JP3771377B2 - Weighing device - Google Patents

Description

【０００７】
したがって、もとの振幅Ａ１は床振動補正によってＡ１・√（２−２ｃｏｓθ）の振幅となる。位相差θがゼロであれば補正後の振幅もゼロとなり、床振動成分が完全に除去されたことになるが、位相差θがあると、完全に除去されない。この位相差は、例えばθ＝１°のときには、√（２−２ｃｏｓθ）＝０．０１７４であるから、計量セルの振幅の１．７４％が除去されずに残っていることになり、計量セルの振幅が大きいときには、わずかな位相差でも無視することができない。このように、高精度の計量を行う計量装置においては、この位相差による誤差によって床振動補償の正確性が低下するという問題があった。
【０００８】
本発明は、上記の問題点を解決して、計量セルと床振動検出セルの動特性の相違によって両信号に位相差が生じても、高精度の計量を図ることができる計量装置を提供することを目的としている。
【０００９】
【課題を解決するための手段】
上記目的を達成するために、請求項１の発明は、被計量物を計量して、その重量に対応した計量信号を出力する計量セルと、この計量セルが設置された床の振動を検出して、床振動検出信号を出力する床振動検出セルと、上記両セルの動特性の相違による両信号の位相差を打ち消すように、両信号の少なくとも一方の信号の位相を調整する位相調整手段と、上記位相差が打ち消された状態で、計量信号から床振動検出信号を減算して、床振動に起因する計量信号の誤差を補償した床振動補正済信号を出力する床振動補償手段とを備えている。
上記構成によれば、上記位相調整手段は、両セルの動特性の相違による両信号の位相差を調整して、両信号の位相差を打ち消している。したがって、計量信号から床振動検出信号を減算する床振動補償の正確性を向上させることができる。
【００１０】
請求項２の発明は、請求項１において、さらに、上記計量セルが出力するアナログ計量信号からノイズを除去する第１のアナログフィルタと、上記床振動検出セルが出力するアナログ床振動検出信号からノイズを除去する第２のアナログフィルタとを備え、上記位相調整手段は、上記第１のアナログフィルタと、このフィルタと異なるフィルタ特性をもつ第２のアナログフィルタとからなる。
上記構成によれば、上記位相調整手段は、両信号の位相差に応じて、アナログフィルタのフィルタ特性を変更するので、そのフィルタリングにより両信号の位相差を容易に打ち消すことができる。
【００１１】
請求項３の発明は、請求項１において、さらに、上記計量セルからの計量信号と床振動検出セルからの床振動検出信号をディジタル変換するＡ／Ｄ変換器と、上記ディジタル変換された計量信号をフィルタリングする第１のディジタルフィルタと、上記ディジタル変換された床振動検出信号をフィルタリングする第２のディジタルフィルタとを備え、上記位相調整手段は、上記第１のディジタルフィルタと、このフィルタと異なるフィルタ特性をもつ第２のディジタルフィルタとからなる。
上記構成によれば、上記位相調整手段は、両信号の位相差に応じて、ディジタルフィルタのフィルタ特性を変更するので、そのフィルタリングにより両信号の位相差を容易に打ち消すことができる。
【００１２】
請求項４の発明は、請求項１において、上記位相調整手段が、上記計量セルと床振動検出セルの少なくとも一方に振動減衰力を調整する減衰力調整部材を貼付することにより、両セルから出力する両信号の位相差を打ち消すものである。
上記構成によれば、上記位相調整手段は、両信号の位相差に応じて、減衰力調整部材の貼付量を変更するので、両信号の位相差を容易に打ち消すことができる。
【００１３】
【発明の実施の形態】
以下、本発明の実施形態を図面に基づいて説明する。
図１に、本発明の第１実施形態に係る計量装置の構成を示す。本計量装置は、被計量物を計量して、その重量に対応したアナログ計量信号を出力する計量セル２、およびこの計量セル２が設置された床Ｆの振動を検出して、アナログ床振動検出信号を出力する床振動検出セル４を備えている。計量セル２の起歪体Ｋ１には計量皿Ｄ１が支持され、床振動検出セル４の起歪体Ｋ２には錘りＤ２が設けられており、歪発生量の大きい上下面の４か所に歪ゲージＧが貼り付けられている。
【００１４】
本計量装置は、さらに、アナログ計量信号からノイズを除去する第１のアナログ（ローパス）フィルタ５、アナログ床振動検出信号からノイズを除去する第２のアナログ（ローパス）フィルタ６、各アナログ信号を増幅するアンプ７、各アナログ信号について一定周波数以上の信号を除去するアンチエイリアスフィルタ８、各アナログ信号をディジタル変換するＡ／Ｄコンバータ９、ＣＰＵ（マイクロコンピュータ）１５、および位相調整手段１８を備えている。この位相調整手段１８は、両セル２，４の形状、材質、寸法等の差違に起因する動特性の相違による両信号の位相差を打ち消すように、両信号の少なくとも一方の信号の位相を調整するものである。
【００１５】
上記ＣＰＵ１５は、Ａ／Ｄコンバータ９，９によりディジタル変換した計量信号と床振動検出信号をフィルタリングしてフィルタ済計量信号とフィルタ済床振動検出信号を出力する第１および第２のディジタルフィルタ１０，１１、このフィルタ済床振動検出信号を両セルの出力感度比に基づいてゲイン補正するゲイン補正手段１２、およびフィルタ済計量信号ｙm からゲイン補正されたフィルタ済床振動検出信号ｙc を減算して床振動補正済信号ｙを出力する床振動補償手段１４を備えている。
【００１６】
図２のように、計量セル２および床振動検出セル４のそれぞれ４つの歪ゲージＧによりブリッジ回路Ｂが形成されており、その出力端子Ｏ１，Ｏ２からアナログ計量信号，アナログ床振動検出信号が取り出されている。上記第１および第２のアナログフィルタ５，６は、キャパシタであるコンデンサＨを有しており、計量セル２，床振動検出セル４の歪ゲージＧとコンデンサＨによって１次フィルタを構成する。位相調整手段１８は、第１および第２のアナログフィルタ５，６からなり、アナログフィルタ５，６のフィルタ特性が、従来と異なり、互いに相違するように設定されている。この設定は、アナログフィルタ５，６のコンデンサＨのキャパシタンスを相違させることによりなされる。
