JP3756571B2 - Positive / negative pressure adapter for respiratory protection device - Google Patents

Description

【００２５】
上表が示すように、マフラーは、１２．５Hz〜２０KHz の周波数領域に亙って積分音圧レベルを典型的に２０dB低減させる。これは、マフラー部材を持たないアダプタで得られた結果の４分の１の騒音レベルに相当する。さらに多孔部材５４は、空気流の強さを分散させるディフューザとして作用し、フェースマスク２６に進入する空気の最大速度を減少させる一方で、使用者の要求を上回る供給空気を間断無く流通させる。
【００２６】
図４は、正圧／負圧アダプタ２２又は２４の断面側面図であり、フィルタカートリッジ３２又は３４をフェースマスク２６の１つの吸入口６２に流体の流通が可能なように連結する状態を示す。フィルタカートリッジ３２（３４）は、アダプタ２２（２４）の吸入口６８に設けた差込コネクタ６０に取付けられる。フェースマスク２６の吸入口６２に隣接して、対応の差込コネクタ６０′が設けられる。好適な実施形態では、差込コネクタ６０、６０′は同一構造であり、フィルタカートリッジ３２（３４）をフェースマスク２６に直接取付け可能となっている。しかし適用によっては、一方の差込コネクタ６０、６０′の構造を変更して、それに取付けられる部材の構造を限定することが望ましい場合もある。アダプタ２２（２４）とフィルタカートリッジ３２（３４）及びフェースマスク２６との間には、それぞれシール６４を介在させることが好ましい。これらシールは、様々な弾性材料から構成できるが、独立気泡ウレタンゴム又はシリコーンがこの用途では好適である。
【００２７】
図示実施形態では差込コネクタ６０、６０′を開示したが、本発明は、様々な構成要素２２、２４、２６、３２、３４を流体の流通が可能なように連結するために使用されるこのようなコネクタの形式を限定するものではない。所望によりガスケットを用いてシールされた状態で対応の一体形シリンダに螺着されるねじ付部材を恒久的又は着脱可能に受容する形式のコネクタも、本発明の範囲内で採用可能である。また、幾つかの構成要素を１つのユニットとして形成することもできる。例えば、フィルタカートリッジ３２（３４）とアダプタ２２（２４）とをユニット化できる。或いは、フェースマスク２６の吸入口６２とアダプタ２２（２４）とを１つのユニットとして形成できる。
【００２８】
図４に示すように、空気が多孔部材５４を通過して出入口領域５２に進入すると、正圧弁６６は、空気が吸入口６８を通ってフィルタカートリッジ３２（３４）に進入するのを制止する。正圧弁６６は、吸入口６８にて形成された開口内に実質的に延びる支持部７０に取付けられる。空気の圧力は、正圧弁６６をアダプタハウジング２３に設けた弁座７２に押し付け、弁のシール力を増強する。正圧空気源３８が使用者の要求を満たす空気流を供給しない場合は、使用者の吸入作用が、フェースマスク室８４内に正味負圧を生じさせる。正味負圧は弁６６を弁座７２から引き離し、カートリッジ３２（３４）を通して空気を吸引することを可能にする。図示実施形態では、正圧弁６６は、シリコーンゴム等の高可撓性材料から形成されるダイヤフラム弁である。この用途で様々な構造の逆止弁を好適に使用でき、本発明はこのような逆止弁を特定の形式に限定するものではない。
【００２９】
吸入弁８０は、吸入口６２に隣接した開口８２を横断するように配置され、出入口領域５２内の空気が、フェースマスク２６と使用者の顔（図示せず）との間に画成されるフェースマスク室８４に進入することを可能にする。吸入弁８０もまた、シリコーンゴム等の高可撓性材料から形成できる。図示構成の代わりに、吸入弁８０をアダプタハウジング２３に設置してもよい。使用者の呼気の間に生じるフェースマスク室８４内の正味正圧は、吸入弁８０を弁座８６に対して押し付ける。フェースマスク室８４内の過剰な圧力は、排気口２８（図１参照）から放出される。
【００３０】
正圧空気源３８は、例えばコンプレッサの作動不良、空気導管３６の偶発的なもつれや切断、機動性の向上を目的とした使用者による意図的な空気導管３６の分離等の、様々な理由で縮小されたり終結されることがある。図５の矢印は、正圧空気源３８が使用者の要求により縮小され、又は終結されたときの、呼吸用保護装置２０を通る空気の流れを示す。出入口領域５２に正圧が生じないので、正圧弁６６は弁座７２から持ち上げられて、空気がフィルタカートリッジ３２（３４）を通って流れることを可能にする。図５に示す状態では、呼吸用保護装置２０は負圧装置として作用し、使用者の肺活量に依存して、空気をフィルタカートリッジ３２（３４）の開口９０を通し、濾過媒体９２を通過させて、フェースマスク室８４内に吸い込む。図４に関連して説明したように、使用者の呼気時に吸入弁８０が弁座８６に押し付けられ、フェースマスク室８４内の過剰な圧力は、排気口２８（図１参照）から放出される。
