device, and supplies power supplied from a second other device to the first other device. The power supply method of the supply device includes a supply control step of controlling supply of power to the first other device and a charge control step of controlling charging by the power storage unit.
[0074]
A program according to the present invention causes a computer to execute the above-described power supply method.
[0075]
The program of the present invention is recorded on a predetermined recording medium, read out by, for example, a drive, and installed in an image printing apparatus. The recording medium is a magnetic disk such as a floppy disk, an optical disk such as a CD-ROM (Compact Disk Read Only Memory), a DVD-ROM (Digital Versatile Disk), or a magneto-optical disk such as an MD (Mini-Disk) (trademark). It is composed of a disk or a semiconductor memory.
[0076]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is a diagram showing a configuration example of a vehicle theft prevention alarm system to which the present invention is applied. In FIG. 1, the vehicle anti-theft alarm system includes a battery unit 1 and a sensor unit 2 electrically connected to each other by a cable 3.
[0077]
The battery unit 1 electrically connects the cigarette power supply plug 11 connected to a cigarette lighter socket provided on a vehicle (not shown), a battery box 12 containing a secondary battery 14, and the cigarette power supply plug 11 and the battery box 12. Is constituted by a cable 13 to be connected to. The cigarette power plug 11 is a dedicated plug that can be electrically connected to a cigarette lighter socket (not shown), and through the connected cigarette lighter socket, generates electric power from a car engine or power supplied from a car battery. Power plug to get.
[0078]
The battery box 12 is connected to the sensor unit 2 via the cable 3, and supplies power supplied from the cigarette power plug 11 to the sensor unit 2 electrically connected via the cable 3. The battery box 12 can charge the built-in secondary battery 14 using the power supplied from the cigarette power plug 11, and is charged when no power is supplied from the cigarette power plug 11. Power is supplied to the sensor unit 2 using the secondary battery 14. Further, the battery box 12 is provided with an LED (Light Emitting Diode) 15 that indicates a state of charge of the secondary battery 14.
[0079]
The sensor unit 2 is operated by the electric power supplied from the battery unit 1 via the cable 3 and monitors the condition inside the installed vehicle. The sensor unit 2 is provided with a sensor, which will be described later. The sensor unit 2 detects breakage of glass, opening and closing of a door, disconnection of a cable 3, and the like. It notifies the controller and outputs an alarm sound from the speaker 16.
[0080]
FIG. 2 is a diagram showing an example of the appearance of the cigarette power plug 11 and the cable 13 of FIG.
[0081]
As shown in FIG. 2A, a positive terminal 21 connected to the positive terminal of the cigarette lighter socket is fixed to the cigarette power plug 11, which is one end of the cable 13, and the cigarette power plug 11 is fixed to the cigar lighter socket. The spring force of the springs 22A and 22B is adjusted according to the size of the springs 22A and 22B, which are plate-like springs, and the hole diameter of the cigar lighter socket, and the insertion pressure of the cigarette power plug 11 is adjusted. A slider 23 is provided. The spring 22B also functions as a negative terminal, as described later, and is connected to a negative terminal of the cigarette lighter socket.
[0082]
The other end of the cable 13 is provided with a dedicated plug 24 that can be attached to a terminal of the battery box 12. The dedicated plug 24 is provided with a cylindrical negative terminal 25 and a positive terminal 26 located inside the cylinder of the negative terminal 25 and insulated from the negative terminal 25.
[0083]
As shown in FIG. 2B, the positive terminal 21 of the cigarette power plug 11 is connected to the positive terminal 26 of the dedicated plug 24, and the negative terminal 26 of the cigarette power plug 11 is provided with a spring 22B. It is connected to the negative terminal 25 of the plug 24.
[0084]
FIG. 3 is a perspective view showing an example of the appearance of the battery box 12 of FIG.
[0085]
In FIG. 3, the battery box 12 extends over an upper surface 12-1, which is an upper surface in the drawing, and upper surfaces of three surfaces 12-2, 12-3, and 12-4, which are side surfaces in the drawing. , A lid 31 are formed. The battery box 12 stores a secondary battery 14 such as a nickel-metal hydride battery, and can charge and discharge the secondary battery. The lid 31 covers the stored secondary battery 14, and the user opens the lid 31 and mounts or replaces the secondary battery 14 in the battery box 12. This allows the user to charge the secondary battery using the battery box 12, remove the secondary battery 14 having no remaining capacity from the battery box 12, and use another charger to charge the secondary battery 14. It is also possible to charge the battery 14.
[0086]
In addition, an LED 15 for indicating the state of charge of the secondary battery 14 and a terminal 32 to which the terminal 24 of the cable 13 for connecting the cigarette power plug 11 shown in FIG. Is provided. The LED 15 turns on while the secondary battery 14 is being charged, and turns off when the charging is completed. Also, when the secondary battery 14 is not connected to the battery box 12 or the ambient temperature is out of the predetermined temperature range, and the battery cannot be charged, the LED flashes. Further, a cable 3 is connected near the center of the surface 12-5 facing the surface 12-2 as shown in FIG.
[0087]
Next, the sensor unit will be described.
[0088]
FIG. 5 is a diagram showing an example of the appearance of the sensor unit 2 of FIG. A sensor 51 is provided at the center of the upper front part of the sensor unit 2 in the drawing. The sensor 51 is constituted by a pressure sensor, and detects a change in the vehicle interior pressure when the door is opened or closed or the glass is broken. Note that the sensor 51 may be a sensor other than a pressure sensor, for example, a vibration sensor that detects vibration of a vehicle body, a pyroelectric sensor that detects intrusion of a suspicious person into the vehicle, or a sensor An inclination sensor for detecting an inclination may be used.
[0089]
Further, LEDs 52A and 52B are provided on both sides of the sensor 51, and these LEDs 52A and 52B are turned on or blinked according to the situation, for example, when the sensor 51 detects an abnormality.
[0090]
Further, on the lower side surface of the LEDs 52A and 52B in the figure of the sensor unit 2, infrared receiving units 53A and 53B for receiving infrared signals supplied from a remote controller described later are provided. The user can perform setting and operation of the sensor unit 2 using the remote controller carried by the user.