【００１７】
以下、本計量装置の動作を説明する。
まず、図１に示す計量セル２から検出された被計量物の計量信号、および床振動検出セル４から検出された床振動検出信号は、それぞれアナログフィルタ５，６でノイズを除去され、アンプ７で増幅され、アンチエイリアスフィルタ８で一定の周波数以上が除去されて、Ａ／Ｄ変換器９でディジタル変換される。次に、ＣＰＵ１５において、計量信号は第１のディジタルフィルタ１０でフィルタリングされて、フィルタ済計量信号ｙm として出力される。また、床振動検出信号は、第２のディジタルフィルタ１１でフィルタリングされ、さらに、ゲイン補正手段１２で両セル２，４の出力感度比に基づいてゲイン補正されることにより、両セル２，４のゲインを一致させたのち、フィルタ済床振動検出信号ｙc として出力される。そして、床振動補償手段２０により、フィルタ済計量信号ｙm からゲイン補正されたフィルタ済床振動検出信号ｙc を減算する減算処理を行い、床振動を補正した床振動補正済信号ｙを出力する。これにより、床振動に起因する計量信号の誤差が補償された床振動補正済計量信号ｙが得られる。
【００１８】
図３（ａ）は、計量セル２と床振動検出セル４の周波数−位相特性の一例を示す。横軸は床振動の周波数（Ｈｚ）、縦軸は床振動と各セル２，４からのアナログ出力信号との位相のずれ（度）である。ここで、両セル２，４の動特性が同一でない場合には、図３（ａ）のように、計量セル２から出力する計量信号と床振動検出セル４から出力する床振動検出信号とに位相差が生じる。この図では、床振動検出信号より計量信号の位相が遅れている。図３（ａ）の特性は、例えば、被計量物をのせないで、床振動を図１の両セル２，４に与え、アンプ７からの信号を外部のシグナルアナライザに入力して、位相差を測定することにより得られる。
【００１９】
計量セル２からの計量信号の位相が床振動検出信号より相対的に遅れている場合には、その遅れている分だけ計量信号の位相が進むように、第１および第２のアナログフィルタ５，６のフィルタ特性を変更する。図４に、コンデンサＨのキャパシタンスを変化させたときのアナログフィルタ５，６の周波数−位相特性を示す。この図のように、キャパシタンスを小さくするに従って相対的に位相が進むことになる。図３（ｂ）は、（ａ）の計量信号の遅れ位相に応じて、その分計量信号の位相が相対的に進むようにフィルタ特性を変えたアナログフィルタ５，６の周波数−位相特性を示す。
【００２０】
図３（ｂ）のフィルタ特性を変えたアナログフィルタ５，６で両信号をフィルタリングした結果を、図３（ｃ）に示す。この図のように、床振動の周波数範囲である約２０Ｈｚ以下において、両信号の位相差はほぼゼロとなりその位相差が打ち消されている。
【００２１】
上記位相調整手段１８の動作を伝達関数の演算式を用いて説明する。まず、アナログフィルタ５，６の入力と出力の関係を示す伝達関数は、歪ゲージＧの抵抗をＲ、コンデンサＨのキャパシタンスをＣとすると、１／（１＋ｊω（ＲＣ／２））で示される。このフィルタ５，６の伝達関数Ｇ₁ (jω) ，Ｇ₂ (jω) は、両信号の位相差に応じて、その位相差を打ち消すように、キャパシタンスＣを変えることによりフィルタ特性を変えた後のものである（図３（ｂ））。計量セル２の伝達関数Ｇ₁₁(jω) と床振動検出セル４の伝達関数Ｇ₀₀(jω) は、両セル２，４の動特性に依存している（図３（ａ））。両セル２，４からの信号は、これらフィルタ特性を変えたアナログフィルタ５，６によりフィルタリングされるので、結局、各セル２，４とアナログフィルタ５，６を組み合わせた伝達関数は次式で示される（図３（ｃ））。
計量セル２側 Ｇ₁₁(jω) Ｇ₁ (jω)
床振動検出セル４側 Ｇ₀₀(jω) Ｇ₂ (jω)
計量セル２および床振動検出セル４から位相差を有して出力する両信号は、上記フィルタ特性に設定されたアナログフィルタ５，６のフィルタリングにより、その位相差がほぼゼロになる。
【００２２】
この例ではアナログフィルタ５，６の両方のキャパシタンスＣを変えているが、いずれか一方だけのキャパシタンスＣを変えるようにしてもよい。また、アナログフィルタ５，６のキャパシタンスＣを変更する代わりに、別のコンデンサをコンデンサＨに並列接続してもよい。
【００２３】
なお、アナログフィルタ５，６のフィルタ特性を変えることで、そのゲイン特性も変わってくるが、このフィルタ５，６のカットオフ周波数は床振動周波数よりもかなり高い領域にあるので、低周波領域のゲインにはほとんど影響を及ぼさない。また、より正確に補正しようとすると、位相調整後、再度ゲイン調整すればよい。
【００２４】
このように、本計量装置は、計量セル２と床振動検出セル４の動特性の相違によって生じる両信号の位相差に応じて、ノイズを除去するアナログフィルタ５，６によって両信号に反対方向の位相差を与え、そのフィルタリングにより両信号の位相差を打ち消すから、両信号の位相差がなくなり、計量信号から床振動検出信号を減算する床振動補償の正確性を向上させることができる。また、計量装置に既存のアナログフィルタ５，６を用いて両信号の位相差を打ち消すので、容易かつ低コストで高精度の計量を図ることができる。さらに、セル２，４と、予め位相調整済のアナログフィルタ５，６とを１セットとして用意しておくことにより、セル２，４の取り替えに際して、後段側の回路を位相調整のために調整する必要がなく、その１セットの取り替えのみで済むので、保守，点検が容易となる。
【００２５】
なお、図１に示したように、計量セル２側および床振動検出セル４側のそれぞれにＡ／Ｄコンバータ９を設けるのではなく、マルチプレクサを設けて、Ａ／Ｄコンバータ９を単一にしてもよい。各信号は、マルチプレクサにより、計量セル２または床振動検出セル４から、アナログフィルタ５，６、アンプ７、アンチエイリアスフィルタ８を経て、選択的に取り出され、単一のＡ／Ｄコンバータ９で順次ディジタル信号に変換されたのち、デマルチプレクサ手段により、対応するディジタルフィルタ１０、１１に選択的に入力される。各セルが複数の場合であっても、Ａ／Ｄコンバータ９は単一でよいので、低コスト化を図ることができる。
