JP2004187166A - Radio base station apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To effectively prevent noise and to set appropriate temperature in a device by suppressing an increase in power consumption. <P>SOLUTION: A noise prevention shutter 13 is provided in an air blow out port 9 of a cabinet 7 of this radio base station apparatus, the soundproof shutter 13 is set as a totally closed state (fig. (c)) in the nighttime and set as a half-open state (fig. (b)) in the daytime. The air is blown out even at the totally closed state by providing the soundproof shutter 13 with a filter 14. When the temperature in the device is saturated and not lowered even when a fan 10 is rotated at rotation speed corresponding to the temperature in the device, cooling efficiency is enhanced by changing the soundproof shutter 13 from the totally closed state to the half-open state in the nighttime and changing it from the half-open state to the totally closed state (fig. (a)) in the daytime. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

なお、ここでは、ファン１０（図２）の最大回転速度を５０００ｍｉｎ^−１とするが、これに限定されるものではない。また、以下では、防音モードは夜間に設定し、省電力モードは昼間に設定するものとするが、本発明は、上記のように、これのみに限るものではない。
【００２９】
上記表１において、温度センサ１１の検出温度はクラスで区分されており、筐体７（図２）内の装置内温度を検出する温度センサ１１の検出温度が、表示１での温度クラスと照合される。温度クラス０〜４は夫々表１に括弧内に示す温度範囲であり、温度センサ１１の検出温度がかかる温度クラス０〜４のいずれかにあるときには、防音シャッタ１３は、夜間で全閉しており、昼間で半開している。なお、夜間は、騒音が特に問題となる時間帯であって、例えば、午後４時から翌日の午前８時とし、昼間は午前８時から午後４時とするなど、適宜決めることができる。
【００３０】
夜間か昼間かの判定は、制御部５が内蔵のタイマを用いて判定するようにし、夜間から昼間に切り換わると、省電力モードとなって防音シャッタ１３を半開状態に初期設定し、昼間から夜間に切り換わると、防音モードとなって防音シャッタ１３を全閉状態に初期設定する。そして、制御部５は、温度センサ１１からその検出温度を取り込み、表１に示す温度テーブル１２と照合してどの温度クラスに入るかを判定し、該当する温度クラスに対するファン回転速度を読み取って、このファン回転速度でファン１０（図２）が回転するように、冷却手段６を制御する。これにより、例えば、検出温度が３０℃とすると、上記表１により、制御部５は温度テーブル１２からファン回転速度３０００ｍｉｎ^−１を読み取り、この回転速度でファン１０を回転させる。このとき、防音モードでは、防音シャッタ１３が全閉状態にあり、省電力モードでは、防音シャッタ１３が半開状態にある。
【００３１】
温度センサ１１の検出温度は一定の周期で制御部５に取り込まれ、次に検出温度を取り込むときには、冷却手段６の冷却運転により、通常、筐体７内の温度（装置内温度）、従って、検出温度も低下している。制御部５はこの低下した検出温度に対応するファン回転速度を温度テーブル１２から読み取り、ファン１０をこの回転速度で回転させる。このようにして、装置内温度は順次低下していく。なお、制御部５は、検出温度を複数回取り込む毎にその平均値を求め、この平均検出温度に対応する温度クラスの回転速度を温度テーブル１２から読み取ってファン１０の回転速度を設定するようにしてもよい。
【００３２】
このようにして、時間経過とともに、装置内温度も下がっていき、これとともに、温度センサ１１の検出温度も低下していって温度ランクも下がっていき、ファン１０の回転速度も低くなっていく。そして、温度ランクが０となると、ファン１０は停止することになる。この状態で装置内温度が再び高くなって０℃を越えると、温度ランクが０から１に変化するから、制御部５は再びファン１０を２０００ｍｉｎ^−１の回転速度で回転させることになる。
【００３３】
また、例えば、昼間で省電力モードにあるときには、外気温度が上昇して行くとともに、そのときのファン１０の回転速度では、充分な冷却が行なわれず、装置内温度が上昇した場合には、温度ランクも上昇するから、これとともに、ファン１０の回転速度も高くなる。
【００３４】
また、外気温度などの関係から、温度テーブル１２で指定されるファン１０の回転速度では、装置内温度が低下できず、所定回数温度センサ１１の検出温度をみても、それが変化しない場合もある。かかる状態を、以下、装置内温度が飽和したということにする。かかる装置内温度の飽和状態で温度センサ１１の検出温度が予め設定された筐体７内での適正な温度範囲（以下、適正温度範囲という）内にあるならば、ファン１０を同じ回転速度で回転させることにする。
【００３５】
しかし、装置内温度が飽和して検出温度を所定回数取り込んでも、それに変化がなく、しかも、この検出温度が適正温度範囲を越えているときには、制御部５は、ファン１０の回転速度をそのときのものに保持して、夜間の防音モードの場合には、防音シャッタ１３を全閉状態から半開状態に変更し、昼間の省電力モードの場合には、防音シャッタ１３を半開状態から全開状態に変更する。例えば、温度ランク２で装置内温度が飽和した場合には、防音シャッタ１３を、防音モードの場合、全閉状態から半開状態に変更し、省電力モードの場合には、防音シャッタ１３を半開状態から全開状態に変更する。即ち、表１での温度ランク５とするものである。同様にして、表１により、温度ランク３で装置内温度が飽和した場合には、温度ランク６の状態とし、温度ランク４で装置内温度が飽和した場合には、温度ランク７の状態とする。
【００３６】
このように、装置内温度が適正温度範囲を越えた温度に飽和したときには、防音シャッタ１３の開閉状態を開く方向に変更することにより、騒音は増加するが、装置内での熱交換効率が向上し、これによって冷房効率が上昇して装置内温度が低くなっていく。そして、これによって指定された温度ランク５，６，７の温度範囲を下回る状態となると、温度ランク７の場合には、上記と同様に、防音シャッタ１３の開閉状態はそのまま保持されて、ファン１０の回転速度が低下され、順次温度ランク６，５へと変更されていき、温度ランク６の場合も、同様にして、温度ランク５へと変更される。しかし、温度ランク５の場合に、その温度範囲を下回る場合には、装置内温度が上記の適正温度範囲に入っているので、ファン１０の回転速度が３０００ｍｉｎ^−１から２０００ｍｉｎ^−１に変更され、さらに、夜間の防音モードの場合には、防音シャッタ１３が半開状態から全閉状態に、昼間の省電力モードの場合には、防音シャッタ１３が全開状態から半開状態に夫々変更されて、温度ランク１の状態に設定される。
【００３７】
