JPH0926352A - Multipoint cell type metering device - Google Patents
Multipoint cell type metering deviceInfo
- Publication number
- JPH0926352A JPH0926352A JP19814395A JP19814395A JPH0926352A JP H0926352 A JPH0926352 A JP H0926352A JP 19814395 A JP19814395 A JP 19814395A JP 19814395 A JP19814395 A JP 19814395A JP H0926352 A JPH0926352 A JP H0926352A
- Authority
- JP
- Japan
- Prior art keywords
- weighing
- frequency
- article
- signal
- cell
- 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.)
- Granted
Links
Landscapes
- Sorting Of Articles (AREA)
Abstract
Description
【0001】[0001]
【産業上の利用分野】この発明は、計量コンベアを支持
する複数の計量セルからの計量信号を加算して、計量コ
ンベア上を移動する物品の重量を計測する多点セル型計
量装置に関し、その計測の高速,高精度化に関する。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-point cell type weighing device for measuring the weight of an article moving on a weighing conveyor by adding weighing signals from a plurality of weighing cells supporting the weighing conveyor. Regarding high-speed and high-accuracy measurement.
【0002】[0002]
【従来の技術】一般に、計量装置の計量信号は、計量対
象の物品を載荷したときの衝撃や重量検出系の固有振動
の影響を受けて、物品の重量を示す真の計量信号にその
重量に応じた機械振動成分が重畳されている。このた
め、真の計量信号を得るには、このような不要な成分を
フィルタによって除去する必要がある。なお、この重量
検出系の固有振動とは、物品載荷時の載台とこれを支持
する計量セル(ロードセル)とからなる重量検出系にお
ける減衰効果を無視したときの自由振動の振動数を意味
する。2. Description of the Related Art In general, a weighing signal of a weighing device is affected by an impact when an article to be weighed is loaded and a natural vibration of a weight detection system, and is converted into a true weighing signal indicating the weight of the article. The corresponding mechanical vibration component is superimposed. Therefore, in order to obtain a true weighing signal, it is necessary to remove such unnecessary components with a filter. The natural vibration of the weight detection system means the frequency of free vibration when the damping effect in the weight detection system consisting of the platform for loading the article and the weighing cell (load cell) supporting the platform is ignored. .
【0003】ところが、この不要成分を除去するために
ローパスフィルタを用いると、計量信号の応答性が悪く
なり、計量の高速化が図れないという問題点があった。
このため、従来から種々の計量装置が提案されている。However, when a low-pass filter is used to remove this unnecessary component, there is a problem that the response of the weighing signal deteriorates and the weighing cannot be speeded up.
For this reason, various measuring devices have been conventionally proposed.
【0004】例えば、特公平6−21814号公報で開
示された計重(量)装置の計重(量)信号の濾波装置が
ある。この装置は、計量信号のサンプリング値について
各回の移動平均の移動平均数を、計量装置の計量範囲に
よって定まる振動及び或いは計量装置により生じる強い
共振振動を含む周波数帯及びその近傍に複数のノッチ周
波数が存在するように、それぞれ異ならせている。つま
り、移動平均を移動平均数を適当に選択して異ならせて
複数回行うことにより、ローパス特性を有するノッチフ
ィルタを作成して、応答性を向上するようにしている。[0004] For example, there is a filtering device for a weighing signal of a weighing device disclosed in Japanese Patent Publication No. 6-21814. In this device, the moving average number of each moving average for the sampling value of the weighing signal is determined by a plurality of notch frequencies in and around a frequency band including a vibration determined by the weighing range of the weighing device and / or a strong resonance vibration generated by the weighing device. They are different so that they exist. That is, a notch filter having a low-pass characteristic is created by performing the moving average a plurality of times by appropriately selecting the moving average number and making it different, thereby improving the responsiveness.
【0005】[0005]
【発明が解決しようとする課題】上記従来の濾波装置
は、計量対象の物品を載せる載台を、単一の計量セルに
より1点で支持する計量装置に適用されるものであり、
物品の重量が一定範囲内であれば、重量検出系の固有振
動周波数は変化しない。The above-mentioned conventional filtering device is applied to a weighing device in which a table for placing articles to be weighed is supported at one point by a single weighing cell.