【００２６】
図５に、第２実施形態の計量装置の構成図を示す。この第２実施形態では、アナログフィルタ５，６を用いた第１の位相調整手段１８に加えて、第１のディジタルフィルタ１０と、このフィルタ１０と異なるフィルタ特性をもつ第２のディジタルフィルタ１１とからなる第２の位相調整手段２８を設けている。この第２の位相調整手段２８は、第１の位相調整手段１８により大まかに位相差を打ち消したのち、残った僅かな位相差を打ち消す微調整手段として用いられる。このディジタルフィルタ１０，１１には、通常のＦＩＲ（Finite Impulse Response)形フィルタに加え、位相補正用として、例えば再帰形フィルタのＩＩＲ(Infinite Impulse Response) 形が用いられる。
【００２７】
ディジタルフィルタ１０，１１のフィルタ特性は、従来と異なり、互いに相違するように設定されている。つまり、Ａ／Ｄ変換器９，９からの両信号の位相差に応じて、この位相差と反対方向の位相差を与えて位相差を打ち消すようにディジタルフィルタ１０および１１のフィルタ特性を変更する。フィルタ特性を変更すると、カットオフ周波数が変わる。例えば、カットオフ周波数を低くすると、位相遅れが大きくなる。Ａ／Ｄ変換器９から出力された計量セル２側の計量信号の位相が遅れている場合には、その遅れている分だけ、Ａ／Ｄ変換器９から出力された床振動検出セル６側の床振動検出信号の位相が遅れるように、両ディジタルフィルタ１０，１１のフィルタ特性を手動で変更することになる。
【００２８】
これにより、第２の位相調整手段２８は、両信号の位相差を十分に打ち消すことができる。
【００２９】
なお、ＣＰＵ１５内に計量信号と床振動検出信号の位相差を検出する手段と、ディジタルフィルタ１０，１１のフィルタ特性を変更する手段とを設け、位相差に応じて、ディジタルフィルタ１０，１１のフィルタ特性を自動的に変更してもよい。
【００３０】
なお、この実施形態では、両ディジタルフィルタ１０，１１のフィルタ特性を変更しているが、いずれか一方のフィルタ特性を変更するようにしてもよい。また、両セル２，４の動特性の差が小さいためにセル２，４から出力されるアナログ信号の位相差が小さい場合には、第１の位相調整手段１８を割愛して、つまり、アナログフィルタ５，６のフィルタ特性を同一にして、第２の位相調整手段２８単独で、位相差を打ち消すようにしてもよい。
【００３１】
つぎに、第３実施形態の計量装置について説明する。本計量装置は、第１実施形態と異なり、図６の床振動検出セル４ａ（または計量セル２ａ）の伝達関数そのものを変えて、両信号の位相差を打ち消すものである。本計量装置の位相調整手段３８は、計量セル２ａと床振動検出セル４ａの少なくとも一方に貼り付けられて振動減衰力を調整する減衰力調整部材からなり、この減衰力調整部材３８により、両セル２ａ，４ａの動特性の相違によって生じる両信号の位相差を打ち消す。減衰力調整部材３８は、ロードセルの固有振動数でのピーク値を抑えてロードセルの使用可能なダイナミックレンジを拡げる作用をもつものであるが、本発明では、この減衰力調整部材３８がロードセルから出力する信号の位相ずれをも生じさせる作用をもつことに着目したものである。信号処理の回路構成は、図１のアナログフィルタ５，６のフィルタ特性を同一にした点を除いて、図１と同一である。
【００３２】
減衰力調整部材３８は例えばブチルゴムからなる。床振動検出セル４ａは、床Ｆに支持される固定部３２と、上下のビーム部を形成する薄いステンレス製の基板３４と、これら基板３４を介して固定部３２に支持された可動部（錘り部）３３と、固定部３２に取り付けられて可動部３３の上下移動を制限するストッパ部材であるストッパねじ３７を有している。また、ステンレス板３４の表面にはノッチ部３６が設けられ、このステンレス板３４の裏面に、ノッチ部３６と対向する位置に歪ゲージＧが例えばスパッタリングにより形成されている。ステンレス板３４および歪ゲージＧの表面にはブチルゴム３８がその粘着力によって貼付される。
【００３３】
以下、上記減衰力調整部材（ブチルゴム）３８の動作を説明する。まず、上記第１実施形態の場合と同様に、被計量物をのせない状態で、シグナルアナライザにより計量信号と床振動検出信号の位相差を測定して、図３（ａ）の特性を得る。得られた両信号の位相差に応じて、両信号の位相差を打ち消すように図６の床振動検出セル４ａへのブチルゴム３８の貼付量を設定する。このとき、ブチルゴム３８を貼付した床振動検出セル４ａの伝達関数Ｇ₀₁(jω) は、可動部３３の質量をｍ、減衰定数をｃ、ばね定数をｋとすると、次式で示される。
【００３４】

ここで、一定寸法（一定質量）のブチルゴム３８を用いた場合、ブチルゴム３８の貼付量（枚数）と減衰定数ｃおよびばね定数ｋとには、表１に示すように、一定の相関関係がある。そこで、両信号の位相差を打ち消す伝達関数Ｇ₀₁(jω) となるように、床振動検出セル４ａのブチルゴム３８の貼付量、つまり枚数を表１の値に基づいて設定する。
【００３５】
【表１】

【００３６】
図７に、床振動検出セル４ａに貼付するブチルゴム３８の枚数を変化させたとき、床振動検出セル４ａの周波数−位相特性を示す。この図のように、ブチルゴム３８の枚数を多くするに従って位相が遅れる。計量信号の位相が遅れている場合には、その遅れている分だけ床振動検出信号の位相も遅れるように、床振動検出セル４ａに貼付するブチルゴム３８の枚数を設定することになる。
【００３７】
これにより、第３実施形態の位相調整手段３８は、両信号の位相差に応じて、両信号に反対方向の位相差を与えるので、両信号の位相差を容易に打ち消すことができる。
【００３８】
なお、この実施形態では、床振動検出セル４ａのステンレス板３４および歪ゲージＧの表裏面にブチルゴム３８を貼付しているが、いずれか一方の面にのみ貼付してもよい。また、床振動検出セル４ａにのみブチルゴム３８を貼付しているが、計量セル２ａにのみ貼付してもよく、両セルに貼付するようにしてもよい。
