Deprecated: The each() function is deprecated. This message will be suppressed on further calls in /home/zhenxiangba/zhenxiangba.com/public_html/phproxy-improved-master/index.php on line 456
JP5337209B2 - Fire alarm - Google Patents
[go: Go Back, main page]

JP5337209B2 - Fire alarm - Google Patents

Fire alarm Download PDF

Info

Publication number
JP5337209B2
JP5337209B2 JP2011186565A JP2011186565A JP5337209B2 JP 5337209 B2 JP5337209 B2 JP 5337209B2 JP 2011186565 A JP2011186565 A JP 2011186565A JP 2011186565 A JP2011186565 A JP 2011186565A JP 5337209 B2 JP5337209 B2 JP 5337209B2
Authority
JP
Japan
Prior art keywords
fire
time
smoke
predetermined
alarm
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Fee Related
Application number
JP2011186565A
Other languages
Japanese (ja)
Other versions
JP2011238296A (en
Inventor
光輝 西田
佳典 西上
浩 笠原
修平 黒田
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
New Cosmos Electric Co Ltd
Original Assignee
New Cosmos Electric Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by New Cosmos Electric Co Ltd filed Critical New Cosmos Electric Co Ltd
Priority to JP2011186565A priority Critical patent/JP5337209B2/en
Publication of JP2011238296A publication Critical patent/JP2011238296A/en
Application granted granted Critical
Publication of JP5337209B2 publication Critical patent/JP5337209B2/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

Links

Images

Landscapes

  • Fire-Detection Mechanisms (AREA)

Description

本発明は、煙を検知する煙検知部と、前記煙検知部が検知した出力に基づく煙濃度が、所定の閾値以上となった時点から蓄積時間の計測を開始するとともに、前記煙濃度が前記閾値以上である状態が所定時間の間継続した場合に、警報部が火災警報を発するように制御する制御部とを備えた火災報知器に関する。   The present invention starts the measurement of the accumulation time from the time when the smoke concentration based on the output detected by the smoke detection unit detecting the smoke and the smoke detection unit becomes a predetermined threshold or more, and the smoke concentration is The present invention relates to a fire alarm including a control unit that controls an alarm unit to emit a fire alarm when a state equal to or greater than a threshold value continues for a predetermined time.

この種の火災報知器では、例えば特許文献1に示されるように、煙検知部の検知結果が予め設定した検知レベルを超えてもすぐに火災警報を発しないようにしている。つまり、タバコの煙や湯気などの火災とは無関係な現象に反応して、非火災時に火災警報を発することが無いように、煙検知部の検知結果が所定の閾値を超えた時点から蓄積時間を計測し、検知結果が所定の閾値を超えた状態で所定時間に達したら火災警報を発するようにしている。   In this type of fire alarm, for example, as disclosed in Patent Document 1, even if the detection result of the smoke detector exceeds a preset detection level, a fire alarm is not immediately issued. In other words, the accumulation time from when the detection result of the smoke detection unit exceeds a predetermined threshold so that a fire alarm is not issued in the event of a non-fire in response to a phenomenon unrelated to fire such as cigarette smoke or steam. Is measured, and a fire alarm is issued when a predetermined time is reached with the detection result exceeding a predetermined threshold.

特開平7−182573号公報JP-A-7-182573

ところで、非火災時に火災警報を発することを防止する観点からは、上述の所定時間は長い方が好ましい。一方、火災時に素早く警報を発するためには、上述の所定時間は短い方が好ましい。   By the way, from the viewpoint of preventing issuing a fire alarm at the time of non-fire, it is preferable that the predetermined time is longer. On the other hand, in order to issue a warning quickly at the time of a fire, it is preferable that the predetermined time is shorter.

しかし、上述の火災報知器では、火災と非火災とに関係なく、煙濃度が所定の閾値を越えた状態が所定時間を経過してから火災警報を発していた。このため、火災時に素早く警報を発する観点から、所定時間を短く設定する必要があり、非火災時に火災警報が発せられることを十分に防止できない場合があるという問題があった。   However, in the above-described fire alarm, regardless of whether the fire is fire or non-fire, the fire alarm is issued after a predetermined time has passed after the smoke concentration exceeds a predetermined threshold. For this reason, from the viewpoint of quickly issuing an alarm in the event of a fire, it is necessary to set the predetermined time short, and there has been a problem that it may not be possible to sufficiently prevent the fire alarm from being issued in the event of a non-fire.

本発明は、上述の問題点に鑑みてなされたものであり、その目的は、火災時には素早く火災警報を発しつつ、非火災時には火災警報を発することを防止することができる火災報知器を提供することにある。   The present invention has been made in view of the above-described problems, and an object thereof is to provide a fire alarm capable of generating a fire alarm quickly in the event of a fire and preventing a fire alarm in the event of a non-fire. There is.

本発明の第1特徴構成は、煙を検知する煙検知部と、火災警報を発する警報部と、前記煙検知部が検知した出力に基づく煙濃度が、所定の閾値以上となった時点から蓄積時間の計測を開始するとともに、前記煙濃度が前記閾値以上である状態が所定時間の間継続した場合に、警報部が火災警報を発するように制御する制御部と、を備え、前記所定時間は、前記煙濃度が前記閾値以上となる前から予め設定されており、前記制御部が、少なくとも前記煙濃度が前記閾値以上になった時点以降から、所定の解析時間における前記煙濃度の変化量の経時変化の挙動に基づいて、前記蓄積時間が前記所定時間に達する前に、火災と非火災とを識別し、火災であると識別した場合の前記所定時間の短縮及び、非火災であると識別した場合の前記所定時間の延長のうちの少なくとも何れか一方の制御を行う火災報知器において、前記煙濃度の変化量の経時変化の挙動は、前記煙濃度の変化量の周波数スペクトルである点にある。 The first characteristic configuration of the present invention is that the smoke detection unit that detects smoke, the alarm unit that issues a fire alarm, and the smoke concentration based on the output detected by the smoke detection unit is accumulated from the time when the smoke concentration becomes a predetermined threshold or more. And a control unit that controls the alarm unit to emit a fire alarm when the state where the smoke concentration is equal to or higher than the threshold value continues for a predetermined period of time, and the predetermined period is The smoke concentration is preset before the smoke concentration becomes equal to or higher than the threshold value, and the control unit determines the amount of change in the smoke concentration during a predetermined analysis time from at least the time when the smoke concentration becomes equal to or higher than the threshold value. Based on the behavior of change over time, before the accumulation time reaches the predetermined time, a fire and a non-fire are identified, and when it is identified as a fire, the predetermined time is shortened and a non-fire is identified The predetermined time when In fire alarm for performing at least one of the control of the extension, the behavior of the time course of the change amount of the smoke density is that the frequency spectrum of the variation of the smoke density.

