JP2006004249A - Standby power supply system for disaster prevention device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To exchange a rechargeable battery without reconstruction of a disaster prevention device. <P>SOLUTION: The standby power supply system for the disaster prevention device equipped with a standby power supply connector 8 enabling to put on and take off a nicad battery as a standby power supply comprises the second rechargeable battery pack 11, a type different from the nicad battery, and a charge and discharge control part 12 for controlling charge and discharge of the second rechargeable battery pack 11, enabling to connect the second rechargeable battery pack 11 and charge and discharge control part 12 directly and indirectly to the standby power supply connecting part 8. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a standby power supply system for a disaster prevention device, which is provided in various disaster prevention devices such as a fire alarm facility and a security facility, and which supplies power to the disaster prevention device in advance when an abnormality or the like occurs in a main power source. .

  When various disaster prevention devices such as fire alarm equipment and security equipment cannot perform their required disaster prevention functions when necessary, there is a possibility of inviting a serious situation involving human lives. Therefore, a high degree of reliability is required for such a disaster prevention device. For this reason, a spare battery has conventionally been installed in the disaster prevention apparatus in addition to the main power source. Specifically, a spare battery accommodating portion for detachably attaching a spare battery is provided inside the disaster prevention device or the like, and the spare battery is attached to the spare battery accommodating portion. According to such a configuration, when a failure occurs in the power supply from the main power supply due to a power failure or other abnormality, the required disaster prevention function can be maintained by supplying power from the spare battery.

  Conventionally, rechargeable nickel-cadmium batteries have been widely used as spare batteries for such disaster prevention devices (see, for example, Patent Documents 1 to 3). The nickel-cadmium battery is charged by a charging method generally referred to as a trickle charging method. This trickle charging method normally charges the battery with a current that is about 1/40 to 1/50 of the battery capacity. By charging in this way, the nickel-cadmium battery is always charged. I was getting the required power when needed.

JP 2001-118165 A JP 2001-268820 A JP 2001-338362 A

  Here, due to the recent increase in awareness of environmental problems, other secondary batteries having a relatively low environmental load, such as lithium ion batteries and nickel metal hydride batteries, instead of nickel cadmium batteries that use cadmium, which is a harmful substance, are used. There is a growing need to use. However, since charge control and discharge control are different between the nickel-cadmium battery and other secondary batteries, other secondary batteries cannot simply be installed in place of the nickel-cadmium battery. In this case, it is also conceivable to provide a control circuit for charging / discharging a secondary battery other than the NiCad battery by modifying the standby power supply system for the newly installed disaster prevention device. However, since it is difficult to modify the control unit of the existing disaster prevention device, a standby power supply system that can replace the secondary battery without such modification has been demanded.

  This invention is made in view of the above, Comprising: It aims at providing the standby power supply system of a disaster prevention apparatus etc. which can replace | exchange a secondary battery without accompanying the modification of a disaster prevention apparatus, etc. .

  In order to solve the above-described problems and achieve the object, the standby power supply system of the disaster prevention device according to claim 1 is provided with a standby power connection means that can attach and detach the first secondary battery as a backup power source. In the standby power supply system of the apparatus, comprising: a second secondary battery of a type different from the first secondary battery; and charge / discharge control means for performing charge control and discharge control of the second secondary battery, The second secondary battery and the charge / discharge control means can be connected directly or indirectly to the standby power supply connection means.

  The standby power supply system for the disaster prevention device according to claim 2 is the standby power supply system for the disaster prevention device according to claim 1, wherein the second secondary battery and the charge / discharge control means are connected to the standby power supply means. It is housed in a housing that can be directly connected to the housing.

  The standby power supply system for the disaster prevention device according to claim 3 is the standby power supply system for the disaster prevention device according to claim 1, wherein the second secondary battery and the charge / discharge control means are connected to the standby power supply means. It is possible to connect indirectly via the first connector.

  Further, the standby power supply system of the disaster prevention device according to claim 4 is the standby power supply system of the disaster prevention device according to claim 1, wherein the charge / discharge control means is connected to the secondary power supply connecting means. The second secondary battery is housed and connected to the second connector.

  Moreover, the standby power supply system of the disaster prevention device according to claim 5 is the standby power supply system of the disaster prevention device according to any one of claims 1 to 4, wherein the charge / discharge control means controls a current during charging. And a charge control means for controlling the current during discharge.