【００３９】
また、第１実施形態のアナログフィルタ５，６のフィルタ特性による調整と、第３実施形態の減衰力調整部材による調整とを組合せて、両信号の位相差を打ち消すようにしてもよい。
【００４０】
【発明の効果】
本発明によれば、位相調整手段は、両セルの動特性の相違による両信号の位相差を打ち消している。従って、計量信号から床振動検出信号を減算する床振動補償の正確性を向上させることができる。
【図面の簡単な説明】
【図１】本発明の第１実施形態に係る計量装置を示す構成図である。
【図２】第１実施形態の位相調整手段を示す回路図である。
【図３】上記位相調整手段の動作を示す特性図である。
【図４】アナログフィルタの周波数−位相特性を示す特性図である。
【図５】第２実施形態に係る計量装置を示す構成図である。
【図６】第３実施形態に係る計量装置の床振動検出セルを示す側面図である。
【図７】上記床振動検出セルの周波数−位相特性を示す特性図である。
【符号の説明】
２…計量セル、４…床振動検出セル、５…第１のアナログフィルタ、６…第２のアナログフィルタ、９…Ａ／Ｄ変換器、１０…第１のディジタルフィルタ、１１…第２のディジタルフィルタ、１４…床振動補償手段、１８，２８，３８…位相調整手段。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a weighing device that removes a weighing error due to a vibration component of a floor on which a weighing cell is installed from a weighing signal output from the weighing cell.
[0002]
[Prior art]
Generally, when weighing objects in factory production lines, floor vibrations of low frequency (about 20 Hz or less) occur due to the environment such as the ground, building, floor, gantry, etc. The vibration component is superimposed on the weighing signal. For this reason, in the weighing device, a floor vibration detection cell for outputting a floor vibration detection signal is provided on the same floor as the weighing cell in the vicinity of the weighing cell for weighing an object to be weighed and outputting a weighing signal corresponding to the weight. In some cases, floor vibration compensation is performed by removing the floor vibration component in the measurement signal by installing and subtracting the floor vibration signal from the measurement signal.
[0003]
In the weighing device that performs floor vibration compensation, if the weighing cell and the floor vibration detection cell are not the same size, such as when the floor vibration detection cell is downsized to save space, the weighing cell side and the floor vibration Since the gain of the output signal with respect to the input signal is different on the detection cell side, it is necessary to perform gain correction that matches the output sensitivity of one of the cells with the other to match the output gain of both cells.
[0004]
[Problems to be solved by the invention]
However, if the dynamic characteristics of the weighing cell and the floor vibration detection cell are not the same, that is, if the amplitude and phase lag (damping force) of the output signal with respect to the input signal (excitation force) are not the same, only the difference in the above gains However, a difference in dynamic characteristics causes a phase difference between the weighing signal and the floor vibration detection signal.