If the weight of the article is within a certain range, the natural vibration frequency of the weight detection system does not change.
【0006】これに対して、計量コンベアを複数の計量
セルにより支持して、計量コンベア上を移動する物品の
重量を各計量セルからの計量信号を加算した加算信号に
より求める多点セル型計量装置においては、物品の移動
に伴って各計量セルの固有振動周波数も変化する。On the other hand, a multi-point cell type weighing device in which the weighing conveyor is supported by a plurality of weighing cells and the weight of the article moving on the weighing conveyor is obtained by an addition signal obtained by adding the weighing signals from the respective weighing cells. In, the natural vibration frequency of each weighing cell also changes with the movement of the article.
【0007】例えば、図7のような計量コンベア1を計
量セル2-1,2-2によって2点支持する場合に、物品M
がまず計量コンベア1の入口端に載せられると、計量セ
ル2-1にかかる物品Mの重量が大きいのでその固有振動
周波数が低くなる一方、計量セル2-2にかかる物品Mの
重量が小さいので固有振動周波数は高くなる。その後、
物品Mが出口端に移動すると、計量セル2-1にかかる物
品Mの重量が小さくなるので固有振動周波数は高くなる
一方、計量セル2-2にかかる物品Mの重量が大きくなる
のでその固有振動周波数が低くなる。このように、多点
セル型計量装置においては、計量コンベア1上で物品M
が移動すると、これに伴って各計量セルの固有振動周波
数が変化するので、上記従来の濾波装置では対応できな
いという問題があった。For example, when the weighing conveyor 1 as shown in FIG. 7 is supported by the weighing cells 2-1 and 2-2 at two points, the article M is
Is first placed on the entrance end of the weighing conveyor 1, the weight of the article M on the weighing cell 2-1 is large and its natural vibration frequency is low, while the weight of the article M on the weighing cell 2-2 is small. The natural vibration frequency becomes high. afterwards,
When the article M moves to the outlet end, the weight of the article M on the weighing cell 2-1 becomes smaller and the natural vibration frequency becomes higher, while the weight of the article M on the weighing cell 2-2 becomes larger and its natural vibration becomes higher. The frequency becomes low. As described above, in the multi-point cell type weighing device, the articles M are placed on the weighing conveyor 1.
However, since the natural vibration frequency of each metering cell changes accordingly, there is a problem that the above-mentioned conventional filtering device cannot cope with this.
【0008】この発明は、上記の問題点を解決して、計
量対象の物品の移動により計量コンベアを支持するロー
ドセル出力の固有振動周波数が変化しても、高速かつ高
精度の計量を図ることができる多点セル型計量装置を提
供することを目的としている。The present invention solves the above problems and enables high-speed and high-accuracy weighing even if the natural vibration frequency of the load cell output for supporting the weighing conveyor changes due to the movement of the articles to be weighed. It is an object of the present invention to provide a multi-point cell type weighing device that can be used.
【0009】[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、物品を搬送しながら計量するた
めの計量コンベアを複数の計量セルにより支持して、計
量コンベア上を移動する物品の重量を各計量セルからの
計量信号を加算した加算信号により求める多点セル型計
量装置であって、各計量セルの出力値から各計量セル間
の出力感度比を求めて感度係数を算出し、求めたそれぞ
れの感度係数に基づいて上記計量信号を補正する感度補
正手段と、所定の遮断周波数より高い上記計量信号の周
波数成分を減衰して出力させるローパスフィルタと、上
記ローパスフィルタと組み合わされ、上記加算信号の固
有振動の周波数をノッチ周波数とするノッチフィルタと
を備えている。In order to achieve the above object, the invention of claim 1 supports a weighing conveyor for weighing articles while conveying them by a plurality of weighing cells and moves on the weighing conveyor. A multi-point cell type weighing device that obtains the weight of the article to be obtained by the addition signal obtained by adding the weighing signals from each weighing cell, and obtains the output sensitivity ratio between the weighing cells from the output value of each weighing cell to obtain the sensitivity coefficient. A combination of the sensitivity correction means that corrects the weighing signal based on the calculated and obtained respective sensitivity coefficients, a low-pass filter that attenuates and outputs the frequency component of the weighing signal that is higher than a predetermined cutoff frequency, and the low-pass filter And a notch filter that uses the natural vibration frequency of the added signal as a notch frequency.