また、夜間の防音モードの場合には、さらに、温度ランク６にあっても、装置内温度が飽和しているときには、防音シャッタ１３が、さらに、半開状態から全開状態に変更されて、表１に示す温度ランク８の状態に設定され、また、温度ランク７にあっても、装置内温度が飽和しているときには、防音シャッタ１３が、さらに、半開状態から全開状態に変更されて、表１に示す温度ランク９の状態に設定される。昼間の省電力モードの場合には、温度ランク６，７で既に防音シャッタ１３が全開状態に設定されているので、温度ランク８，９になることはなく、そのまま温度ランク６，７の状態が維持されることになる。
【００３８】
このようにして、適正温度範囲を越えて装置内温度が飽和したときには、防音防止シャッタ１３を開くようにして冷房能力を高めるようにする。これにより、騒音が多少増加するが、消費電力の増加を抑えることができる。
【００３９】
次に、以上の制御部５の動作をさらに詳細に説明する。
【００４０】
図３は測定温度が温度クラス１までの制御部５の制御動作を示すフローチャートである。
【００４１】
同図において、ステップ１００は制御部５が検出する夜間の時間帯と昼間の時間帯との切替え時点を示すものであり、この時点になると、昼間の時間帯から夜間の時間帯に切り替わったときには（ステップ１０１）、防音モードとして、上記表１に示すように、防音シャッタ１３を全閉状態にし（ステップ１０２）、夜間の時間帯から昼間の時間帯に切り替わったときには（ステップ１０１）、防音モードとして、上記のように、防音シャッタ１３を半開状態にする（ステップ１０３）。また、このとき、制御部５は、温度ランクを０として保持する。
【００４２】
かかる防音モードもしくは省電力モードにおいて、温度センサ１１の検出温度を取り込んで装置内温度を測定し（ステップ１０４）、規定した回数、例えば、５回測定したかどうかを判定し、規定回数測定していなければ（ステップ１０５）、次の装置内温度の測定（ステップ１０４）を待つ。そして、規定回数の測定をすると（ステップ１０４）、この規定回数部の測定による検出温度を平均化し、その平均値を測定温度とする（ステップ１０６）。
【００４３】
このようにして測定温度が得られると、制御部５はこの測定温度と上記表１で示す温度テーブル１２での各温度ランクの温度範囲とを照合し（ステップ１０７）、この測定温度が温度クラス０であるか否か判定する（ステップ１０８）。温度クラス０である場合には、制御部５は、温度テーブル１２からこの温度ランク０のファン回転速度０ｍｉｎ^−１を読み出し、これによってファン１０を停止状態とするとともに、温度テーブル１２との照合結果である温度ランクの値０を保持する。そして、ステップ１０４からの制御動作を繰り返す。
【００４４】
また、測定温度が、温度クラス０ではなく、温度テーブル１２の温度クラス１であるときには（ステップ１１０）、制御部５は温度テーブル１２からこの温度クラス１のファン回転速度２０００ｍｉｎ^−１を読み取り、ファン１０をこの回転速度で回転させるとともに、温度テーブル１２との照合結果である温度ランクの値０を保持する。そして、ステップ１０４に戻る。
【００４５】
このようにして、測定温度が温度クラス０（０℃以下）のときには、ファン１０を停止状態にしたままとする。しかし、装置内温度が上昇して測定温度が温度クラス１なると、ファン１０を２０００ｍｉｎ^−１で回転させる。また、測定温度が温度クラス１のときには、ファン１０を２０００ｍｉｎ^−１で回転駆動する状態に保持するが、その後、装置内温度が低下して、測定温度が温度クラス０になると、ファン１０を停止させる。
【００４６】
次に、図４により、測定温度が温度ランク２〜４の場合の動作について説明する。
【００４７】
同図において、温度テーブル１２と照合して、測定温度が温度クラス２である場合には（ステップ１１２）、制御部５は、その保持している温度ランクも用いて、この温度クラス２が所定回数Ｎ（例えば、Ｎ＝５）繰り返したか否か判定する（ステップ１１３）。つまり、測定温度が温度ランク２以上のときには、このように、制御部５が保持している過去Ｎ−１回の温度テーブル１２との照合による温度クラスと今回の照合による温度クラスとから同じ温度クラスがこの所定回数Ｎだけ続いたか否かを判定することにより装置内温度が飽和したか否かを判定する。温度クラス２が所定回数Ｎだけ続くと、装置内温度が飽和したとして、図５のステップ１２０に移行するが、温度クラス２が所定回数Ｎ繰り返していなければ、温度テーブル１２からこの温度クラス２に対する回転速度３０００ｍｉｎ^−１を読み取りとし、ファン１０をこの回転速度で回転させる状態とする（ステップ１１４）。そして、制御部５はこの温度クラス２を保持し、図３のステップ１０４に戻る。
【００４８】
なお、制御部５としては、温度クラスをこの所定回数Ｎ以上の分保持すればよい。また、温度テーブル１２との照合による温度クラスが１以下のときには、制御部５は必ずしもかかる温度クラスを保持する必要がなく、また、これまで保持していた２以上の温度クラスを消去してもよい。
【００４９】
また、温度テーブル１２と照合して、測定温度が温度クラス３である場合には（ステップ１１５）、制御部５は、その保持している温度ランクをも用いて、この温度クラス３が上記の所定回数Ｎ続いたか否か判定し（ステップ１１６）、続いたならば、装置内温度が飽和したとして、図５のステップ１２１に移行するが、温度クラス３が所定回数Ｎ続いていなければ、温度テーブル１２から回転速度４０００ｍｉｎ^−１を読み取りとし、ファン１０をこの回転速度で回転させる状態とする（ステップ１１７）。そして、制御部５はこの照合結果の温度クラス３を保持し、図３のステップ１０４に戻る。
【００５０】
さらに、温度テーブル１２と照合して、測定温度が温度クラス２，３でない場合には（ステップ１１２，１１５）、温度クラス４であり、制御部５は、その保持している温度ランクを用いて、この温度クラス４が上記の所定回数Ｎ続いたか否か判定し（ステップ１１８）、続いたならば、装置内温度が飽和したとして、図５のステップ１２２に移行するが、温度クラス４が所定回数Ｎ続いていなければ、温度テーブル１２からファン回転速度５０００ｍｉｎ^−１を読み取り、ファン１０をこの回転速度で回転させる状態とする（ステップ１１９）。そして、制御部５はこの照合結果の温度クラス４を保持し、図３のステップ１０４に戻る。
【００５１】
次に、図５により、測定温度が温度ランク５〜７の場合の動作について説明する。
【００５２】
同図において、温度ランク２が規定回数Ｎ続くと（図４のステップ１１３）、制御部５は、夜間では、防止シャッタ１３を全閉状態（図２（ｃ））から半開状態（図２（ｂ））に変更し、また、昼間では、防止シャッタ１３を半開状態（図２（ｂ））から全開状態（図２（ａ））に変更して夫々温度ランク５とし、これを保持する（ステップ１２０）。また、温度ランク３が規定回数Ｎ続くと（図４のステップ１１６）、制御部５は、夜間では、防止シャッタ１３を全閉状態から半開状態に変更し、また、昼間では、防止シャッタ１３を半開状態から全開状態に変更して夫々温度ランク６とし、これを保持する（ステップ１２１）。さらに、温度ランク４が規定回数Ｎ続くと（図４のステップ１１８）、制御部５は、夜間では、防止シャッタ１３を全閉状態から半開状態に変更し、また、昼間では、防止シャッタ１３を半開状態から全開状態に変更して夫々温度ランク７とし、これを保持する（ステップ１２２）。
【００５３】
そして、このように、ステップ１２０〜１２２で夫々防止シャッタ１３の開閉状態が変更されると、まず、制御部５は、自己が保持している温度クラスがクラス５か否か判定し（ステップ１２３）、温度クラス５であるときには、温度センサ１１からの検出温度によるステップ１０６で求めた測定温度がこの温度クラス５の温度範囲（２１℃〜３５℃：表１）を下回らない場合には（ステップ１２４）、図３のステップ１０４に戻って温度センサ１１の検出温度の次の取り込みを行なうが、測定温度がこの温度クラス５の温度範囲を下回る場合には、装置内温度が上記の２０℃以下の適正温度範囲に入るから、温度ランクをランク５からランク２に変更する（ステップ１２５）。このために、温度テーブル１２（上記表１）をもとに、防音シャッタ１３を半開状態から全閉状態に変更するとともに、ファン１０の回転速度を２０００ｍｉｎ^−１とする。そして、図３のステップ１０４に戻る。
【００５４】