本構成によれば、制御部が、少なくとも前記所定時間中の所定の解析時間における煙濃度の変化量の周波数スペクトルに基づいて、火災と非火災とを識別し、火災であると識別した場合の前記所定時間の短縮及び、非火災であると識別した場合の前記所定時間の延長のうちの少なくとも何れか一方の制御を行う。この結果、火災の可能性が高い場合には所定時間を短くし素早く火災警報を発する機能及び、火災の可能性が低い場合には所定時間を長くし火災警報の発令を防止する機能のうちの少なくとも何れか一方を有することとなる。   According to this configuration, when the control unit identifies a fire and a non-fire based on the frequency spectrum of the amount of change in smoke density at least for a predetermined analysis time in the predetermined time, and identifies a fire Control of at least one of the shortening of the predetermined time and the extension of the predetermined time when the non-fire is identified is performed. As a result, when the possibility of a fire is high, the predetermined time is shortened to quickly issue a fire alarm, and when the possibility of a fire is low, the predetermined time is lengthened to prevent the fire alarm from being issued. It will have at least one of them.

また、本構成によれば、少なくとも所定時間中の煙濃度の変化量の周波数スペクトルに基づいて所定時間を制御する。このため、例えば蓄積時間の開始前の煙濃度のみに基づいて所定時間を制御する場合と比較して、より火災と非火災とで前記周波数スペクトルが異なる時点で火災と非火災とを識別することとなる。この結果、火災と非火災とを確実に識別して、所定時間を適切に制御することができる。   Further, according to this configuration, the predetermined time is controlled based on at least the frequency spectrum of the change amount of the smoke density during the predetermined time. For this reason, for example, compared with the case where the predetermined time is controlled based only on the smoke concentration before the start of the accumulation time, the fire and the non-fire can be distinguished from the fire and the non-fire at the time when the frequency spectrum is different. It becomes. As a result, fire and non-fire can be reliably identified and the predetermined time can be appropriately controlled.

上述の結果、所定時間を適切に制御し、火災時には素早く火災警報を発しつつ、非火災時には火災警報を発することを防止することができる火災報知器を提供することができる。   As a result of the above, it is possible to provide a fire alarm capable of appropriately controlling a predetermined time, quickly issuing a fire alarm in the event of a fire, and preventing issuing a fire alarm in the event of a non-fire.

本構成によれば、制御部が、煙濃度の変化量の周波数スペクトルに基づいて火災と非火災とを確実に識別し、所定時間を適切に制御することができる。   According to this structure, a control part can identify fire and non-fire reliably based on the frequency spectrum of the variation | change_quantity of smoke density, and can control predetermined time appropriately.

本発明の第2特徴構成は、前記制御部は、周波数が0.20〜0.45Hzの領域で、前記周波数スペクトルを積分し、その積分値が所定値以下の場合に火災であると識別し、前記積分値が前記所定値よりも大きい場合に非火災と識別する点にある。   In the second characteristic configuration of the present invention, the control unit integrates the frequency spectrum in a frequency range of 0.20 to 0.45 Hz, and identifies a fire when the integrated value is equal to or less than a predetermined value. The non-fire is identified when the integral value is larger than the predetermined value.

本発明の第3特徴構成は、煙を検知する煙検知部と、火災警報を発する警報部と、前記煙検知部が検知した出力に基づく煙濃度が、所定の閾値以上となった時点から蓄積時間の計測を開始するとともに、前記煙濃度が前記閾値以上である状態が所定時間の間継続した場合に、警報部が火災警報を発するように制御する制御部と、を備え、前記所定時間は、前記煙濃度が前記閾値以上となる前から予め設定されており、前記制御部が、少なくとも前記煙濃度が前記閾値以上になった時点以降から、所定の解析時間における前記煙濃度の変化量の経時変化の挙動に基づいて、前記蓄積時間が前記所定時間に達する前に、火災と非火災とを識別し、火災であると識別した場合の前記所定時間の短縮及び、非火災であると識別した場合の前記所定時間の延長のうちの少なくとも何れか一方の制御を行う火災報知器において、前記煙濃度の変化量の経時変化の挙動は、所定の解析時間に達するまで、所定の検知周期毎に煙濃度を読み込み記憶し、前回読み込んだ煙濃度との差を求めることを繰り返して算出され記憶された煙濃度の変化量の経時変化である点にある。The third characteristic configuration of the present invention is that the smoke detection unit for detecting smoke, the alarm unit for issuing a fire alarm, and the smoke concentration based on the output detected by the smoke detection unit are accumulated from the time when the predetermined threshold or more is reached. And a control unit that controls the alarm unit to emit a fire alarm when the state where the smoke concentration is equal to or higher than the threshold value continues for a predetermined period of time, and the predetermined period is The smoke concentration is preset before the smoke concentration becomes equal to or higher than the threshold value, and the control unit determines the amount of change in the smoke concentration during a predetermined analysis time from at least the time when the smoke concentration becomes equal to or higher than the threshold value. Based on the behavior of change over time, before the accumulation time reaches the predetermined time, a fire and a non-fire are identified, and when it is identified as a fire, the predetermined time is shortened and a non-fire is identified The predetermined time when In the fire alarm that controls at least one of the extensions, the behavior of the temporal change in the amount of change in the smoke concentration is read and stored at every predetermined detection period until a predetermined analysis time is reached. This is a change over time in the amount of change in smoke density calculated and stored by repeatedly obtaining the difference from the smoke density read in the previous time.