【００３１】
使用者が空気導管３６を正圧空気源３８から分離した場合、呼吸用保護装置２０が負圧モードで作動しているときは、空気導管３６内の逆止弁４０が、汚染空気が空気導管に吸い込まれるのを防ぐ。図１に示す実施形態では、逆止弁４０は、使用者が正圧空気源３８から呼吸用保護装置２０を分離することを可能にする急速解除機構４２に隣接して配置される。
【００３２】
図６（ａ）、（ｂ）は、正圧／負圧アダプタ２２、２４の製造方法の一例を示す。アダプタの主要構成要素は、ベース１００、カバー１０２、多孔部材５４、及びガスケット５５である。ベース１００は、フェースマスク２６の差込コネクタ６０′に係合する雌差込コネクタ６０Ｆを備える。さらにベース１００は、空気導管３６を保持するための嵌め輪又は他の許容できる固定手段を有した引っかけ付コネクタ１０４を備える。空気導管３６を引っかけ付コネクタ１０４に保持するために、引張板ばね及び保持クリップを追加することもできる。ベース１００及びカバー１０２は、ポリエチレン、ポリプロピレン、ポリスチレン等の様々な高分子材料から形成できる。この用途では、ミネソタ州ミネアポリスのHimontから入手可能なポリプロピレン6323が好適である。
【００３３】
空気導管３６は一般に、引っかけ付コネクタ１０４の外径に相当する６mmの内径を有するが、内径３mmの空気導管も好適に使用される。小形の動力付空気浄化式呼吸器を使用するアプリケーションに関しては、一般に２５mmの孔径を有した空気導管が要求される。引っかけ付コネクタ１０４の外径は、いかなる寸法の空気導管をも受容するように製造できる。この用途では、テキサス州ヒューストンのシェルケミカル社から入手可能なShell Kraton G2701及びG2705 の50/50 混合物から形成される管を使用できる。
【００３４】
図６（ｂ）は、空気導管３６をコネクタ１０４に取付ける方法、及びベース１００とカバー１０２との間に気密シールを形成する方法の一例を示す。空気導管３６に取付けられたアダプタハウジング２３は、型内に配置されて高分子材料１０６を被覆成形される。この用途では様々な高分子材料１０６を使用できるが、特定の高分子材料の適合性により、理想の機械的強度及び気密シールを形成する化学接着を生じることが分かっている。例えば、バーモント州セントアルバンスのクオリティサービステクノロジーから入手可能な商標名Monprene 2850Mで販売されている高分子材料、前述のKraton、又はポリプロピレンは、ポリプロピレンからなるベース１００及びカバー１０２、並びにKraton又はMonpreneからなる空気導管３６に特に適合する。
【００３５】
図７（ａ）、（ｂ）は、一対のアダプタ２２、２４を連結するためのＹコネクタ３７を形成する被覆成形技術の使用を示す。Ｙ取付具１１０は、空気導管３６の３つの部分に取付けられる。次いでＹ取付具１１０と空気導管３６とは、上記材料を用いて、図７（ｂ）に示すように被覆成形される。
図８及び図９は、呼吸用保護装置２０の変形例を示す。この変形例では、空気導管３６がフェースマスク２６の後方に延長される。図９に示すように、空気導管３６は使用者の背後に向けて延長され、使用者の活動を妨げないようになっている。
【００３６】
図１０は、呼吸用保護装置２０の他の変形例を示す。この変形例では、フィルタカートリッジ３２、３４が取外され、代わりに弁蓋１１２、１１４が取付けられている。図１０に示す構成では、呼吸用保護装置２０は、図１に実質的に対応する正圧式呼吸用保護装置としてのみ作動する。
図１１は、変形例としてフルフェースマスク式の呼吸用保護装置２０′を示す。この装置は、正圧空気源３８に接続された一対の正圧／負圧アダプタ２２′、２４′を備える。フルフェースマスク式の呼吸用保護装置２０′は、一般に使用者の口、鼻及び両目を覆う。
【００３７】
上記した種々の実施形態は、本発明の範囲を限定するものではなく、本発明の他の様々な修正は上記説明から当業者に自明であろう。上記説明は、発明を明示するための特定の実施形態を例示するものであって、本発明は、上記実施形態、及びそれに含まれる特定の要素、寸法、材料、形状に限定されるものではない。本発明の様々な修正及び変形は、特許請求の範囲の記載に包含される。