【0010】請求項2の発明は、請求項1において、上
記ローパスフィルタとノッチフィルタは、ディジタルフ
ィルタである。According to a second aspect of the present invention, in the first aspect, the low pass filter and the notch filter are digital filters.
【0011】[0011]
【作用および効果】この請求項1の発明によれば、所定
の遮断周波数より高い計量信号の周波数成分を減衰して
出力させるローパスフィルタと、物品を載せた計量コン
ベアの各計量セルの加算信号の固有振動周波数をノッチ
周波数とするノッチフィルタとを組み合わせて用いるこ
とにより、ローパスフィルタの遮断周波数を高くするこ
とができ、計量信号の応答性が向上する。これにより、
被計量物の移動により各計量セルの固有振動周波数が変
化しても、高速かつ高精度の計量を図ることができる多
点セル型計量装置を提供することができる。According to the invention of claim 1, the low-pass filter for attenuating and outputting the frequency component of the weighing signal higher than the predetermined cutoff frequency, and the addition signal of each weighing cell of the weighing conveyor on which the article is placed. The cutoff frequency of the low-pass filter can be increased by using a notch filter having the natural vibration frequency as the notch frequency in combination, and the response of the weighing signal is improved. This allows
It is possible to provide a multi-point cell type weighing device capable of performing high-speed and highly accurate weighing even if the natural vibration frequency of each weighing cell changes due to the movement of the object to be weighed.
【0012】この請求項2の発明によれば、ローパスフ
ィルタとノッチフィルタは、ディジタルフィルタであ
る。従って、フィルタ定数の変更を容易にするととも
に、計量の高速性を向上することができる。According to the invention of claim 2, the low-pass filter and the notch filter are digital filters. Therefore, it is possible to easily change the filter constant and improve the speed of weighing.
【0013】[0013]
【実施例】以下、この発明の実施例を図面に基づいて説
明する。図1に、この発明の一実施例に係る多点セル型
計量装置の構成を示す。この計量装置は、物品Mを搬送
しながら計量するための計量コンベア1を備えており、
計量コンベア1は多点(この例では2つ)の計量セル2
(2-1,2-2)を有している。Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows the configuration of a multipoint cell type weighing device according to an embodiment of the present invention. This weighing device includes a weighing conveyor 1 for weighing the articles M while conveying the articles M,
The weighing conveyor 1 has a multi-point (two in this example) weighing cells 2
It has (2-1, 2-2).
【0014】計量コンベア1は、両端の支持ローラJ1
と支持ローラJ2 との間にベルトBが掛け渡され、モー
タM1 によって両支持ローラJ1 ,J2 を駆動させてベ
ルトBを走行させるベルトコンベアCと、両支持ローラ
J1 ,J2 を支持するコンベア支持台3と、この支持台
3の両端下方に配置されて、この支持台3に起歪体4の
可動部4aが固定され、固定部4bが架台Fに固定され
ている計量セル(ビーム型ロードセル)2とを有してい
る。また、計量コンベア1の入口端には、物品Mの通過
を検知するための光電センサ5が配置されている。The weighing conveyor 1 has support rollers J1 at both ends.
The belt B is stretched between the supporting roller J2 and the supporting roller J2, and the motor M1 drives both supporting rollers J1 and J2 to run the belt B, and the conveyor support base that supports both supporting rollers J1 and J2. 3 and a measuring cell (beam type load cell) which is arranged below both ends of the support base 3 and to which the movable portion 4a of the flexure element 4 is fixed, and the fixed portion 4b is fixed to the mount F. 2 and. A photoelectric sensor 5 for detecting the passage of the article M is arranged at the entrance end of the weighing conveyor 1.
【0015】また、この計量装置は、増幅器(DCアン
プ)6,アナログLPF(ローパスフィルタ)8,A/
D変換器10,感度係数補正手段12,加算手段14,
ローパスフィルタ16,ノッチフィルタ18,および重
量推定手段20を備えている。感度係数補正手段12,
加算手段14,ローパスフィルタ16,ノッチフィルタ
18,および重量推定手段20はCPU22に内蔵され
ている。以下、この装置の動作を説明する。Further, this measuring device includes an amplifier (DC amplifier) 6, an analog LPF (low-pass filter) 8, A /
D converter 10, sensitivity coefficient correction means 12, addition means 14,
A low pass filter 16, a notch filter 18, and a weight estimating means 20 are provided. Sensitivity coefficient correction means 12,
The adding means 14, the low-pass filter 16, the notch filter 18, and the weight estimating means 20 are built in the CPU 22. Hereinafter, the operation of this device will be described.