制御部５が保持している温度クラスがクラス５でないときには（ステップ１２３）、制御部５は、クラス６か否か判定し（ステップ１２６）、温度クラス６であるときには、温度センサ１１からの検出温度によるステップ１０６で求めた測定温度がこの温度クラス６の温度範囲（３６℃〜４９℃：表１）を下回らない場合には（ステップ１２７）、図６のステップ１３１に進むが、測定温度がこの温度クラス６の温度範囲を下回る場合には、温度ランクをランク６からランク５に変更する（ステップ１２８）。このために、温度テーブル１２（上記表１）をもとに、防音シャッタ１３は、夜間では、そのまま半開状態に保持し、また、昼間では、そのまま全開状態に保持し、ファン１０の回転速度を４０００ｍｉｎ^−１から３０００ｍｉｎ^−１に変更する。そして、図３のステップ１０４に戻る。
【００５５】
制御部５が保持している温度クラスがクラス５，６でないときには（ステップ１２３，１２６）、温度クラスがクラス７であり、制御部５は、温度センサ１１からの検出温度によるステップ１０６で求めた測定温度がこの温度クラス７の温度範囲（５０℃〜５２℃：表１）を下回るか否か判定し（ステップ１２９）、下回らない場合には、図６のステップ１３３に進むが、測定温度がこの温度クラス７の温度範囲を下回る場合には、温度ランクをランク７からランク６に変更する（ステップ１３０）。このために、温度テーブル１２（上記の表１）をもとに、防音シャッタ１３は、夜間では、そのまま半開状態に保持し、また、昼間では、そのまま全開状態に保持し、ファン１０の回転速度を５０００ｍｉｎ^−１から４０００ｍｉｎ^−１に変更する。そして、図３のステップ１０４に戻る。
【００５６】
このようにして、外気温度が高いことなどによって、冷房手段６を動作させても、装置内温度が下がらない場合には、防音シャッタ１３を開くことになるから、装置内温度を低下させることができ、装置内温度の低下とともに、ファン１０の回転速度を低下させて消費電力の低減を図ることができる。そして、充分装置内温度が低下し、適正温度範囲になると、ファン１０の回転速度を低下させるとともに、防音シャッタ１３を閉じるようにするものであるから、消費電力の低減とともに、騒音防止を達成できることになる。
【００５７】
次に、図６により、測定温度が温度ランク８，９の場合の動作について説明する。これら温度ランクは、温度テーブル１２の内容を示す表１から明らかなように、夜間にのみ設定される。
【００５８】
同図において、制御部５に温度ランク６が保持されているときに、図３のステップ１０６で得られる測定温度が所定回数Ｍだけ続けてこの温度ランク６の温度範囲（３６℃〜４９℃：表１）を下回らないとき（図５のステップ１２７）、夜間の防音モードにあるときには（ステップ１３１）、制御部５は防音シャッタ１３を全開し、温度ランクをランク８とする。また、制御部５に温度ランク７が保持されているときに、図３のステップ１０６で得られる測定温度が所定回数Ｍだけ続けてこの温度ランク７の温度範囲（５０℃以上：表１）を下回らないとき（図５のステップ１２９）、夜間の防音モードにあるときには（ステップ１３３）、制御部５は防音シャッタ１３を全開し、温度ランクをランク９とする。
【００５９】
そして、まず、制御部５は、自己が保持している温度クラスがクラス８か否か判定し（ステップ１３５）、温度クラス８であるときには、温度センサ１１からの検出温度によるステップ１０６で求めた測定温度がこの温度クラス８の上記温度範囲を下回らない場合には（ステップ１３６）、図３のステップ１０４に戻って温度センサ１１の検出温度の次の取り込みを行なうが、測定温度がこの温度クラス８の温度範囲を下回る場合には、防音シャッタ１３を全開状態から半閉状態に変更して温度ランク５する（ステップ１３７）。そして、図３のステップ１０４に戻る。
【００６０】
また、制御部５が保持している温度クラスがクラス８ではなく（ステップ１３５）、クラス９であるときには、制御部５は温度センサ１１からの検出温度によるステップ１０６で求めた測定温度がこの温度クラス９の上記温度範囲を下回るか否か判定し（ステップ１３８）、下回らない場合には、図３のステップ１０４に戻るが、測定温度がこの温度クラス９の温度範囲を下回る場合には、防音シャッタ１３を全開状態に保持したまま、ファン１０の回転速度を５０００ｍｉｎ^−１から４０００ｍｉｎ^−１に変更し、温度ランクをランク８に変更する。そして、図３のステップ１０４に戻る。
【００６１】
このようにして、夜間では、装置内温度が下がらない場合には、防音シャッタ１３を全開状態でファン１０を最大の回転速度付近で回転させることができ、これによって、急速に装置内温度を低下させることができて防音シャッタ１３が閉じる方向の防音モードに戻すことが可能となる。
【００６２】
以上、本発明の一実施形態について説明したが、本発明はかかる実施形態のみに限定されるものではない。例えば、上記実施形態では、具体的にファン１０の回転速度を数値で示したが、かかる数値は一例を示しているものに過ぎない。また、防音モードを夜間とし、省電力モードを昼間としたが、周囲環境に応じて寝かかる防音モードと省電力モードの時間帯を適宜決めることができる。更に、防音シャッタとしては、図２に示すように、全閉，半開，全開の３段階の開閉状態を取りえるものとしたが、これに限らず、２段階や４段階以上の開閉状態を取りえるものであってもよく、これに応じて、温度ランク設定ややこれに応じたファン１０の回転数を適宜割り当てるようにすることが可能である。
【００６３】
【発明の効果】
以上説明したように、本発明によれば、騒音防止と消費電力の低減を図りながら、冷却手段を能率的に動作させて装置内温度を下げることが可能となる。
【図面の簡単な説明】
【図１】本発明による無線基地局装置の一実施形態の回路ブロック構成を示すブロック図である。
【図２】図１に示す実施形態の概略外観を示す斜視図である。
【図３】図１及び図２における冷却手段の制御動作の一具体例の測定温度が温度クラス１までの部分を示すフローチャートである。
【図４】図３に示す制御動作に続く測定温度が温度クラス２〜４の部分の制御動作を示すフローチャートである。
【図５】図４に示す制御動作に続く測定温度が温度クラス５〜７の部分の制御動作を示すフローチャートである。
【図６】図５に示す制御動作に続く測定温度が温度クラス８，９の部分の制御動作を示すフローチャートである。
【図７】無線基地局装置の一従来例の回路ブロック構成を示すブロック図である。
【図８】図７に示す従来例の概略外観を示す斜視図である。
【符号の説明】
１ 送受信アンテナ
２ 無線部
３ 信号処理部
４ 有線インターフェース部
５ 制御部
６ 冷却手段
７ 筐体
８ 空気吸込口
９ 空気吹出口
１０ ファン
１１ 温度センサ
１２ 温度テーブル
１３ 防音シャッタ
１４ フィルタ[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a wireless base station apparatus provided with a cooling unit installed outdoors such as on the roof of a station of a wireless base station.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there are radio base station apparatuses that are housed in a housing and installed indoors, and those that are installed outdoors. 2. Description of the Related Art In a wireless base station device installed indoors, such as in a base station of a wireless base station, in order to prevent the temperature inside the housing (hereinafter, referred to as the device temperature) from excessively rising, the wireless base station needs An air conditioner is provided in a section where the wireless base station device is installed, and the room is adjusted to a constant ideal temperature.