【図面の簡単な説明】
【図１】正圧空気源に接続された正圧／負圧アダプタを備える呼吸用保護装置の概略図である。
【図２】図１の呼吸用保護装置の側面図である。
【図３】正圧／負圧アダプタの切り欠き斜視図である。
【図４】正圧空気源に接続された正圧／負圧アダプタを備える呼吸用保護装置の断面側面図である。
【図５】正圧空気源が縮小又は終結された状態の、図４の呼吸用保護装置の図である。
【図６】（ａ）被覆成形前の正圧／負圧アダプタの断面側面図、及び（ｂ）被覆成形後の正圧／負圧アダプタの断面側面図、である。
【図７】（ａ）被覆成形前の正圧／負圧アダプタ用のＹ取付具の斜視図、及び（ｂ）被覆成形後の正圧／負圧アダプタ用のＹ取付具の斜視図、である。
【図８】図１の呼吸用保護装置の変形形態を示す図である。
【図９】図８の呼吸用保護装置の側面図である。
【図１０】フィルタカートリッジを取り外した図１の呼吸用保護装置の変形形態を示す図である。
【図１１】正圧空気源に接続された正圧／負圧アダプタを備えるフルフェースマスク式の呼吸用保護装置の変形形態を示す図である。
【符号の説明】
２０…呼吸用保護装置
２２、２４…正圧／負圧アダプタ
２６…フェースマスク
３２、３４…フィルタカートリッジ
３６…空気導管
３８…正圧空気源
４０…逆止弁
５４…多孔部材
６６…正圧弁
８０…吸入弁[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a respiratory protection device of a positive pressure type and a negative pressure type, and more particularly to a positive pressure / negative pressure adapter used in the respiratory protection device.
[0002]
[Prior art and problems to be solved by the invention]
Respirators are used in a variety of hazardous environments such as painting booths, grain storage facilities, laboratories, and production facilities where contaminants are present. In general, breathing masks will accept a variety of filter cartridges or air supply connectors to provide a breathable air source to the wearer so that the same structured face mask can be used in a variety of different hazardous environments. ing.
[0003]
Respiratory protection devices are roughly classified into two types: positive pressure type respiratory protective devices and negative pressure type respiratory protective devices. Generally, a positive pressure respirator includes a positive pressure air source such as an external pump or a pressurized tank for pumping clean air into the face mask. A positive pressure air source overpours the face mask with clean and breathable air. The net positive pressure generated in the face mask by the positive pressure air source prevents ambient air from being drawn around the face seal of the mask.