【0016】この例では、計量対象の物品Mを2種類
(すなわち、重量が同じ20kgで長手方向に寸法が異
なる30型(300mm)と50型(500mm))用
意し、計量コンベア1のベルト速度Vを3種類(すなわ
ち、40a(a=0.5,1,1.5)(m/mi
n))に設定して、それぞれについて計量精度特性デー
タを測定している。In this example, two kinds of articles M to be weighed are prepared (that is, 30 type (300 mm) and 50 type (500 mm) having the same weight of 20 kg and different lengthwise dimensions, and the belt speed of the weighing conveyor 1 is set. Three types of V (that is, 40a (a = 0.5, 1, 1.5) (m / mi
n)), and the measurement accuracy characteristic data is measured for each.
【0017】まず、計量セル2-1,計量セル2-2により
検出された物品Mの荷重信号f1(t),f2(t) は、それ
ぞれ増幅器6により増幅され、アナログLPF(ローパ
スフィルタ)8によって一定の周波数以上が除去され、
A/D変換器10により所定サンプリング周波数でディ
ジタル変換されて、ディジタル荷重信号df1(t),df
2(t) を出力する。この場合、アナログLPF8はA/
D変換器10の上記サンプリング周波数との関係で一定
の周波数以上を除去(アンチエリアス)する目的で使用
される。First, the load signals f1 (t) and f2 (t) of the article M detected by the weighing cell 2-1 and the weighing cell 2-2 are respectively amplified by the amplifier 6 and the analog LPF (low-pass filter) 8 is supplied. Above a certain frequency is removed,
The digital weight signals df1 (t) and df are digitally converted by the A / D converter 10 at a predetermined sampling frequency.
Output 2 (t). In this case, the analog LPF8 is A /
It is used for the purpose of removing (anti-aliasing) a certain frequency or more in relation to the sampling frequency of the D converter 10.
【0018】次に、このディジタル荷重信号df1(t),
df2(t) は、CPU22に入力され、CPU22内の
各手段によって、物品Mの重量に応じて重畳された機械
振動成分が除去され、かつ重量が推定されることによ
り、物品Mの重量が計測される。以下、CPU22内の
各手段の動作を説明する。Next, the digital weight signal df1 (t),
df2 (t) is input to the CPU 22, and the mechanical vibration component superimposed according to the weight of the article M is removed by each means in the CPU 22 and the weight is estimated to measure the weight of the article M. To be done. The operation of each unit in the CPU 22 will be described below.
【0019】まず、ディジタル荷重信号df1(t),df
2(t) は、感度係数補正手段12に入力される。この感
度係数補正手段12は、計量セル2-1と計量セル2-2の
出力値から両セル間のばね定数および歪ゲージの歪感度
の相違に起因する出力感度比を求めて感度係数αを算出
し、算出されたそれぞれの感度係数αに基づいて、計量
セル2-1,2-2のディジタル荷重信号df1(t),df2
(t) を補正して、感度補正済信号α・df1(t) また
はα・df2(t) を出力する。First, the digital weight signals df1 (t), df
2 (t) is input to the sensitivity coefficient correction means 12. The sensitivity coefficient correcting means 12 obtains an output sensitivity ratio resulting from a difference in spring constant between both cells and strain sensitivity of the strain gauge from the output values of the weighing cell 2-1 and the weighing cell 2-2 to obtain a sensitivity coefficient α. The digital load signals df1 (t) and df2 of the weighing cells 2-1 and 2-2 are calculated based on the calculated sensitivity coefficients α.
(t) is corrected to output the sensitivity-corrected signal α · df1 (t) or α · df2 (t).