[0003]
On the other hand, when the wireless base station device is installed outdoors such as on the roof of a station building, since the outside air temperature cannot be controlled by the air conditioner, the wireless base station device is easily affected by the outside air temperature. It becomes. For this reason, in such a radio base station apparatus, the thermal design of the housing is performed in accordance with the maximum temperature condition of the environment in which the apparatus is installed, and a cooling means such as a fan is provided to cool the inside of the apparatus and The temperature is kept below a specified temperature.
[0004]
FIG. 7 is a block diagram showing a circuit block configuration of a conventional example of such a conventional radio base station apparatus provided with a cooling means, wherein 1 is a transmitting / receiving antenna, 2 is a radio section, 3 is a signal processing section, and 4 is a wired section. An interface unit 5, a control unit 5, and a cooling unit 6 are provided.
[0005]
In the figure, a wired interface unit 4 is connected to a line network in a radio base station (not shown), and when a signal is transmitted from this radio base station to a mobile radio station (not shown), control of the control unit 5 is also performed. At the same time, a signal to be transmitted from this line network via the wired interface unit 4 is supplied, and after a predetermined signal processing is performed by the signal processing unit 3, the signal is supplied to the radio unit 3 and converted into a transmission signal of a predetermined frequency band. The power is further amplified and transmitted from the transmitting / receiving antenna 1. When a signal from a radio mobile station (not shown) is received, a radio wave of this signal is received by the radio unit 2 from the transmission / reception antenna 1, subjected to a predetermined reception process, and then supplied to the signal processing unit 3 as a reception signal. , Predetermined signal processing is performed. The received signal output from the signal processing unit 3 is sent to a line network in a wireless base station via a wired interface unit 4.
[0006]
The wireless base station apparatus further includes a cooling unit 6 including a fan and the like, and is controlled by the control unit 5 to operate at a predetermined rotation speed. Such a wireless base station device is thermally designed in accordance with the environment of the place where it is used, specifically, the maximum temperature condition in the device (that is, in the housing). For example, when the maximum temperature condition in the device is set to 50 ° C. and the rotation speed of the fan is set to 4000 min at which the optimum cooling effect is obtained when the temperature in the device is 50 ° C. which is the maximum temperature condition ^-1 And The control unit 5 determines that the rotation speed of the fan is 4000 min. ^-1 The cooling means is controlled so that
[0007]
FIG. 8 is a perspective view schematically showing the appearance of such a wireless base station device, wherein 7 is a housing, 8 is an air inlet, 9 is an air outlet, and 10 is a fan.
[0008]
In this figure, the block configuration shown in FIG. For example, an air inlet 8 of the cooling means (FIG. 7) is provided on an upper surface side of the housing 1, and an air outlet 9 to which a fan 10 is attached is provided on a side surface thereof. The air suction port 8 is provided with a filter for preventing intruders from the outside.
[0009]
By the rotation of the fan 10, outside air is sucked in from the air inlet 8, and this air absorbs heat in the housing 7 and is discharged from the air outlet 9. Thereby, the inside of the housing 7 is cooled.
[0010]
By the way, such a cooling means 6 can be used even if the outside air temperature changes between nighttime and daytime, or even in an area where the outside air temperature is low and the temperature inside the device does not reach the maximum temperature condition of 50 ° C. , The fan is operated at the specified rotation speed of 4000 min. ^-1 It is driven so as to rotate with. Therefore, even when cooling in the apparatus is not required, and even if cooling is not required such high-speed rotation of the fan, the cooling operation by such high-speed rotation of the fan can be performed. This will result in unnecessary cooling. In such a useless cooling operation, power consumption is increased uselessly.
[0011]
On the other hand, as another conventional cooling means of the wireless base station apparatus, a cooling means for further reducing power consumption has been proposed. This includes a heat exchanger that absorbs the heat of the air in the casing of the wireless base station apparatus circulated by the external fan and sends the heat to the outside air that is sucked in from the outside by the external fan and discharged to the outside, A thermistor for detecting the temperature inside the housing is provided. According to the detected temperature of the thermistor, the lower the detected temperature, the lower the rotation speed of the external and internal fans, and when these temperatures become lower than a predetermined temperature, the fans are stopped. (For example, see Patent Document 1).
[0012]
Further, in the cooling means provided with such a fan or the cooling means provided with a heat exchanger, the noise caused by the flow of air in the housing, the noise generated when the fan cuts off the air, the rotation noise of the fan motor, etc. Noise is generated. Such noise is discharged to the outside from the air inlet 8 and the air outlet 9 of the housing 7 as shown in FIG. Such noise causes an environmental problem particularly when the wireless base station device is installed near a house such as a residential area. Therefore, it is necessary for the wireless base station apparatus to consider noise prevention as one of environmental measures.
[0013]
2. Description of the Related Art As one of measures against noise of a wireless base station device, a method using a soundproof hood has been conventionally proposed. In this, a hood using a sound absorbing material is provided at an air inlet and an air outlet of a housing of a wireless base station device, and an obstacle made of the sound absorbing material is provided in the hood. The noise generated in the housing collides with an obstacle when passing through the hood, and is absorbed and attenuated at each collision. In this way, noise emitted to the outside is reduced (for example, see Patent Document 2).
[0014]
[Patent Document 1]
JP-A-10-2697
[0015]
[Patent Document 2]
JP 2000-223849 A
[0016]
[Problems to be solved by the invention]
By the way, by using the conventional technology described in Patent Document 1 and the conventional technology described in Patent Document 2, a radio base station device capable of reducing noise while reducing power consumption by the cooling means. Can be realized.