[0004]
An example of a positive pressure air source used in a positive pressure respiratory protection device is a powered air purifying respirator (PAPR). In general, a powered air purifying respirator includes a respiratory tube that extends from a face mask to a battery-powered blower worn by a user. This blower generally contains a filter for removing contaminants from the ambient air. A powered air purifier has the advantage that the user can move freely without being constrained by the air conduit. However, powered air purifiers tend to be more expensive than steady flow respirators. The powered air purifying respirator can be used only for a limited time because it is battery operated. Moreover, in general, a powered air purifying respirator requires a large-diameter (about 25 mm) respiratory tube because the battery-powered blower cannot generate sufficient pressure on the small-diameter respiratory tube. Such a large-diameter respiratory tract is difficult for the user to handle.
[0005]
Alternatively, the positive pressure air source can be a compressor or pressure tank connected to the user by an air conduit. Generally, such systems include a filter in the compressor to provide breathable air to the user. However, depending on the application, the air conduit may limit the user's ability to perform certain movements. In addition, the air conduit may become tangled or the supply of pressurized air may stop unexpectedly, exposing the user to contaminants.
[0006]
Respirators that are broadly classified into other types are called negative pressure respirators because air is drawn through the filter cartridge into the face mask by the user's inhalation. Filter cartridges include various filtration elements such as blown microfibers and carbon systems for protection against gases and vapors. The negative pressure respirator has the advantage that the wearer does not have to drag the air conduit and does not have to wear an expensive powered air purifier. The disadvantage of negative pressure respirators is that the user must use pulmonary force to inhale air through the filtration medium, and the negative pressure in the resulting face mask can cause contaminants around the face seal. There is a possibility of being drawn. Also, if the respiratory force of the lungs is used to suck air through the filtration media, the face mask temperature will increase and the wearer will tend to feel uncomfortable. Therefore, in general, the negative pressure type respiratory protection device has a lower protection capability than the positive pressure type respiratory protection device.
[0007]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the invention described in claim 1 is a pneumatic adapter for connecting a positive-pressure air source to a portable respiratory protection device worn by a user so that fluid can flow. An adapter housing that can be directly connected to the protective device, and an inlet portion that can be connected to a positive pressure air source and an inlet / outlet region that can be connected to the respiratory protective device so as to be able to flow through the fluid can mutually flow inside the adapter housing. An adapter housing that is connected, and a porous member that is interposed between the inlet portion and the inlet / outlet region, the porous member reducing air conduit noise and allowing air to flow from the inlet portion to the inlet / outlet region; A pneumatic adapter is provided.
The invention according to claim 2, fluid positive pressure air source to the respiratory protection device having a filter cartridge Te pressure / vacuum adapter smell for connecting the fluidly, the filter cartridge respirator and doorway area for fluidly connecting an inlet portion for connecting the positive pressure air source entrance area, the flow of air from the entrance region to the filter cartridge in response to a positive pressure from the positive pressure air source A positive / negative pressure adapter is provided that includes an adapter housing having a first check valve for restriction.
The invention according to claim 3 is a portable respiratory protection device that is worn by a user and used with a positive pressure air source, the face mask having an exhaust port and at least one suction port, An adapter housing that can be connected to at least one suction port so as to allow fluid flow, and an inlet portion that can be connected to a positive pressure air source and an inlet / outlet region that can be connected to the face mask so as to allow fluid flow can be connected to each other inside the adapter housing. A porous member interposed between the adapter housing and the inlet portion and the inlet / outlet region, which is connected to be able to flow, and reduces the air conduit noise and allows the air to flow from the inlet portion to the inlet / outlet region. A respiratory protection device comprising a member.
[0008]
A second check valve may be provided to restrict the flow of air from the respiratory protection device to the entrance / exit area.
The present invention also provides the positive pressure / negative pressure adapter, wherein the first check valve is installed at the inlet for fluidly connecting the inlet / outlet region to the filter cartridge. To do.
[0009]
The second check valve can be installed in a suction port provided in the positive / negative pressure adapter or the respiratory protection device.