  The standby power supply system for a disaster prevention device according to claim 6 is the standby power supply system for the disaster prevention device according to any one of claims 1 to 5, wherein the first secondary battery is a nickel-cadmium battery. The second secondary battery is a nickel metal hydride battery or a lithium ion battery.

  The standby power supply system for a disaster prevention apparatus according to the present invention can easily replace an existing secondary battery with another type of secondary battery with reduced environmental load without modifying the disaster prevention apparatus. Therefore, the secondary battery can be easily replaced also in the existing disaster prevention device at the time of periodic inspection.

  Further, the standby power system of the disaster prevention apparatus according to the present invention can replace the secondary battery simply by removing the existing secondary battery from the standby power connection means and housing the casing in the backup power connection means. it can.

  Moreover, the standby power supply system of the disaster prevention apparatus according to the present invention replaces the secondary battery only by removing the existing secondary battery from the standby power connection means and connecting the first connector to the backup power connection means. be able to.

  Moreover, the standby power system of the disaster prevention apparatus according to the present invention replaces the secondary battery only by removing the existing secondary battery from the standby power connection means and connecting the second connector to the backup power connection means. be able to.

  Moreover, the standby power supply system of the disaster prevention device according to the present invention can perform charge control and discharge control, and can absorb the difference in charge / discharge system according to the type of secondary battery.

  Moreover, the standby power supply system of the disaster prevention device according to the present invention can replace the nickel-cadmium battery with a nickel-metal hydride battery or a lithium ion battery.

  Exemplary embodiments of a standby power supply system for a disaster prevention device according to the present invention will be explained below in detail with reference to the accompanying drawings. First, [I] the basic concept of the present invention will be described, then [II] each embodiment of the present invention will be described, and [III] Finally, modifications to the embodiment of the present invention will be described.

[I] Basic concept of the present invention First, the basic concept of the present invention will be described. The present invention relates to a standby power supply system provided in a disaster prevention device used for various disaster prevention facilities. Here, the specific configuration of the disaster prevention equipment is arbitrary, and all equipment that can realize an arbitrary function related to disaster prevention is applicable. For example, a fire occurrence or a gas leak in a specific monitoring area is detected and notified. Fire gas leak notification equipment, fire extinguishing equipment that automatically extinguishes when a fire occurs, and security equipment that controls the entry and exit of people within a specific monitoring area. In addition, the specific configuration of the disaster prevention device is also arbitrary, and all facilities that can realize an optional function related to disaster prevention are applicable. For example, in a fire alarm facility, the alarm output from a plurality of fire detectors is received. This applies to receivers that perform relocation control.

  Here, one of the main features of the present invention is that, instead of a secondary battery (for example, a nickel-cadmium battery) in a conventional standby power supply system, a different type of secondary battery (for example, an environmental load is less than that of a nickel-cadmium battery), Lithium ion battery or nickel metal hydride battery) can be used, and in particular, such battery replacement can be performed without requiring improvement of the disaster prevention device. For this reason, in the present invention, a nickel-metal hydride battery or a lithium ion battery and a charge / discharge control unit that performs charge control and discharge control of these batteries are connected to a standby power supply connection unit to which a conventional secondary battery is connected. Connectable. According to this configuration, a new secondary battery can be connected to the same standby power supply connection unit as in the past, and differences in battery charging methods can be absorbed by the charge / discharge control unit. There is no need to modify the connections. Therefore, the conventional nickel-cadmium battery can be replaced with a lithium ion battery or a nickel metal hydride battery for the existing disaster prevention device.

[II] Embodiments of the Present Invention Next, embodiments of the standby power supply system of the disaster prevention apparatus according to the present invention will be described. However, the present invention is not limited by these embodiments.

[Embodiment 1]
First, the first embodiment will be described. The standby power supply system of the disaster prevention apparatus according to the first embodiment is schematically (1) a second secondary battery of a type different from the first secondary battery, and charge control of the second secondary battery. And a charge / discharge control means for performing discharge control, the second secondary battery and the charge / discharge control means can be connected directly or indirectly to the standby power supply connection means, and (2) a second The secondary battery and the charge / discharge control means are housed in a casing that can be directly connected to the standby power supply connection means.