【0020】その後、計量セル2-1と計量セル2-2の感
度補正済信号は加算手段14により加算されて、計量信
号W (t) を出力する。図2に、加算信号W (t) の波
形の一例を示す。この図のように、この計量信号W
(t) には、物品Mの重量に応じた機械振動成分が重畳
されている。なお、この例では、光電センサ5が物品M
を検知して作動する0.5秒前を時間t(sec) の原
点としている。Thereafter, the sensitivity-corrected signals of the weighing cell 2-1 and the weighing cell 2-2 are added by the adding means 14 to output the weighing signal W (t). FIG. 2 shows an example of the waveform of the addition signal W (t). As shown in this figure, this weighing signal W
A mechanical vibration component corresponding to the weight of the article M is superimposed on (t). In this example, the photoelectric sensor 5 is the article M.
0.5 seconds before the detection and operation is made the origin of time t (sec).
【0021】次に、図1の加算信号W (t) は、LPF
(ローパスフィルタ)16に入力される。このLPF1
6では、所定の遮断周波数(例えば、8Hz)より高い
加算信号W (t) の周波数成分を減衰して、フィルタ済
信号F (t) を出力させる。図3に、フィルタ済信号F
(t) の波形の一例を示す。この図のように、フィルタ
済信号F (t) は、物品Mの重量に応じて重畳された機
械振動成分が除去されている。なお、LPF16単独の
場合には、この機械振動成分を除去するために、遮断周
波数を例えば2Hzに低く設定する必要がある(図4参
照)。Next, the addition signal W (t) in FIG.
(Low-pass filter) 16 is input. This LPF1
At 6, the frequency component of the addition signal W (t) higher than a predetermined cutoff frequency (for example, 8 Hz) is attenuated to output the filtered signal F (t). FIG. 3 shows the filtered signal F
An example of the waveform of (t) is shown. As shown in this figure, the filtered signal F (t) has the mechanical vibration component superimposed according to the weight of the article M removed. In the case of the LPF 16 alone, it is necessary to set the cutoff frequency as low as 2 Hz in order to remove this mechanical vibration component (see FIG. 4).
【0022】次に、図1のフィルタ済信号F (t) は、
NF(ノッチフィルタ)18に入力される。NF18
は、物品Mを載せた計量コンベア1の各計量セル2-1,
2-2の加算信号の固有振動周波数、すなわち、物品Mが
計量コンベア1の重心位置近傍にある場合の計量コンベ
ア1の固有振動周波数(例えば、中心周波数30Hz)
をノッチ周波数とする。図4に、二点鎖線で表すLPF
16単独の場合と、実線で表すLPF16とこのNF1
8とを組み合わせた場合の減衰特性を示す。Next, the filtered signal F (t) of FIG.
It is input to the NF (notch filter) 18. NF18
Is each weighing cell 2-1 of the weighing conveyor 1 on which the article M is placed,
The natural vibration frequency of the addition signal 2-2, that is, the natural vibration frequency of the weighing conveyor 1 when the article M is near the center of gravity of the weighing conveyor 1 (for example, a center frequency of 30 Hz)
Is the notch frequency. The LPF represented by the chain double-dashed line in FIG.
16 alone and LPF16 and this NF1 shown by the solid line
The attenuation characteristics when 8 and 8 are combined are shown.
【0023】このノッチ周波数を計量コンベア1の固有
振動周波数(30Hz)に精度よく設定したNF18に
より、フィルタ済信号F (t) は、その固有振動周波数
を中心とした所定帯域の周波数が除去される。そして、
LPF16と、この計量コンベア1の固有振動周波数
(30Hz)を精度よく除去しかつ応答性のよいNF1
8とを組み合せることにより、図4に示すように、LP
F16単独の場合には遮断周波数を2Hzに設定する必
要があったのに比較して、LPF16の遮断周波数を8
Hzに高く設定することができ、計量信号の応答性が向
上する。The filtered signal F (t) has a frequency in a predetermined band centered on its natural vibration frequency removed by the NF 18 which accurately sets this notch frequency to the natural vibration frequency (30 Hz) of the weighing conveyor 1. . And
The LPF 16 and the NF 1 which removes the natural vibration frequency (30 Hz) of the weighing conveyor 1 with high accuracy and has a good response.
As shown in FIG. 4, by combining with 8 and LP
In the case of F16 alone, it was necessary to set the cutoff frequency to 2 Hz.
It can be set to a high value of Hz, and the response of the weighing signal is improved.