[0017]
However, according to the noise prevention method described in Patent Literature 2, the hood acts as a resistance that impedes the flow of intake air and blown air. If the temperature inside the housing is relatively low and it is not necessary to rotate the fan at high speed, the amount of flowing air is small and the air speed can be reduced, so this may not be a problem for each case. If it is necessary to rapidly perform the heat exchange of the air in the fan, a high-speed rotation of the fan is required. In such a case, a large amount of air needs to be sucked in and blown out at a high speed, so that the hood has a large resistance to the flow of the air and compensates for the reduction in the amount of air due to the air resistance. In addition, measures such as increasing the rotation speed of the fan are required. In particular, when the outside air temperature is extremely high, such as during the daytime in a hot season, the temperature inside the device becomes abnormally high due to this. However, the air resistance of the hood increases in accordance with the flow rate of the air, and the flow rate decreases as compared with the case where the hood is not provided at the same rotation speed of the fan. For this reason, it is necessary to further increase the rotation speed of the fan in order to compensate for this reduction, and as a result, the power consumption also increases.
[0018]
An object of the present invention is to provide a radio base station apparatus which solves such a problem, effectively prevents noise, and suppresses an increase in power consumption so that an appropriate internal temperature can be set. It is in.
[0019]
[Means for Solving the Problems]
In order to achieve the above object, the present invention relates to a radio base station apparatus provided with a cooling means for cooling the inside of a housing, wherein the soundproofing is provided at an air outlet for cooling provided in the housing. A shutter, first control means for changing the open / close state of the soundproof shutter in accordance with a specified time period, a temperature sensor for detecting a temperature in the housing, and a fan for a cooling means in accordance with the temperature detected by the temperature sensor. A temperature table that defines a rotation speed, and a second control unit that reads a rotation speed corresponding to a temperature detected by a temperature sensor from the temperature table and sets a rotation speed of the fan to the rotation speed read from the temperature table. It is.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram showing a circuit block configuration of an embodiment of a radio base station apparatus according to the present invention, in which 11 is a temperature sensor, 12 is a temperature table, 13 is a soundproof shutter, and a portion corresponding to FIG. Are denoted by the same reference numerals, and redundant description is omitted.
[0021]
As shown in FIG. 1, this embodiment is different from the conventional wireless base station apparatus shown in FIG. 7 in that a temperature sensor 11, a temperature table 12, a soundproof shutter 13, and a temperature sensor 11 for measuring the internal temperature of the wireless base station apparatus. However, the configuration is such that a drive unit for the soundproof shutter 13 and the like are added. Here, the control unit 5 drives the soundproof shutter 13 by controlling the drive unit. However, for simplification of description, the illustration of such a drive unit is omitted, and the control unit 5 uses the soundproof shutter. 13 will be described.
[0022]
FIG. 2 shows the open / closed state of the soundproof shutter 13. Reference numeral 14 denotes a filter, and portions corresponding to FIGS. 1 and 7 are denoted by the same reference numerals.
[0023]
In FIG. 2, the housing 7 is provided with a soundproof shutter 13 so as to open and close the air outlet 9. FIG. 2A shows a fully opened state of the soundproof shutter 13, in which the entire air outlet 9 is open, and the air that has absorbed heat in the housing 7 is blown out from the entire air outlet 9. You. FIG. 2B shows the soundproof shutter 13 in a half-open state. The soundproof shutter 13 is lowered from the upper portion of the air outlet 9 and almost the upper half of the air outlet 9 is closed. Therefore, the air that has absorbed the heat in the housing 7 is blown out from substantially the lower half of the air outlet 9. FIG. 2C shows the soundproof shutter 13 in a fully closed state, and the entire air outlet 9 is closed by the soundproof shutter 13. However, a ventilating filter 14 is provided in the center of the soundproof shutter 13, and the filter 14 can blow out air that has absorbed heat in the housing 7. Thus, even if the cooling unit 6 is operated with the soundproof shutter 13 fully closed, the inside of the housing 7 can be cooled by operating the cooling unit 6.
[0024]
In addition, here, the width of the filter 14 is substantially equal to the width of the air outlet 9, and the length of the filter 14 is about １ ／ of the width of the air outlet 9, but is not limited thereto. However, as shown in FIG. 2C, the soundproof shutter 13 is completely closed in order to block noise generated in the housing 7 and prevent the noise from coming outside. 14 cannot be too large. Further, even when the soundproof shutter 13 is fully closed, the filter 14 cannot be made too small in order to perform cooling (ie, air can be blown out). In short, when the fan of the cooling means 6 is rotated at a rotation speed corresponding to the internal temperature of the apparatus, the size of the cooling means 6 is set to a value capable of blowing out an amount of air for obtaining a good cooling effect. Here, as an example, as will be described later, the size is set such that a good cooling operation can be performed even when the soundproof shutter 13 is fully closed, until the temperature in the apparatus is approximately 50 ° C.
[0025]
Returning to FIG. 1, for example, the control unit 5 changes the open / closed state of the soundproof shutter 13 between night and day. That is, at night, the soundproof shutter 13 tends to be closed from the viewpoint of noise prevention. Even if the air is closed, the temperature of the outside air is lower and the temperature of the inside of the apparatus is lower in the nighttime than in the daytime, so that the rotation speed of the fan can be reduced. 13 is closed, and noise prevention is given priority. In the daytime, the outside air temperature is higher and the internal temperature of the apparatus tends to be higher than noise prevention. Therefore, the soundproof shutter 13 is opened slightly, and the rotation speed of the fan is reduced accordingly to reduce power consumption. Try to plan. Of course, even in the daytime, if the outside air temperature is low, the soundproof shutter 13 is made to close slightly so that the noise is reduced as much as possible.
[0026]
However, in general, depending on the surrounding situation, there is a time zone in which noise prevention must be emphasized and a time zone in which power saving can be emphasized, not only at night and during the daytime. In addition, the soundproof shutter 13 tends to be closed (hereinafter, referred to as a soundproof mode), and in a time zone in which power saving can be emphasized, the soundproof shutter 13 is likely to be opened as described above (hereinafter, referred to as “soundproof mode”). Power mode).
[0027]
The temperature table 12 shows the relationship between the rotation speed of the fan 10 (FIG. 2) in the cooling means 6 and the open / closed state of the soundproof shutter 13 with respect to the temperature detected by the temperature sensor 11, and one specific example thereof will be described below. It is shown in Table 1.
[0028]
[Table 1]

Here, the maximum rotation speed of the fan 10 (FIG. 2) is set to 5000 min. ^-1 However, the present invention is not limited to this. In the following, the soundproof mode is set at night and the power saving mode is set at daytime, but the present invention is not limited to this as described above.