[0005]
Here, in the weighing cell and the floor vibration detection cell having different dynamic characteristics, the weighing signal from the weighing cell is Y1, the floor vibration detection signal from the floor vibration detection cell is Y2, the respective amplitudes are A1 and A2, and the phase difference is θ. When the floor vibration frequency is ω, the weighing signal Y1 and the floor vibration detection signal Y2 are expressed by the following equations.
Y1 = A1 · cos ωt, Y2 = A2 · cos (ωt + θ)
In the floor vibration compensation, as described above, the coefficient C is multiplied so that the amplitude A2 of the floor vibration detection signal Y2 is equal to the amplitude A1 of the measurement signal Y1 with respect to the same excitation force (in this case, floor vibration) ( That is, after gain correction: A1 = C · A2), the two signals are subtracted.
[0006]

[0007]
Therefore, the original amplitude A1 becomes an amplitude of A1 · √ (2-2 cos θ) by the floor vibration correction. If the phase difference θ is zero, the corrected amplitude is zero and the floor vibration component is completely removed. However, if the phase difference θ is present, the amplitude is not completely removed. For example, when θ = 1 °, this phase difference is √ (2-2 cos θ) = 0.0174. Therefore, 1.74% of the amplitude of the weighing cell remains without being removed. When the amplitude of is small, even a slight phase difference cannot be ignored. As described above, in the weighing apparatus that performs high-precision weighing, there is a problem that the accuracy of the floor vibration compensation is lowered due to the error due to the phase difference.
[0008]
The present invention solves the above-described problems and provides a weighing device capable of high-precision weighing even if a phase difference occurs between both signals due to a difference in dynamic characteristics between the weighing cell and the floor vibration detection cell. The purpose is that.
[0009]
[Means for Solving the Problems]
In order to achieve the above object, the invention of claim 1 is to detect a vibration of a weighing cell that weighs an object to be measured and outputs a weighing signal corresponding to its weight, and a floor on which the weighing cell is installed. A floor vibration detection cell that outputs a floor vibration detection signal, and a phase adjustment unit that adjusts the phase of at least one of the two signals so as to cancel the phase difference between the two signals due to the difference in dynamic characteristics of the two cells. A floor vibration compensation means for subtracting the floor vibration detection signal from the weighing signal in a state where the phase difference is canceled and outputting a floor vibration corrected signal that compensates for an error in the weighing signal caused by the floor vibration. ing.
According to the above configuration, the phase adjusting means adjusts the phase difference between the two signals due to the difference in the dynamic characteristics of the two cells and cancels out the phase difference between the two signals. Accordingly, it is possible to improve the accuracy of floor vibration compensation in which the floor vibration detection signal is subtracted from the measurement signal.
[0010]
According to a second aspect of the present invention, in the first aspect, the first analog filter that removes noise from the analog weighing signal output from the weighing cell, and the noise from the analog floor vibration detection signal output from the floor vibration detection cell. And the phase adjusting means includes the first analog filter and a second analog filter having a filter characteristic different from that of the filter.
According to the above configuration, the phase adjusting unit changes the filter characteristics of the analog filter in accordance with the phase difference between the two signals, so that the phase difference between the two signals can be easily canceled by the filtering.
[0011]
According to a third aspect of the present invention, in the first aspect, the A / D converter that digitally converts the weighing signal from the weighing cell and the floor vibration detection signal from the floor vibration detection cell, and the digitally converted weighing signal. And a second digital filter for filtering the digitally converted floor vibration detection signal, and the phase adjusting means includes the first digital filter and a filter different from the filter. And a second digital filter having characteristics.
According to the above configuration, the phase adjusting unit changes the filter characteristics of the digital filter in accordance with the phase difference between the two signals, so that the phase difference between the two signals can be easily canceled by the filtering.
[0012]
According to a fourth aspect of the present invention, in the first aspect, the phase adjusting means outputs from both cells by attaching a damping force adjusting member for adjusting the vibration damping force to at least one of the measuring cell and the floor vibration detecting cell. This cancels out the phase difference between the two signals.
According to the above configuration, the phase adjusting unit changes the amount of the damping force adjusting member depending on the phase difference between the two signals, so that the phase difference between the two signals can be easily canceled out.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows a configuration of a weighing device according to the first embodiment of the present invention. This weighing device detects the vibration of the weighing cell 2 that measures an object to be measured and outputs an analog weighing signal corresponding to the weight, and the floor F in which the weighing cell 2 is installed, and detects the analog floor vibration. A floor vibration detection cell 4 for outputting a signal is provided. A weighing pan D1 is supported on the strain body K1 of the weighing cell 2, and a weight D2 is provided on the strain body K2 of the floor vibration detection cell 4, and is provided at four locations on the upper and lower surfaces where the strain generation amount is large. A strain gauge G is attached.
[0014]
The weighing apparatus further includes a first analog (low-pass) filter 5 that removes noise from the analog weighing signal, a second analog (low-pass) filter 6 that removes noise from the analog floor vibration detection signal, and amplifies each analog signal. An anti-aliasing filter 8 that removes a signal having a predetermined frequency or higher for each analog signal, an A / D converter 9 that digitally converts each analog signal, a CPU (microcomputer) 15, and a phase adjusting means 18. This phase adjusting means 18 adjusts the phase of at least one of the two signals so as to cancel out the phase difference between the two signals due to the difference in dynamic characteristics caused by the difference in shape, material, size, etc. of the cells 2 and 4. To do.