[0091]
On the lower surface of the sensor unit 2 in the drawing, in addition to the terminal 54 to which the terminal of the cable 3 can be detachably attached, for example, a large volume that outputs an alarm sound that is louder than the alarm sound output from the speaker 16. An option connection terminal 55 for connecting an optional device such as a speaker 57 is provided.
[0092]
As shown in FIG. 5, when the dedicated cable 56 of the high volume speaker 57 is connected to the option connection terminal 55, the sensor unit 2 causes the high volume speaker 57 to output an alarm sound when an abnormality is detected.
[0093]
FIG. 6 is a view of the sensor unit 2 of FIG. 5 viewed from the lateral direction.
[0094]
A mounting spring 61 for easily mounting the sensor unit 2 on a sun visor or the like is provided on a surface of the sensor unit 2 facing the surface on which the speakers 16 are provided. When attaching the sensor unit 2 to the sun visor, the user can install the sensor unit 2 such that the sun visor is sandwiched between the attachment spring 61 and the housing of the sensor unit 2.
[0095]
FIG. 7 is a diagram showing an external appearance of a remote controller for controlling the above-described sensor unit 2.
[0096]
In FIG. 7, a super button 71 for setting the detection level of the sensor 51 of the sensor unit 2 to an extremely weak level that can detect even a slight level abnormality is provided on the front surface of the remote controller 70 in the figure. A normal button 72 for setting the detection level of 51 to a normal level in which the sensitivity of the sensor is lower than the ultra-weak level; an alert setting button 73 for setting the sensor unit 2 to an alert mode operating as a vehicle anti-theft device; 2 is provided with a warning release button 74 for releasing the warning mode so as to stop the operation as a vehicle theft prevention device.
[0097]
Further, on the left side in the figure of the remote controller 70, an infrared transmitter 75 for outputting an infrared signal is provided in order to transmit the operation to the sensor unit 2 when the user operates the various buttons described above. ing.
[0098]
The user points the infrared transmitter 75 of the remote controller 70 to the infrared receiver 53A or 53B of the sensor unit 2 and presses any one of the super button 71, the normal button 72, the alert setting button 73, and the alert release button 74. When operated, the infrared transmitter 75 outputs an infrared signal corresponding to the user's operation. When the infrared receiving unit 53A or 53B of the sensor unit 2 receives the signal, the sensor unit 2 performs an operation according to a user's instruction.
[0099]
Next, an example of the electrical configuration inside the battery unit 1 and the sensor unit 2 will be described.
[0100]
FIG. 8 is a block diagram showing an example of the internal configuration of the battery box 12 shown in FIG. 3 and FIG.
[0101]
The positive electrode 32-1 of the terminal 32 to which the cable 13 is connected is connected to the anode of a backflow prevention diode 82 for preventing a current from flowing backward and flowing into the positive electrode 32-1. The cathode of the backflow prevention diode 82 is connected to a power supply control unit 83 that controls the electrical operation of each unit of the battery box 12. The power control unit 83 is connected to the positive electrode 85 of the terminal to which the cable 3 is connected.
[0102]
The secondary battery 14 has a positive electrode connected to the power control unit 83 and the positive electrode 85, a negative electrode grounded, and the power supplied from the power control unit 83 to the positive electrode 85 is It is configured to be supplied also to the secondary battery 14.
[0103]
Further, the LED 15 indicating the state of charge has an anode connected to the power supply control unit 83, and a cathode connected to the other terminal of the resistor 84, one terminal of which is grounded.
[0104]
Note that the terminal 32 to which the cable 13 is connected and the negative electrode of the terminal to which the cable 3 is connected are grounded, and thus description thereof is omitted.
[0105]
The cigarette power plug 11 connected to the terminal 32 is connected to the cigarette lighter socket via the cable 13, and when power is supplied from the vehicle side, a voltage is applied to the positive electrode 32-1 of the battery box 12. . The voltage is applied to the power supply control unit 83 via the backflow prevention diode 82. The power supply control unit 83 outputs the voltage from the positive electrode 85 and applies the voltage to the sensor unit 2 and, when the secondary battery 14 can be charged, applies the voltage to the positive electrode of the secondary battery 14 The charging of the battery 14 is started. At this time, the power supply control unit 83 applies a predetermined voltage to the anode of the LED 15 to cause a current to flow in the LED 15 in the forward direction, thereby lighting the LED 15.
[0106]
When the secondary battery 14 is not connected as described above, the power supply control unit 83 blinks the LED 15 by intermittently applying a predetermined voltage to the anode of the LED 15 at predetermined intervals.
[0107]
Further, the power supply control unit 83 has a function of measuring the temperature around the secondary battery 14, and when the ambient temperature of the secondary battery 14 is equal to or higher than a first predetermined temperature (for example, 40 ° C.). Alternatively, when the temperature is equal to or lower than the second predetermined temperature (for example, 0 ° C.), it is impossible to charge the secondary battery 14.
[0108]
When no voltage is applied to the positive electrode 32-1, the voltage of the positive electrode of the secondary battery 14 is applied to the power supply control unit 83 and the positive electrode 85. Thereby, when the secondary battery 14 is sufficiently charged, the battery box 12 can supply power to the sensor unit 2 using the secondary battery 14.
[0109]
FIG. 9 is a block diagram showing an example of the internal configuration of the sensor unit 2 shown in FIGS.
[0110]
The positive electrode 54-1 of the terminal 54 to which the cable 3 is connected has a power supply circuit unit 91 for performing processing such as adjustment of an applied voltage, and monitors the level of the applied voltage to disconnect the cable 3 or the like. Is connected to a disconnection detection circuit unit 92 that monitors whether the supply of power from the battery unit 1 has stopped.
[0111]
The power supply circuit unit 91 applies the adjusted voltage to the CPU 94 that controls each unit of the sensor unit 2, and applies a voltage to the positive electrode of the built-in battery 93, which is a secondary battery having a smaller capacity than the secondary battery 14. A voltage is applied to charge the built-in battery 93 used when the power supply from the battery unit 1 is stopped.
[0112]
When the supply of power to the power supply circuit unit 91 is stopped and a disconnection is detected, the disconnection detection circuit unit 92 supplies information indicating the detection to the CPU 94. At this time, each unit of the sensor unit 2 operates using the electric power supplied from the built-in battery 93.
[0113]
Upon receiving the infrared signal transmitted from the infrared transmitter 75 of the remote controller 70 shown in FIG. 7, the infrared controller 95 including the infrared receivers 53A and 53B converts the infrared signal into an electric signal and supplies it to the CPU 94.
