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JP7675310B2 - Spectroscopic Probe - Google Patents
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JP7675310B2 - Spectroscopic Probe - Google Patents

Spectroscopic Probe Download PDF

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JP7675310B2
JP7675310B2 JP2021073816A JP2021073816A JP7675310B2 JP 7675310 B2 JP7675310 B2 JP 7675310B2 JP 2021073816 A JP2021073816 A JP 2021073816A JP 2021073816 A JP2021073816 A JP 2021073816A JP 7675310 B2 JP7675310 B2 JP 7675310B2
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JP2022168403A (en
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正裕 大嶋
悠太 引間
峻介 細江
正博 渡
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Kyoto University NUC
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Description

本発明は、分光分析計に用いられる分光プローブに関する。 The present invention relates to a spectroscopic probe for use in a spectroscopic analyzer.

例えば、二酸化炭素等の低分子ガスからなる発泡剤を樹脂中に溶解させて、成形行程中に低分子ガスの気泡を樹脂中に形成する発砲成形装置がある。特許文献1等に記載されている通り、発砲成形装置は、近赤外分光分析計を使って、樹脂中に溶解した低分子ガス濃度をオンラインで測定して、その測定結果に基づいて低分子ガスの供給を制御することができ、その結果、発砲成形体の品質を向上することができる。そして、近赤外分光分析計において、近赤外分光プローブが使用される。 For example, there is a foam molding device that dissolves a blowing agent made of a low molecular gas such as carbon dioxide in resin to form bubbles of the low molecular gas in the resin during the molding process. As described in Patent Document 1 and other publications, the foam molding device uses a near-infrared spectrometer to measure the concentration of the low molecular gas dissolved in the resin online and can control the supply of the low molecular gas based on the measurement results, thereby improving the quality of the foamed molded article. A near-infrared spectrometer probe is used in the near-infrared spectrometer.

近赤外分光分析計では、近赤外分光プローブから近赤外線(波長800nm~2500nm)を樹脂に照射して、入射光及び反射光から吸収されたスペクトルを計算して、樹脂中に溶け込んでいる低分子ガスの濃度が測定される。樹脂中に溶解する低分子ガスの濃度が所定の設定値になるようフィードバック制御することで、樹脂中に形成される気泡の直径及び個数等を制御して、高品質な発泡成形体を形成することができる。 In a near-infrared spectrometer, near-infrared light (wavelength 800 nm to 2500 nm) is irradiated onto the resin from a near-infrared spectrometer probe, and the spectrum absorbed from the incident and reflected light is calculated to measure the concentration of low-molecular-weight gas dissolved in the resin. By feedback-controlling the concentration of low-molecular-weight gas dissolved in the resin to a predetermined set value, the diameter and number of bubbles formed in the resin can be controlled, resulting in the formation of a high-quality foamed molded product.

近赤外分光分析計では、一対の近赤外分光プローブが、発泡成形装置の樹脂出口に取り付けられ、一方の近赤外分光プローブが近赤外線を照射して樹脂中を通過して、他方の近赤外分光プローブが樹脂中を通過した近赤外線を受光する。 In a near-infrared spectrometer, a pair of near-infrared spectroscopic probes are attached to the resin outlet of a foam molding device, one of the near-infrared spectroscopic probes emits near-infrared light that passes through the resin, and the other near-infrared spectroscopic probe receives the near-infrared light that has passed through the resin.

近赤外分光分析計に用いられる近赤外分光プローブは、近赤外線を伝達する導光部と、導光部を収納する円筒状ハウジング部と、近赤外線を透過する窓部と、を備える。導光部は、近赤外線等の光を伝達する素材(例えば、石英ガラス、プラスチック)で構成される。窓部は、高温及び高圧に耐える透過性素材(例えば、サファイヤ、石英、フッ化カルシウム)で構成されており、導光部の先端を保護するようにハウジング部に固定されて、導光部の先端及び窓部が樹脂中ないしその近傍に配置される。 The near-infrared spectroscopic probe used in the near-infrared spectroscopic analyzer comprises a light-guiding section that transmits near-infrared light, a cylindrical housing section that houses the light-guiding section, and a window section that transmits near-infrared light. The light-guiding section is made of a material that transmits light such as near-infrared light (e.g., quartz glass, plastic). The window section is made of a transparent material that can withstand high temperatures and high pressures (e.g., sapphire, quartz, calcium fluoride), and is fixed to the housing section so as to protect the tip of the light-guiding section, and the tip of the light-guiding section and the window section are disposed in or near the resin.

従来の近赤外分光プローブでは、窓部は、ハウジング部の先端に融着されるが、発泡成形装置の樹脂が所定の圧力(例えば30MPa)以上の高圧の場合、樹脂中ないしその近傍に配置された窓部が高圧によって破損することがあり、それにより、高温の樹脂がハウジング部の先端に漏れて導光部を破損するおそれがあった。その結果、近赤外分光プローブが動作不良や故障することがある。また、それらの保守作業や交換作業を頻繁に行う必要が生じてしまい、近赤外分光分析計の稼働率が低下してしまう。 In conventional near-infrared spectroscopic probes, the window is fused to the tip of the housing, but when the resin in the foam molding device is at a pressure equal to or greater than a certain pressure (e.g., 30 MPa), the window located in or near the resin can be damaged by the high pressure, which can cause high-temperature resin to leak to the tip of the housing and damage the light guide. As a result, the near-infrared spectroscopic probe can malfunction or break down. Furthermore, frequent maintenance and replacement work is required, reducing the operating rate of the near-infrared spectroscopic analyzer.

特開2001-150518号公報JP 2001-150518 A

そこで、本発明が解決しようとする課題は、高温及び高圧中でも窓部が破損しないよう構成された分光プローブを提供することである。 The problem that the present invention aims to solve is to provide a spectroscopic probe that is designed so that the window portion will not break even under high temperatures and pressures.

上記の課題を解決するために、本発明に係る分光プローブは、分光分析計に用いられる分光プローブであって、光を伝達する導光部と、導光部を収納する円筒状ハウジング部と、光を透過する窓部と、窓部を収納してハウジング部に固定する固定部と、を備える。ハウジング部に設けられた第1ねじ部と固定部に設けられた第2ねじ部とが締め付けられて、窓部がハウジング部と固定部との間に固定される。 In order to solve the above problems, the spectroscopic probe according to the present invention is a spectroscopic probe used in a spectroscopic analyzer, and includes a light guide section that transmits light, a cylindrical housing section that houses the light guide section, a window section that transmits light, and a fixing section that houses the window section and fixes it to the housing section. A first screw section provided in the housing section and a second screw section provided in the fixing section are tightened, and the window section is fixed between the housing section and the fixing section.