[0029]
In Table 1 above, the detected temperature of the temperature sensor 11 is classified by class, and the detected temperature of the temperature sensor 11 for detecting the temperature in the device in the housing 7 (FIG. 2) is compared with the temperature class in the display 1. Is done. The temperature classes 0 to 4 are the temperature ranges shown in parentheses in Table 1, and when the temperature detected by the temperature sensor 11 is in any of the temperature classes 0 to 4, the soundproof shutter 13 is fully closed at night. It is half open during the day. It should be noted that the nighttime is a time zone in which noise is particularly problematic, and can be appropriately determined, for example, from 4:00 pm to 8:00 am the next day, and in the daytime from 8:00 am to 4:00 pm.
[0030]
The control unit 5 determines whether it is nighttime or daytime by using a built-in timer. When switching from nighttime to daytime, the control unit 5 enters a power saving mode and the soundproof shutter 13 is initialized to a half-open state, and from daytime. When the mode is switched at night, the soundproof mode is set and the soundproof shutter 13 is initialized to the fully closed state. Then, the control unit 5 fetches the detected temperature from the temperature sensor 11, compares the detected temperature with the temperature table 12 shown in Table 1, determines which temperature class is included, reads the fan rotation speed for the corresponding temperature class, The cooling means 6 is controlled so that the fan 10 (FIG. 2) rotates at this fan rotation speed. Thus, for example, assuming that the detected temperature is 30 ° C., according to Table 1 above, the control unit 5 determines from the temperature table 12 that the fan rotation speed is 3000 min. ^-1 Is read, and the fan 10 is rotated at this rotation speed. At this time, in the soundproof mode, the soundproof shutter 13 is in a fully closed state, and in the power saving mode, the soundproof shutter 13 is in a half open state.
[0031]
The temperature detected by the temperature sensor 11 is taken into the control unit 5 at a constant cycle, and when the next temperature is taken, the cooling operation of the cooling means 6 usually causes the temperature inside the housing 7 (the temperature inside the device), The detected temperature has also dropped. The control unit 5 reads the fan rotation speed corresponding to the lowered detected temperature from the temperature table 12, and rotates the fan 10 at this rotation speed. In this way, the temperature inside the device decreases sequentially. The control unit 5 obtains the average value each time the detected temperature is acquired a plurality of times, reads the rotational speed of the temperature class corresponding to the average detected temperature from the temperature table 12, and sets the rotational speed of the fan 10. You may.
[0032]
In this manner, as the time elapses, the internal temperature of the device also decreases, the temperature detected by the temperature sensor 11 also decreases, the temperature rank decreases, and the rotation speed of the fan 10 also decreases. Then, when the temperature rank becomes 0, the fan 10 stops. In this state, if the temperature inside the device rises again and exceeds 0 ° C., the temperature rank changes from 0 to 1, and the control unit 5 again turns the fan 10 on for 2000 minutes. ^-1 It will rotate at the rotation speed of.
[0033]
Further, for example, when in the power saving mode in the daytime, the outside air temperature rises, and at the rotation speed of the fan 10 at that time, sufficient cooling is not performed, and when the temperature inside the device rises, the temperature increases. Since the rank increases, the rotation speed of the fan 10 also increases.
[0034]
Further, due to the relationship between the outside air temperature and the like, the internal temperature of the apparatus cannot be reduced at the rotation speed of the fan 10 specified in the temperature table 12, and the temperature may not change even if the temperature detected by the temperature sensor 11 is viewed a predetermined number of times. . Such a state is hereinafter referred to as a case where the temperature inside the apparatus has been saturated. If the temperature detected by the temperature sensor 11 is within a predetermined appropriate temperature range (hereinafter, referred to as an appropriate temperature range) in the housing 7 in the saturated state of the internal temperature of the device, the fan 10 is rotated at the same rotation speed. I will rotate it.
[0035]
However, even if the temperature inside the device is saturated and the detected temperature is taken in a predetermined number of times, there is no change, and if this detected temperature exceeds the appropriate temperature range, the control unit 5 sets the rotation speed of the fan 10 to In the case of the night soundproof mode, the soundproof shutter 13 is changed from the fully closed state to the half open state, and in the daytime power saving mode, the soundproof shutter 13 is changed from the half open state to the fully open state. change. For example, when the temperature inside the apparatus is saturated at the temperature rank 2, the soundproof shutter 13 is changed from the fully closed state to the half open state in the soundproof mode, and the soundproof shutter 13 is changed to the half open state in the power saving mode. Change to fully open state from. That is, the temperature rank is set to 5 in Table 1. Similarly, according to Table 1, when the temperature inside the device is saturated at temperature rank 3, the state is temperature rank 6, and when the temperature inside the device is saturated at temperature rank 4, the state is temperature rank 7. .
[0036]
As described above, when the temperature in the apparatus is saturated to a temperature exceeding the appropriate temperature range, the noise is increased by changing the open / close state of the soundproof shutter 13 to the open direction, but the heat exchange efficiency in the apparatus is improved. As a result, the cooling efficiency increases and the temperature inside the device decreases. Then, when the temperature falls below the temperature range of the designated temperature ranks 5, 6, and 7, in the case of the temperature rank 7, the open / close state of the soundproof shutter 13 is held as it is and the fan 10 Is gradually reduced to temperature ranks 6 and 5, and the temperature rank 6 is similarly changed to temperature rank 5. However, when the temperature is lower than the temperature range in the case of the temperature rank 5, the rotation speed of the fan 10 is 3000 min because the temperature in the apparatus is within the above-mentioned appropriate temperature range. ^-1 From 2000min ^-1 Further, in the case of the night soundproof mode, the soundproof shutter 13 is changed from the half open state to the fully closed state, and in the daytime power saving mode, the soundproof shutter 13 is changed from the fully open state to the half open state. Thus, the state of temperature rank 1 is set.
[0037]
Further, in the case of the night soundproof mode, even when the temperature in the apparatus is in the temperature rank 6, when the internal temperature of the apparatus is saturated, the soundproof shutter 13 is further changed from the half-open state to the fully open state. When the temperature in the apparatus is saturated even in the temperature rank 7, the soundproof shutter 13 is further changed from the half-open state to the full-open state. Is set to the state of temperature rank 9 shown in FIG. In the case of the daytime power saving mode, since the soundproof shutter 13 has already been set to the fully open state at the temperature ranks 6 and 7, the temperature ranks 8 and 9 do not occur and the state of the temperature ranks 6 and 7 remains unchanged. Will be maintained.
[0038]
In this way, when the temperature inside the apparatus is saturated beyond the appropriate temperature range, the soundproofing shutter 13 is opened to increase the cooling capacity. As a result, although noise increases somewhat, an increase in power consumption can be suppressed.
[0039]
Next, the operation of the control unit 5 will be described in more detail.
[0040]
FIG. 3 is a flowchart showing the control operation of the control unit 5 when the measured temperature is up to the temperature class 1.
[0041]
In the figure, step 100 indicates a switching time point between the night time zone and the day time zone detected by the control unit 5. At this time, when the time zone is switched from the day time zone to the night time zone, (Step 101) As the soundproof mode, as shown in Table 1 above, the soundproof shutter 13 is fully closed (step 102), and when the time is switched from the night time zone to the daytime time (step 101), the soundproof mode is set. As described above, the soundproof shutter 13 is half-opened (step 103). At this time, the control unit 5 holds the temperature rank as 0.