[0114]
When the sensor unit 96 including the sensor 51 detects an abnormality in the sensor 51, the sensor unit 96 supplies information indicating the detection to the CPU 94.
[0115]
The CPU 94 performs various processes such as an alarm process for warning an abnormality based on the various information supplied as described above, controls the LED unit 97 including the LEDs 52A and 52B, and causes the LEDs 52A and 52B to emit light. Also, it controls the speaker unit 98 including the speaker 16 to output an alarm sound from the speaker 16, and controls optional devices connected to the terminal 55, such as the loud speaker 57.
[0116]
The built-in battery 93 only needs to have enough capacity to perform the above-described alarm processing when the cable 3 is cut or the like. Therefore, compared to the secondary battery 14, the built-in battery 93 can be small and light, and a small secondary battery can be used.
[0117]
In the above description, the secondary battery is used as the built-in battery 93. However, the present invention is not limited to this, and a primary battery may be used. In that case, the manufacturing cost of the sensor unit 2 can be reduced by using a commercially available primary battery.
[0118]
In FIGS. 3 and 4, the cable 3 is described as being fixedly connected to the battery box 12. However, the present invention is not limited to this. You may make it more detachable. In FIG. 2, the description has been made such that the cable 13 is fixedly connected to the cigarette power plug 11. However, the present invention is not limited to this. May be detachable.
[0119]
Further, in the battery unit 1 of FIG. 1, as shown in FIG. 10, the user attaches the terminal 101 of the cable 102 of the AC adapter 103 to the terminal 32 to which the dedicated plug 24 of the cable 13 is attached, and May be used to charge the secondary battery 14 of the battery box 12.
[0120]
Next, the operation of each unit will be described. As described above, the power supply control unit 83 of the battery box 12 of FIG. 8 not only supplies the power supplied through the cigarette power supply plug 11 to the sensor unit but also controls the charging of the secondary battery 14. The charge control process executed by the battery box 12 shown in FIG. 8 will be described with reference to the flowchart in FIG.
[0121]
First, in step S1, the power control unit 83 determines whether or not to terminate the charge control process. When the user removes the secondary battery 14 from the battery box 12 and cannot perform the charge control process, the power supply control unit 83 determines that the charge control process is to be terminated, and executes the termination process in step S2 to charge the battery. The control processing ends.
[0122]
If it is determined in step S1 that the charge control process is not to be ended, the power control unit 83 proceeds to step S3 and determines whether the voltage of the secondary battery 14 is lower than a predetermined voltage value. When the voltage of the secondary battery 14 is higher than a predetermined voltage value and it is determined that the secondary battery 14 is fully charged, the power supply control unit 83 proceeds to step S1 without performing the charging process. And repeat the subsequent processing. If it is determined in step S3 that the voltage of the secondary battery 14 is lower than the predetermined voltage value, the power control unit 83 advances the process to step S4, and sets the temperature around the secondary battery 14 to the chargeable temperature range. It is determined whether it is within.
[0123]
The power supply control unit 83 monitors the ambient temperature of the secondary battery 14, and if it is determined that the temperature is outside the predetermined temperature range and charging is not possible, the process proceeds to step S1 without performing the charging process. And repeat the subsequent steps. If it is determined in step S4 that the ambient temperature is within the chargeable temperature range, the process proceeds to step S5, in which the charging process is started, and a predetermined voltage is applied to the positive electrode of the secondary battery 14 to charge the battery. The charging of the next battery 14 is started.
[0124]
In step S6, the power supply control unit 83 that has started the charging process determines whether the temperature around the secondary battery 14 is within the chargeable temperature range, and the ambient temperature is outside the chargeable temperature range. If it is determined that charging is impossible, the charging process is temporarily stopped in step S7.
[0125]
The power supply control unit 83 that has temporarily stopped the charging process determines in step S8 whether or not to end the charging control process. If it is determined that the charging control process is not to end, the process proceeds to step S9, and the process proceeds to step S9. It is determined whether the temperature is within the chargeable temperature range. If the ambient temperature of the secondary battery 14 is outside the chargeable temperature range and it is determined that charging is not possible, the power control unit 83 returns the process to step S8, and repeats the subsequent processes. That is, the power supply control unit 83 waits until the ambient temperature falls within the chargeable range or the charge control process ends, while repeating the processes of steps S8 and S9.
[0126]
If it is determined in step S8 that the charge control process is to be ended, the power control unit 83 proceeds to step S2, executes the end process, and ends the charge control process.
[0127]
If it is determined in step S9 that the ambient temperature is within the chargeable temperature range, the power supply control unit 83 returns to step S5 and restarts the charging process.
[0128]
If it is determined in step S6 that the ambient temperature is within the chargeable temperature range after the start of the charging process, the power supply control unit 83 advances the process to step S10, and determines whether to end the charging control process. . If it is determined that the charging is to be terminated, the power control unit 83 proceeds to step S2, executes the termination process, and terminates the charging control process.
[0129]
If it is determined in step S10 that the charge control process is not to be ended, the power control unit 83 proceeds to step S11 and determines whether a predetermined charge end condition is satisfied. The charging termination condition is a predetermined condition for terminating the charging process. For example, the charging time has elapsed one hour, or the voltage value of the secondary battery 14 has reached a specified voltage value or more. Such conditions as presetting are set in advance and are recorded in a ROM (Read Only Memory) or a RAM (Random Access Memory) built in the power supply control unit 83. If any of these conditions is not satisfied, the power supply control unit 83 determines that the charging end condition is not satisfied, returns the process to step S6, and performs the subsequent processes while performing the subsequent processes. Is continued.
[0130]
If it is determined in step S11 that any of the above-described charging end conditions is satisfied, the power supply control unit 83 ends the charging process of the secondary battery 14 in step S12, and returns the process to step S1. .
[0131]
The power control unit 83 of the battery box 12 controls the charging of the secondary battery 14 as described above.
[0132]
The CPU 94 of the sensor unit 2 of FIG. 9 supplied with power from the battery box 12 as described above controls each unit of the sensor unit 2 and performs a process of detecting an abnormality in the installed vehicle. Next, control processing by the sensor unit will be described with reference to the flowcharts of FIGS.