好ましくは、ハウジング部は、本体部及び突出部を備える。突出部は、本体部の直径よりも小さい直径を有し、外周に設けられた第1ねじ部を備える。固定部は、突出部及び窓部を収納して、内周に設けられた第2ねじ部を備える。 Preferably, the housing portion includes a main body portion and a protruding portion. The protruding portion has a diameter smaller than the diameter of the main body portion and includes a first threaded portion provided on the outer periphery. The fixing portion houses the protruding portion and the window portion and includes a second threaded portion provided on the inner periphery.

また、窓部は、ハウジング部の突出部に当接される基部と、基部の当接面よりも小さな先端面を有する先端部とからなる。ここで、先端部の先端面は、基部の当接面に平行な面とする。 The window portion also comprises a base portion that abuts against the protruding portion of the housing portion, and a tip portion having a tip surface that is smaller than the abutment surface of the base portion. Here, the tip surface of the tip portion is a surface that is parallel to the abutment surface of the base portion.

また、窓部は、ハウジング部の突出部に当接される円柱状の基部と、基部の直径よりも小さな直径を有し、基部の中心に設けられた円柱状の先端部とからなることが望ましい。 It is also preferable that the window portion comprises a cylindrical base portion that abuts against the protrusion of the housing portion, and a cylindrical tip portion that has a diameter smaller than the diameter of the base and is provided at the center of the base.

また、分光プローブは、弾性を有するOリングを備える。Oリングは、窓部の基部と先端部との接続角部に配置されることが望ましい。 The spectroscopic probe also includes an elastic O-ring. It is preferable that the O-ring be disposed at the connecting corner between the base and tip of the window.

また、窓部は、ハウジング部の突出部に当接される円柱状の基部と、基部から連続的に窄まるように形成された円錐台状の先端部とからなることが望ましい。 It is also preferable that the window portion comprises a cylindrical base portion that abuts against the protruding portion of the housing portion, and a truncated cone-shaped tip portion that tapers continuously from the base portion.

また、分光プローブは、弾性を有するOリングを備える。Oリングは、窓部の先端部に配置されることが望ましい。 The spectroscopic probe also includes an elastic O-ring. It is preferable that the O-ring is disposed at the tip of the window portion.

本発明に係る分光プローブは、高温及び高圧中でも窓部が破損しないよう構成されている。それにより、分光プローブが動作不良や故障することがない。その結果、それらの保守作業や交換作業を頻繁に行う必要がなく、分光分析計の稼働率が向上する。 The spectroscopic probe according to the present invention is configured so that the window portion will not break even at high temperatures and high pressures. This prevents the spectroscopic probe from malfunctioning or breaking down. As a result, there is no need to perform frequent maintenance or replacement work, improving the operating rate of the spectroscopic analyzer.

分光プローブを備えた発砲成形装置を示す概略図。FIG. 1 is a schematic diagram showing a foam molding apparatus equipped with a spectroscopic probe. 分光プローブを示す断面図。FIG. 第1実施形態の分光プローブの先端側を示す拡大断面図。FIG. 2 is an enlarged cross-sectional view showing the tip side of the spectroscopic probe according to the first embodiment. 第1実施形態の分光プローブの先端側を分解した状態を示す拡大断面図。FIG. 2 is an enlarged cross-sectional view showing a state in which the tip side of the spectroscopic probe according to the first embodiment is disassembled. 第2実施形態の分光プローブの先端側を示す拡大断面図。FIG. 11 is an enlarged cross-sectional view showing the tip side of a spectroscopic probe according to a second embodiment. 第2実施形態の分光プローブの先端側を分解した状態を示す拡大断面図。FIG. 11 is an enlarged cross-sectional view showing a state in which the tip side of the spectroscopic probe according to the second embodiment is disassembled.

以下、図面に基づいて、本発明に係る分光プローブの実施形態を説明する。本実施形態では、分光プローブは近赤外線を分光する近赤外線分光プローブからなる。 Below, an embodiment of the spectroscopic probe according to the present invention will be described with reference to the drawings. In this embodiment, the spectroscopic probe is a near-infrared spectroscopic probe that disperses near-infrared light.

<発泡成形装置>
図1に示す通り、本実施形態の発泡成形装置は、射出成型機100からなる。なお、発砲成形装置は、押出成形機等でもよい。射出成型機100は、射出シリンダー101と、射出シリンダー101の内部に設けられたスクリュー部102とを備える。スクリュー部102は、駆動機構(不図示)によって前後進及び回転するように構成される。射出成型機100は、射出シリンダー101に接続されたホッパー部104を備える。ホッパー部104は、成形樹脂材料(例えば、ポリプロピレン、ポリエチレン、ポリスチレン)のペレットPを射出シリンダー101に供給する。
<Foam molding equipment>
As shown in FIG. 1, the foam molding apparatus of this embodiment is composed of an injection molding machine 100. The foam molding apparatus may be an extrusion molding machine or the like. The injection molding machine 100 includes an injection cylinder 101 and a screw unit 102 provided inside the injection cylinder 101. The screw unit 102 is configured to move forward and backward and rotate by a drive mechanism (not shown). The injection molding machine 100 includes a hopper unit 104 connected to the injection cylinder 101. The hopper unit 104 supplies pellets P of a molding resin material (e.g., polypropylene, polyethylene, polystyrene) to the injection cylinder 101.

射出成型機100は、射出シリンダー101に接続されたガス注入部105を備える。ガス注入部105は、樹脂中に溶解する低分子ガス(例えば、二酸化炭素)を射出シリンダー101に供給する。射出シリンダー101は、加熱器(不図示)によって加熱されて、ホッパー部104から供給されたペレットPを溶融して溶融樹脂とする。そして、ガス注入部105から供給されるガスが、溶融樹脂に溶解される。 The injection molding machine 100 includes a gas injection section 105 connected to the injection cylinder 101. The gas injection section 105 supplies a low molecular weight gas (e.g., carbon dioxide) that dissolves in resin to the injection cylinder 101. The injection cylinder 101 is heated by a heater (not shown) to melt the pellets P supplied from the hopper section 104 into molten resin. Then, the gas supplied from the gas injection section 105 is dissolved in the molten resin.

射出成型機100は、射出シリンダー101の先端に設けられたノズル部103を備える。スクリュー部102の前進及び回転によって、射出シリンダー101内の溶融樹脂がノズル部103に搬送される。溶融樹脂は、ガスが溶解されており、高温及び高圧の状態でノズル部103に搬送される。 The injection molding machine 100 has a nozzle portion 103 provided at the tip of the injection cylinder 101. The forward movement and rotation of the screw portion 102 transports the molten resin in the injection cylinder 101 to the nozzle portion 103. The molten resin contains dissolved gas and is transported to the nozzle portion 103 under high temperature and pressure.