[0042]
In the soundproof mode or the power saving mode, the temperature detected by the temperature sensor 11 is taken in, the temperature inside the device is measured (step 104), and it is determined whether the measurement has been performed a specified number of times, for example, 5 times, and the specified number of times is measured. If not (step 105), the process waits for the next temperature measurement in the apparatus (step 104). Then, when the specified number of times are measured (step 104), the detected temperatures measured by the specified number of times are averaged, and the average value is set as the measured temperature (step 106).
[0043]
When the measured temperature is obtained in this manner, the control unit 5 compares the measured temperature with the temperature range of each temperature rank in the temperature table 12 shown in Table 1 (Step 107), and determines that the measured temperature is the temperature class. It is determined whether it is 0 (step 108). When the temperature class is 0, the control unit 5 determines from the temperature table 12 that the fan rotation speed of the temperature rank 0 is 0 min. ^-1 Is read out, the fan 10 is stopped, and the value 0 of the temperature rank, which is the result of comparison with the temperature table 12, is held. Then, the control operation from step 104 is repeated.
[0044]
When the measured temperature is not the temperature class 0 but the temperature class 1 of the temperature table 12 (step 110), the control unit 5 determines from the temperature table 12 that the fan rotation speed of the temperature class 1 is 2000 min. ^-1 Is read, the fan 10 is rotated at this rotation speed, and the value 0 of the temperature rank, which is the result of comparison with the temperature table 12, is held. Then, the process returns to step 104.
[0045]
In this way, when the measured temperature is in the temperature class 0 (0 ° C. or lower), the fan 10 is kept stopped. However, when the temperature inside the device rises and the measured temperature becomes temperature class 1, the fan 10 is turned on for 2000 minutes. ^-1 Rotate with. When the measured temperature is in the temperature class 1, the fan 10 is turned on for 2000 minutes. ^-1 Then, when the internal temperature of the apparatus decreases and the measured temperature becomes temperature class 0, the fan 10 is stopped.
[0046]
Next, the operation in the case where the measured temperatures are in the temperature ranks 2 to 4 will be described with reference to FIG.
[0047]
In the figure, when the measured temperature is in the temperature class 2 by comparing with the temperature table 12 (step 112), the control unit 5 determines the temperature class 2 by using the temperature rank held therein. It is determined whether or not the number N (for example, N = 5) has been repeated (step 113). That is, when the measured temperature is equal to or higher than the temperature rank 2, the temperature class obtained by comparing the temperature table 12 held by the control unit 5 with the past N-1 times and the temperature class obtained by the current comparison are the same. By determining whether or not the class has continued for the predetermined number N, it is determined whether or not the internal temperature of the apparatus has been saturated. If the temperature class 2 continues for a predetermined number of times N, it is determined that the internal temperature of the apparatus has been saturated, and the process proceeds to step 120 in FIG. 5. Rotation speed 3000min ^-1 Is read, and the fan 10 is rotated at this rotational speed (step 114). Then, the control unit 5 holds the temperature class 2 and returns to step 104 in FIG.
[0048]
The control unit 5 may hold the temperature class for the predetermined number N or more. Further, when the temperature class based on the comparison with the temperature table 12 is 1 or less, the control unit 5 does not necessarily need to hold the temperature class, and even if two or more temperature classes held so far are deleted. Good.
[0049]
If the measured temperature is in the temperature class 3 by comparing with the temperature table 12 (step 115), the control unit 5 uses the held temperature rank to determine the temperature class 3 as described above. It is determined whether or not the predetermined number N has continued (step 116). If it has continued, it is determined that the internal temperature of the apparatus has been saturated, and the process proceeds to step 121 in FIG. Rotation speed 4000 min from table 12 ^-1 Is read, and the fan 10 is rotated at this rotation speed (step 117). Then, the control unit 5 holds the temperature class 3 of the collation result, and returns to step 104 in FIG.
[0050]
Further, if the measured temperature is not in temperature classes 2 and 3 (steps 112 and 115), the temperature is classified into temperature class 4 and control unit 5 uses the temperature rank held by the temperature class. It is determined whether or not the temperature class 4 has continued for the predetermined number of times N (step 118). If the temperature class 4 has continued, it is determined that the internal temperature of the apparatus has been saturated, and the process proceeds to step 122 in FIG. If the number of times N has not been continued, the fan rotation speed from the temperature table 12 is set to 5000 min. ^-1 Is read, and the fan 10 is rotated at this rotation speed (step 119). Then, the control unit 5 holds the temperature class 4 of the collation result, and returns to step 104 in FIG.
[0051]
Next, the operation in the case where the measured temperatures are in the temperature ranks 5 to 7 will be described with reference to FIG.
[0052]
In the figure, when the temperature rank 2 continues for a specified number of times N (Step 113 in FIG. 4), at night, the control unit 5 changes the prevention shutter 13 from the fully closed state (FIG. 2C) to the half open state (FIG. 2C). b)), and in the daytime, the prevention shutter 13 is changed from the half-open state (FIG. 2 (b)) to the fully open state (FIG. 2 (a)) to obtain the respective temperature ranks 5 and hold them ( Step 120). When the temperature rank 3 continues for the specified number N (step 116 in FIG. 4), the control unit 5 changes the prevention shutter 13 from the fully closed state to the half-open state at night, and switches the prevention shutter 13 at daytime. The temperature is changed from the half-opened state to the fully-opened state to each of the temperature ranks 6 and is held (step 121). Further, when the temperature rank 4 continues for the specified number of times N (step 118 in FIG. 4), the control unit 5 changes the prevention shutter 13 from the fully closed state to the half-open state at night, and sets the prevention shutter 13 at daytime. The temperature is changed from the half-opened state to the fully-opened state to each of the temperature ranks 7 and held (step 122).
[0053]
When the open / close state of the prevention shutter 13 is changed in each of steps 120 to 122, the control unit 5 first determines whether the temperature class held by the control unit 5 is class 5 (step 123). If the temperature class is 5, and the measured temperature obtained in step 106 based on the temperature detected by the temperature sensor 11 does not fall below the temperature range of this temperature class 5 (21 ° C. to 35 ° C .: Table 1) (step 1). 124), the process returns to step 104 in FIG. 3 to perform the next acquisition of the detected temperature of the temperature sensor 11. If the measured temperature is lower than the temperature range of the temperature class 5, the internal temperature of the apparatus is equal to or less than 20 ° C. , The temperature rank is changed from rank 5 to rank 2 (step 125). Therefore, based on the temperature table 12 (Table 1 above), the soundproof shutter 13 is changed from the half-open state to the fully closed state, and the rotation speed of the fan 10 is set to 2000 min. ^-1 And Then, the process returns to step 104 of FIG.