[0133]
First, in step S41 of FIG. 12, the CPU 94 of the sensor unit 2 determines whether to end the control processing. At this time, the sensor unit 2 is in the normal mode in which the function of the sensor 51 is stopped. As described above, when it is determined that the control process is to be terminated by enabling the function of the sensor 51 and stopping the power supply in a state where the alert mode for performing the alert activity is not set, the CPU 94 sets the built-in battery 93. , And the process is terminated in step S42, and the control process is terminated.
[0134]
If it is determined in step S41 that the control process is not to be terminated, the CPU 94 proceeds to step S43, controls the infrared control unit 95, and determines whether an instruction has been obtained from the remote controller 70 shown in FIG. judge. When it is determined that the information related to the user's instruction has not been supplied from the infrared control unit 95 and the instruction has not been obtained, the CPU 94 returns the process to step S41 and repeats the subsequent processes.
[0135]
When information on the user's instruction corresponding to the operation of the remote controller 70 by the user is supplied from the remote controller 70 as an infrared signal, the CPU 94 obtains the information via the infrared control unit 95, and in step S43, It is determined that the instruction has been obtained from the remote controller 70, and the process proceeds to step S44.
[0136]
In step S44, the CPU 94 determines whether or not the acquired instruction is an alert setting instruction for instructing the alert mode setting. If the CPU 94 determines that the acquired instruction is not the alert setting instruction, the CPU 94 proceeds to step S41. Return and perform the subsequent processing. If it is determined in step S44 that the acquired instruction is the alert setting instruction, the CPU 94 advances the process to step S45, shifts the setting from the normal mode to the alert mode, and advances the process to step S46 in FIG.
[0137]
In step S46 of FIG. 13, the CPU 94 determines whether or not to end the control processing, and when it is determined to end, returns the processing to step S42 of FIG. 12, performs the end processing, and ends the control processing. .
[0138]
If it is determined in step S46 of FIG. 13 that the control process is not to be ended, the CPU 94 proceeds to step S47, controls the sensor unit 96, and determines whether an abnormality is detected. If it is determined that an abnormality has been detected, the CPU 94 proceeds to step S49. If it is determined in step S47 that the sensor 51 has not detected an abnormality and has not detected an abnormality, the CPU 94 determines in step S48 whether a disconnection has been detected. If the disconnection detection circuit unit 92 detects the disconnection and determines that the disconnection is detected by supplying the information to the CPU 94, the CPU 94 advances the process to step S49, controls the speaker unit 98, and controls the speaker 16 to An alarm output process of outputting an alarm sound or controlling the LED unit 97 to turn on the LEDs 52A and 52B to generate an alarm is executed. After executing the alarm output process, the CPU 94 advances the process to step S50.
[0139]
If it is determined in step S48 that a disconnection has not been detected, that is, if no abnormality has been detected in the vehicle, the CPU 94 skips step S49 and proceeds to step S50.
[0140]
In step S50, the CPU 94 determines whether or not an instruction from the user has been received from the remote controller 70. When the CPU 94 controls the infrared control unit 95 and determines that the instruction from the user has not been received, the CPU 94 returns the processing to step S46 and repeats the subsequent processing.
[0141]
If it is determined in step S50 that an instruction from the user has been received from the remote controller 70, the CPU 94 determines in step S51 whether the instruction is an alert release setting instruction. If it is determined that the instruction is the alert release setting instruction, the CPU 94 shifts the setting from the alert mode to the normal mode in step S52, returns the process to step S41 in FIG. 12, and repeats the subsequent processes.
[0142]
In step S51, when it is determined that the instruction from the user transmitted from the remote controller 70 is not the alert release setting instruction, the CPU 94 determines in step S53 that the instruction is to set the detection level of the sensor 51 by the sensor detection level setting instruction. It is determined whether or not there is. If it is determined that the instruction is not a sensor detection level setting instruction, the CPU 94 returns the processing to step S46, and repeats the subsequent processing.
[0143]
If it is determined in step S53 that the instruction is a sensor detection level setting instruction, in step S54, the CPU 94 sets the designated sensor detection level (either the ultra-slight level or the normal level), and proceeds to step S46. Return the process and repeat the subsequent processes.
[0144]
As described above, the CPU 94 controls each part of the sensor unit 2 and performs a warning process in the installed vehicle.
[0145]
As described above, by configuring the battery unit 1 that supplies power to the sensor unit 2 separately from the sensor unit 2, the size and weight of the sensor unit 2 can be reduced. Thereby, the sensor unit 2 can be installed in a narrower space in the vehicle, the mounting method can be simplified, and the user can easily install the sensor unit 2 at a suitable position. Further, the cost of the mounting member can be reduced.
[0146]
Generally, in the vehicle anti-theft alarm system having the above-described configuration, the weight of the secondary battery 14 of the battery unit 1 is the heaviest. However, the user installs the battery box 12 storing the heavy secondary battery 14 at a low position in the vehicle, for example, under a seat, and mounts the sensor unit 2 lighter than the battery box 12 on, for example, a sun visor or a dashboard. Since the sensor 51 can be installed at a high position in the vehicle, such as above, where the sensor 51 is generally easy to detect an abnormality, each part can be easily and more suitably arranged.
[0147]
Further, even after the vehicle anti-theft alarm system is installed as described above, even when the sensor unit 2 is separated from the fixed place, the sensor unit 2 is compared with the case where the secondary battery 14 is incorporated. It is safer because it is lightweight.
[0148]
Further, by separating the battery unit 1 having the secondary battery 14 from the sensor unit 2, the secondary battery 14 can be enlarged without changing the size and weight of the sensor unit 2 which greatly affects the user's feeling of use. The capacity can be increased, and the continuous operation time of the sensor unit 2 can be easily extended.
[0149]
In the above, the sensor unit 2 has been described to output an alarm sound from the speaker 16 or the loud speaker 57 or to emit the LEDs 52A and 52B when an abnormality is detected. However, the present invention is not limited to this. The sensor unit 2 may perform wireless communication with a remote controller held by the user, and supply alarm information to the remote controller.
[0150]
14 and 15 are external views showing another example of the sensor unit 2. FIG.
[0151]
In FIG. 14, a sensor 141 including a pressure sensor similar to the sensor 51 of FIG. Further, on both sides of the sensor 141, LEDs 142A and 142B similar to the LEDs 52A and 52B of FIG. 5 are provided.