射出成型機100は、金型106を開閉して締め付ける型締め機構107を備える。型締め機構107によって、金型106が閉じて固定されて、射出工程の際に受ける圧力に耐えうる圧力で保持される。金型106は、所定形状の空隙が形成される。そして、射出シリンダー101のノズル部103が金型106に挿入される。スクリュー部102の前進及び回転によって、射出シリンダー101内の溶融樹脂が、ノズル部103を介して、金型106の空隙に注入される。金型106内の樹脂が冷却されて、金型106が開いて、成形された樹脂製品が金型106から取り出される。 The injection molding machine 100 is equipped with a clamping mechanism 107 that opens and closes the mold 106 to clamp it. The mold 106 is closed and fixed by the clamping mechanism 107, and is held at a pressure that can withstand the pressure received during the injection process. A gap of a predetermined shape is formed in the mold 106. Then, the nozzle portion 103 of the injection cylinder 101 is inserted into the mold 106. As the screw portion 102 advances and rotates, the molten resin in the injection cylinder 101 is injected into the gap of the mold 106 through the nozzle portion 103. The resin in the mold 106 is cooled, the mold 106 opens, and the molded resin product is removed from the mold 106.

射出成型機100は、近赤外分光分析計を使って、樹脂中に溶解した低分子ガスの濃度をオンラインで測定して、その測定結果に基づいて低分子ガスの供給を制御するよう構成されている。低分子ガスの供給を制御することで、発砲成形体の品質を向上することができる。近赤外分光分析を行うために、射出成型機100は、射出成型機100のノズル部103に取り付けられた一対の近赤外分光プローブ1,1を備える。 The injection molding machine 100 is configured to measure the concentration of low molecular gas dissolved in the resin online using a near-infrared spectroscopic analyzer, and to control the supply of low molecular gas based on the measurement results. By controlling the supply of low molecular gas, the quality of the foamed molded body can be improved. To perform near-infrared spectroscopic analysis, the injection molding machine 100 is equipped with a pair of near-infrared spectroscopic probes 1, 1 attached to the nozzle portion 103 of the injection molding machine 100.

一方の近赤外分光プローブ1が近赤外線(波長800nm~2500nm)を照射して樹脂中を通過して、他方の近赤外分光プローブ1が樹脂中を通過した近赤外線を受光する。そして、入射光及び反射光から吸収されたスペクトルを計算して、樹脂中に溶解された低分子ガスの濃度が測定される。樹脂中に溶解する低分子ガスの濃度が所定の設定値になるようフィードバック制御することで、樹脂中に形成される気泡の直径及び個数等を制御して、高品質な発泡成形体を形成することができる。 One of the near-infrared spectroscopic probes 1 irradiates near-infrared light (wavelength 800 nm to 2500 nm) which passes through the resin, and the other near-infrared spectroscopic probe 1 receives the near-infrared light that has passed through the resin. The absorbed spectrum is then calculated from the incident light and reflected light to measure the concentration of the low molecular weight gas dissolved in the resin. By feedback controlling the concentration of the low molecular weight gas dissolved in the resin to a predetermined set value, the diameter and number of bubbles formed in the resin can be controlled, resulting in the formation of a high-quality foamed molded product.

<近赤外分光プローブ>
図2に示す通り、近赤外分光プローブ1は、近赤外線を伝達する導光部10と、導光部10を収納する円筒状ハウジング部11と、近赤外線を透過する窓部12と、を備える。導光部10は、近赤外線等の光を伝達する素材(例えば、石英ガラス、プラスチック)で構成される。窓部12は、高温及び高圧に耐える透過性素材(例えば、サファイヤ、石英、フッ化カルシウム)で構成される。窓部12は、固定部13によって、導光部10の先端を保護するようにハウジング部11に固定される。ハウジング部11及び固定部13は、高温及び高圧に耐える金属等で構成される。ハウジング部11は、射出シリンダー101のノズル部103に固定される。そして、導光部10の先端及び窓部12が、溶融樹脂中に配置される。
<Near-infrared spectroscopic probe>
As shown in FIG. 2, the near-infrared spectroscopic probe 1 includes a light guide 10 that transmits near-infrared rays, a cylindrical housing 11 that houses the light guide 10, and a window 12 that transmits near-infrared rays. The light guide 10 is made of a material that transmits light such as near-infrared rays (e.g., quartz glass, plastic). The window 12 is made of a transparent material that can withstand high temperatures and high pressures (e.g., sapphire, quartz, calcium fluoride). The window 12 is fixed to the housing 11 by the fixing part 13 so as to protect the tip of the light guide 10. The housing 11 and the fixing part 13 are made of a metal that can withstand high temperatures and high pressures. The housing 11 is fixed to the nozzle 103 of the injection cylinder 101. Then, the tip of the light guide 10 and the window 12 are placed in the molten resin.

<第1実施形態>
図3及び図4に基づいて、第1実施形態の近赤外分光プローブ1の先端側について説明する。
First Embodiment
The tip side of the near-infrared spectroscopic probe 1 of the first embodiment will be described with reference to FIGS.

ハウジング部11は、導光部10を挿通する挿通部114を備える。さらに、ハウジング部11は、本体部110と突出部111とを備え、本体部110がノズル部103に取り付けられる。本体部110がノズル部103に取り付けられると、突出部111は、ノズル部103の内側に配置される。突出部111は、本体部110の直径よりも小さい直径を有する。それにより、本体部110と突出部111との境界に段差が形成されて、壁面113が設けられる。突出部111は、外周に設けられた第1ねじ部(雄ねじ部)150を備える。 The housing part 11 includes an insertion part 114 through which the light guide part 10 is inserted. The housing part 11 further includes a main body part 110 and a protruding part 111, and the main body part 110 is attached to the nozzle part 103. When the main body part 110 is attached to the nozzle part 103, the protruding part 111 is disposed inside the nozzle part 103. The protruding part 111 has a diameter smaller than that of the main body part 110. As a result, a step is formed at the boundary between the main body part 110 and the protruding part 111, and a wall surface 113 is provided. The protruding part 111 includes a first screw part (male screw part) 150 provided on the outer periphery.