The present invention also provides the positive pressure / negative pressure adapter, wherein the adapter housing further comprises a porous member interposed between the inlet portion and the inlet / outlet region.
[0010]
The present invention also provides the positive / negative pressure adapter described above, wherein the porous member is selected from the group comprising sintered metal, porous polypropylene, porous polyethylene, porous acetal, porous ceramic and porous glass bead structure. Provides a pressure adapter.
The porous member can have the function of a muffler, a diffuser, or both.
[0011]
The present invention also provides a positive / negative pressure adapter in which the adapter housing and the respiratory protection device are formed as a single unit.
The adapter housing and the filter cartridge can be formed as one unit.
[0012]
The present invention also provides a positive / negative pressure adapter as described above, further comprising an air conduit connecting the inlet to a positive pressure air source.
The present invention also provides a positive pressure / negative pressure adapter as described above, comprising a face mask, an exhaust port and at least one suction port, and an inlet / outlet region is connected to at least one suction port of the respiratory protection device so as to allow fluid to flow therethrough. A positive / negative pressure adapter is provided.
[0013]
The positive pressure air source can have a small powered air purifier or a steady air flow supplied from a compressor or pressurized tank. The air conduit may include a quick release mechanism that allows the wearer to be removed from the air conduit. When separated from a positive pressure air source, the respiratory protection device acts as a negative pressure respiratory protection device. The check valve is preferably disposed between the quick release mechanism and the face mask so that ambient air is drawn into the respiratory protection device.
[0014]
The present invention further relates to a positive / negative pressure type respiratory protective device connectable to a positive pressure air source, comprising a face mask having an exhaust port and at least one suction port, and a filter cartridge as at least one suction port. A positive / negative pressure adapter having an inlet / outlet region coupled to fluid flow and an inlet portion connectable to a positive pressure air source, and from the inlet / outlet region to the filter cartridge in response to positive pressure from the positive pressure air source Provided is a positive / negative pressure respiratory protection device comprising a first check valve arranged to restrict the flow of air.
[0015]
The positive pressure / negative pressure type respiratory protection device of the present invention provides both the functions of the positive pressure type respiratory protection device and the negative pressure type respiratory protection device to the suction port of the face mask. The second check valve can be installed in close proximity to the face mask to restrict the flow of air from the face mask chamber to the positive / negative pressure adapter.
Furthermore, the present invention relates to a method for operating a positive pressure / negative pressure combined respiratory protection device, wherein a positive pressure air source is connected to a positive pressure / negative pressure adapter for fluidly connecting the filter cartridge to the respiratory protection device. To restrict the flow of air from the positive / negative pressure adapter to the filter cartridge in response to positive pressure from the positive pressure air source so that the respiratory protection device operates as a positive pressure respiratory protection device. Each step of reducing the flow of air from a positive pressure air source to a positive / negative pressure adapter so that at least a portion of the air is introduced into the respiratory protection device through the filter cartridge. Provide a method.
[0017]
In the present specification, the term “ambient air” means ambient air. The term “check valve” means any device for automatically restricting flow in one direction. The term “contaminant” means a gaseous, vaporous or particulate chemical that is harmful to breathing. The term “external environment” means ambient air outside the respiratory protection device. The term “face mask” means a mask that completely or partially covers a user's face, neck, head, etc. in close contact. The term “coating” means that the object is subjected to a forming process in order to add additional forming structures. The term “positive pressure air source” means a device that pumps breathable air to a respiratory protection device, such as a powered air purifying respirator (PAPR), a stationary air pump or compressor, a pressurized tank, etc. Includes small air pump.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows a combined positive / negative pressure respiratory protection device 20. The pair of positive / negative pressure adapters 22 and 24 are connected to the partial face mask 26 at respective suction ports (FIG. 4). The face mask 26 includes an exhaust port 28 having a check valve (not shown) and a strap 30 for wearing to the user. The partial face mask 26 substantially covers the user's mouth and nose. The positive / negative pressure adapter according to the present invention can be used with any type of face mask.