[0015]
The CPU 15 filters the weighing signal digitally converted by the A / D converters 9 and the floor vibration detection signal, and outputs a filtered weighing signal and a filtered floor vibration detection signal. 11. Gain correction means 12 for correcting the gain of this filtered floor vibration detection signal based on the output sensitivity ratio of both cells, and subtracting the filtered floor vibration detection signal yc whose gain has been corrected from the filtered weighing signal ym Floor vibration compensation means 14 for outputting a vibration corrected signal y is provided.
[0016]
As shown in FIG. 2, a bridge circuit B is formed by four strain gauges G in each of the weighing cell 2 and the floor vibration detection cell 4, and an analog weighing signal and an analog floor vibration detection signal are taken out from the output terminals O1 and O2. It is. The first and second analog filters 5 and 6 have a capacitor H which is a capacitor, and the strain gauge G and the capacitor H of the weighing cell 2 and the floor vibration detection cell 4 constitute a primary filter. The phase adjusting unit 18 includes first and second analog filters 5 and 6, and the filter characteristics of the analog filters 5 and 6 are set to be different from each other unlike conventional ones. This setting is made by making the capacitances of the capacitors H of the analog filters 5 and 6 different.
[0017]
Hereinafter, the operation of the weighing device will be described.
First, the weighing signal of the object to be weighed detected from the weighing cell 2 and the floor vibration detection signal detected from the floor vibration detection cell 4 shown in FIG. The anti-aliasing filter 8 removes a certain frequency or more, and the A / D converter 9 performs digital conversion. Next, in the CPU 15, the weighing signal is filtered by the first digital filter 10 and outputted as a filtered weighing signal ym. Further, the floor vibration detection signal is filtered by the second digital filter 11 and further gain-corrected by the gain correction means 12 based on the output sensitivity ratio of both cells 2 and 4, thereby After matching the gains, the filtered floor vibration detection signal yc is output. Then, the floor vibration compensation means 20 performs a subtraction process for subtracting the filtered floor vibration detection signal yc whose gain has been corrected from the filtered weighing signal ym, and outputs a floor vibration corrected signal y obtained by correcting the floor vibration. As a result, the floor vibration corrected weighing signal y in which the error of the weighing signal due to floor vibration is compensated is obtained.
[0018]
FIG. 3A shows an example of frequency-phase characteristics of the weighing cell 2 and the floor vibration detection cell 4. The horizontal axis represents the floor vibration frequency (Hz), and the vertical axis represents the phase shift (degree) between the floor vibration and the analog output signals from the cells 2 and 4. Here, when the dynamic characteristics of both the cells 2 and 4 are not the same, the weighing signal output from the weighing cell 2 and the floor vibration detection signal output from the floor vibration detection cell 4 as shown in FIG. A phase difference occurs. In this figure, the phase of the weighing signal is delayed from the floor vibration detection signal. The characteristic of FIG. 3A is that, for example, a floor vibration is applied to both the cells 2 and 4 of FIG. 1 without placing an object to be measured, and a signal from the amplifier 7 is input to an external signal analyzer to obtain a phase difference. Is obtained by measuring.
[0019]
When the phase of the weighing signal from the weighing cell 2 is relatively delayed from the floor vibration detection signal, the first and second analog filters 5 and 5 are arranged so that the phase of the weighing signal advances by the amount of the delay. 6 is changed. FIG. 4 shows the frequency-phase characteristics of the analog filters 5 and 6 when the capacitance of the capacitor H is changed. As shown in this figure, the phase advances relatively as the capacitance is reduced. FIG. 3B shows the frequency-phase characteristics of the analog filters 5 and 6 in which the filter characteristics are changed so that the phase of the measurement signal is relatively advanced in accordance with the delay phase of the measurement signal of FIG. .
[0020]
FIG. 3C shows the result of filtering both signals with the analog filters 5 and 6 with the filter characteristics changed in FIG. 3B. As shown in this figure, when the floor vibration frequency range is about 20 Hz or less, the phase difference between the two signals is almost zero, and the phase difference is cancelled.
[0021]
The operation of the phase adjusting means 18 will be described using a transfer function arithmetic expression. First, the transfer function indicating the relationship between the input and output of the analog filters 5 and 6 is represented by 1 / (1 + jω (RC / 2)), where R is the resistance of the strain gauge G and C is the capacitance of the capacitor H. The transfer functions G ₁ (jω) and G ₂ (jω) of the filters 5 and 6 change the filter characteristics by changing the capacitance C so as to cancel the phase difference according to the phase difference between both signals. (FIG. 3B). The transfer function G ₁₁ (jω) of the weighing cell 2 and the transfer function G ₀₀ (jω) of the floor vibration detection cell 4 depend on the dynamic characteristics of both the cells 2 and 4 (FIG. 3A). Since the signals from both the cells 2 and 4 are filtered by the analog filters 5 and 6 in which the filter characteristics are changed, the transfer function combining the cells 2 and 4 and the analog filters 5 and 6 is expressed by the following equation. (FIG. 3C).
Weighing cell 2 side G ₁₁ (jω) G ₁ (jω)
Floor vibration detection cell 4 side G ₀₀ (jω) G ₂ (jω)
Both signals output with a phase difference from the weighing cell 2 and the floor vibration detection cell 4 have a phase difference of almost zero due to the filtering of the analog filters 5 and 6 set to the filter characteristics.
[0022]
In this example, both the capacitances C of the analog filters 5 and 6 are changed, but only one of the capacitances C may be changed. Further, another capacitor may be connected in parallel to the capacitor H instead of changing the capacitance C of the analog filters 5 and 6.