窓部12は、基部120及び先端部121からなる。基部120は、ハウジング部11の突出部111に当接され、直径φ1の円柱形状で構成される。先端部121は、基部120の直径φ1よりも小さな直径φ2の円柱形状で構成され、基部120の中心に設けられる。基部120は円板状であって、先端部121は基部120より長く延設されている。窓部12は、中実な透過性素材で構成され、基部120及び先端部121が一体に成形される。そのため、基部120は、ハウジング部11の突出部111に当接する当接面120aを有し、当接面120aは直径φ1の円形となる。また、先端部121は、先端側に先端面121aを有し、先端面121aは直径φ2の円形となる。直径φ1及び直径φ2は、導光部10の径又はノズル部103の径に応じて決定すればよく、限定されるものではないが、近赤外分光プローブ1を小型化する観点では、直径φ1は、25.0mm以下、更に15.0mm、10.0mm以下、7.5mm以下とすることが好ましく、直径φ2は、10.0mm以下、更に5.0mm以下、4.0mm以下、2.5mm以下とすることが好ましい。一方、製造上の容易さ、及び、近赤外分光分析の精度の観点からは、直径φ1は、2.0mm以上とすることが好ましく、直径φ2は、0.5mm以上とすることが好ましい。 The window portion 12 is composed of a base portion 120 and a tip portion 121. The base portion 120 abuts against the protruding portion 111 of the housing portion 11 and is formed in a cylindrical shape with a diameter φ1. The tip portion 121 is formed in a cylindrical shape with a diameter φ2 smaller than the diameter φ1 of the base portion 120 and is provided at the center of the base portion 120. The base portion 120 is disk-shaped, and the tip portion 121 extends longer than the base portion 120. The window portion 12 is composed of a solid transparent material, and the base portion 120 and the tip portion 121 are molded integrally. Therefore, the base portion 120 has an abutment surface 120a that abuts against the protruding portion 111 of the housing portion 11, and the abutment surface 120a is a circle with a diameter φ1. The tip portion 121 has a tip surface 121a on the tip side, and the tip surface 121a is a circle with a diameter φ2. The diameters φ1 and φ2 may be determined according to the diameter of the light guide section 10 or the diameter of the nozzle section 103, and are not limited thereto. From the viewpoint of miniaturizing the near-infrared spectroscopic probe 1, the diameter φ1 is preferably 25.0 mm or less, more preferably 15.0 mm, 10.0 mm or less, or 7.5 mm or less, and the diameter φ2 is preferably 10.0 mm or less, more preferably 5.0 mm or less, 4.0 mm or less, or 2.5 mm or less. On the other hand, from the viewpoint of ease of manufacture and accuracy of near-infrared spectroscopic analysis, the diameter φ1 is preferably 2.0 mm or more, and the diameter φ2 is preferably 0.5 mm or more.

弾性を有するOリング14が、窓部12の基部120及び先端部121の接続角部12aに配置される。Oリング14は、高温及び高圧に耐える樹脂素材等で構成される。Oリングは、先端部121に嵌め込まれて密着するよう、先端部12の直径φ2よりも若干小さな内径で構成される。 An elastic O-ring 14 is placed at the connection corner 12a of the base 120 and tip 121 of the window 12. The O-ring 14 is made of a resin material that can withstand high temperatures and high pressures. The O-ring has an inner diameter that is slightly smaller than the diameter φ2 of the tip 12 so that it fits tightly into the tip 121.

固定部13は、突出部111及び窓部12の基部120を収納する第1収納部130を有する。第1収納部130は、内側に設けられた第2ねじ部(雌ねじ部)151を備える。第2ねじ部151は、突出部111の第1ねじ部150に締め付けられる。その際、第1収納部130は、基部120の周囲に密着するように構成される。 The fixing portion 13 has a first storage portion 130 that stores the protrusion 111 and the base portion 120 of the window portion 12. The first storage portion 130 has a second threaded portion (female threaded portion) 151 provided on the inside. The second threaded portion 151 is tightened to the first threaded portion 150 of the protrusion 111. At that time, the first storage portion 130 is configured to be in close contact with the periphery of the base portion 120.

固定部13は、窓部12の先端部121を収納する第2収納部131を有する。第2収納部131は、先端部121の周囲に密着するように構成され、先端部121の先端側が開口している。それにより、導光部10からの近赤外線が、基部120を通過して、先端部121から照射され、一方で、樹脂を通過した近赤外線が、先端部121から受光されて、基部120を通過して、導光部10に送られる。 The fixing section 13 has a second storage section 131 that stores the tip section 121 of the window section 12. The second storage section 131 is configured to fit closely around the tip section 121, and is open at the tip side of the tip section 121. As a result, near-infrared rays from the light-guiding section 10 pass through the base section 120 and are irradiated from the tip section 121, while near-infrared rays that have passed through the resin are received by the tip section 121, pass through the base section 120, and are sent to the light-guiding section 10.

固定部13は、第1収納部130と第2収納部131との境界に段差部13bが形成されるので、突出部111に設けられた第1ねじ部150と固定部13に設けられた第2ねじ部151とが締め付けられると、窓部12の基部120が、ハウジング部11の突出部111と固定部13の段差部13bとで挟まれて、導光部10を挿通する挿通部114を塞ぐように密着固定される。 The fixed portion 13 has a step portion 13b formed at the boundary between the first storage portion 130 and the second storage portion 131. When the first screw portion 150 provided on the protruding portion 111 and the second screw portion 151 provided on the fixed portion 13 are tightened, the base portion 120 of the window portion 12 is sandwiched between the protruding portion 111 of the housing portion 11 and the step portion 13b of the fixed portion 13, and is tightly fixed so as to block the insertion portion 114 through which the light guide portion 10 is inserted.

固定部13は、第1収納部130と第2収納部131との接続角部に切欠き部132を備え、Oリング14が切欠き部132に配置される。それにより、突出部111に設けられた第1ねじ部150と固定部13に設けられた第2ねじ部151とが締め付けられると、窓部12が突出部111と固定部13との間に固定されると共に、Oリング14が変形して、固定部13の切欠き部132、窓部12の基部120及び先端部121に密着される。その結果、固定部13の第2収納部131と窓部12の先端部121との間で樹脂が漏れても、Oリング14が樹脂の浸入を確実に防ぐことができる。
固定部13の最大径は、特に限定されるものではなく、上記φ1及びφ2、ノズル部103の径並びに固定部13に求められる機械的強度等を考慮して決定すればよい。射出成型機100として市販品を用いる観点からは、固定部13の最大径は、通常、7.0mm以上、20mm以下とできる。
The fixed portion 13 has a notch 132 at a connection corner between the first storage portion 130 and the second storage portion 131, and the O-ring 14 is disposed in the notch 132. Thereby, when the first screw portion 150 provided on the protruding portion 111 and the second screw portion 151 provided on the fixed portion 13 are fastened, the window portion 12 is fixed between the protruding portion 111 and the fixed portion 13, and the O-ring 14 is deformed and is brought into close contact with the notch 132 of the fixed portion 13, the base portion 120 and the tip portion 121 of the window portion 12. As a result, even if resin leaks between the second storage portion 131 of the fixed portion 13 and the tip portion 121 of the window portion 12, the O-ring 14 can reliably prevent the resin from entering.
The maximum diameter of the fixing part 13 is not particularly limited, and may be determined in consideration of the above φ1 and φ2, the diameter of the nozzle part 103, and the mechanical strength required of the fixing part 13. From the viewpoint of using a commercially available product as the injection molding machine 100, the maximum diameter of the fixing part 13 can usually be set to 7.0 mm or more and 20 mm or less.

<第2実施形態>
図5及び図6に基づいて、第2実施形態の近赤外分光プローブ1の先端側について説明する。
Second Embodiment
The tip side of the near-infrared spectroscopic probe 1 according to the second embodiment will be described with reference to FIGS.