(Outline of standby power supply system for disaster prevention equipment)
First, an outline of the standby power supply system for the disaster prevention apparatus according to Embodiment 1 will be described. FIG. 1 is a circuit diagram illustrating the configuration of the power supply system of the disaster prevention device. In FIG. 1, an internal circuit 1 is a conceptual circuit that exhibits the main function of the disaster prevention apparatus according to the first embodiment. The power supply system for supplying required power to the internal circuit 1 includes a main power supply 2, rectifier circuits 3 and 4, a power supply monitoring circuit 5, a changeover switch 6, a charging current control circuit 7, and a standby power supply connection unit 8. Has been.

  Among these, the main power supply 2 is a power supply during normal operation, and for example, a commercial power supply is used. The rectifier circuits 3 and 4 are rectifiers that convert alternating current into direct current by transforming and rectifying the alternating current. The power supply monitoring circuit 5 monitors the voltage supplied to the internal circuit 1 and drives the changeover switch 6 composed of a relay or the like when an abnormality occurs in the main power supply 2, so that the standby power supply It is power supply monitoring means for switching to. The charging current control circuit 7 is charging control means for limiting the charging current to the nickel-cadmium battery 9 connected to the standby power supply connection unit 8 to a predetermined value or less in order to prevent overcharging of the secondary battery. .

  Further, the standby power connection unit 8 is for detachably connecting a secondary battery as a backup power source, and corresponds to backup power connection means in the claims. Specifically, the standby power supply connection portion 8 is configured as a connector that can attach and detach a nickel-cadmium battery 9 (corresponding to the first secondary battery in the claims) or a secondary battery unit 10 described later. In addition, the nickel-cadmium battery 9 connected to the standby power connection unit 8 in this way can be specifically configured as a battery pack configured by directly connecting a plurality of nickel-cadmium units (not shown), for example, 24V is output by directly connecting 20 1.2V NiCd battery units.

  In such a configuration, an alternating current supplied from the main power supply 2 is converted into a direct current by the rectifier circuit 4 and then supplied to the internal circuit 1. Here, when the supply voltage to the internal circuit 1 is equal to or higher than a predetermined value, the power supply monitoring circuit 5 determines that there is no abnormality in the main power supply 2 and sets the changeover switch 6 to the main power supply side (the solid line shown in the figure). The current from the main power supply 2 is supplied to the internal circuit 1. On the other hand, when the supply voltage to the internal circuit 1 falls below a predetermined value, the power supply monitoring circuit 5 determines that an abnormality has occurred in the main power supply 2 due to a power failure or the like, and switches the changeover switch 6 to the standby power supply side ( Switch to the dotted line side in the figure. In this case, the standby power supply connection unit 8 is connected to the internal circuit 1, and the current supplied from the nickel-cadmium battery 9 or the secondary battery unit 10 attached to the standby power supply connection unit 8 is supplied to the internal circuit 1. Therefore, the function of the internal circuit 1 is maintained even when the main power supply 2 is abnormal.

  In addition, with such a power supply system, the nickel-cadmium battery 9 is charged by the trickle charging method as in the conventional case. That is, the current supplied from the main power supply 2 is made constant current or current limited by the charging current control circuit 7 and then supplied to the nickel-cadmium battery 9 via the standby power supply connection portion 8. Here, the supplied current is a minute current corresponding to the amount of self-discharge of the nickel-cadmium battery 9, and the self-discharge is supplemented by this current, so that the nickel-cadmium battery 9 is maintained in a fully charged state.

(Configuration of secondary battery unit)
Next, the secondary battery unit 10 connected to the standby power connection unit 8 will be described. FIG. 2 is a circuit diagram centering on the secondary battery unit of FIG. In FIG. 2, the secondary battery unit 10 can be detachably connected to the standby power supply connection portion 8 instead of the nickel-cadmium battery 9, and the secondary battery pack 11 and the charge / discharge control circuit 12 are combined into one unit. The housing 13 is packaged and configured. Among these, the secondary battery pack 11 is configured by directly connecting a plurality of predetermined secondary batteries of a different type from the nickel-cadmium battery 9 of FIG. 1, for example, a lithium ion battery unit or a nickel hydrogen battery unit, This corresponds to the second secondary battery in the claims. In the following description, it is assumed that the secondary battery pack 11 is configured using a lithium ion battery unit. Although the number of connected lithium ion battery units and the output voltage of a single unit are arbitrary, it is preferable to secure an output voltage equivalent to the Nicad battery 9 of FIG. By directly connecting 20 lithium ion battery units, the secondary battery pack 11 outputs 24V.