[0152]
An antenna 143 for performing wireless communication with a remote controller described later is provided on the left side surface of the sensor unit 2 in the drawing, and the sensor unit 2 wirelessly communicates with the remote controller at a predetermined frequency via the antenna 143. Perform communication.
[0153]
Further, an option connection terminal 145 similar to the option connection terminal 55 in FIG. 5 is provided on the lower surface of the sensor unit 2 in the figure, in addition to the terminal 144 for connecting the cable 3.
[0154]
Further, as shown in FIG. 15, a detection level setting switch 151 for switching the sensitivity setting of the sensor 141 and an alarm sound setting switch 152 for switching the operation mode of the sensor unit 2 are provided on the right side of the sensor unit 2 in the drawing. Is provided. By operating the detection level setting switch 151, the user sets the detection level of the sensor 141 to an extremely weak level or to a normal level. Further, the user operates the alarm sound setting switch 152 to set or cancel the sensor unit 2 to the alert mode.
[0155]
Although not shown, a mounting spring 61 may be provided on the back surface of the sensor unit 2 as in the case of FIG.
[0156]
FIGS. 16 to 20 are views showing examples of the appearance of a remote controller for controlling the sensor unit 2 described above.
[0157]
In FIG. 16, a battery display LED 162 for indicating a charge of a secondary battery built in the remote controller 161 is provided on a front surface 161-1 in the figure of the remote controller 161, and a sensor alert for displaying a sensor alert mode setting. An LED group such as a mode display LED 163, a hit-and-run error display LED 164 for displaying a hit-and-run error, a glass break fault-display LED 165 for displaying a glass break fault, and a door open / close fault display LED 166 for displaying a door open / close fault is provided. ing.
[0158]
The battery indicator LED 162 lights up while the secondary battery built in the remote controller 161 is being charged. Also, when the remaining capacity of the secondary battery is low, it flashes and notifies the user.
[0159]
The sensor alert mode display LED 163 lights in red when the sensor unit 2 is set in the alert mode, and lights in green when the alert mode is released (in a non-alert state).
[0160]
In addition, the hit-and-run abnormal display LED 164 turns on when a hit-and-run or a strong impact corresponding thereto is detected, the glass break fault display LED 165 turns on when a glass break is detected, and the door open / close fault display LED indicates that the door is opened. Lights when is detected.
[0161]
Further, the remote controller 161 has a built-in antenna for performing wireless communication with the sensor unit 2.
[0162]
FIG. 17 is a diagram illustrating an example of a surface 162-1 facing the surface 161-1 of the remote controller 161. A battery cover 171 as a lid for fixing a secondary battery such as a nickel-metal hydride battery stored inside the remote controller 161 is provided on the lower side in FIG. 17. The user can open the battery cover 171 and replace the secondary battery mounted therein.
[0163]
As shown in FIG. 18, a confirmation setting button 181 is provided on the right side surface 161-3 of the remote controller 161 in FIG. 16, as shown in FIG. Have been. The user instructs confirmation of the communication state, for example, by pressing the confirmation setting button 181 and releasing it within a predetermined time. When the above operation is performed by the user, the remote controller 161 performs wireless communication with the sensor unit 2 via the built-in antenna and performs processing for confirming the communication state. When the user presses the confirmation setting button 181 for more than 2 seconds, for example, the remote controller 161 performs wireless communication with the sensor unit 2 via the built-in antenna and switches the currently set alert mode setting. .
[0164]
On a surface 161-4 opposite to the surface 161-3 shown in FIG. 18, a power switch 191 for turning on or off the power of the remote controller 161 is provided as shown in FIG. Further, a charge connector cover 192 for storing a connector for charging a secondary battery incorporated in the remote controller 161 is provided below the surface 161-4.
[0165]
As shown in FIG. 20, a battery cover 171 for storing a secondary battery and a charging connector cover 192 for storing a charging connector are provided on the bottom surface 161-5 of the remote controller 161 in FIG. Is provided.
[0166]
Using the remote controller 161 as described above, the user instructs the setting of the sensor unit 2. The remote controller 161 transmits the input user's instruction to the sensor unit 2 by wireless communication via the built-in antenna. When an abnormality is found, the sensor unit 2 transmits the information to the remote controller 161 via the antenna 143. The remote controller 161 causes the corresponding LED to emit light based on the information, and notifies the user of the content of the information.
[0167]
With the above-described configuration, the user can operate the sensor unit from outside the vehicle, and further know that the sensor unit 2 has detected an abnormality outside the vehicle not only by the alarm sound but also by the display of the remote controller 161. be able to.
[0168]
FIG. 21 is a block diagram showing an example of the internal configuration of the sensor unit 2 shown in FIG. 14 and FIG.
[0169]
The positive electrode 144-1 of the terminal 144 to which the cable 3 is connected has a power supply circuit unit 211 that performs processing such as adjustment of an applied voltage, and monitors the level of the applied voltage to disconnect the cable 3. The disconnection detection circuit unit 212 that monitors whether or not the supply of power from the battery unit 1 has stopped is connected.
[0170]
In addition, the power supply circuit unit 211 applies the adjusted voltage to the CPU 214 that controls each unit of the sensor unit 2, and applies a voltage to the positive electrode of the built-in battery 213 that is a secondary battery having a smaller capacity than the secondary battery 14. A voltage is applied to charge the internal battery 213. Then, when the application of the voltage to the power supply circuit unit 211 is stopped, the electric charge charged in the internal battery 213 is supplied to the CPU 214.
[0171]
When the supply of power to the power supply circuit unit 211 is stopped and the disconnection is detected, the disconnection detection circuit unit 212 supplies information indicating the detection to the CPU 214.
[0172]
The switch unit 215 including the detection level setting switch 151 and the alarm sound setting switch 152 detects an operation of the detection level setting switch 151 or the alarm sound setting switch 152 by the user, and instructs the CPU 214 to perform a process corresponding to the operation.
[0173]
When detecting an abnormality in the sensor 141, the sensor unit 216 including the sensor 141 supplies information indicating the detection to the CPU 214.