ハウジング部11は、導光部10を挿通する挿通部114を備える。さらに、ハウジング部11は、本体部110と突出部111とを備え、本体部110がノズル部103に取り付けられる。本体部110がノズル部103に取り付けられると、突出部111は、ノズル部103の内側に配置される。突出部111は、本体部110の直径よりも小さい直径を有する。それにより、本体部110と突出部111との境界に段差が形成されて、壁面113が設けられる。突出部111は、外周に設けられた第1ねじ部(雄ねじ部)150を備える。 The housing part 11 includes an insertion part 114 through which the light guide part 10 is inserted. The housing part 11 further includes a main body part 110 and a protruding part 111, and the main body part 110 is attached to the nozzle part 103. When the main body part 110 is attached to the nozzle part 103, the protruding part 111 is disposed inside the nozzle part 103. The protruding part 111 has a diameter smaller than that of the main body part 110. As a result, a step is formed at the boundary between the main body part 110 and the protruding part 111, and a wall surface 113 is provided. The protruding part 111 includes a first screw part (male screw part) 150 provided on the outer periphery.

窓部12は、基部122及び先端部123からなる。基部122は、ハウジング部11の突出部111に当接され、直径φ3の円柱形状で構成される。先端部123は、基部122から連続的に窄まるように形成された円錐台状で構成される。そのため、先端部123は、基部122側の直径が基部122の直径φ3と同一であって、先端側の直径φ4が基部122の直径φ3よりも小さな直径で構成される。窓部12は、中実な透過性素材で構成され、基部122及び先端部123が一体に成形される。そのため、基部122は、ハウジング部11の突出部111に当接する当接面122aを有し、当接面122aは直径φ3の円形となる。また、先端部123は、先端側に先端面123aを有し、先端面123aは直径φ4の円形となる。直径φ3及び直径φ4は、導光部10の径又はノズル部103の径に応じて決定すればよく、限定されるものではないが、近赤外分光プローブ1を小型化する観点では、直径φ3は、15.0mm以下、更に9.0mm以下、7.0mm以下、4.6mm以下とすることが好ましく、直径φ4は、10.0mm以下、更に5.0mm以下、4.0mm以下、2.6mm以下とすることが好ましい。一方、製造上の容易さ、及び、近赤外分光分析の精度の観点からは、直径φ3は、1.5mm以上とすることが好ましく、直径φ4は、0.5mm以上とすることが好ましい。 The window portion 12 consists of a base portion 122 and a tip portion 123. The base portion 122 abuts against the protruding portion 111 of the housing portion 11 and is configured in a cylindrical shape with a diameter of φ3. The tip portion 123 is configured in a truncated cone shape formed so as to continuously narrow from the base portion 122. Therefore, the diameter of the tip portion 123 on the base portion 122 side is the same as the diameter φ3 of the base portion 122, and the diameter φ4 on the tip side is configured with a diameter smaller than the diameter φ3 of the base portion 122. The window portion 12 is made of a solid transparent material, and the base portion 122 and the tip portion 123 are molded integrally. Therefore, the base portion 122 has an abutment surface 122a that abuts against the protruding portion 111 of the housing portion 11, and the abutment surface 122a is a circle with a diameter of φ3. In addition, the tip portion 123 has a tip surface 123a on the tip side, and the tip surface 123a is a circle with a diameter of φ4. The diameters φ3 and φ4 may be determined according to the diameter of the light guide section 10 or the diameter of the nozzle section 103, and are not limited thereto. From the viewpoint of miniaturizing the near-infrared spectroscopic probe 1, the diameter φ3 is preferably 15.0 mm or less, more preferably 9.0 mm or less, 7.0 mm or less, or 4.6 mm or less, and the diameter φ4 is preferably 10.0 mm or less, more preferably 5.0 mm or less, 4.0 mm or less, or 2.6 mm or less. On the other hand, from the viewpoint of ease of manufacture and accuracy of near-infrared spectroscopic analysis, the diameter φ3 is preferably 1.5 mm or more, and the diameter φ4 is preferably 0.5 mm or more.

弾性を有するOリング14が、窓部12の先端部123に配置される。Oリング14は、高温及び高圧に耐える樹脂素材で構成される。Oリングは、先端部123に嵌め込まれて密着するよう、先端部123の先端側の直径φ4よりも若干大きな内径で構成される。 An elastic O-ring 14 is placed on the tip 123 of the window 12. The O-ring 14 is made of a resin material that can withstand high temperatures and high pressures. The O-ring has an inner diameter that is slightly larger than the diameter φ4 of the tip side of the tip 123 so that it fits tightly into the tip 123.

固定部13は、突出部111を収納する第3収納部133を有する。第3収納部133は、内側に設けられた第2ねじ部(雌ねじ部)151を備える。第2ねじ部151は、突出部111の第1ねじ部150に締め付けられる。その際、窓部12の基部120が、導光部10を挿通する挿通部114を塞ぐように当接される。 The fixing portion 13 has a third storage portion 133 that stores the protrusion 111. The third storage portion 133 has a second screw portion (female screw portion) 151 provided on the inside. The second screw portion 151 is tightened to the first screw portion 150 of the protrusion 111. At that time, the base 120 of the window portion 12 abuts so as to block the insertion portion 114 through which the light guide portion 10 is inserted.

固定部13は、窓部12の基部122及び先端部123を収納する第4収納部134を有する。第4収納部134は、基部122の周囲に密着するように構成されると共に、先端部123の先端側が開口するように開口部135が形成されている。それにより、導光部10からの近赤外線が、基部122を通過して、先端部123から照射され、一方で、樹脂を通過した近赤外線が、先端部123から受光されて、基部122を通過して、導光部10に送られる。 The fixing section 13 has a fourth storage section 134 that stores the base 122 and tip 123 of the window section 12. The fourth storage section 134 is configured to fit closely around the periphery of the base 122, and has an opening 135 formed so that the tip side of the tip 123 is open. As a result, near-infrared rays from the light-guiding section 10 pass through the base 122 and are irradiated from the tip 123, while near-infrared rays that have passed through the resin are received by the tip 123, pass through the base 122, and are sent to the light-guiding section 10.

固定部13は、第4収納部134に開口部135が形成されており、開口部135は、窓部12の先端部123と同一形状で開口している。そのため、突出部111の第1ねじ部150と固定部13の第2ねじ部151とが締め付けられると、窓部12の先端部123が、ハウジング部11の突出部111と固定部13の開口部135とで挟まれて、導光部10を挿通する挿通部114を塞ぐように密着固定される。
固定部13の最大径は、特に限定されるものではなく、上記φ3及びφ4、ノズル部103の径並びに固定部13に求められる機械的強度等を考慮して決定すればよい。射出成型機100として市販品を用いる観点からは、固定部13の最大径は、通常、7.0mm以上、20mm以下とできる。
The fixing part 13 has an opening 135 formed in the fourth storage part 134, and the opening 135 opens in the same shape as the tip part 123 of the window part 12. Therefore, when the first screw part 150 of the protruding part 111 and the second screw part 151 of the fixing part 13 are fastened, the tip part 123 of the window part 12 is sandwiched between the protruding part 111 of the housing part 11 and the opening part 135 of the fixing part 13, and is fixed in close contact so as to block the insertion part 114 through which the light guide part 10 is inserted.
The maximum diameter of the fixing part 13 is not particularly limited, and may be determined in consideration of the above φ3 and φ4, the diameter of the nozzle part 103, and the mechanical strength required of the fixing part 13. From the viewpoint of using a commercially available product as the injection molding machine 100, the maximum diameter of the fixing part 13 can usually be set to 7.0 mm or more and 20 mm or less.