  The charge / discharge control circuit 12 performs charge control and discharge control of the secondary battery, and corresponds to charge / discharge control means in the claims. The charge / discharge control circuit 12 includes a charge control circuit 14 and a discharge control circuit 15. Among these, the charge control circuit 14 performs charge control for the lithium ion battery in order to prevent overcharge of the lithium ion battery, and corresponds to the charge control means in the claims. The discharge control circuit 15 performs discharge control on the lithium ion battery in order to prevent overdischarge of the lithium ion battery, and corresponds to the discharge control means in the claims. In addition, the secondary battery unit 10 includes a fuse 18 for short circuit protection.

(Removable battery unit configuration)
The secondary battery unit 10 configured in this manner can be detachably connected to the standby power supply connection portion 8 in substantially the same manner as the nickel-cadmium battery 9 of FIG. Specifically, the secondary battery unit 10 is housed in a housing 13 having substantially the same external shape as the nickel-cadmium battery 9, and the secondary battery unit 10 is accommodated in the same accommodation space as the nickel-cadmium battery 9. Can do. In addition, connection terminals 13a are provided at both ends of the housing 13, and the positions and shapes of the connection terminals 13a substantially correspond to the connection terminals provided at both ends of the nickel-cadmium battery 9 in FIG. Yes. Therefore, the secondary battery unit 10 is accommodated in the accommodation space of the nickel-cadmium battery 9 so that the connection terminal 13a is connected to the connection terminal 10a provided in the standby power supply connection portion 10, and thus the secondary battery unit 10 is shown in FIG. 1 is connected to the main power supply 2 or the internal circuit 1 and can be charged and discharged in the same manner as the nickel-cadmium battery 9.

(Charge control of secondary battery unit)
Next, charging control for the secondary battery unit 10 will be described in more detail. As a charging method for the secondary battery unit 10, a known method according to the appropriateness of the secondary battery used for the secondary battery unit 10 can be adopted. However, since the charging system is different between the nickel-cadmium battery 9 of FIG. 1 and the lithium ion battery, it is necessary to consider this difference. That is, the NiCad battery 9 employs the trickle charging method as described above, and is charged by constantly supplying a constant current to the NiCad battery 9. On the other hand, when charging a lithium ion battery, it is known that if left in a fully charged state, it will cause battery deterioration. Therefore, a trickle charging system that constantly supplies a constant current is not preferable.

  For this reason, in this embodiment, a pulse charging method is adopted as a charging method for the lithium ion battery. FIG. 3 is a circuit diagram of the charge control circuit of FIG. As shown in FIG. 3, the charging control circuit 14 includes a voltage detection circuit 14a, a switching control circuit 14b, and a changeover switch 14c. Among these, the voltage detection circuit 14 a is voltage value monitoring means for detecting the voltage value of the secondary battery pack 11. The switching control circuit 14b is switching control means for switching the selector switch 14c based on the control from the voltage detection circuit 14a.

In such a configuration, the current supplied from the main power supply 2 of FIG. 1 and converted into direct current by the rectifier circuit 3 is supplied to the charging control circuit 14 of FIG. Then, the voltage detection circuit 14a, until the voltage value of the secondary battery pack 11 reaches a predetermined charge termination voltage V _1, it is determined not to have reached the overcharge, by controlling the switching control circuit 14b selector switch 14c is turned on and charging is performed by supplying a constant current to the secondary battery pack 11. Thereafter, when the voltage value of the secondary battery pack 11 reaches the predetermined charging end voltage V ₁ , the voltage detection circuit 14a determines that there is a risk of overcharging if further charging is continued, and switching control is performed. The circuit 14b is controlled to turn off the changeover switch 14c, and the charging is stopped by interrupting the current supply to the secondary battery pack 11. These steps are repeated, and the charging is terminated when the time during which charging is stopped becomes equal to or greater than a certain value with respect to the time during which charging is performed. Thereby, the overcharge of the secondary battery pack 11 can be prevented.