[0174]
The selector 218 performs a process of switching a circuit connected to the antenna 143, and connects one of the wireless receiving unit 219 and the wireless transmitting unit 220 to the antenna 143. When the selector 218 acquires the transmission signal received from the remote controller 161 shown in FIGS. 16 to 20 via the antenna 143, the transmission signal is supplied to the wireless reception unit 219. The wireless reception unit 219 processes the acquired signal, extracts information from the signal, and supplies the information to the CPU 214.
[0175]
The CPU 214 performs various processes such as an alarm process for warning an abnormality based on the various types of information supplied as described above, controls the LED unit 217 to make the LEDs 142A and 142B emit light, and sets the speaker unit 221 to emit light. It controls to output an alarm sound from the speaker 16, controls the wireless transmission unit 220, transmits information related to an alarm to the remote controller 161 via the antenna 143 based on a predetermined wireless communication method, For example, the optional device connected to the 145 is controlled.
[0176]
The built-in battery 213 only needs to have enough capacity to perform the above-described alarm processing when the cable 3 is cut or the like. Therefore, compared to the secondary battery 14, the built-in battery 213 can be a small, light, and small secondary battery.
In the above description, the secondary battery is used as the built-in battery 213. However, the present invention is not limited to this, and a primary battery may be used. In that case, the manufacturing cost of the sensor unit 2 can be reduced by using a commercially available primary battery.
[0177]
Next, control processing by the sensor unit 2 shown in FIG. 21 will be described with reference to the flowcharts in FIGS.
[0178]
First, in step S81 of FIG. 22, the CPU 214 of the sensor unit 2 determines whether to end the control processing. At this time, the sensor unit 2 is in the normal mode in which the function of the sensor 141 is stopped. As described above, when it is determined that the control process is to be terminated by enabling the function of the sensor 141 and stopping the power supply in a state where the alert mode for performing the alert activity is not set, the CPU 214 determines whether the internal battery 213 is used. , The process is terminated in step S82, and the control process is terminated.
[0179]
If it is determined in step S81 that the control process is not to be ended, the CPU 214 advances the process to step S83, controls the wireless reception unit 219, and determines whether an instruction has been obtained from the remote controller 161. When it is determined that the information related to the user's instruction has not been supplied from the wireless reception unit 219 and the instruction has not been obtained, the CPU 214 returns the process to step S81, and repeats the subsequent processes.
[0180]
When information about a user's instruction corresponding to an operation of the remote controller 161 by the user is supplied from the remote controller 161 as a wireless signal of a predetermined frequency, the CPU 214 acquires the information via the wireless receiving unit 219. Then, in step S83, it is determined that the instruction has been obtained from the remote controller 70, and the process proceeds to step S84.
[0181]
In step S84, the CPU 214 determines whether or not the acquired instruction is an alert setting instruction for instructing the setting of the alert mode. If the CPU 214 determines that the acquired instruction is not an alert setting instruction, the CPU 214 proceeds to step S81. Return and perform the subsequent processing. If it is determined in step S84 that the acquired instruction is the alert setting instruction, the CPU 214 advances the process to step S85, shifts the setting from the normal mode to the alert mode, and advances the process to step S86 in FIG.
[0182]
In step S86 in FIG. 23, the CPU 214 determines whether or not to end the control processing, and when it is determined to end, returns the processing to step S82 in FIG. 22, performs the end processing, and ends the control processing. .
[0183]
If it is determined in step S86 of FIG. 23 that the control process is not to be ended, the CPU 214 proceeds to step S87, controls the sensor unit 216, and determines whether an abnormality is detected. When determining that an abnormality has been detected, the CPU 214 advances the processing to step S88. In step S88, the CPU 214 controls the speaker unit 221 to output an alarm sound from the speaker 16, and controls the LED unit 217 to perform an alarm output process of emitting an alarm by turning on the LEDs 142A and 142B. I do. Further, in step S89, the CPU 214 controls the wireless transmission unit 220 to supply, via the antenna 143, alarm information as information for notifying an abnormality to the remote controller 161 carried by the user.
[0184]
In step S90, the CPU 214 determines whether or not an instruction from the user has been received from the remote controller 161. When controlling the wireless reception unit 219 and determining that the instruction from the user has not been received, the CPU 214 returns the processing to step S86, and repeats the subsequent processing.
[0185]
If it is determined in step S90 that an instruction from the user has been received from the remote controller 161, the CPU 214 determines in step S91 whether the instruction is a warning release setting instruction. If it is determined that the instruction is the alert release setting instruction, the CPU 214 shifts the setting from the alert mode to the normal mode in step S92, returns the process to step S81 in FIG. 22, and repeats the subsequent processes.
[0186]
If it is determined in step S87 that the sensor 141 has not detected any abnormality and has not detected any abnormality, the CPU 214 determines in step S93 whether a disconnection has been detected. When the disconnection detection circuit unit 212 detects the disconnection and supplies the information to the CPU 214 to determine that the disconnection has been detected, the CPU 214 advances the processing to step S88 and executes the subsequent processing.
[0187]
If it is determined in step S93 that a disconnection has not been detected, that is, if no abnormality is found in the vehicle, the CPU 214 skips steps S88 and S89, proceeds to step S90, and thereafter proceeds to step S90. The processing of is performed.
[0188]
If it is determined in step S91 that the instruction from the user transmitted from the remote controller 161 is not the alert release setting instruction, the CPU 214 determines in step S94 that the instruction has been received by the sensor detection level setting instruction for setting the detection level of the sensor 141. It is determined whether or not there is. If it is determined that the instruction is not a sensor detection level setting instruction, the CPU 214 returns the processing to step S86, and repeats the subsequent processing.
[0189]
If it is determined in step S94 that the instruction is a sensor detection level setting instruction, in step S95, the CPU 214 sets the designated sensor detection level (either the ultra-slight level or the normal level), and proceeds to step S86. Return the process and repeat the subsequent processes.
[0190]
As described above, the CPU 214 controls each unit of the sensor unit 2 and performs a warning process in the installed vehicle.
[0191]
In the above description, the battery unit 1 has been described such that the cigarette power plug 11 and the battery box 12 are configured separately. However, the present invention is not limited to this. For example, as in the battery unit 241 shown in FIG. The power plug 11 and the battery box 12 may be integrally formed as a plug 242 and a battery 243, respectively.
[0192]
In FIG. 24, the vehicle anti-theft alarm system includes a battery unit 241 and a sensor unit 2 electrically connected to each other by a cable 3.
