JP2007037024A - Inspection apparatus for loudspeaker line - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To detect short-circuitings and disconnections of loudspeaker lines. <P>SOLUTION: The output of a power amplifier 10 is supplied to loudspeaker lines 1a, 1b, respectively. The output side of the amplifier 10 is connected to a starting end of both or selected one of the loudspeaker lines 1a, 1b by switching elements 8a, 8b. Impedance of a loudspeaker line connected to the output side of the power amplifier 10 via the switching elements 8a, 8b is measured by a detection circuit 18. Based on the impedance measured by the detection circuit 18, in a state of connecting both the loudspeaker lines 1a, 1b to the output side of the power amplifier 10 via the switching elements 8a, 8b, a CPU 20 determines short-circuiting or disconnection of any one of the loudspeaker lines 1a, 1b. If short-circuiting is determined, the CPU 20 causes the switching elements 8a, 8b to connect the loudspeaker lines one by one to the power amplifier 10, the impedance of the relevant loudspeaker line is measured for each connection by the detection circuit 18, and whether it is short-circuiting or not is determined, based on the measured impedance. <P>COPYRIGHT: (C)2007,JPO&amp;INPIT

Description

  The present invention relates to a speaker line inspection device, and more particularly to a plurality of speaker line inspection devices.

  As an inspection apparatus for a plurality of speaker lines, for example, there is one disclosed in Patent Document 1. The inspection device of Patent Document 1 inspects whether there is a short circuit for each system when a short circuit occurs in any of a plurality of speaker lines.

JP 2001-36995 A

  However, this inspection apparatus can detect which of each system is short-circuited, but cannot detect disconnection.

  It is an object of the present invention to provide a speaker line inspection apparatus that can detect not only which of a plurality of systems has a short circuit but also whether a disconnection has occurred in any of the systems. .

  The speaker line inspection apparatus of one embodiment of the present invention includes a plurality of speaker lines to which the output of the power amplifier is supplied. In each system, a speaker is connected to the speaker line. The connecting means connects the output side of the amplifier to the start ends of all the speaker lines of each system or the start ends of the selected speaker lines. The impedance measuring means measures the impedance of the speaker line of the system connected to the output side of the power amplifier via the connecting means. As this impedance measuring means, for example, one that measures the voltage or current at the beginning of the speaker line or one that measures voltage and current can be used. In a state in which the speaker lines of all the systems are connected to the output side of the power amplifier via the connection means, the short-circuit / breakage determination means is based on the impedance measured by the impedance measurement means. Detects short circuit or disconnection of the speaker line of the system. For example, the short-circuit / disconnection determination unit compares the measured impedance with two reference impedances having different values, for example, and determines that the disconnection is normal or short-circuit. When this short-circuit / disconnection determining means determines that one of the systems is short-circuited, the connection means connects the speaker line to the power amplifier one by one, and the impedance measuring means for each connection causes the speaker of the system to be connected. The impedance of the line is measured, and the short-circuit determining means determines whether or not it is a short circuit based on the measured impedance.

  In the inspection apparatus for the speaker line configured as described above, when the short circuit / disconnection determining unit determines that the short circuit is detected, the impedance measuring unit is connected by the connecting unit for each system, and it is determined whether each system is short-circuited. Therefore, it can be determined which of each system is short-circuited. Furthermore, it is possible to detect that a disconnection has occurred in any of the systems by the short-circuit / disconnection determining means.

  The determination means can control the connection means so that the speaker line of the system determined to be short-circuited by the short-circuit determination means is disconnected from the power amplifier. If only a short-circuit / disconnection determination means is provided, it is only found that a short-circuit has occurred in any system, and even if it is found that a short-circuit has occurred, Since it is unknown whether a short circuit has occurred in the system, the output of the power amplifier is not transmitted to the speaker line of any system. On the other hand, when configured as described above, it is determined in which system the disconnection has occurred by the short-circuit determination means, and the identified system is disconnected from the power amplifier. The transmission of the output signal can be continued.

  In addition, an AC signal having a non-audible frequency can be continuously supplied for the impedance measurement via the connecting means. The AC signal can be supplied from the input side of the power amplifier via the connection means, or can be supplied from the output side of the power amplifier via the connection means. If comprised in this way, since the alternating current signal is supplied continuously, even when the normal audio frequency signal is not output from a power amplifier, a short circuit or a disconnection can be detected. In addition, since this AC signal has an inaudible frequency, even if a normal audio frequency signal is output from the power amplifier, there is no obstacle.

  As described above, according to the present invention, it is possible to determine not only whether any of the systems is short-circuited, but also whether any of the systems is disconnected.

  As shown in FIG. 1, a speaker line inspection apparatus according to an embodiment of the present invention includes a plurality of speaker lines, for example, two speaker lines. The one speaker line 1a includes a hot line 2a and a cold line 4a, and a plurality of speakers 6a are connected therebetween. Another speaker line 1b of one system consists of a hot line 2b and a cold line 4b, and a plurality of speakers 6b are also connected between them. These two speaker lines 1a and 1b are laid, for example, in each room or hallway of a building, and the speaker 6a of one system and the speaker 6b of the other system correspond to each other as shown by being surrounded by a dotted line. Has been placed. Therefore, even when broadcasting cannot be performed in one system, broadcasting in the other system is performed, so that no broadcasting can be heard in each room or hallway.