窓部12が第4収納部134に収納されると、窓部12の先端部123と第4収納部134との間にスペース部13aが形成される(図5)。すなわち、窓部12の先端部123は、断面が傾斜したテーパ状に構成される一方、第4収納部134は、断面が直線状に構成されていることから、それらの間にスペース部13aが形成され、Oリング14がスペース部13aに配置される。それにより、突出部111の第1ねじ部150と固定部13の第2ねじ部151とが締め付けられると、窓部12が突出部111と固定部13との間に固定されると共に、Oリング14が変形して、固定部13の第4収納部134及び窓部12の先端部123に密着される。その結果、固定部13の第4収納部134と窓部12の先端部123との間で樹脂が漏れても、Oリング14が樹脂の浸入を確実に防ぐことができる。 When the window portion 12 is stored in the fourth storage portion 134, a space portion 13a is formed between the tip portion 123 of the window portion 12 and the fourth storage portion 134 (FIG. 5). That is, the tip portion 123 of the window portion 12 is configured to have a tapered cross section, while the fourth storage portion 134 is configured to have a linear cross section, so that a space portion 13a is formed between them, and the O-ring 14 is placed in the space portion 13a. As a result, when the first screw portion 150 of the protrusion 111 and the second screw portion 151 of the fixing portion 13 are tightened, the window portion 12 is fixed between the protrusion 111 and the fixing portion 13, and the O-ring 14 is deformed and is tightly attached to the fourth storage portion 134 of the fixing portion 13 and the tip portion 123 of the window portion 12. As a result, even if resin leaks between the fourth storage portion 134 of the fixing portion 13 and the tip portion 123 of the window portion 12, the O-ring 14 can reliably prevent the resin from entering.

以上、本発明の好ましい実施形態を説明したが、本発明の構成はこれらの実施形態に限定されない。
上記実施形態では、分光プローブは近赤外線を分光する近赤外線分光プローブ1からなるが、測定対象や目的等に応じて、中赤外線、遠赤外線、可視光等の最適な光を分光するよう構成されていてもよい。
上記実施形態では、第1ねじ部150は、ハウジング部11の突出部111の外周に設けられているが、突出部111が設けられておらず、ハウジング部11の本体部110の外周に設けられていてもよい。
Although the preferred embodiments of the present invention have been described above, the configuration of the present invention is not limited to these embodiments.
In the above embodiment, the spectroscopic probe is composed of the near-infrared spectroscopic probe 1 that disperses near-infrared light, but the spectroscopic probe may be configured to disperse light into optimal light such as mid-infrared light, far-infrared light, or visible light depending on the measurement target, purpose, etc.
In the above embodiment, the first screw portion 150 is provided on the outer periphery of the protrusion 111 of the housing portion 11, but the protrusion 111 may not be provided and the first screw portion 150 may be provided on the outer periphery of the main body portion 110 of the housing portion 11.

本発明の効果について説明する。 The effects of the present invention will be explained.

本発明に係る分光プローブは、分光分析計に用いられる分光プローブであって、光を伝達する導光部10と、導光部10を収納する円筒状ハウジング部11と、光を透過する窓部12と、窓部12を収納してハウジング部11に固定する固定部13と、を備える。ハウジング部11に設けられた第1ねじ部150と固定部13に設けられた第2ねじ部151とが締め付けられて、窓部12がハウジング部11と固定部13との間に固定される。 The spectroscopic probe according to the present invention is a spectroscopic probe used in a spectroscopic analyzer, and includes a light guide section 10 that transmits light, a cylindrical housing section 11 that houses the light guide section 10, a window section 12 that transmits light, and a fixing section 13 that houses the window section 12 and fixes it to the housing section 11. A first screw section 150 provided on the housing section 11 and a second screw section 151 provided on the fixing section 13 are tightened to fix the window section 12 between the housing section 11 and the fixing section 13.

本発明に係る分光プローブでは、ハウジング部11に設けられた第1ねじ部150と固定部13に設けられた第2ねじ部151とが締め付けられて、窓部12がハウジング部11と固定部13との間に固定される。このように、ねじ部150,151を強固に締め付けて、窓部12を機械的に固定することができるので、発泡成形装置の樹脂が所定の圧力(例えば30MPa)以上の高圧であっても、窓部12がハウジング部11から外れることがなく、さらに、窓部12をハウジング部11に密着することができるので、高温の樹脂がハウジング部11に漏れて導光部10を破損することもない。その結果、分光プローブが動作不良や故障することがなく、また、それらの保守作業や交換作業を頻繁に行う必要がなく、分光分析計の稼働率を向上できる。また、ねじ部150,151を緩めるだけで窓部12を取り外しできるので、窓部12を容易に交換することができ、保守作業や交換作業を容易に行うことができる。
さらに、本発明に係る分光プローブは、十分な耐圧強度を確保でき、しかも、接着部や融着部等、使用時に劣化し得る脆弱部を含まない。このため、本発明に係る分光プローブは、脆弱部の劣化により実用上の支障を生じやすい形態、例えば、窓部やプローブ全体を小型化した形態であっても、実用に耐えうる。本発明に係る分光プローブを小型化すれば、特に、射出成型機ノズル部に設けられた汎用接続部、例えば、圧力計又は温度計等の接続孔にそのまま適用することができる。もちろん、本発明に係る分光プローブは、特定の射出成型機ノズル部に設けられた接続孔に適合するよう、予め窓部及び固定部等の形状を決定してもよい。
なお、上記実施形態では、第1ねじ部150は、ハウジング部11の突出部111の外周に設けられているが、突出部111が設けられておらず、ハウジング部11の本体部110の外周に設けられていてもよい。
In the spectroscopic probe according to the present invention, the first screw portion 150 provided on the housing portion 11 and the second screw portion 151 provided on the fixing portion 13 are fastened to fix the window portion 12 between the housing portion 11 and the fixing portion 13. In this way, the screw portions 150 and 151 can be fastened firmly to mechanically fix the window portion 12, so that even if the resin of the foam molding device is at a high pressure of a predetermined pressure (e.g., 30 MPa) or more, the window portion 12 does not come off the housing portion 11, and further, since the window portion 12 can be tightly attached to the housing portion 11, high-temperature resin does not leak into the housing portion 11 and damage the light guide portion 10. As a result, the spectroscopic probe does not malfunction or break down, and there is no need to frequently perform maintenance work or replacement work therefor, so that the operating rate of the spectroscopic analyzer can be improved. In addition, since the window portion 12 can be removed simply by loosening the screw portions 150 and 151, the window portion 12 can be easily replaced, and maintenance work and replacement work can be easily performed.
Furthermore, the spectroscopic probe according to the present invention can ensure sufficient pressure resistance and does not include fragile parts such as adhesive parts or fused parts that may deteriorate during use. Therefore, the spectroscopic probe according to the present invention can withstand practical use even in a form in which deterioration of fragile parts is likely to cause practical problems, such as a form in which the window part or the entire probe is miniaturized. If the spectroscopic probe according to the present invention is miniaturized, it can be directly applied to general-purpose connection parts provided in the nozzle part of an injection molding machine, such as connection holes for pressure gauges or thermometers. Of course, the shapes of the window part, fixing part, etc. of the spectroscopic probe according to the present invention may be determined in advance so as to fit the connection hole provided in the nozzle part of a specific injection molding machine.
In the above embodiment, the first screw portion 150 is provided on the outer periphery of the protrusion 111 of the housing portion 11, but the protrusion 111 may not be provided and the first screw portion 150 may be provided on the outer periphery of the main body portion 110 of the housing portion 11.