[0019]
The pair of filter cartridges 32 and 34 are attached to the positive / negative pressure adapters 22 and 24, respectively. An air conduit 36 with a Y connector 37 connects each adapter 22, 24 to a positive pressure air source 38. Because each pair of positive / negative pressure adapters 22, 24 and filter cartridges 32, 34 is used, the respiratory protection device 20 is held in a substantially horizontal equilibrium. However, the present invention encompasses respiratory protection devices each having one adapter and a filter cartridge.
[0020]
The air conduit 36 includes a check valve 40 and a quick release mechanism 42 so that the connection between the user and the positive pressure air source 38 can be quickly released. The check valve 40 prevents ambient air from being drawn into the face mask 26 when the air conduit 36 is removed from the positive pressure air source 38. The check valve 40 can be placed anywhere along the air conduit 36 between the quick release mechanism 42 and the respiratory protection device 20. Suitable for this application is a check valve known under the trade name ICV series from the Generant Company of Butler, New Jersey. The air conduit 36 or check valve 40 may incorporate a low pressure alarm device. The low pressure alarm device alerts the user that the air flow from the positive pressure air source 38 has dropped below a predetermined level and that the filter cartridges 32, 34 are providing at least a portion of their air. .
[0021]
FIG. 2 is a side view of the respiratory protection device 20 of FIG. 1 showing an air conduit 36 extending forward from the face mask 26. A belt clip 39 is provided to attach the air conduit 36 to the user so that the respiratory protection device 20 is not inadvertently pulled from the user's face (not shown).
FIG. 3 is a sectional perspective view of the positive / negative pressure adapters 22, 24, and the flow of air flowing from the air conduit 36 into the air distribution path 50 is indicated by arrows. In the embodiment shown in FIG. 3, the air distribution passage 50 extends substantially around the inlet / outlet region 52 as will be described below. However, various shapes of air distribution channels can be used without departing from the scope of the present invention. The plug connector 60 is provided adjacent to the suction port 68 of the adapter housing 23.
[0022]
The supplied air enters the air distribution path 50 as indicated by an arrow, passes through the porous member 54 in the radial direction, and flows into the inlet / outlet region 52. The porous member 54 can be formed from various porous materials such as sintered material (eg brass), porous polypropylene or acetal, porous ceramic or glass bead structure. Preferably used in this application is a porous polyethylene having an average pore size of 100 μm produced by General Polymeric, Leading Pennsylvania.
[0023]
Air Conduit Noise Attenuation Test Breathing masks were tested in a quiet laboratory with carpet and sound absorbing ceiling treatments for the magnitude of noise caused by air flow through air conduits, adapters, valves, and face mask fittings. The tested respiratory mask was affixed to the mannequin's head, and the sound collection microphone was placed 3.5 cm away from the head surface, corresponding to the simulated ear. The sound produced by the airflow was captured using a microphone, preamplifier, and A-weighted signal amplifier (model 2610 available from Bruel & Kjaer, Neelam, Denmark). The signal was analyzed using a dynamic signal analyzer (model 3561A available from Hewlett-Packard Company, Everett, Washington) set to 1/3 octave mode with an rms. The analysis frequency bandwidth was 12.5 Hz to 20 KHz. The microphone, preamplifier and amplifier were calibrated using a volume calibrator (model 4230 available from Bruel & Kjaer). A half-mask respirator (3M brand Easi-Air ™ 7200 available from 3M, St. Paul, Minn.) With an air conduit adapter (3M W-3187) The inventive adapter (with and without the porous member (ie, muffler ) 54) was tested at an air flow of 3.304 liters per second. The porous member 54 had an outer diameter of 4.0 cm, an inner diameter of 3.3 cm, and a height of 1.1 cm. The sound pressure levels measured with the microphone are shown in the table below.