【0024】次に、図1において、LPF16およびN
F18によりフィルタリング処理された後に、重量推定
手段20により、例えば適当な区間の移動平均が求めら
れ、物品Mの重量を早期に推定する重量推定値が得られ
て、物品Mの重量が高速に測定される。Next, referring to FIG. 1, LPF 16 and N
After the filtering process by F18, the weight estimating unit 20 obtains a moving average of, for example, an appropriate section, obtains a weight estimated value for early estimation of the weight of the article M, and measures the weight of the article M at high speed. To be done.
【0025】図5に、30型の物品Mについて、3種類
のコンベア速度Vごとの重量推定値のばらつき3σ
(t)を示す。なお、横軸は時間t (s) を、縦軸はば
らつき3σ(t)を示す。各ばらつき3σ(t)の最小
の時刻(最適推定時刻)のデータ(つまり、ばらつきの
最も少ないデータ)が、高精度のデータとして取り込ま
れる。この図において、図1のベルトコンベアCのベル
ト速度Vが最も速いa=1.5の60m/minのとき
に、ばらつき3σ(t)の最適推定時刻が最も短い。ま
た、ベルト速度Vが最も遅いa=0.5の20m/mi
nのときに、ばらつき3σ(t)の最適推定時刻が最も
長い。つまり、ベルト速度Vが遅くなるほど、ばらつき
3σ(t)が最小の時刻を長く維持することができ、高
精度測定が可能になる。FIG. 5 shows a variation 3σ in the weight estimation value for each of the three conveyor speeds V for the 30-type article M.
(T) is shown. The horizontal axis represents time t (s) and the vertical axis represents variation 3σ (t). The data at the minimum time (optimum estimated time) of each variation 3σ (t) (that is, the data with the least variation) is captured as highly accurate data. In this figure, when the belt speed V of the belt conveyor C in FIG. 1 is 60 m / min, where a = 1.5, which is the fastest, the optimum estimated time of the variation 3σ (t) is the shortest. Further, the belt speed V is the slowest, a = 0.5, 20 m / mi
When n, the optimum estimated time of the variation 3σ (t) is the longest. That is, the slower the belt speed V, the longer the time when the variation 3σ (t) is minimum can be maintained, and the highly accurate measurement becomes possible.
【0026】図6に、30型の物品Mでベルト速度Vが
40m/minに設定した場合に、LPF処理のみした
ときと、LPF処理+NF処理したときのばらつき3σ
の効果の比較を示す。この図のように、LPF16の遮
断周波数fL が大きくなればなるほど、LPF16の処
理にNF18の処理を加えることによる高精度測定の効
果が大きいことが示される。この場合、この計量装置
は、精度1/4000(±5g,3σ)の測定が可能と
なっている。なお、遮断周波数fL が2Hz程度になる
と、NF18の処理を加える効果はほとんどない。FIG. 6 shows a variation 3σ between the LPF process only and the LPF process + NF process when the belt speed V is set to 40 m / min for a 30-type article M.
The comparison of the effect of is shown. As shown in this figure, the higher the cut-off frequency fL of the LPF 16, the greater the effect of highly accurate measurement by adding the process of the NF 18 to the process of the LPF 16. In this case, this weighing device can measure with an accuracy of 1/4000 (± 5 g, 3σ). When the cutoff frequency fL becomes about 2 Hz, the effect of adding the processing of the NF 18 has almost no effect.
【0027】以上のように、この多点セル型計量装置
は、所定の遮断周波数より高い計量信号の周波数成分を
減衰して出力させるLPF16と、物品Mを載せた計量
コンベア1の各計量セル2-1,2-2の加算信号の固有振
動周波数をノッチ周波数とするNF18とを組み合わせ
て用いることにより、LPF16の遮断周波数を高くす
ることができ、計量信号の応答性が向上する。As described above, this multi-point cell type weighing device attenuates the frequency component of the weighing signal higher than the predetermined cutoff frequency and outputs it, and each weighing cell 2 of the weighing conveyor 1 on which the article M is placed. The cutoff frequency of the LPF 16 can be increased by using the NF 18 in which the natural vibration frequencies of the addition signals of −1 and 2-2 are used as the notch frequency, and the response of the weighing signal is improved.