(Discharge control of secondary battery unit)
Next, the discharge control for the secondary battery unit 10 will be described in more detail. In FIG. 2, a discharge control circuit 15 that performs discharge control of the secondary battery unit 10 can be configured in substantially the same manner as the charge control circuit 14 of FIG. That is, the discharge control circuit 15 includes a voltage detection circuit, a change control circuit, and a changeover switch (not shown). In FIG. 1, when an abnormality occurs in the main power supply 2 and power supply switching is performed by the power supply monitoring circuit 5, a voltage detection circuit (not shown) in the discharge control circuit 15 of FIG. Until the voltage value reaches a predetermined discharge end voltage V ₁ , it is determined that overdischarge has not occurred, and the changeover control circuit is controlled to turn on the changeover switch. Power is supplied to the disaster prevention device via Thereafter, when the voltage value of the secondary battery pack 11 reaches the predetermined discharge end voltage V ₁ , the voltage detection circuit determines that there is a risk of overdischarge if further discharge is continued, and the switching control circuit Is controlled to turn off the changeover switch to stop the power supply to the disaster prevention device. Thereby, the overdischarge of the secondary battery pack 11 can be prevented.

(Effect of Embodiment 1)
As described above, according to the standby power supply system of the disaster prevention apparatus according to the present embodiment, the secondary battery unit 10 can be directly connected to the standby power supply connection portion 8 instead of the nickel-cadmium battery 9. For this reason, it is possible to easily replace the battery with a reduced environmental load without modifying the disaster prevention device. Moreover, since the overcharge can be prevented by the charge control circuit 14 and the overdischarge can be prevented by the discharge control circuit 15, the difference in charge / discharge format can be absorbed on the battery side without modifying the disaster prevention device.

[Embodiment 2]
Next, a standby power supply system for a disaster prevention apparatus according to Embodiment 2 will be described. The standby power supply system of the disaster prevention apparatus according to the present embodiment generally has the same features as those of the first embodiment, except that the second secondary battery and the charge / discharge control means are connected to the backup power supply connecting means with a connector. One of the main features is that connection is possible indirectly. Note that structures and methods that are not particularly described are the same as those in the first embodiment described above, and the same components are described with the same reference numerals.

(Outline of standby power supply system for disaster prevention equipment)
FIG. 4 is a circuit diagram illustrating the configuration of the power supply system of the disaster prevention device according to the second embodiment, and FIG. 5 is a circuit diagram centering on the secondary battery unit of FIG. In FIG. 4, the disaster prevention apparatus is provided with a main body side connector 20. The main body side connector 20 is for detachably connecting a secondary battery as a backup power source, and corresponds to the backup power source connecting means in the claims. Specifically, the main body side connector 20 is configured as a connector to which the battery side connector 30 can be attached and detached.

  In addition, the battery-side connector 30 and the nickel-cadmium battery 9 or the secondary battery unit 10 are sequentially and integrally connected to the main body-side connector 20. That is, the battery side connector 30 and the nickel-cadmium battery 9 are integrally connected, or the battery side connector 30 and the secondary battery unit 10 are integrally connected. Among these, the battery-side connector 30 enables the nickel-cadmium battery 9 or the secondary battery unit 10 to be indirectly connected to the main-body-side connector 20 as a backup power source connecting means, and is used as the first connector in the claims. Correspond. The specific structure of the battery-side connector 30 is arbitrary. For example, the battery-side connector 30 is configured by covering a conductive wire with resin, and can be fixed to the main body-side connector 20 via a lock mechanism (not shown). Here, the battery-side connector 30 connected integrally to the nickel-cadmium battery 9 and the battery-side connector 30 connected integrally to the secondary battery unit 10 are configured in the same manner.

(Configuration of secondary battery unit)
Further, as shown in FIG. 5, the secondary battery unit 10 is configured by packaging a secondary battery pack 11 and a charge / discharge control circuit 12 in a single housing 13. Since these secondary battery pack 11 and charge / discharge control circuit 12 can be configured in the same manner as in the first embodiment, description thereof is omitted. The secondary battery pack 11 and the charge / discharge control circuit 12 are each connected to a battery side connector 30 as shown in the figure, and indirectly via the battery side connector 30 to a main body side connector 20 serving as a backup power source connecting means. Connected to.

  In such a configuration, when the battery-side connector 30 and the nickel-cadmium battery 9 are connected to the existing disaster prevention device, the battery-side connector 30 and the nickel-cadmium battery 9 are integrally removed while being integrally connected. By preparing the battery side connector 30 and the secondary battery unit 10 and inserting the battery side connector 30 into the main body side connector 20, the secondary battery unit 10 can be easily connected to the disaster prevention device.