好ましくは、ハウジング部11は、本体部110及び突出部111を備える。突出部111は、本体部110の直径よりも小さい直径を有し、外周に設けられた第1ねじ部150を備える。固定部13は、突出部111及び窓部12を収納して、内周に設けられた第2ねじ部151を備える。 Preferably, the housing portion 11 includes a main body portion 110 and a protruding portion 111. The protruding portion 111 has a diameter smaller than the diameter of the main body portion 110 and includes a first threaded portion 150 provided on the outer periphery. The fixing portion 13 houses the protruding portion 111 and the window portion 12 and includes a second threaded portion 151 provided on the inner periphery.

突出部111は、本体部110の直径よりも小さい直径を有していることから、本体部110と突出部111との境界に段差が形成されて、壁面113が設けられる。その結果、ねじ部150,151の締め付けによって、突出部111に固定部13が固定されると、固定部13が壁面113に対向して配置される。そして、高圧な樹脂によって、固定部13がハウジング部11の本体部110側にさらに押し込まれても、壁面113が固定部13の移動を制止でき、窓部12が破損することがない。さらに、分光プローブが動作不良や故障することがなく、また、それらの保守作業や交換作業を頻繁に行う必要がなく、分光分析計の稼働率を向上できる。 Since the protruding portion 111 has a diameter smaller than that of the main body portion 110, a step is formed at the boundary between the main body portion 110 and the protruding portion 111, and a wall surface 113 is provided. As a result, when the fixing portion 13 is fixed to the protruding portion 111 by tightening the screw portions 150 and 151, the fixing portion 13 is disposed facing the wall surface 113. Even if the fixing portion 13 is further pushed into the main body portion 110 side of the housing portion 11 by the high-pressure resin, the wall surface 113 can stop the fixing portion 13 from moving, and the window portion 12 is not damaged. Furthermore, the spectroscopic probe does not malfunction or break down, and there is no need to frequently perform maintenance or replacement work on the spectroscopic probe, improving the operating rate of the spectroscopic analyzer.

また、窓部12は、ハウジング部11の突出部111に当接される基部120,122と、基部120,121の当接面120a,122aよりも小さな先端面121a,123aを有する先端部121,123とからなる。 The window portion 12 also consists of base portions 120, 122 that abut against the protruding portion 111 of the housing portion 11, and tip portions 121, 123 that have tip surfaces 121a, 123a that are smaller than the abutment surfaces 120a, 122a of the base portions 120, 121.

ここで、先端部121,123の先端面121a,123aは、基部120,122の当接面120a,122aに平行な面である。窓部12において、先端部121,123の先端面121a,123aが、ハウジング部11の突出部111に対する基部120,122の当接面120a,122aより小さいことによって、圧力が分散されやすく耐圧性に優れるという効果がある。そのため、保守作業や交換作業の回数を少なくすることができ、分光分析計の稼働率を向上できる。 Here, the tip surfaces 121a, 123a of the tip portions 121, 123 are parallel to the abutment surfaces 120a, 122a of the base portions 120, 122. In the window portion 12, the tip surfaces 121a, 123a of the tip portions 121, 123 are smaller than the abutment surfaces 120a, 122a of the base portions 120, 122 against the protrusion 111 of the housing portion 11, which has the effect of making it easier to disperse pressure and providing excellent pressure resistance. This reduces the number of maintenance and replacement operations, improving the operating rate of the spectrometer.

第1実施形態では、窓部12は、ハウジング部11の突出部111に当接される円柱状の基部120と、基部120の直径φ1よりも小さな直径φ2を有し、基部120の中心に設けられた円柱状の先端部121とからなることが望ましい。 In the first embodiment, the window portion 12 desirably comprises a cylindrical base portion 120 that abuts against the protrusion portion 111 of the housing portion 11, and a cylindrical tip portion 121 that has a diameter φ2 smaller than the diameter φ1 of the base portion 120 and is provided at the center of the base portion 120.

基部120及び先端部121が円柱状に構成されていることから、圧力が分散されやすく耐圧性に優れると共に、成形加工が行いやすく加工性に優れるという効果を奏する。そのため、保守作業や交換作業の回数を少なくすることができ、分光分析計の稼働率を向上できる。また、生産性に優れ、安価に製作することができ、製作及び保守の費用を低減することができる。また、この形状によって、基部120が、ハウジング部11の突出部111と固定部13に挟み込まれて、窓部12を確実に固定することができる。 The base 120 and tip 121 are cylindrically configured, which provides the advantages of easy pressure dispersion, excellent pressure resistance, and easy molding and processing. This reduces the number of maintenance and replacement operations, improving the operating rate of the spectrometer. It also provides excellent productivity and can be manufactured at low cost, reducing manufacturing and maintenance costs. This shape allows the base 120 to be sandwiched between the protruding portion 111 and the fixing portion 13 of the housing portion 11, ensuring that the window portion 12 is securely fixed.

また、分光プローブは、弾性を有するOリング14を備える。Oリング14は、窓部12の基部120と先端部121との接続角部12aに配置されることが望ましい。 The spectroscopic probe also includes an elastic O-ring 14. It is desirable for the O-ring 14 to be disposed at the connection corner 12a between the base 120 and the tip 121 of the window portion 12.

突出部111に設けられた第1ねじ部150と固定部13に設けられた第2ねじ部151とが締め付けられて、窓部12が突出部111と固定部13との間に固定され、Oリング14が変形して、固定部13、窓部12の基部120及び先端部121に密着される。その結果、固定部13と窓部12の先端部121との間で樹脂が漏れても、Oリング14が樹脂の浸入を確実に防ぐことができる。 The first screw portion 150 provided on the protruding portion 111 and the second screw portion 151 provided on the fixed portion 13 are tightened, the window portion 12 is fixed between the protruding portion 111 and the fixed portion 13, and the O-ring 14 is deformed and adheres closely to the fixed portion 13, the base portion 120 of the window portion 12, and the tip portion 121. As a result, even if resin leaks between the fixed portion 13 and the tip portion 121 of the window portion 12, the O-ring 14 can reliably prevent the resin from entering.