  At one of the speaker lines of each system, for example, at the start ends of the hot lines 2a and 2b, connection means, for example, switching elements 8a and 8b are arranged. These switching elements 8a and 8b can be provided on both the hot lines 2a and 2b and the cold lines 4a and 4b, or can be provided only on the cold lines 4a and 4b. As the switching element, a mechanical switch such as a relay contact can be used, or an electronic switch such as an FET or a bipolar transistor can be used.

  The hot line 2a and the cold line 4a are connected to the power amplifier 10 via the switching element 8a, and the hot line 2b and the cold line 4b are also connected to the power amplifier 10 via the switching element 8b. Accordingly, when the switching elements 8a and 8b are both closed, the two speaker lines 1a and 1b are connected to the power amplifier 10 in parallel. On the other hand, when the switching element 8 a is closed and the switching element 8 b is opened, only the speaker line 1 a is connected to the power amplifier 10. Conversely, when the switching element 8a is opened and the switching element 8b is closed, only the speaker line 1b is connected to the power amplifier 10.

  For example, an audio signal from a microphone 12 is supplied to the power amplifier 10 as an audio signal source. The audio signal is amplified by the power amplifier 10 and supplied to the speaker lines 1a and 1b. Further, a mixer 14 is provided on the input side of the power amplifier 10, and an audio signal from the microphone 12 and an inspection signal source, for example, an AC signal from an inaudible frequency, specifically, an AC signal source 16 of 40 Hz, are provided. The power is mixed and supplied to the power amplifier 10. This AC signal is continuously supplied to the mixer 14.

  The hot line 2a and the cold line 4a are connected to the impedance measuring means, for example, the detection circuit 18 through the switching element 8a. Similarly, the hot line 2b and the cold line 4b are also connected to the detection circuit 18 through the switching element 8b. When the switching elements 8a and 8b are both closed, the detection circuit 18 detects an AC signal current flowing through the speaker lines 1a and 1b, the switching element 8a is closed, and the switching block 8b is opened. When the current of the AC signal flowing through the speaker line 1a is detected, and the switching element 8a is opened and the switching element 8b is closed, the current of the AC signal flowing through the speaker line 1b is measured. For this reason, the detection circuit 18 includes extraction means for extracting an AC signal, for example, a filter. Since the voltage of the AC signal from the AC signal source 16 is constant, the impedance when the speaker lines 1a and 1b are connected in parallel according to the open / close state of the switching elements 8a and 8b by measuring the current. The impedance of only the speaker line 1a and the impedance of only the speaker line 1b can be measured. Note that the voltage when the speaker lines 1a and 1b are connected in parallel, the voltage of only the speaker line 1a, and the voltage of only the speaker line 1b are also measured according to the switching state of the switching elements 8a and 8b. It is also possible to obtain the impedance from the measured current.

  The measured current is supplied to a short circuit / disconnection determination unit and a short circuit determination unit, for example, the CPU 20. The CPU 20 operates in accordance with a storage unit, for example, a program stored in the memory 22, opens and closes the switching elements 8a and 8b, determines whether any one of the speaker lines 1a and 1b is short-circuited or disconnected, If it is determined that a short circuit has occurred, it is determined which of the speaker lines 1a and 1b has a short circuit. When the speaker line in which the short circuit has occurred is found, the switching element corresponding to the speaker line is opened.

  As a premise for performing such processing, when both the speaker lines 1a and 1b are in a normal state, a current flowing in the speaker lines 1a and 1b connected in parallel, a current flowing only in the speaker line 1a, and a current flowing only in the speaker line 1b Measure. For the measurement instruction, a measurement instruction means, for example, an initial switch 24 is connected to the CPU 20. When the initial switch 24 is operated, as shown in FIG. 2, the CPU 20 closes both the switching elements 8a and 8b (step S2), measures the current Iab at that time, and stores it in the memory 22 (step S4). ). Next, the switching element 8a is closed and the switching element 8b is opened (step S6), and the current Ia at that time is measured and stored in the memory 22 (step S8). Further, the switching element 8a is opened and the switching element 8b is closed (step S10), and the current Ib at that time is measured and stored in the memory 22 (step S12).

  Next, the CPU 22 always performs a short circuit / disconnection determination process shown in FIG. When this determination is made, the switching elements 8a and 8b are both closed, and the audio signal from the microphone 12 is transmitted to both speaker lines 1a and 1b. It is determined whether the current I measured by the detection circuit 18 is smaller than the allowable lower limit current obtained by subtracting a predetermined value α from the current Iab measured in the initial state (step S14). If the result of this determination is yes, it can be determined that a disconnection has occurred in either of the speaker lines 1a, 1b, so the CPU 20 displays a disconnection notification on a display means (not shown) (step S16). Even if one of the speaker lines 1a and 1b is disconnected, broadcasting can be continued through the other speaker line. Accordingly, only a notification for promptly requesting the repair company to perform repair is performed.