[0193]
The battery unit 241 includes a plug 242 connected to a cigarette lighter socket provided in a vehicle (not shown) and a battery 243 containing the secondary battery 14. The plug 242 is a dedicated plug that can be electrically connected to a cigarette lighter socket (not shown), and acquires power generated by a car engine or power supplied by a car battery via the connected cigarette lighter socket. Power plug.
[0194]
The battery unit 243 includes a terminal 244 to which the cable 3 is connected, and supplies power supplied from the vehicle side via the plug unit 242 to the sensor unit 2 electrically connected via the cable 3. . The secondary battery 14 is built in the battery unit 243, and the secondary battery 14 can be charged using the power supplied from the plug unit 242, and power is supplied from the plug unit 242. Otherwise, power is supplied to the sensor unit 2 using the secondary battery 14 via the cable 3 connected to the terminal 244. The battery unit 243 is provided with an LED 15 that indicates the state of charge of the battery unit 14.
[0195]
The internal configuration of the battery unit 241 is basically the same as that of the battery unit 1 shown in FIG. 1, and the operation of the battery unit 241 is basically the same as that of the battery unit 1 shown in FIG. Therefore, their description is omitted.
[0196]
In the battery unit 241 of FIG. 24, as shown in FIG. 25, the user attaches the terminal 253 of the cable 252 of the AC adapter 251 to the terminal 244 to which the cable 3 is attached, and uses a household power supply to The secondary battery 14 stored in the battery unit 243 of the unit 241 may be charged.
[0197]
With the above configuration, the user can easily replace the battery unit 241 that stores the secondary battery 14 with the spare battery unit 241 that stores the fully charged secondary battery 14, and , The secondary battery having no remaining capacity can be charged using a household power supply or the like.
[0198]
Although the alarm system for preventing vehicle theft has been described above, the present invention is not limited to this, and the present invention includes a main unit and a battery unit serving as a power source for the main unit. Any system may be used as long as the main body is operated using a battery unit as a power source.
[0199]
Further, the present invention is not limited to a vehicle-mounted system, for example, when the main body must be installed in a narrow space where the installation place is limited, such as the above-described vehicle anti-theft alarm system, It is particularly suitable when the effect can be obtained by reducing the size and weight of the main body, such as when the part must be made inconspicuous.
[0200]
When a series of processing is executed by software, a program constituting the software executes various functions by installing a computer built in dedicated hardware or installing various programs. For example, it is installed from a network or a recording medium into a general-purpose personal computer or the like.
[0201]
Although not shown, the recording medium is distributed separately from the apparatus main body to provide the user with the program, and is recorded on a magnetic disk (including a floppy disk) on which the program is recorded, an optical disk (CD-ROM, In addition to a package medium including a DVD, a magneto-optical disk (including an MD), or a semiconductor memory, a program that is provided to a user in a state where the program is incorporated in a main body of the apparatus in advance is recorded. The power control unit 83, the CPU 94, or the ROM 214 or the RAM built in the CPU 214.
[0202]
In this specification, a step of describing a program recorded on a recording medium may be performed in chronological order according to the described order, or may be performed in parallel or not necessarily in chronological order. This also includes processes executed individually.
[0203]
【The invention's effect】
As described above, according to the alarm system, the alarm device and the method, the power supply device and the method, and the program of the present invention, the device can be suitably installed. In particular, the vehicle anti-theft device can be reduced in size and weight, can be installed more safely and easily, and at the same time, increase in battery capacity and improvement in convenience can be achieved while suppressing an increase in cost. Can be.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration example of a vehicle theft prevention alarm system to which the present invention is applied.
FIG. 2 is a diagram showing an example of the appearance of the cigarette power plug and cable of FIG. 1;
FIG. 3 is a perspective view showing an example of the appearance of the battery box of FIG. 1;
FIG. 4 is a perspective view showing an example of the appearance of the battery box of FIG.
FIG. 5 is a diagram showing an example of the appearance of the sensor unit of FIG. 1;
FIG. 6 is a diagram showing an example of the appearance of the sensor unit of FIG. 1;
FIG. 7 is a diagram showing an appearance of a remote controller for controlling the sensor units of FIGS. 5 and 6.
8 is a block diagram showing an example of the internal configuration of the battery box shown in FIGS. 3 and 4. FIG.
FIG. 9 is a block diagram showing an example of the internal configuration of the sensor unit shown in FIGS. 5 and 6;
FIG. 10 is a diagram showing an example of connecting an AC adapter to the battery box of FIG. 1;
FIG. 11 is a flowchart illustrating a charge control process executed by the battery box shown in FIG. 8;
FIG. 12 is a flowchart illustrating a control process performed by a sensor unit.
FIG. 13 is a flowchart illustrating the control processing by the sensor unit, continued from FIG. 12;
FIG. 14 is an external view showing another example of the sensor unit.
FIG. 15 is an external view showing another example of the sensor unit.
FIG. 16 is a diagram illustrating an example of an external appearance of a remote controller corresponding to the sensor units in FIGS. 14 and 15;
FIG. 17 is a diagram illustrating an example of an external appearance of a remote controller corresponding to the sensor units in FIGS. 14 and 15;
FIG. 18 is a diagram illustrating an example of an external appearance of a remote controller corresponding to the sensor units in FIGS. 14 and 15;
FIG. 19 is a diagram illustrating an example of an external appearance of a remote controller corresponding to the sensor units in FIGS. 14 and 15;
FIG. 20 is a diagram illustrating an example of an external appearance of a remote controller corresponding to the sensor units in FIGS. 14 and 15;
FIG. 21 is a block diagram showing an example of the internal configuration of the sensor unit shown in FIGS. 14 and 15;
FIG. 22 is a flowchart illustrating a control process performed by the sensor unit shown in FIG. 21.
FIG. 23 is a flowchart illustrating the control processing by the sensor unit shown in FIG. 21 and subsequent to FIG. 22;
FIG. 24 is a diagram showing another configuration example of the battery unit.
25 is a diagram showing an example in which an AC adapter is connected to the battery unit in FIG. 24.