本構成によれば、火災の可能性が高い場合には蓄積時間を短くし、火災の可能性が低い場合には蓄積時間を長くすることができる。この結果、火災時には素早く火災警報を発しつつ、非火災時には火災警報を発することを防止することができる。According to this configuration, the accumulation time can be shortened when the possibility of fire is high, and the accumulation time can be lengthened when the possibility of fire is low. As a result, it is possible to quickly issue a fire alarm in the event of a fire, and to prevent issuing a fire alarm in the event of a non-fire.
また、蓄積時間中の煙濃度の変化量の経時変化の挙動に基づいて蓄積時間を制御しているので、例えば蓄積時間の開始前の煙濃度のみに基づいて蓄積時間を制御する場合と比較して、火災の場合の煙濃度の挙動と非火災の場合の煙濃度の挙動との相違がより顕著な時点で火災と非火災とを識別することとなる。この結果、火災と非火災とを確実に識別して、蓄積時間を適切に制御することができる。上述の結果、蓄積時間を適切に制御し、火災時には素早く火災警報を発しつつ、非火災時には火災警報を発することを防止することができる。In addition, since the accumulation time is controlled based on the behavior of the change in the smoke concentration during the accumulation time over time, for example, compared to the case where the accumulation time is controlled only based on the smoke concentration before the start of the accumulation time. Thus, when the difference between the smoke concentration behavior in the case of a fire and the smoke concentration behavior in the case of a non-fire is more prominent, a fire and a non-fire are distinguished. As a result, fire and non-fire can be reliably identified and the accumulation time can be controlled appropriately. As a result of the above, it is possible to appropriately control the accumulation time, to quickly issue a fire alarm in the event of a fire, and to prevent issuing a fire alarm in the event of a non-fire.

本発明に係る火災報知器を示すブロック図The block diagram which shows the fire alarm which concerns on this invention 火災報知の動作を示すフローチャートFlow chart showing fire alarm operation 蓄積時間制御処理を示すフローチャートFlow chart showing accumulation time control processing 煙濃度の経時変化を示す図Figure showing the change in smoke concentration over time 煙濃度の変化量の経時変化を示す図A diagram showing the change over time in the amount of smoke density change 煙濃度の変化量の平均値と標準偏差との相関を示す図Figure showing the correlation between the mean value of the change in smoke density and the standard deviation 煙濃度の変化量の周波数スペクトルFrequency spectrum of change in smoke density

(火災報知器)
図1は本実施形態に係る火災報知器1の構成を示すブロック図である。
この火災報知器1は、煙濃度を検知する煙検知部3と、火災報知器1を制御する制御部2と、火災警報を発する警報部4とを有する。
(Fire alarm)
FIG. 1 is a block diagram showing a configuration of a fire alarm 1 according to the present embodiment.
The fire alarm 1 includes a smoke detector 3 that detects smoke concentration, a controller 2 that controls the fire alarm 1, and an alarm unit 4 that issues a fire alarm.

煙検知部3としては、煙検知機能を有する例えば散乱光式煙センサを用いることができる。散乱光式煙センサは、発光部と受光部(ともに図示しない)とを有し、発光部からの光が煙粒子にあたると生じる散乱現象を利用して、受光部の受光素子が散乱光を受けて生じる光電流の変化を検出する。
なお、煙検知部3としては、上述のものに限られず、例えば透過光式煙センサを用いても良い。透過光式煙センサは、受光部の受光素子が透過光を受けて生じる光電流の変化を検出する。
As the smoke detection unit 3, for example, a scattered light type smoke sensor having a smoke detection function can be used. The scattered light type smoke sensor has a light emitting part and a light receiving part (both not shown), and the light receiving element of the light receiving part receives scattered light by utilizing a scattering phenomenon that occurs when light from the light emitting part hits smoke particles. Changes in photocurrent are detected.
The smoke detection unit 3 is not limited to the above-described one, and for example, a transmitted light type smoke sensor may be used. The transmitted light type smoke sensor detects a change in photocurrent generated when a light receiving element of a light receiving unit receives transmitted light.

制御部2は、煙検知部3が検知した出力に基づく煙濃度が、所定の閾値(以下、適宜「警報レベル」とも称する)以上となった時点から蓄積時間tの計測を開始するとともに、前記煙濃度が警報レベル以上である状態が所定の蓄積時間Tの間継続した場合に、警報部4が火災警報を発するように制御する。また、制御部2は、少なくとも前記煙濃度が警報レベル以上になった時点から所定時間(以下、適宜「解析時間」とも称する)における煙濃度の変化量の経時変化の挙動に基づいて、蓄積時間Tに達する前に、火災と非火災とを識別する。そして、火災であると識別した場合の蓄積時間Tの短縮及び、非火災であると識別した場合の蓄積時間Tの延長のうちの少なくとも何れか一方の制御を行う。   The control unit 2 starts measuring the accumulation time t from when the smoke density based on the output detected by the smoke detection unit 3 becomes equal to or higher than a predetermined threshold (hereinafter also referred to as “alarm level” as appropriate) When the state where the smoke concentration is equal to or higher than the alarm level continues for a predetermined accumulation time T, the alarm unit 4 is controlled to issue a fire alarm. Further, the control unit 2 performs the accumulation time based on the behavior of the change in smoke concentration over time for a predetermined time (hereinafter also referred to as “analysis time” as appropriate) from the time when the smoke concentration becomes equal to or higher than the alarm level. Before reaching T, distinguish between fire and non-fire. Then, at least one of the shortening of the accumulation time T when it is identified as a fire and the extension of the accumulation time T when it is identified as a non-fire is performed.

制御部2は、濃度判定手段21・計時手段22・蓄積時間制御手段23・火災/非火災判定手段24・表示管理手段25を有する。濃度判定手段21は、煙検知部3の検知結果に基づく煙濃度が警報レベル以上か否かを判定する。計時手段22は、蓄積時間tを計測する。蓄積時間制御手段23は、前記経時変化の挙動に基づいて蓄積時間を制御する。また、表示管理手段25は、火災/非火災判定手段24が火災であると判定した際に、警報部4に対して火災信号を発する。   The control unit 2 includes a concentration determination unit 21, a time measurement unit 22, an accumulation time control unit 23, a fire / non-fire determination unit 24, and a display management unit 25. The density determination means 21 determines whether or not the smoke density based on the detection result of the smoke detector 3 is equal to or higher than the alarm level. The time measuring means 22 measures the accumulation time t. The accumulation time control means 23 controls the accumulation time based on the behavior of change with time. In addition, the display management unit 25 issues a fire signal to the alarm unit 4 when the fire / non-fire determination unit 24 determines that there is a fire.