第2実施形態では、窓部12は、ハウジング部11の突出部111に当接される円柱状の基部122と、基部122から連続的に窄まるように形成された円錐台状の先端部123とからなることが望ましい。 In the second embodiment, it is preferable that the window portion 12 comprises a cylindrical base portion 122 that abuts against the protrusion portion 111 of the housing portion 11, and a truncated cone-shaped tip portion 123 that is formed so as to taper continuously from the base portion 122.

基部122が円柱状に構成され、先端部123が円錐台状に構成されており、この形状によって、窓部12におけるフレネル損による光の多重反射を少なくでき、その結果、光の迷光を少なくすることができるので、正確に分光分析計を行うことができる。さらに、圧力が分散されやすく耐圧性に優れる。そのため、保守作業や交換作業の回数を少なくすることができ、分光分析計の稼働率を向上できる。 The base 122 is cylindrical and the tip 123 is truncated cone. This shape reduces multiple reflections of light due to Fresnel loss in the window 12, and as a result, reduces stray light, allowing for accurate spectroscopic analysis. Furthermore, pressure is easily dispersed and the pressure resistance is excellent. This reduces the number of maintenance and replacement operations, improving the operating rate of the spectroscopic analyzer.

また、分光プローブは、弾性を有するOリング14を備える。Oリング14は、窓部12の先端部123に配置されることが望ましい。 The spectroscopic probe also includes an elastic O-ring 14. It is preferable that the O-ring 14 is disposed at the tip 123 of the window portion 12.

窓部12の先端部123は傾斜したテーパ状に構成されることから、固定部13との間にスペース部13aを形成することができる。そのため、Oリング14をスペース部13aに配置することができる。そして、突出部111に設けられた第1ねじ部150と固定部13に設けられた第2ねじ部151とが締め付けられて、窓部12が突出部111と固定部13との間に固定され、Oリング14が変形して、固定部13及び窓部12の先端部123に密着される。その結果、固定部13と窓部12の先端部123との間で樹脂が漏れても、Oリング14が樹脂の浸入を確実に防ぐことができる。 The tip 123 of the window portion 12 is configured in an inclined tapered shape, so that a space portion 13a can be formed between the fixed portion 13. Therefore, the O-ring 14 can be placed in the space portion 13a. Then, the first screw portion 150 provided on the protruding portion 111 and the second screw portion 151 provided on the fixed portion 13 are tightened, and the window portion 12 is fixed between the protruding portion 111 and the fixed portion 13, and the O-ring 14 is deformed and is tightly attached to the fixed portion 13 and the tip portion 123 of the window portion 12. As a result, even if resin leaks between the fixed portion 13 and the tip portion 123 of the window portion 12, the O-ring 14 can reliably prevent the resin from entering.

1 分光プローブ
10 導光部
11 ハウジング部
110 本体部
111 突出部
12 窓部
120,122 基部
120a,122a 当接面
121,123 先端部
121a,123a 先端面
13 固定部
150 第1ねじ部
151 第2ねじ部
14 Oリング
REFERENCE SIGNS LIST 1 Spectroscopic probe 10 Light guide section 11 Housing section 110 Main body section 111 Protrusion section 12 Window section 120, 122 Base section 120a, 122a Abutment surface 121, 123 Tip section 121a, 123a Tip surface 13 Fixing section 150 First screw section 151 Second screw section 14 O-ring

Claims (2)

分光分析計に用いられる分光プローブであって、
光を伝達する導光部と、
前記導光部を収納する円筒状ハウジング部と、
前記光を透過する窓部と、
前記窓部を収納して前記ハウジング部に固定する固定部と、
弾性を有するОリングと、を備え、
前記窓部は、円柱状の基部と、前記基部から連続的に窄まるように形成された円錐台状の先端部と、を備え、
前記固定部は、前記先端部の先端側と同一形状で開口し、
前記固定部は、前記窓部が当該固定部に収納されているときにスペースを前記先端部の外周面との間に確保する内周面を有し、
前記Оリングは、前記スペースに配置されるものであり、
前記ハウジング部に設けられた第1ねじ部と前記固定部に設けられた第2ねじ部とが締め付けられて、前記窓部が前記ハウジング部と前記固定部とで挟まれ固定されると共に、前記Оリングが前記スペースにて前記固定部の前記内周面と前記先端部の前記外周面とに密着される、分光プローブ。
A spectroscopic probe for use in a spectroscopic analyzer, comprising:
A light guide portion that transmits light;
A cylindrical housing portion that houses the light guide portion;
A window portion that transmits the light;
a fixing portion that receives the window portion and fixes it to the housing portion;
and an elastic O-ring .
The window portion includes a cylindrical base portion and a truncated cone-shaped tip portion formed so as to continuously narrow from the base portion,
The fixing portion has an opening having the same shape as the tip side of the tip portion,
the fixed portion has an inner circumferential surface that ensures a space between the inner circumferential surface of the tip portion and the window portion when the window portion is housed in the fixed portion,
The O-ring is disposed in the space,
A spectroscopic probe in which a first screw portion provided on the housing portion and a second screw portion provided on the fixed portion are tightened to sandwich and fix the window portion between the housing portion and the fixed portion, and the O-ring is tightly attached to the inner surface of the fixed portion and the outer surface of the tip portion in the space .
前記ハウジング部は、本体部と、前記窓部が固定されたときに前記基部が当接する突出部と、を備え、
前記突出部は、前記本体部の直径よりも小さい直径を有し、
前記第1ねじ部は、前記突出部の外周に設けられ、
前記固定部は、前記突出部を収納するように構成され、
前記第2ねじ部は、前記固定部の内周に設けられている、
請求項1に記載の分光プローブ。
the housing portion includes a main body portion and a protrusion portion against which the base portion abuts when the window portion is fixed ,
the protrusion has a diameter smaller than a diameter of the body portion;
The first screw portion is provided on an outer periphery of the protruding portion,
The fixing portion is configured to receive the protrusion,
The second screw portion is provided on an inner periphery of the fixed portion.
The spectroscopic probe according to claim 1 .
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Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2002310907A (en) 2001-04-16 2002-10-23 Yokogawa Electric Corp Analysis equipment
JP2002540421A (en) 1999-03-26 2002-11-26 バイエル アクチェンゲゼルシャフト Pressure-resistant viewing window
JP2004028982A (en) 2002-01-17 2004-01-29 Bayer Ag Process window unit and optical process window system for spectroscopic research

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2002540421A (en) 1999-03-26 2002-11-26 バイエル アクチェンゲゼルシャフト Pressure-resistant viewing window
JP2002310907A (en) 2001-04-16 2002-10-23 Yokogawa Electric Corp Analysis equipment
JP2004028982A (en) 2002-01-17 2004-01-29 Bayer Ag Process window unit and optical process window system for spectroscopic research

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