[Explanation of symbols]
1 Battery unit
2 Sensor unit
11 Cigarette power plug
12 Battery box
14 Secondary battery
16 speakers
61 Mounting spring
83 Power control unit
92 Disconnection detection circuit
93 Built-in battery
94 CPU
212 Disconnection detection circuit
214 CPU
241 Battery unit
242 plug section
243 Battery section

Claims (27)

An alarm device that detects abnormalities in the surroundings,
An alarm system comprising a power supply device detachably connected to the alarm device and supplying power to the alarm device,
The alarm device,
Detecting means that operates with the electric power supplied from the power supply device, monitors a state around the alarm device, and detects an abnormality.
Operating by the power supplied from the power supply device, the detecting means, when the abnormality is detected, an alarm means for alarming,
First control means for controlling the detection means and the alarm means,
The power supply device,
Acquiring means for acquiring power from another device;
A first power storage unit that includes a power storage element and stores the power acquired by the acquisition unit;
A first power supply unit configured to supply the power acquired by the acquisition unit or the power stored by the first power storage unit to the alarm device;
An alarm system comprising: a second control unit that controls the first power storage unit and the first power supply unit and controls power supply to the alarm device. 2. The alarm system according to claim 1, wherein the obtaining unit obtains the power from a power supply device of a vehicle in which the alarm device is installed or a commercial power supply. 3. The alarm system according to claim 1, wherein the first power storage unit is detachable from the power supply device. The second control means includes:
When the obtaining unit can obtain the power, the first power supply unit is controlled, and the power obtained by the obtaining unit is supplied to the alarm device;
The method according to claim 1, wherein when the acquisition unit cannot acquire the power, the first power supply unit is controlled to supply the power stored by the first power storage unit to the alarm device. 3. The alarm system according to any one of 3. When the output voltage of the first power storage means is equal to or less than a predetermined threshold, the second control means controls the first power storage means to store the power obtained by the obtaining means. The alarm system according to any one of claims 1 to 4, wherein The power supply device further includes a temperature measurement unit that measures a temperature around the first power storage unit,
The second control unit controls the first power storage unit to store the power acquired by the acquisition unit when the measurement result by the temperature measurement unit is within a predetermined temperature range. The alarm system according to any one of claims 1 to 5, wherein: The second control means controls the first power storage means when a predetermined time has elapsed from the power storage start time of the first power storage means, and stores the power of the power acquired by the acquisition means. The alarm system according to any one of claims 1 to 6, wherein the alarm system is terminated. The alarm system according to any one of claims 1 to 7, wherein the power supply device further includes a display unit that displays information related to power storage by the first power storage unit. The detecting means detects at least one of a pressure change around the alarm device, a vibration of the alarm device, a temperature change around the alarm device, and a tilt of the alarm device. The alarm system according to any one of claims 1 to 8, wherein 10. The alarm device according to claim 1, wherein the alarm unit includes at least one of a sound output unit that outputs an alarm sound and a light emitting unit that includes a light emitting element, and issues an alarm by sound or light. The alarm system described. The first control means may include an operation mode of the alarm device, a first mode for operating the detection means and the alarm means, and a second mode for not operating the detection means and the alarm means. The alarm system according to any one of claims 1 to 10, wherein the alarm system is set to any one of them. The alarm device,
Power supply abnormality detection means for detecting a stop of supply of power from the power supply device,
And second power supply means for supplying power.
The first control means operates using the power supplied from the second power supply means when an abnormality is detected by the power supply abnormality detection means, and in this case, the operation mode of the alarm device is The alarm system according to claim 11, wherein in the first mode, the alarm unit is controlled to generate an alarm. 13. The alarm system according to claim 12, wherein the second power supply unit includes a primary battery. The alarm system according to claim 12, wherein the second power supply unit includes a power storage element, and includes a second power storage unit that stores the power supplied from the power supply device. The alarm system according to any one of claims 1 to 14, wherein the alarm device further includes a receiving unit that receives an instruction from a user. 16. The method according to claim 15, wherein the receiving unit is configured separately from the alarm device, and supplies the received instruction from the user to the alarm device via wireless communication using infrared rays or radio waves. The alarm system described. The alarm unit further includes a wireless communication unit that performs wireless communication using radio waves,
2. The method according to claim 1, wherein when an abnormality is detected by the detection unit, alarm information for alarming the abnormality is transmitted to a wireless receiving device carried by the user using wireless communication by the wireless communication unit. 17. The alarm system according to any one of claims 16 to 16. In a power supply device detachably connected to a first other device and supplying power to the first other device,
Acquiring means for acquiring power from the second other device;
A power storage unit comprising a power storage element and storing the power obtained by the obtaining unit;
A power supply unit configured to supply the power acquired by the acquisition unit or the power stored by the power storage unit to the first other device;
Control means for controlling the power storage means and the power supply means and controlling supply of power to the first other device. 19. The power supply device according to claim 18, wherein the acquisition unit acquires the power from a power supply device of a vehicle in which the first other device is installed or a commercial power supply. 20. The power supply device according to claim 18, wherein the power storage unit is detachable from the power supply device. The control means includes:
When the obtaining unit can obtain the power, the power control unit controls the power supply unit, and supplies the power obtained by the obtaining unit to the first other device;
21. The method according to claim 18, wherein when the acquisition unit cannot acquire the power, the power supply unit is controlled to supply the power stored by the power storage unit to the first device. A power supply device according to claim 1. 22. The control device according to claim 18, wherein when the output voltage of the power storage device is equal to or lower than a predetermined threshold, the control device controls the power storage device to store the power obtained by the obtaining device. A power supply device according to any one of the above. The power supply device further includes a temperature measurement unit that measures a temperature around the power storage unit,
19. The control device according to claim 18, wherein when the measurement result by the temperature measurement device is within a predetermined temperature range, the control device controls the power storage device to store the power acquired by the acquisition device. 23. The power supply device according to any one of claims to 22. The control means controls the power storage means and terminates the storage of the power acquired by the acquisition means when a predetermined time has elapsed from the power storage start time by the power storage means. 24. The power supply device according to any one of 18 to 23. The power supply device according to any one of claims 18 to 24, wherein the power supply device further includes a display unit that displays information regarding power storage by the power storage unit. A power supply device that includes a power storage unit including a power storage element, is detachably connected to the first other device, and supplies power supplied from the second other device to the first other device. In the power supply method,
A supply control step of controlling supply of the power to the first other device;
A charging control step of controlling charging by the power storage unit. A program for causing a computer to execute the power supply method according to claim 26.

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