本論文は，医用検査で利用される分析装置を搬送路で結合したシステムの処理時間性能を解析して定量的な評価を行う．搬送路沿いに並んだ分析装置が搬送路上に並んだ検体を吸い取る方式（PLS: Pipe Line System）は，検査項目のばらつきが少ない検体を処理する方式として1990年代まで活躍した．その後，検査項目数が増え，その依頼にばらつきが出てくると，バッファおよび追い越し機能を付加した方式（STS: Side Track System）が考案され現在も稼働している．STSのポテンシャルは高く，その性能の可能性を追求することは今後の開発にとって意義深い．そこで以下3点につき解析，数値実験を通して明らかにした．1) STSでは搬送路の1検体あたりの搬送時間が(検体の分析処理時間)/(装置数+1)を超えると処理時間性能が大きく劣化する．2) 引き込みラインの入口出口それぞれにバッファを1個持つ装置4台構成において，ランダムな分析装置間経路を持つ全200検体を検査処理終了するまでの時間は，STSがPLSに対して平均30%圧縮する．3) STSのバッファを2個以上にしてもさらに30%圧縮するほどではない．性能解析では，ランダムな検体列において特定装置に立ち寄らない検体が連続して出現することに着目し，立ち寄らないことで発生する空きを圧縮するアーキテクチャとしてSTSを位置づけた．本研究によりSTSの可能性を定量的に確認し，搬送路およびバッファの設計基準を構築した．

This paper reports quantitative performance analysis for the processing time of clinical instrument system connected by a conveyor. PLS (Pipe Line System) is one of the architectures to implement the system where clinical instruments are aligned along the conveyor and each instrument pipettes samples on the conveyor. PLS was used to deal with almost uniformly requested tests for samples in the 1990s. After that, as a variety of tests is made wide and requested tests are deviated in sample by sample, STS (Side Track System) was devised and is now working. STS has a buffer function and passing function for samples to skip unrequested instrument. STS has its potential capacity in processing performance so that it is of great significance to pursue its possibility. This paper clarifies the following: 1) The performance significantly diminishes when the conveyance time per one specimen for a conveyor exceeds (the processing time of a specimen)/ ((number of the devices) + 1) in STS, 2) the processing time of STS is 30% shorter than the one of PLS in average where both systems process the same 200 samples which drop in four instruments randomly and those instruments have one buffer in each of entrance and exit of the side track, and 3) the increase of buffers does not have impact more than 30% performed by one buffer. Our performance analysis focuses the sequence of random specimen samples which skip a specific instrument, and placed STS as the architecture to compress the space caused by skipping. This study confirms possibility of STS quantitatively and in this way builds the design guideline for the conveyor and the buffer of STS.