警報部4は、例えばスピーカとLEDなどを備える。警報部4は、火災/非火災判定手段24が火災であると判定した場合に、表示管理手段25からの警報信号により、スピーカからの音声や、LEDの点滅など聴覚的・視覚的な火災警報を発する。   The alarm unit 4 includes, for example, a speaker and an LED. When the fire / non-fire judgment means 24 judges that the fire is a fire, the alarm section 4 uses an alarm signal from the display management means 25 to hear an audio / visual fire alarm such as a sound from a speaker or blinking of an LED. To emit.

(火災報知器の動作)
次に、この火災報知器1の動作を図2に基づいて説明する。
煙濃度判定手段21は、煙検知部3が煙を検知すると(♯1のY分岐)、検知レベルに基づく煙濃度が所定の閾値(警報レベル)以上か否かを判定する(♯2)。煙濃度が警報レベル未満の場合には(♯2のN分岐)、蓄積時間t及び後述するフラグFを0にセットし(♯8)、再び検知レベルの読み込みを行う(♯1)。一方、煙濃度が警報レベル以上である場合には(♯2のY分岐)、蓄積時間tの計測を開始する(♯3)。
(Operation of fire alarm)
Next, operation | movement of this fire alarm 1 is demonstrated based on FIG.
When the smoke detector 3 detects smoke (Y branch of # 1), the smoke density determination means 21 determines whether or not the smoke density based on the detection level is equal to or higher than a predetermined threshold (alarm level) (# 2). If the smoke density is less than the alarm level (N branch of # 2), the accumulation time t and a flag F described later are set to 0 (# 8), and the detection level is read again (# 1). On the other hand, when the smoke density is equal to or higher than the alarm level (Y branch of # 2), measurement of the accumulation time t is started (# 3).

その後、フラグFが0か否かを判定する(♯4)。ここで、フラグF=0は、後述する蓄積時間制御処理が未だ行われていないことを示し、フラグF=1は、蓄積時間制御処理が既に行われていることを示す。
フラグF=0の場合には(♯4のY分岐)、蓄積時間制御処理が未だ行われていないので、蓄積時間制御処理を行い、蓄積時間Tを短縮又は延長する(♯5)。一方、フラグF=1の場合は(♯4のN分岐)、既に蓄積時間制御処理が行われているので、蓄積時間制御処理は行わず、蓄積経過時間tの計測を継続する。
Thereafter, it is determined whether or not the flag F is 0 (# 4). Here, the flag F = 0 indicates that an accumulation time control process described later has not yet been performed, and the flag F = 1 indicates that an accumulation time control process has already been performed.
When the flag F = 0 (Y branch of # 4), since the accumulation time control process has not been performed yet, the accumulation time control process is performed, and the accumulation time T is shortened or extended (# 5). On the other hand, when flag F = 1 (N branch of # 4), since the accumulation time control process has already been performed, the accumulation time control process is not performed, and the measurement of the accumulation elapsed time t is continued.

蓄積時間tが所定の蓄積時間Tに達すると(♯6のY分岐)、火災警報を発する。一方、蓄積時間tが所定の蓄積時間Tに達していない場合は(♯6のN分岐)、上述の♯1〜♯4,♯6の処理を繰り返す。また、蓄積時間tが所定の蓄積時間Tに達する前に煙濃度が警報レベル未満になった場合には(♯2のN分岐)、蓄積時間t及びフラグFを0にセットし(♯8)、再び煙の検知を行う(♯1)。   When the accumulation time t reaches a predetermined accumulation time T (Y branch of # 6), a fire alarm is issued. On the other hand, when the accumulation time t has not reached the predetermined accumulation time T (N branch of # 6), the above-described processes of # 1 to # 4 and # 6 are repeated. If the smoke concentration falls below the alarm level before the accumulation time t reaches the predetermined accumulation time T (N branch of # 2), the accumulation time t and the flag F are set to 0 (# 8). The smoke is detected again (# 1).

(蓄積時間制御処理)
次に図3に基づいて、蓄積時間制御処理について説明する。蓄積時間制御処理は、煙濃度の変化量の経時変化の挙動に基づいて、火災か非火災かを識別し、火災であると識別した場合には蓄積時間Tを短縮し、非火災であると識別した場合には、蓄積時間Tを延長する処理である。
蓄積時間制御処理に入ると、解析時間の計測を開始するとともに(♯51)、煙濃度を読み込み記憶する。例えば、前回読み込んだ煙濃度との差を求めることにより煙濃度の変化量を算出し、煙濃度の変化量の経時変化を記憶する(♯52)。解析時間が所定の解析時間Ta未満であれば(♯53のN分岐)、解析時間Taに達するまで、上述の操作を繰り返し、煙濃度の変化量の経時変化を記憶する。解析時間Taに達すると(♯53のY分岐)、前記変化量の経時変化の挙動に基づいて、火災か非火災かの予備判定を行う(♯54)。予備判定において、火災であると識別された場合には(♯55のY分岐)、蓄積時間TをT−dT1に短縮する(♯56)。一方、非火災であると識別された場合には(♯55のN分岐)、蓄積時間TをT+dT2に延長する(♯57)。また、蓄積時間制御処理が行われたことを示すためにフラグFを1にセットする(♯58)。
(Accumulation time control processing)
Next, the accumulation time control process will be described with reference to FIG. The accumulation time control process identifies whether it is a fire or a non-fire based on the behavior of the change in smoke concentration over time, and if it is identified as a fire, the accumulation time T is shortened and the fire is non-fire. In the case of identification, the accumulation time T is extended.
When the accumulation time control process is started, measurement of analysis time is started (# 51), and the smoke density is read and stored. For example, the change in smoke density is calculated by obtaining the difference from the smoke density read last time, and the change over time in the change in smoke density is stored (# 52). If the analysis time is less than the predetermined analysis time Ta (N branch at # 53), the above operation is repeated until the analysis time Ta is reached, and the change over time in the amount of change in smoke density is stored. When the analysis time Ta is reached (Y branch of # 53), a preliminary determination is made as to whether it is a fire or non-fire based on the behavior of the change over time (# 54). If it is determined in the preliminary determination that there is a fire (Y branch of # 55), the accumulation time T is shortened to T-dT1 (# 56). On the other hand, if the non-fire is identified (N branch of # 55), the accumulation time T is extended to T + dT2 (# 57). Further, flag F is set to 1 to indicate that the accumulation time control process has been performed (# 58).