(Effect of Embodiment 2)
As described above, according to the standby power supply system of the disaster prevention apparatus according to the present embodiment, the secondary battery unit 10 is indirectly connected to the main body side connector 20 via the battery side connector 30 instead of the nickel-cadmium battery 9. Can do. For this reason, it is possible to easily replace the battery with a reduced environmental load without modifying the disaster prevention device. Further, since the overcharge can be prevented by the charge control circuit 14 built in the secondary battery unit 10 and the overdischarge can be prevented by the discharge control circuit 15, the battery side can be charged without modifying the disaster prevention device. It can absorb the difference in discharge type.

[Embodiment 3]
Next, a standby power supply system for a disaster prevention apparatus according to Embodiment 3 will be described. The standby power supply system of the disaster prevention apparatus according to the present embodiment generally has the same characteristics as those of the second embodiment, but the charge / discharge control means is accommodated in a second connector that can be connected to the standby power connection means. One of the main features is that the second secondary battery is connected to the second connector. Note that the structure and method that are not particularly described are the same as those in the third embodiment described above, and the same components are described with the same reference numerals.

(Outline of standby power supply system for disaster prevention equipment)
FIG. 6 is a circuit diagram illustrating the configuration of the power supply system of the disaster prevention device according to the third embodiment, and FIG. 7 is a circuit diagram centering on the secondary battery unit of FIG. In FIG. 6, the disaster prevention apparatus is provided with a main body side connector 20. The main body side connector 20 is for detachably connecting a secondary battery as a backup power source, and corresponds to the backup power source connecting means in the claims. The main body side connector 20 is configured in the same manner as in the second embodiment, and the nickel-cadmium battery 9 can be connected via the battery side connector 30 in the second embodiment.

  Further, the battery-side connector 40 and the secondary battery pack 11 are sequentially and integrally connected to the main body-side connector 20. Among these, the battery-side connector 40 is configured to include a charge / discharge control circuit 41, and this charge / discharge control circuit 41 can be connected to the main body-side connector 20 as a reserve power supply connecting means. This corresponds to the second connector in the claims. As shown in FIG. 7, the charge / discharge control circuit 41 built in the battery-side connector 40 includes a charge control circuit 14 and a discharge control circuit 15 similar to those in the first embodiment. Therefore, the difference in charge / discharge format based on the difference in battery type can be absorbed in the battery side connector 40.

  Moreover, since the secondary battery pack 11 can be configured in the same manner as in the first embodiment, the description thereof is omitted. As shown in FIG. 7, the secondary battery pack 11 is connected to a charge / discharge control circuit 41 of the battery-side connector 40, and the battery-side connector 40 is connected to the main body-side connector 20 as a standby power source connection means. Connected indirectly.

  In such a configuration, when the battery-side connector 40 and the nickel-cadmium battery 9 are connected to the existing disaster prevention device, the battery-side connector 40 and the nickel-cadmium battery 9 are integrally removed while being integrally connected. By preparing the battery side connector 40 and the secondary battery pack 11 and inserting the battery side connector 40 into the main body side connector 20, the secondary battery pack 11 can be easily connected to the disaster prevention device.

(Effect of Embodiment 3)
As described above, according to the standby power supply system of the disaster prevention apparatus according to the present embodiment, the secondary battery pack 11 is replaced with the main body side connector 20 serving as the backup power source connecting portion via the battery side connector 40 instead of the nickel-cadmium battery 9. Can be connected indirectly. For this reason, it is possible to easily replace the battery with a reduced environmental load without modifying the disaster prevention device. Moreover, since the overcharge can be prevented by the charge control circuit 14 built in the battery side connector 40 and the overdischarge can be prevented by the discharge control circuit 15, the battery side can be charged / discharged without modifying the disaster prevention device. Can absorb differences in format.

[III] Modifications to Embodiments Although the embodiments of the present invention have been described above, the specific configuration and method of the present invention are within the scope of the technical idea of each invention described in the claims. Can be arbitrarily modified and improved. Hereinafter, such a modification will be described.

(About batteries)
The specific type of battery is not limited to the above-described content. For example, the first secondary battery may be any battery other than the nickel-cadmium battery 9, and the second secondary battery exchanged with the first secondary battery is also a lithium ion battery or nickel metal hydride. It can be any battery other than a battery.