[0054]
If the temperature class held by the control unit 5 is not class 5 (step 123), the control unit 5 determines whether or not the class is class 6 (step 126). If the measured temperature obtained in step 106 based on the temperature does not fall below the temperature range of this temperature class 6 (36 ° C. to 49 ° C .: Table 1) (step 127), the process proceeds to step 131 in FIG. If the temperature falls below the temperature range of temperature class 6, the temperature rank is changed from rank 6 to rank 5 (step 128). For this reason, based on the temperature table 12 (Table 1 above), the soundproof shutter 13 is kept in a half-open state at night, and is kept in a fully open state in the daytime, and the rotational speed of the fan 10 is reduced. 4000min ^-1 From 3000min ^-1 Change to Then, the process returns to step 104 of FIG.
[0055]
When the temperature class held by the control unit 5 is not the class 5 or 6 (steps 123 and 126), the temperature class is the class 7, and the control unit 5 calculates the temperature class in step 106 based on the temperature detected by the temperature sensor 11. It is determined whether or not the measured temperature falls below the temperature range of this temperature class 7 (50 ° C. to 52 ° C .: Table 1) (step 129). If not, the process proceeds to step 133 in FIG. If the temperature falls below the temperature range of the temperature class 7, the temperature rank is changed from rank 7 to rank 6 (step 130). For this purpose, based on the temperature table 12 (Table 1 above), the soundproof shutter 13 is kept in a half-open state at night, and is kept in a fully open state in the daytime. 5000min ^-1 From 4000min ^-1 Change to Then, the process returns to step 104 of FIG.
[0056]
In this way, if the inside temperature of the apparatus does not decrease even if the cooling means 6 is operated due to a high outside air temperature, the soundproof shutter 13 is opened, so that the inside temperature of the apparatus can be lowered. It is possible to reduce the power consumption by lowering the rotation speed of the fan 10 along with the temperature inside the device. When the internal temperature of the apparatus is sufficiently lowered to reach an appropriate temperature range, the rotation speed of the fan 10 is reduced and the soundproof shutter 13 is closed. Therefore, it is possible to reduce power consumption and achieve noise prevention. become.
[0057]
Next, referring to FIG. 6, the operation when the measured temperatures are in the temperature ranks 8 and 9 will be described. These temperature ranks are set only at night, as is clear from Table 1 showing the contents of the temperature table 12.
[0058]
3, when the control section 5 holds the temperature rank 6, the measured temperature obtained in step 106 of FIG. 3 continues for a predetermined number of times M, and the temperature range of this temperature rank 6 (36 ° C. to 49 ° C .: When the temperature does not fall below (Table 127) (step 127 in FIG. 5) and when the camera is in the night soundproof mode (step 131), the control unit 5 fully opens the soundproof shutter 13 and sets the temperature rank to rank 8. Further, when the temperature rank 7 is held in the control unit 5, the measured temperature obtained in step 106 of FIG. If it does not fall below (step 129 in FIG. 5), and if it is in the night soundproof mode (step 133), the control unit 5 fully opens the soundproof shutter 13 and sets the temperature rank to rank 9.
[0059]
The control unit 5 first determines whether the temperature class held by the control unit 5 is class 8 (step 135). When the temperature class is 8, the control unit 5 determines the temperature class in step 106 based on the temperature detected by the temperature sensor 11. If the measured temperature does not fall below the above-mentioned temperature range of this temperature class 8 (step 136), the process returns to step 104 of FIG. 3 and the next detection temperature of the temperature sensor 11 is taken. If the temperature falls below the temperature range of 8, the soundproof shutter 13 is changed from the fully open state to the semi-closed state, and the temperature rank is set to 5 (step 137). Then, the process returns to step 104 of FIG.
[0060]
When the temperature class held by the control unit 5 is not class 8 (step 135) but is class 9, the control unit 5 determines that the measured temperature obtained from step 106 based on the temperature detected by the temperature sensor 11 is equal to this temperature. It is determined whether or not the temperature falls below the temperature range of class 9 (step 138). If not, the process returns to step 104 of FIG. 3. If the measured temperature falls below the temperature range of temperature class 9, soundproofing is performed. While keeping the shutter 13 in the fully open state, the rotation speed of the fan 10 is ^-1 From 4000min ^-1 , And the temperature rank is changed to rank 8. Then, the process returns to step 104 of FIG.
[0061]
In this way, when the temperature in the apparatus does not decrease at night, the soundproof shutter 13 can be fully opened and the fan 10 can be rotated near the maximum rotation speed, thereby rapidly lowering the temperature in the apparatus. The soundproof shutter 13 can be returned to the soundproof mode in the closing direction.
[0062]
As mentioned above, although one Embodiment of this invention was described, this invention is not limited only to such embodiment. For example, in the above embodiment, the rotation speed of the fan 10 is specifically shown by a numerical value, but such a numerical value is merely an example. Further, the soundproof mode is set to night and the power saving mode is set to daytime. However, the time period of the soundproof mode and the power saving mode in which the user falls asleep can be appropriately determined according to the surrounding environment. Further, as shown in FIG. 2, the soundproof shutter can be opened and closed in three stages, that is, fully closed, half-opened, and fully opened. According to this, it is possible to appropriately set the temperature rank and appropriately assign the rotation speed of the fan 10 according to the temperature rank.
[0063]
【The invention's effect】
As described above, according to the present invention, it is possible to efficiently operate the cooling unit and reduce the temperature in the apparatus while preventing noise and reducing power consumption.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a circuit block configuration of an embodiment of a wireless base station device according to the present invention.
FIG. 2 is a perspective view showing a schematic appearance of the embodiment shown in FIG.
FIG. 3 is a flowchart showing a part of a specific example of a control operation of a cooling unit in FIGS. 1 and 2 in which a measured temperature is up to a temperature class 1;
FIG. 4 is a flowchart showing a control operation of a part where the measured temperature is in temperature classes 2 to 4 following the control operation shown in FIG. 3;
FIG. 5 is a flowchart showing a control operation of a portion where the measured temperature is in temperature classes 5 to 7 following the control operation shown in FIG. 4;
FIG. 6 is a flowchart showing a control operation of a portion where the measured temperature is in temperature classes 8 and 9 following the control operation shown in FIG. 5;
FIG. 7 is a block diagram illustrating a circuit block configuration of a conventional example of a wireless base station device.
8 is a perspective view showing a schematic appearance of the conventional example shown in FIG.
[Explanation of symbols]
1 transmitting and receiving antennas
2 Radio section
3 Signal processing unit
4 Wired interface
5 control part
6 Cooling means
7 Case
8 Air inlet
9 Air outlet
10 fans
11 Temperature sensor
12 Temperature table
13 Soundproof shutter
14 Filter

Claims (1)

In a wireless base station device housed in a housing and provided with cooling means for cooling the inside of the housing,
A soundproof shutter provided at an air outlet for cooling air in the housing formed in the housing;
First control means for changing the open / close state of the soundproof shutter according to a prescribed time zone;
A temperature sensor for detecting a temperature inside the housing;
A temperature table that defines the rotation speed of the fan of the cooling unit according to the temperature detected by the temperature sensor;
Second control means for reading the rotation speed according to the temperature detected by the temperature sensor from the temperature table and setting the rotation speed of the fan of the cooling means to the read rotation speed. Wireless base station device.

Images