上述の蓄積時間制御処理を行うことにより、火災の可能性が高い場合には蓄積時間を短くし、火災の可能性が低い場合には蓄積時間を長くすることができる。この結果、火災時には素早く火災警報を発しつつ、非火災時には火災警報を発することを防止することができる。
また、蓄積時間中の煙濃度の変化量の経時変化の挙動に基づいて蓄積時間を制御しているので、例えば蓄積時間の開始前の煙濃度のみに基づいて蓄積時間を制御する場合と比較して、火災の場合の煙濃度の挙動と非火災の場合の煙濃度の挙動との相違がより顕著な時点で火災と非火災とを識別することとなる。この結果、火災と非火災とを確実に識別して、蓄積時間を適切に制御することができる。上述の結果、蓄積時間を適切に制御し、火災時には素早く火災警報を発しつつ、非火災時には火災警報を発することを防止することができる。
By performing the accumulation time control process described above, the accumulation time can be shortened when the possibility of fire is high, and the accumulation time can be lengthened when the possibility of fire is low. As a result, it is possible to quickly issue a fire alarm in the event of a fire, and to prevent issuing a fire alarm in the event of a non-fire.
In addition, since the accumulation time is controlled based on the behavior of the change in the smoke concentration during the accumulation time over time, for example, compared to the case where the accumulation time is controlled only based on the smoke concentration before the start of the accumulation time. Thus, when the difference between the smoke concentration behavior in the case of a fire and the smoke concentration behavior in the case of a non-fire is more prominent, a fire and a non-fire are distinguished. As a result, fire and non-fire can be reliably identified and the accumulation time can be controlled appropriately. As a result of the above, it is possible to appropriately control the accumulation time, to quickly issue a fire alarm in the event of a fire, and to prevent issuing a fire alarm in the event of a non-fire.

なお、上述の例では蓄積時間Tの延長及び短縮の両方を行う例を示したが、何れか一方のみを行ってもよい。また、短縮する時間dT1と延長する時間dT2とは、同じ時間であってもよく、異なる時間であってもよい。
また、蓄積時間の開始後の煙濃度の変化量に基づいて蓄積時間制御処理を行う例を示したが、蓄積時間の開始前から蓄積時間中に渡っての煙濃度の変化量に基づいて蓄積時間制御処理を行ってもよい。この場合、例えば濃度判定部21が、煙濃度が警報レベルより低い所定値以上であると判定した時点から蓄積時間制御処理を開始してもよい。また、煙濃度が警報レベルに達する以前から煙濃度(若しくは煙濃度の変化量)の経時変化を記憶しておき、煙濃度が警報レベルに達した後に、前記経時変化を呼び出して、蓄積時間制御処理を行ってもよい。
In the above example, the example in which the accumulation time T is both extended and shortened has been shown, but only one of them may be performed. Further, the shortening time dT1 and the extending time dT2 may be the same time or different times.
In addition, although an example of performing accumulation time control processing based on the amount of change in smoke density after the start of the accumulation time has been shown, accumulation is performed based on the amount of change in smoke density over the accumulation time from the start of the accumulation time. Time control processing may be performed. In this case, for example, the accumulation time control process may be started when the concentration determination unit 21 determines that the smoke concentration is equal to or higher than a predetermined value lower than the alarm level. Also, the temporal change in smoke density (or the amount of change in smoke density) is stored before the smoke concentration reaches the alarm level, and after the smoke concentration reaches the alarm level, the change over time is called to control the accumulation time. Processing may be performed.

また、蓄積時間の開始後の煙濃度の変化量に基づいて蓄積時間制御処理を行う場合、必ずしも、煙濃度が警報レベルに達した時点から蓄積時間制御処理を行なわなくてもよい。ただし、蓄積時間の経過前に火災と非火災とを識別する必要がある。このため、煙濃度が警報レベルに達した後、早期に蓄積時間制御処理を開始することが好ましい。   Further, when the accumulation time control process is performed based on the change amount of the smoke density after the accumulation time starts, the accumulation time control process does not necessarily have to be performed from the time when the smoke density reaches the alarm level. However, it is necessary to distinguish between fire and non-fire before the accumulation time elapses. For this reason, it is preferable to start the accumulation time control process early after the smoke concentration reaches the alarm level.

(蓄積時間制御処理の実施例)
次に、蓄積時間制御処理の具体例について説明する。初期の蓄積時間は特に限定はされないが、本実施例では40秒に設定してある。また、警報レベルは10%/mとした。なお、この測定において、煙検知部3として散乱光式煙センサを用い、検知周期を1sとして測定を行った。
また、本実施例では、煙濃度変化量の解析時間を、蓄積時間開始時点(即ち、煙濃度が警報レベルに達した時点)から20秒間とし、20秒を経過した時点で火災か非火災を判断する。
(Example of accumulation time control processing)
Next, a specific example of the accumulation time control process will be described. The initial accumulation time is not particularly limited, but is set to 40 seconds in this embodiment. The alarm level was 10% / m. In this measurement, a scattered light type smoke sensor was used as the smoke detector 3, and the measurement was performed with a detection period of 1 s.
Further, in this embodiment, the analysis time of the smoke concentration change amount is set to 20 seconds from the accumulation time start point (that is, the smoke concentration reaches the alarm level), and when 20 seconds have passed, a fire or non-fire is detected. to decide.