[0023]
The gain characteristics are also changed by changing the filter characteristics of the analog filters 5 and 6. However, since the cut-off frequency of the filters 5 and 6 is in a considerably higher area than the floor vibration frequency, Has little effect on gain. Further, in order to correct more accurately, the gain may be adjusted again after the phase adjustment.
[0024]
As described above, the weighing device is configured so that both signals are opposite to each other by the analog filters 5 and 6 that remove noise according to the phase difference between the two signals caused by the difference in dynamic characteristics between the weighing cell 2 and the floor vibration detection cell 4. Since the phase difference is given and the phase difference between the two signals is canceled by the filtering, the phase difference between the two signals is eliminated, and the accuracy of the floor vibration compensation for subtracting the floor vibration detection signal from the measurement signal can be improved. In addition, since the existing analog filters 5 and 6 are used in the weighing device to cancel the phase difference between the two signals, high-precision weighing can be achieved easily and at low cost. Furthermore, by preparing the cells 2 and 4 and the analog filters 5 and 6 that have been subjected to phase adjustment in advance as a set, the circuit on the rear stage side is adjusted for phase adjustment when the cells 2 and 4 are replaced. There is no need, and only one set needs to be replaced, so maintenance and inspection are easy.
[0025]
As shown in FIG. 1, instead of providing the A / D converter 9 on each of the weighing cell 2 side and the floor vibration detection cell 4 side, a multiplexer is provided to make the A / D converter 9 as a single unit. Also good. Each signal is selectively extracted from the weighing cell 2 or the floor vibration detection cell 4 by the multiplexer through the analog filters 5 and 6, the amplifier 7, and the antialiasing filter 8, and is sequentially digitalized by a single A / D converter 9. After being converted into a signal, it is selectively inputted to the corresponding digital filters 10 and 11 by the demultiplexer means. Even if there are a plurality of cells, the A / D converter 9 may be single, so that the cost can be reduced.
[0026]
In FIG. 5, the block diagram of the weighing | measuring apparatus of 2nd Embodiment is shown. In the second embodiment, in addition to the first phase adjusting means 18 using the analog filters 5 and 6, the first digital filter 10 and the second digital filter 11 having a filter characteristic different from that of the filter 10 are provided. Second phase adjusting means 28 is provided. The second phase adjusting unit 28 is used as a fine adjusting unit that cancels out the slight phase difference after the phase difference is roughly canceled by the first phase adjusting unit 18. The digital filters 10 and 11 use, for example, a recursive filter IIR (Infinite Impulse Response) type for phase correction in addition to a normal FIR (Finite Impulse Response) type filter.
[0027]
Unlike the prior art, the filter characteristics of the digital filters 10 and 11 are set to be different from each other. That is, according to the phase difference between both signals from the A / D converters 9 and 9, the filter characteristics of the digital filters 10 and 11 are changed so as to cancel the phase difference by giving a phase difference in the opposite direction to this phase difference. . Changing the filter characteristics changes the cutoff frequency. For example, when the cut-off frequency is lowered, the phase delay is increased. When the phase of the weighing signal on the weighing cell 2 side outputted from the A / D converter 9 is delayed, the floor vibration detection cell 6 side outputted from the A / D converter 9 is correspondingly delayed. Therefore, the filter characteristics of both the digital filters 10 and 11 are manually changed so that the phase of the floor vibration detection signal is delayed.
[0028]
Thereby, the second phase adjusting means 28 can sufficiently cancel the phase difference between both signals.
[0029]
A means for detecting the phase difference between the weighing signal and the floor vibration detection signal and a means for changing the filter characteristics of the digital filters 10 and 11 are provided in the CPU 15, and the filters of the digital filters 10 and 11 are provided according to the phase difference. The characteristics may be changed automatically.
[0030]
In this embodiment, the filter characteristics of both the digital filters 10 and 11 are changed. However, one of the filter characteristics may be changed. If the phase difference between the analog signals output from the cells 2 and 4 is small because the difference between the dynamic characteristics of the cells 2 and 4 is small, the first phase adjustment means 18 is omitted, that is, the analog The filter characteristics of the filters 5 and 6 may be the same, and the second phase adjusting unit 28 alone may cancel the phase difference.
[0031]
Next, a weighing device according to a third embodiment will be described. Unlike the first embodiment, this weighing device changes the transfer function itself of the floor vibration detection cell 4a (or the weighing cell 2a) in FIG. 6 to cancel the phase difference between the two signals. The phase adjusting means 38 of the present measuring device is composed of a damping force adjusting member that is attached to at least one of the measuring cell 2a and the floor vibration detecting cell 4a and adjusts the vibration damping force. The phase difference between the two signals caused by the difference in the dynamic characteristics of 2a and 4a is canceled out. The damping force adjusting member 38 has an action of expanding the usable dynamic range of the load cell by suppressing the peak value at the natural frequency of the load cell. In the present invention, the damping force adjusting member 38 is output from the load cell. This is because it has an effect of causing a phase shift of the signal to be generated. The signal processing circuit configuration is the same as that of FIG. 1 except that the filter characteristics of the analog filters 5 and 6 of FIG. 1 are the same.
[0032]
The damping force adjusting member 38 is made of, for example, butyl rubber. The floor vibration detection cell 4a includes a fixed portion 32 supported by the floor F, a thin stainless steel substrate 34 that forms upper and lower beam portions, and a movable portion (weight) supported by the fixed portion 32 via these substrates 34. And a stopper screw 37 that is a stopper member that is attached to the fixed portion 32 and restricts the vertical movement of the movable portion 33. Further, a notch portion 36 is provided on the surface of the stainless steel plate 34, and a strain gauge G is formed on the back surface of the stainless steel plate 34 at a position facing the notch portion 36 by, for example, sputtering. Butyl rubber 38 is attached to the surface of the stainless steel plate 34 and the strain gauge G by its adhesive force.