  If the answer to the determination in step S16 is no, or following the process of step S16, it is determined whether the measured current I is greater than an allowable upper limit current obtained by adding a predetermined value に to the current Iab measured in the initial state. (Step S18). If the answer to this determination is yes, it is determined that a short circuit has occurred in either of the speaker lines 1a and 1b, and therefore a short circuit determination process is performed (step S20). If the determination result in step S18 is yes, it is determined to be normal, and thus this process ends.

  In the process in step S20, as shown in FIG. 4, first, a short circuit notification is displayed on a display means (not shown) (step S21). Next, the switching element 8a is closed, the switching element 8b is opened, and the current I is measured (step S22). That is, the current of the speaker line 1a alone is measured. It is determined whether the current I is larger than the current Ia measured by the speaker line 1a alone in the initial state (step S24). If the answer to this determination is yes, it is determined that the speaker line 1a is short-circuited, so the flag F1 is set to 1 (step S26). In the initial state, the flag F1 is set to 0.

  If the answer to the determination in step S24 is no, or following the process of step S26, the switching element 8a is opened, the switching element 8b is closed, and the current I is measured (step S28). That is, the current of the speaker line 1b alone is measured. It is determined whether the current I is larger than the current Ib measured by the speaker line 1b alone in the initial state (step S30). If the answer to this determination is yes, it is determined that the speaker line 1b is short-circuited, so the flag F2 is set to 1. In the initial state, the flag F2 is also set to 0 (step S32).

  If the result of determination in step S30 is no, or following step S32, both the switching elements 8a and 8b are closed (step S34), and then it is determined whether the flag F1 is 1 (step S36). If the answer to this determination is yes, since a short circuit has occurred in the speaker line 1a, the switching element 8a is opened, and the output supply of the power amplifier 10 to the speaker line 1a is stopped (step S38).

  If the answer to the determination in step S36 is no, or following the process of step S38, it is determined whether the flag F2 is 1 (step S40). If the answer to this determination is yes, since a short circuit has occurred in the speaker line 1b, the switching element 8b is opened and the power supply to the speaker line 1b is stopped (step S42). If the answer to the determination in step S40 is no, or following the process of step S42, the short-circuit determination process ends.

  In this way, since the output supply from the power amplifier 10 is stopped for the short-circuited speaker line, broadcasting in the normal system can be continued. In particular, each speaker line 1a, 1b is provided with speakers 6a, 6b of both systems in each room or hallway of the building, so even if one system speaker line is short-circuited, Broadcasting can be continued with the speakers of the remaining speaker lines, and there are no rooms or hallways where the broadcasting cannot be heard. Therefore, emergency broadcasts and the like are surely broadcast to each room or hallway. Moreover, since such a speaker line inspection is always performed using an AC signal of an inaudible frequency, when an emergency broadcast must be performed, a short circuit or disconnection has occurred, and the emergency broadcast is surely performed. Occurrence of situations that cannot be transmitted can be prevented.

  In the above embodiment, an example in which two speaker lines 1a and 1b are laid is shown. However, the present invention is not limited to this, and the present invention is also implemented when more speaker lines are laid. can do.

It is a block diagram of the inspection apparatus of the speaker line of one embodiment of the present invention. It is a flowchart of the initial setting process in the inspection apparatus of FIG. It is a flowchart of the short circuit and a disconnection determination process in the inspection apparatus of FIG. It is a flowchart of the short circuit determination process in the inspection apparatus of FIG.

Explanation of symbols

1a, 1b Speaker line 8a, 8b Switching element 18 Detection circuit (impedance measuring means)
20 CPU (short circuit / disconnection determination means, short circuit determination means)

Claims (3)

A plurality of speaker lines to which the output of the power amplifier is supplied, and
Connection means for connecting the output side of the amplifier to all of the speaker lines of the respective systems or to the start ends of selected ones;
Impedance measuring means for measuring the impedance of the speaker line of the system connected to the output side of the power amplifier via the connection means;
In a state where the speaker lines of all the systems are connected to the output side of the power amplifier via the connecting means, the speaker lines of any system are short-circuited based on the impedance measured by the impedance measuring means. Or a short-circuit / disconnection determining means for determining disconnection,
When this determination means determines that one of the systems is short-circuited, the connection means connects the speaker line to the power amplifier one by one, and the impedance measurement means causes the impedance of the speaker line of the system for each connection. Short circuit determination means for determining whether or not it is a short circuit based on the measured impedance,
A speaker line inspection device provided.   2. The speaker line inspection apparatus according to claim 1, wherein the determination means controls the connection means so that the speaker lines of the system determined to be short-circuited by the short-circuit determination means are disconnected from the power amplifier. Inspection equipment.   3. The speaker line inspection apparatus according to claim 1 or 2, wherein an AC signal having an inaudible frequency is continuously supplied via the connection means for the impedance measurement.

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