火災として布団燻焼火災及びてんぷら油火災を例に、非火災として湯気を例に実験を行った。図4は、各事例における煙濃度の経時変化を、煙濃度が火災警報レベルを超えた時間をゼロとして表したものである。また、図5は、煙濃度の変化量の経時変化を、煙濃度が火災警報レベルを超えた時間をゼロとして表したものである。
これらの図において、実線は布団燻焼火災の結果を、点線はてんぷら油火災の結果を、一点鎖線は湯気の結果を示す。布団燻焼火災の場合は、煙濃度が緩やかに略一定の増加速度で増加した。てんぷら油火災の場合は、煙濃度が略一定の増加速度で急激に上昇し、約20秒後に発火して、煙濃度が略一定になった。湯気の場合は、煙濃度が激しく増減を繰り返した。
上述の図から、布団燻焼火災やてんぷら油火災などの火災と比べて、湯気による非火災の場合は、煙濃度やその変化量の変動が大きいことが分かる。したがって、煙濃度の変化量の経時変化に基づいて火災と非火災とを識別する予備判定を行うことができる。
Experiments were conducted with futon fires and tempura oil fires as examples of fires and steam as an example of non-fires. FIG. 4 shows the time-dependent change in the smoke concentration in each case, assuming that the time when the smoke concentration exceeded the fire alarm level is zero. FIG. 5 shows the change over time in the amount of change in smoke density, with the time when the smoke density exceeds the fire alarm level being represented as zero.
In these figures, the solid line indicates the result of futon fire, the dotted line indicates the result of tempura oil fire, and the alternate long and short dash line indicates the result of steam. In the case of a futon firewood fire, the smoke concentration increased slowly at a substantially constant rate. In the case of a tempura oil fire, the smoke concentration rapidly increased at a substantially constant increasing rate, and fired after about 20 seconds, and the smoke concentration became substantially constant. In the case of steam, the smoke concentration increased and decreased repeatedly.
From the above figure, it can be seen that the smoke concentration and the amount of change are larger in the case of non-fire due to steam compared with fires such as futon fire and tempura oil fires. Therefore, it is possible to make a preliminary determination for distinguishing between a fire and a non-fire based on a change over time in the amount of change in smoke density.

図6は、図1と同様の計測を各事例とも6回行って、各計測時の0〜20sの間の煙濃度変化量の平均値と標準偏差とをプロットしたものである。
上述の図から明らかなように、火災と非火災とでは、平均値と標準偏差との相関関係が異なる。即ち、火災である布団燻焼では、平均値標準偏差ともに小さい値を示している。また、火災であるてんぷら油火災では、平均値は比較的大きな値を示し、標準偏差は比較的小さな値を示している。一方、非火災である湯気の場合は、平均値は小さな値を示し、標準偏差は大きな値を示している。この結果より、標準偏差が小さくなれば火災の可能性が高くなり、標準偏差が大きくかつ平均値が小さくなれば非火災の可能性が高くなることが分かる。
このため、図6において、火災領域と非火災領域とに分割し、解析時間中の煙濃度の変化量の平均値と標準偏差とが、図中の火災領域と非火災領域との何れに存在するかにより火災と非火災とを識別することができる。
FIG. 6 is a graph in which the same measurement as in FIG. 1 is performed 6 times in each case, and the average value and standard deviation of the smoke density change amount between 0 and 20 s at each measurement are plotted.
As is clear from the above-mentioned figure, the correlation between the average value and the standard deviation differs between fire and non-fire. That is, in the futon firewood that is a fire, the average standard deviation shows a small value. Moreover, in the tempura oil fire which is a fire, the average value shows a relatively large value, and the standard deviation shows a relatively small value. On the other hand, in the case of steam that is not fire, the average value shows a small value, and the standard deviation shows a large value. From this result, it is understood that if the standard deviation is small, the possibility of fire is high, and if the standard deviation is large and the average value is small, the possibility of non-fire is high.
For this reason, in FIG. 6, it divides into a fire area | region and a non-fire area | region, and the average value and standard deviation of the smoke density change amount during analysis time exist in any of the fire area | region and non-fire area | region in a figure. Whether fire or non-fire can be distinguished.

上述の例では、煙濃度変化量の解析時間を、警報蓄積開始から20秒間とし、20秒を経過した時点で火災か非火災を判断している。このため、例えば、てんぷら油火災の場合は蓄積時間を、例えば20秒間短縮して、予備判定の直後に警報を発することにより、迅速に火災警報を発することができる。一方、湯気の場合は、例えば蓄積時間を20秒間延長することで、火災警報を発することなく自然に湯気が消えていくことが期待できる。   In the above-described example, the analysis time of the smoke concentration change amount is set to 20 seconds from the start of alarm accumulation, and when 20 seconds have elapsed, it is determined whether fire or non-fire has occurred. For this reason, for example, in the case of a tempura oil fire, it is possible to quickly issue a fire alarm by shortening the accumulation time, for example, 20 seconds, and issuing an alarm immediately after the preliminary determination. On the other hand, in the case of steam, for example, by extending the accumulation time for 20 seconds, it can be expected that steam will disappear naturally without issuing a fire alarm.

このように、蓄積時間内に煙濃度の変化量の経時変化の挙動を評価して火災と非火災との区別を行うことができる。そして、火災の場合は、蓄積時間を短縮して警報を早期に発するとともに、非火災の場合は蓄積時間の延長を行って火災警報の発令を防止することができる。   In this way, it is possible to distinguish between fire and non-fire by evaluating the behavior of the change in smoke concentration over time within the accumulation time. In the case of a fire, the accumulation time can be shortened to give an alarm early. In the case of a non-fire, the accumulation time can be extended to prevent the fire alarm from being issued.

なお、上述の実施例において、必ずしも、煙濃度が警報レベルに達した時点から蓄積時間制御処理を行なわなくてもよい。ただし、てんぷら火災の場合、図4から明らかなように、発火後(約20秒後)は煙濃度が略一定値になり、煙濃度の変化量の経時変化に基づく火災と非火災との判定が困難になる。従って、早期に蓄積時間制御処理を開始することが好ましい。   In the above-described embodiment, the accumulation time control process does not necessarily have to be performed from the time when the smoke concentration reaches the alarm level. However, in the case of a tempura fire, as is clear from FIG. 4, the smoke concentration becomes a substantially constant value after ignition (after about 20 seconds), and it is determined whether a fire is fired or not fired based on the change over time in the amount of smoke concentration change. Becomes difficult. Therefore, it is preferable to start the accumulation time control process early.