【0028】なお、この実施例では、計量信号を感度係
数補正手段12により感度補正して加算したのちに、L
PF16によりフィルタリング処理しているが、フィル
タリングしたのちに、感度補正して加算してもよい。In this embodiment, the weighting signal is sensitivity-corrected by the sensitivity coefficient correction means 12 and added, and then L
Although the filtering process is performed by the PF 16, the sensitivity may be corrected and added after filtering.
【0029】なお、この実施例では、LPF16および
NF18をディジタルフィルタで構成しているが、アナ
ログフィルタで構成してもよい。In this embodiment, the LPF 16 and the NF 18 are digital filters, but they may be analog filters.
【図1】この発明の一実施例に係る多点セル型計量装置
を示す構成図である。FIG. 1 is a configuration diagram showing a multipoint cell type weighing device according to an embodiment of the present invention.
【図2】加算信号を示す図である。FIG. 2 is a diagram showing an addition signal.
【図3】LPF処理後の信号を示す図である。FIG. 3 is a diagram showing a signal after LPF processing.
【図4】LPF単独の場合と、LPFとNFを組み合わ
せた場合の各々の減衰特性を示す図である。FIG. 4 is a diagram showing respective attenuation characteristics when the LPF is used alone and when the LPF and the NF are used in combination.
【図5】重量推定値のばらつき3σ(t)を示す図であ
る。FIG. 5 is a diagram showing variation 3σ (t) in estimated weight value.
【図6】LPF処理のみと、LPF処理+NF処理の効
果の比較を示す図である。FIG. 6 is a diagram showing a comparison of effects of only LPF processing and LPF processing + NF processing.
【図7】2つの計量セルにより2点支持する計量装置を
示す構成図である。FIG. 7 is a configuration diagram showing a weighing device that supports two points by two weighing cells.
1…計量コンベア、2…計量セル、12…感度補正手
段、16…LPF(ローパスフィルタ)、18…NF
(ノッチフィルタ)、M…物品。1 ... Weighing conveyor, 2 ... Weighing cell, 12 ... Sensitivity correction means, 16 ... LPF (low-pass filter), 18 ... NF
(Notch filter), M ... Article.
Claims (2)
量コンベアを複数の計量セルにより支持して、計量コン
ベア上を移動する物品の重量を各計量セルからの計量信
号を加算した加算信号により求める多点セル型計量装置
であって、 各計量セルの出力値から各計量セル間の出力感度比を求
めて感度係数を算出し、求めたそれぞれの感度係数に基
づいて上記計量信号を補正する感度補正手段と、 所定の遮断周波数より高い上記計量信号の周波数成分を
減衰して出力させるローパスフィルタと、 上記ローパスフィルタと組み合わされ、上記加算信号の
固有振動の周波数をノッチ周波数とするノッチフィルタ
とを備えている多点セル型計量装置。1. A weighing conveyor for weighing an article while conveying the article is supported by a plurality of weighing cells, and the weight of the article moving on the weighing conveyor is obtained by an addition signal obtained by adding the weighing signals from the respective weighing cells. A multi-point cell type weighing device, in which the sensitivity coefficient is calculated from the output value of each weighing cell from the output value of each weighing cell, and the sensitivity coefficient is calculated based on the obtained sensitivity coefficient. Correcting means, a low-pass filter that attenuates and outputs the frequency component of the weighing signal that is higher than a predetermined cutoff frequency, and a notch filter that is combined with the low-pass filter and that uses the natural vibration frequency of the addition signal as the notch frequency. Multi-point cell type weighing device equipped.