(About charge / discharge system)
Further, the charge control or discharge control executed by the charge / discharge control circuits 12 and 41 is not limited to the above-described control contents. For example, when a lithium ion battery is used as the second secondary battery, a constant current / constant voltage charging method may be used. Alternatively, when a nickel metal hydride battery is used as the second secondary battery, the charge control circuit 14 detects a -ΔV detection circuit that detects a voltage drop of the second secondary battery, or a rate of temperature increase with time. A ΔT / Δt detection circuit can be used. Further, a protection circuit such as a timer circuit, a temperature detection circuit, or an overvoltage detection circuit may be provided so that overcharge does not occur even when these -ΔV detection circuit and ΔT / Δt detection circuit do not operate. Among these, the timer circuit shuts down charging when the charging time exceeds the set time. In the temperature detection circuit, charging is shut down when the temperature of the second secondary battery exceeds the set temperature. The overvoltage detection circuit shuts down charging when the voltage value of the second secondary battery exceeds the set voltage value. These charge shutdowns can be achieved by turning off the changeover switch of FIG.

(About problems to be solved and effects of the invention)
In addition, the problems to be solved by the invention and the effects of the invention are not limited to the above-described contents, and the present invention solves the problems not described above or has the effects not described above. There are also cases where only some of the described problems are solved or only some of the described effects are achieved. For example, even if a slight improvement is required for the disaster prevention device, as long as the first secondary battery can be easily replaced with the second secondary battery, some of the problems of the present application have been solved. Yes.

(About control)
In addition, all or any part of the control described as being automatically performed in each of the embodiments may be performed manually, and conversely, all or any of the control described as being performed manually is performed. A part may be automated based on a known technique or the above-described idea. In addition, the control unit shown in each embodiment and each processing block in the control unit can actually be configured as a CPU and a computer program read and executed by the CPU, or a hard-wired logic. Can be configured. Further, each of the electrical components described above is functionally conceptual and does not necessarily need to be physically configured as illustrated.

  As described above, the standby power system of the disaster prevention device according to the present invention is useful for replacing the secondary battery installed as the standby power source of the disaster prevention device with a different type of secondary battery. It is suitable for easily replacing the secondary battery without remodeling.

1 is a circuit diagram illustrating the configuration of a power supply system for a disaster prevention device according to Embodiment 1. FIG. It is a circuit diagram centering on the secondary battery unit of FIG. FIG. 3 is a circuit diagram of the charge control circuit of FIG. 2. 6 is a circuit diagram illustrating a configuration of a power supply system of a disaster prevention device according to Embodiment 2. FIG. It is a circuit diagram centering on the secondary battery unit of FIG. 6 is a circuit diagram illustrating the configuration of a power supply system of a disaster prevention device according to Embodiment 3. FIG. It is a circuit diagram centering on the secondary battery unit of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Internal circuit 2 Main power supply 3, 4 Rectification circuit 5 Power supply monitoring circuit 6 Changeover switch 7 Charging current control circuit 8 Reserve power supply connection part 9 Nicad battery 10 Secondary battery unit 10a, 13a Connection terminal 11 Secondary battery pack 12, 41 charge Discharge control circuit 13 Housing 14 Charge control circuit 14a Voltage detection circuit 14b Switching control circuit 14c Changeover switch 15 Discharge control circuit 18 Fuse 20 Main body side connector 30, 40 Battery side connector

Claims (6)

In the standby power supply system of the disaster prevention device provided with the standby power connection means that can attach and detach the first secondary battery as the backup power source,
A second secondary battery of a different type from the first secondary battery;
Charge / discharge control means for performing charge control and discharge control of the second secondary battery,
The second secondary battery and the charge / discharge control means can be connected directly or indirectly to the standby power connection means,
A standby power supply system for disaster prevention equipment. The second secondary battery and the charge / discharge control means are housed in a housing that can be directly connected to the standby power connection means,
The standby power supply system of the disaster prevention device according to claim 1. The second secondary battery and the charge / discharge control means can be indirectly connected to the standby power supply connection means via a first connector;
The standby power supply system of the disaster prevention device according to claim 1. The charge / discharge control means is accommodated in a second connector connectable to the standby power supply connection means, and the second secondary battery is connected to the second connector,
The standby power supply system of the disaster prevention device according to claim 1. The charge / discharge control means includes charge control means for controlling a current during charging, and a discharge control means for controlling a current during discharge.
The standby power supply system of the disaster prevention device according to any one of claims 1 to 4. The first secondary battery is a nickel-cadmium battery;
The second secondary battery is a nickel metal hydride battery or a lithium ion battery;
A standby power supply system for a disaster prevention device according to any one of claims 1 to 5.

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