(蓄積時間制御の別の具体例)
図7は、図5の0〜20秒間の周波数解析を行った周波数スペクトルである。図7において、実線は布団燻焼火災の結果を、点線はてんぷら油火災の結果を、一点鎖線は湯気の結果を示す。
周波数が0.20〜0.45Hzの領域で火災(てんぷら油火災・布団燻焼火災)と非火災(湯気)との違いが顕著である。即ち、非火災である湯気の場合、火災である布団燻焼及びてんぷら油火災の場合と比較して振幅が大きくなっている。このため、例えば、周波数スペクトルを、周波数が0.20〜0.45Hzの領域で積分し、その積分値が所定値以上であれば非火災であると識別し、積分値が所定値以下であれば火災であると識別することができる。
(Another example of accumulation time control)
FIG. 7 is a frequency spectrum obtained by performing frequency analysis for 0 to 20 seconds in FIG. In FIG. 7, the solid line indicates the result of the futon fire, the dotted line indicates the result of the tempura oil fire, and the alternate long and short dash line indicates the result of steam.
The difference between a fire (tempura oil fire / futon fire) and a non-fire (steam) is remarkable in the frequency range of 0.20 to 0.45 Hz. That is, in the case of steam that is not a fire, the amplitude is larger than in the case of futon firewood and tempura oil fires that are fires. Therefore, for example, the frequency spectrum is integrated in the region where the frequency is 0.20 to 0.45 Hz, and if the integrated value is equal to or higher than a predetermined value, it is identified as non-fire, and the integrated value is equal to or lower than the predetermined value. Can be identified as a fire.

なお、上述の蓄積時間制御処理の具体例では、煙濃度の平均値と標準偏差に基づく例、及び周波数スペクトルに基づく例について説明した。しかし、蓄積時間制御処理は上述の例に限られるものではない。例えば、図5に示した煙濃度の変化量の経時変化から、変化量が所定の範囲内(本実施例においては例えば、−20〜+20%/m/s)であれば蓄積時間Tを短縮し、変化量が上記範囲を越えれば蓄積時間Tを延長するなど上述以外であってもよい。   In the above-described specific example of the accumulation time control process, the example based on the average value and standard deviation of the smoke density and the example based on the frequency spectrum have been described. However, the accumulation time control process is not limited to the above example. For example, if the change amount is within a predetermined range (in this embodiment, for example, -20 to + 20% / m / s), the accumulation time T is shortened from the change over time in the change amount of the smoke density shown in FIG. However, if the amount of change exceeds the above range, it may be other than the above, such as extending the accumulation time T.

本発明は、煙を検知する煙検知部と、火災警報を発する警報部と、前記煙検知部が検知した出力に基づく煙濃度が、所定の閾値以上となった時点から蓄積時間の計測を開始するとともに、前記煙濃度が前記閾値以上である状態が所定時間の間継続した場合に、警報部が火災警報を発するように制御する制御部と、を備えた火災報知器に適用可能である。   The present invention starts the measurement of the accumulation time from the time when the smoke concentration based on the output detected by the smoke detection unit for detecting smoke, the alarm unit for issuing a fire alarm, and the output detected by the smoke detection unit becomes equal to or higher than a predetermined threshold. In addition, the present invention can be applied to a fire alarm including a control unit that controls the alarm unit to emit a fire alarm when the smoke concentration is equal to or higher than the threshold value for a predetermined time.

1 火災報知器
2 制御部
3 煙検知部
4 警報部
T 蓄積時間
Ta 解析時間
1 Fire alarm 2 Control unit 3 Smoke detection unit 4 Alarm unit T Accumulation time Ta Analysis time

Claims (3)

煙を検知する煙検知部と、
火災警報を発する警報部と、
前記煙検知部が検知した出力に基づく煙濃度が、所定の閾値以上となった時点から蓄積時間の計測を開始するとともに、前記煙濃度が前記閾値以上である状態が所定時間の間継続した場合に、警報部が火災警報を発するように制御する制御部と、を備え、
前記所定時間は、前記煙濃度が前記閾値以上となる前から予め設定されており、
前記制御部が、少なくとも前記煙濃度が前記閾値以上になった時点以降から、所定の解析時間における前記煙濃度の変化量の経時変化の挙動に基づいて、前記蓄積時間が前記所定時間に達する前に、火災と非火災とを識別し、火災であると識別した場合の前記所定時間の短縮及び、非火災であると識別した場合の前記所定時間の延長のうちの少なくとも何れか一方の制御を行う火災報知器において、
前記煙濃度の変化量の経時変化の挙動は、前記煙濃度の変化量の周波数スペクトルである火災報知器。
A smoke detector for detecting smoke;
An alarm unit for issuing a fire alarm;
When the smoke concentration based on the output detected by the smoke detector starts measuring the accumulation time from the time when the smoke concentration is equal to or higher than a predetermined threshold, and the state where the smoke concentration is equal to or higher than the threshold continues for a predetermined time And a control unit that controls the alarm unit to issue a fire alarm,
The predetermined time is set in advance before the smoke density becomes equal to or higher than the threshold value,
Before the accumulation time reaches the predetermined time based on the behavior of the amount of change in the smoke density over a predetermined analysis time from the time when the smoke density becomes equal to or higher than the threshold, In addition, a fire and a non-fire are identified, and control of at least one of the shortening of the predetermined time when it is identified as a fire and the extension of the predetermined time when it is identified as a non-fire is performed. In the fire alarm to perform ,
The behavior of the change in the smoke density change with time is a fire alarm which is a frequency spectrum of the change in smoke density .
前記制御部は、周波数が0.20〜0.45Hzの領域で、前記周波数スペクトルを積分し、その積分値が所定値以下の場合に火災であると識別し、前記積分値が前記所定値よりも大きい場合に非火災と識別する請求項1に記載の火災報知器。   The control unit integrates the frequency spectrum in a frequency range of 0.20 to 0.45 Hz, identifies a fire when the integrated value is equal to or less than a predetermined value, and the integrated value is less than the predetermined value. The fire alarm according to claim 1, wherein the fire alarm is identified as non-fire when the value is larger. 煙を検知する煙検知部と、A smoke detector for detecting smoke;
火災警報を発する警報部と、An alarm unit for issuing a fire alarm;
前記煙検知部が検知した出力に基づく煙濃度が、所定の閾値以上となった時点から蓄積時間の計測を開始するとともに、前記煙濃度が前記閾値以上である状態が所定時間の間継続した場合に、警報部が火災警報を発するように制御する制御部と、を備え、When the smoke concentration based on the output detected by the smoke detector starts measuring the accumulation time from the time when the smoke concentration is equal to or higher than a predetermined threshold, and the state where the smoke concentration is equal to or higher than the threshold continues for a predetermined time And a control unit that controls the alarm unit to issue a fire alarm,
前記所定時間は、前記煙濃度が前記閾値以上となる前から予め設定されており、The predetermined time is set in advance before the smoke density becomes equal to or higher than the threshold value,
前記制御部が、少なくとも前記煙濃度が前記閾値以上になった時点以降から、所定の解析時間における前記煙濃度の変化量の経時変化の挙動に基づいて、前記蓄積時間が前記所定時間に達する前に、火災と非火災とを識別し、火災であると識別した場合の前記所定時間の短縮及び、非火災であると識別した場合の前記所定時間の延長のうちの少なくとも何れか一方の制御を行う火災報知器において、Before the accumulation time reaches the predetermined time based on the behavior of the amount of change in the smoke density over a predetermined analysis time from the time when the smoke density becomes equal to or higher than the threshold, In addition, a fire and a non-fire are identified, and control of at least one of the shortening of the predetermined time when it is identified as a fire and the extension of the predetermined time when it is identified as a non-fire is performed. In the fire alarm to perform,
前記煙濃度の変化量の経時変化の挙動は、所定の解析時間に達するまで、所定の検知周期毎に煙濃度を読み込み記憶し、前回読み込んだ煙濃度との差を求めることを繰り返して算出され記憶された煙濃度の変化量の経時変化である火災報知器。The behavior of the change in smoke density over time is calculated by repeatedly reading and storing the smoke density at every predetermined detection cycle until the predetermined analysis time is reached, and obtaining the difference from the smoke density read last time. A fire alarm that is a change over time in the amount of change in the stored smoke concentration.
JP2011186565A 2011-08-29 2011-08-29 Fire alarm Expired - Fee Related JP5337209B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP2011186565A JP5337209B2 (en) 2011-08-29 2011-08-29 Fire alarm