フィルタである多点セル型計量装置。2. The multipoint cell type weighing device according to claim 1, wherein the low-pass filter and the notch filter are digital filters.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP19814395A JP3469367B2 (en) | 1995-07-10 | 1995-07-10 | Multi-point cell type weighing device |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP19814395A JP3469367B2 (en) | 1995-07-10 | 1995-07-10 | Multi-point cell type weighing device |
Publications (2)
Publication Number | Publication Date |
---|---|
JPH0926352A true JPH0926352A (en) | 1997-01-28 |
JP3469367B2 JP3469367B2 (en) | 2003-11-25 |
Family
ID=16386180
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
JP19814395A Expired - Fee Related JP3469367B2 (en) | 1995-07-10 | 1995-07-10 | Multi-point cell type weighing device |
Country Status (1)
Country | Link |
---|---|
JP (1) | JP3469367B2 (en) |
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2013076669A (en) * | 2011-09-30 | 2013-04-25 | Minebea Co Ltd | Filter device, indicator and measuring apparatus |
JP2013250237A (en) * | 2012-06-04 | 2013-12-12 | Anritsu Sanki System Co Ltd | Weighing device |
JP2015203668A (en) * | 2014-04-16 | 2015-11-16 | 大和製衡株式会社 | weight indicator |
JP2017134031A (en) * | 2016-01-29 | 2017-08-03 | オムロン株式会社 | Signal processor, control method and control program for the same, and recording medium |
JP2021120642A (en) * | 2020-01-30 | 2021-08-19 | 株式会社イシダ | Measurement device |
-
1995
- 1995-07-10 JP JP19814395A patent/JP3469367B2/en not_active Expired - Fee Related
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2013076669A (en) * | 2011-09-30 | 2013-04-25 | Minebea Co Ltd | Filter device, indicator and measuring apparatus |
JP2013250237A (en) * | 2012-06-04 | 2013-12-12 | Anritsu Sanki System Co Ltd | Weighing device |
JP2015203668A (en) * | 2014-04-16 | 2015-11-16 | 大和製衡株式会社 | weight indicator |
JP2017134031A (en) * | 2016-01-29 | 2017-08-03 | オムロン株式会社 | Signal processor, control method and control program for the same, and recording medium |
US10551242B2 (en) | 2016-01-29 | 2020-02-04 | Omron Corporation | Signal processing device, control method of signal processing device, control program and recording medium |
JP2021120642A (en) * | 2020-01-30 | 2021-08-19 | 株式会社イシダ | Measurement device |
Also Published As
Publication number | Publication date |
---|---|
JP3469367B2 (en) | 2003-11-25 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
USRE36411E (en) | Weighing apparatus with means for correcting effects of vibrations | |
US9417118B2 (en) | Device for vibration compensation of the weight signal of a weighing sensor | |
CA2072696C (en) | Weighing scale with validating reference channel | |
JPH0621814B2 (en) | Method and device for filtering weighing signal of weighing device | |
JP5848880B2 (en) | Weighing device | |
JP5658594B2 (en) | Weighing device | |
US5936206A (en) | Weighing machines with means for correcting effects of floor vibrations on weight signals therefrom | |
JP3469367B2 (en) | Multi-point cell type weighing device | |
Kelemençe et al. | Dynamic weighing using a time-variant low pass filter | |
JP4931666B2 (en) | Meter | |
JPH07209102A (en) | Temperature compensation method and device for load cell | |
KR910001147B1 (en) | Weighting meter system | |
JP3631546B2 (en) | Weighing device | |
JPS5825217B2 (en) | Electric dynamometer torque measurement method | |
WO1991011687A1 (en) | Weight measuring apparatus | |
JP3642639B2 (en) | A weighing device having a plurality of load converting means | |
JP3422546B2 (en) | Floor vibration correction method and apparatus | |
JP3765105B2 (en) | Floor vibration correction method and apparatus | |
JPH08110261A (en) | Apparatus for mass measurement and apparatus for weight measurement | |
US20220299357A1 (en) | Weighing apparatus | |
JP3581179B2 (en) | Mass or weight measuring device | |
JPH10185673A (en) | Weighing device | |
JPH07256216A (en) | Weight selector | |
JP3251707B2 (en) | Combination weighing device | |
JPH11295136A (en) | Measuring method and measuring device |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
R250 | Receipt of annual fees |
Free format text: JAPANESE INTERMEDIATE CODE: R250 |
|
FPAY | Renewal fee payment (prs date is renewal date of database) |
Year of fee payment: 7 Free format text: PAYMENT UNTIL: 20100905 |
|
FPAY | Renewal fee payment (prs date is renewal date of database) |
Year of fee payment: 8 Free format text: PAYMENT UNTIL: 20110905 |
|
FPAY | Renewal fee payment (prs date is renewal date of database) |
Year of fee payment: 9 Free format text: PAYMENT UNTIL: 20120905 |
|
LAPS | Cancellation because of no payment of annual fees |