[0033]
Hereinafter, the operation of the damping force adjusting member (butyl rubber) 38 will be described. First, as in the case of the first embodiment, the phase difference between the measurement signal and the floor vibration detection signal is measured by a signal analyzer in a state where the object to be weighed is not placed, and the characteristic shown in FIG. 3A is obtained. In accordance with the phase difference between the two signals obtained, the amount of butyl rubber 38 applied to the floor vibration detection cell 4a in FIG. 6 is set so as to cancel the phase difference between the two signals. At this time, the transfer function G ₀₁ (jω) of the floor vibration detection cell 4a to which the butyl rubber 38 is attached is expressed by the following equation, where m is the mass of the movable portion 33, c is the damping constant, and k is the spring constant.
[0034]

Here, when the butyl rubber 38 having a certain size (constant mass) is used, the amount (number of sheets) of the butyl rubber 38, the damping constant c, and the spring constant k have a certain correlation as shown in Table 1. . Therefore, the amount of butyl rubber 38 applied to the floor vibration detection cell 4a, that is, the number of sheets, is set based on the values in Table 1 so that the transfer function G ₀₁ (jω) cancels the phase difference between the two signals.
[0035]
[Table 1]

[0036]
FIG. 7 shows the frequency-phase characteristics of the floor vibration detection cell 4a when the number of butyl rubbers 38 attached to the floor vibration detection cell 4a is changed. As shown in this figure, the phase is delayed as the number of butyl rubbers 38 is increased. When the phase of the weighing signal is delayed, the number of butyl rubbers 38 to be affixed to the floor vibration detection cell 4a is set so that the phase of the floor vibration detection signal is also delayed by that delay.
[0037]
As a result, the phase adjusting means 38 of the third embodiment gives a phase difference in the opposite direction to both signals according to the phase difference between both signals, so that the phase difference between both signals can be easily canceled out.
[0038]
In this embodiment, the butyl rubber 38 is affixed to the stainless steel plate 34 of the floor vibration detection cell 4a and the front and back surfaces of the strain gauge G. However, it may be affixed only to one of the surfaces. Moreover, although the butyl rubber 38 is affixed only to the floor vibration detection cell 4a, it may be affixed only to the measurement cell 2a, or may be affixed to both cells.
[0039]
Moreover, you may make it cancel the phase difference of both signals combining the adjustment by the filter characteristic of the analog filters 5 and 6 of 1st Embodiment, and the adjustment by the damping force adjustment member of 3rd Embodiment.
[0040]
【The invention's effect】
According to the present invention, the phase adjusting means cancels the phase difference between the two signals due to the difference in the dynamic characteristics of the two cells. Accordingly, it is possible to improve the accuracy of floor vibration compensation in which the floor vibration detection signal is subtracted from the measurement signal.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing a weighing device according to a first embodiment of the present invention.
FIG. 2 is a circuit diagram showing phase adjusting means of the first embodiment.
FIG. 3 is a characteristic diagram showing the operation of the phase adjusting means.
FIG. 4 is a characteristic diagram showing frequency-phase characteristics of an analog filter.
FIG. 5 is a configuration diagram showing a weighing device according to a second embodiment.
FIG. 6 is a side view showing a floor vibration detection cell of a weighing device according to a third embodiment.
FIG. 7 is a characteristic diagram showing frequency-phase characteristics of the floor vibration detection cell.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 2 ... Measurement cell, 4 ... Floor vibration detection cell, 5 ... 1st analog filter, 6 ... 2nd analog filter, 9 ... A / D converter, 10 ... 1st digital filter, 11 ... 2nd digital Filter, 14 ... floor vibration compensation means, 18, 28, 38 ... phase adjustment means.

Claims (4)

A weighing cell that weighs an object and outputs a weighing signal corresponding to the weight;
A floor vibration detection cell that detects the vibration of the floor where the weighing cell is installed and outputs a floor vibration detection signal;
Phase adjusting means for adjusting the phase of at least one of the two signals so as to cancel the phase difference between the two signals caused by the difference in the dynamic characteristics of the two cells;
Floor vibration compensation means for subtracting the floor vibration detection signal from the weighing signal and outputting a floor vibration corrected signal that compensates for an error in the weighing signal caused by floor vibration in a state where the phase difference is cancelled. Weighing device. The claim 1, further comprising:
A first analog filter for removing noise from the analog weighing signal output by the weighing cell;
A second analog filter for removing noise from the analog floor vibration detection signal output by the floor vibration detection cell,
The phase adjusting means is a weighing device including the first analog filter and a second analog filter having a filter characteristic different from that of the filter. The claim 1, further comprising:
An A / D converter for digitally converting the weighing signal from the weighing cell and the floor vibration detection signal from the floor vibration detection cell;
A first digital filter for filtering the digitally converted weighing signal;
A second digital filter for filtering the digitally converted floor vibration detection signal;
The phase adjusting means is a weighing device including the first digital filter and a second digital filter having a filter characteristic different from that of the first filter. In claim 1,
The phase adjusting means is a measuring device that cancels the phase difference between the two signals by attaching a damping force adjusting member that adjusts the vibration damping force to at least one of the measuring cell and the floor vibration detecting cell.

Images