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP2011186565A JP5337209B2 (en) 2011-08-29 2011-08-29 Fire alarm

Related Parent Applications (1)

Application Number Title Priority Date Filing Date
JP2006146948A Division JP4989109B2 (en) 2006-05-26 2006-05-26 Fire alarm

Publications (2)

Publication Number Publication Date
JP2011238296A JP2011238296A (en) 2011-11-24
JP5337209B2 true JP5337209B2 (en) 2013-11-06

Family

ID=45326110

Family Applications (1)

Application Number Title Priority Date Filing Date
JP2011186565A Expired - Fee Related JP5337209B2 (en) 2011-08-29 2011-08-29 Fire alarm

Country Status (1)

Country Link
JP (1) JP5337209B2 (en)

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR102059925B1 (en) * 2018-11-06 2019-12-27 한국토지주택공사 Smart fire warning method and system based on life pattern and p2p
JP2021128715A (en) * 2020-02-17 2021-09-02 ホーチキ株式会社 Fire detection means, disaster prevention equipment and fire detection method

Family Cites Families (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP3035341B2 (en) * 1990-11-30 2000-04-24 能美防災株式会社 smoke detector
JP3151291B2 (en) * 1992-04-23 2001-04-03 松下電工株式会社 Fire alarm system
JP3106031B2 (en) * 1993-04-23 2000-11-06 松下電工株式会社 Fire alarm system
JP4037802B2 (en) * 2003-07-15 2008-01-23 能美防災株式会社 Flame detector
JP2006085608A (en) * 2004-09-17 2006-03-30 Fuji Photo Film Co Ltd Apparatus and method for detecting smoke, system and method for distinguishing between mist and smoke, and programs therefor

Also Published As

Publication number Publication date
JP2011238296A (en) 2011-11-24

Similar Documents

Publication Publication Date Title
CN115691032B (en) Optical smoke detectors and methods
CN101765867A (en) Alarm with carbon monoxide and smoke sensors
US8681011B2 (en) Apparatus and method for detecting fires
JP5337209B2 (en) Fire alarm
JP4989109B2 (en) Fire alarm
JP5133031B2 (en) Fire alarm
ATE459949T1 (en) DEVICE FOR MONITORING A FIRE ALARM AND CONFIGURATION METHOD AND FIRE ALARM
JP6238335B2 (en) Fire detector
JP4810309B2 (en) Combined fire alarm
JP7131982B2 (en) Smoke detectors and smoke detection systems
CN110223487A (en) A kind of Smoke Detection and method for warming and system based on cigarette smoking identification
JP2011070359A (en) Fire alarm
JP4615295B2 (en) Combined fire alarm
JP5619385B2 (en) Alarm
JP6184749B2 (en) Fire detector
JP2011070360A (en) Fire alarm
JP2008134708A (en) Method for identifying fire, fire alarm, and fire receiver
JP5409448B2 (en) Disaster prevention system
JP5242286B2 (en) Indoor abnormality monitoring alarm system
JP5134295B2 (en) Fire / non-fire discrimination device, fire / non-fire discrimination method and fire alarm
JP2007305114A (en) Alarm
JP6009203B2 (en) Fire alarm and fire judgment method
JP5120688B2 (en) Fire / non-fire discrimination device, fire / non-fire discrimination method and fire alarm
JP7754752B2 (en) fire detector
JPS6292097A (en) Smoke detector

Legal Events

Date Code Title Description
A621 Written request for application examination

Free format text: JAPANESE INTERMEDIATE CODE: A621

Effective date: 20110906

A131 Notification of reasons for refusal

Free format text: JAPANESE INTERMEDIATE CODE: A131

Effective date: 20130131

A977 Report on retrieval

Free format text: JAPANESE INTERMEDIATE CODE: A971007

Effective date: 20130131

A521 Request for written amendment filed

Free format text: JAPANESE INTERMEDIATE CODE: A523

Effective date: 20130329

TRDD Decision of grant or rejection written
A01 Written decision to grant a patent or to grant a registration (utility model)

Free format text: JAPANESE INTERMEDIATE CODE: A01

Effective date: 20130704

A61 First payment of annual fees (during grant procedure)

Free format text: JAPANESE INTERMEDIATE CODE: A61

Effective date: 20130802

R150 Certificate of patent or registration of utility model

Ref document number: 5337209

Country of ref document: JP

Free format text: JAPANESE INTERMEDIATE CODE: R150

Free format text: JAPANESE INTERMEDIATE CODE: R150

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

LAPS Cancellation because of no payment of annual fees