[0024]
[Table 1]

[0025]
As the above table shows, the muffler typically reduces the integrated sound pressure level by 20 dB over the frequency range of 12.5 Hz to 20 KHz. This corresponds to a quarter of the noise level obtained with an adapter without a muffler member. Further, the porous member 54 acts as a diffuser that disperses the strength of the air flow, and reduces the maximum velocity of the air entering the face mask 26, while allowing the supply air exceeding the user's demand to flow without interruption.
[0026]
FIG. 4 is a cross-sectional side view of the positive / negative pressure adapter 22 or 24 and shows a state in which the filter cartridge 32 or 34 is connected to one suction port 62 of the face mask 26 so that fluid can flow. The filter cartridge 32 (34) is attached to an insertion connector 60 provided at the suction port 68 of the adapter 22 (24). A corresponding plug connector 60 ′ is provided adjacent to the suction port 62 of the face mask 26. In the preferred embodiment, the plug connectors 60, 60 ′ have the same structure so that the filter cartridge 32 (34) can be attached directly to the face mask 26. However, depending on the application, it may be desirable to change the structure of one of the plug connectors 60, 60 'to limit the structure of the members attached thereto. Between the adapter 22 (24) and the filter cartridge 32 (34) and the face mask 26, it is preferable to interpose a seal 6 4 respectively. These seals can be constructed from a variety of elastic materials, but closed cell urethane rubber or silicone is preferred for this application.
[0027]
While the illustrated embodiment discloses plug connectors 60, 60 ', the present invention is used to connect the various components 22, 24, 26, 32, 34 to allow fluid flow. The type of connector is not limited. A connector of the type that accepts a threaded member that is screwed into a corresponding integral cylinder in a sealed state with a gasket, if desired, may be employed within the scope of the present invention. Also, several components can be formed as one unit. For example, the filter cartridge 32 (34) and the adapter 22 (24) can be unitized. Alternatively, the suction port 62 of the face mask 26 and the adapter 22 (24) can be formed as one unit.
[0028]
As shown in FIG. 4, when the air passes through the porous member 54 and enters the inlet / outlet region 52, the positive pressure valve 66 prevents the air from entering the filter cartridge 32 (34) through the suction port 68. The positive pressure valve 66 is attached to a support 70 that extends substantially into an opening formed at the suction port 68. The pressure of the air presses the positive pressure valve 66 against the valve seat 72 provided in the adapter housing 23 and enhances the sealing force of the valve. If the positive pressure air source 38 does not supply an air flow that meets the user's requirements, the user's inhalation action creates a net negative pressure in the face mask chamber 84. The net negative pressure pulls the valve 66 away from the valve seat 72 and allows air to be drawn through the cartridge 32 (34). In the illustrated embodiment, the positive pressure valve 66 is a diaphragm valve formed from a highly flexible material such as silicone rubber. Various structures of check valves can be suitably used in this application, and the present invention does not limit such check valves to a specific type.
[0029]
The suction valve 80 is disposed across the opening 82 adjacent to the suction port 62, and air in the inlet / outlet region 52 is defined between the face mask 26 and the user's face (not shown). It is possible to enter the face mask chamber 84. The intake valve 80 can also be formed from a highly flexible material such as silicone rubber. Instead of the illustrated configuration, the suction valve 80 may be installed in the adapter housing 23. The net positive pressure in the face mask chamber 84 that occurs during the exhalation of the user presses the suction valve 80 against the valve seat 86. Excess pressure in the face mask chamber 84 is released from the exhaust port 28 (see FIG. 1).
[0030]
The positive pressure air source 38 can be used for a variety of reasons, such as compressor malfunction, accidental entanglement or disconnection of the air conduit 36, and intentional separation of the air conduit 36 by the user for improved maneuverability. It may be reduced or terminated. The arrows in FIG. 5 show the flow of air through the respiratory protection device 20 when the positive pressure air source 38 is reduced or terminated as required by the user. Since no positive pressure is generated in the inlet / outlet region 52, the positive pressure valve 66 is lifted from the valve seat 72 to allow air to flow through the filter cartridge 32 (34). In the state shown in FIG. 5, the respiratory protection device 20 acts as a negative pressure device, allowing air to pass through the opening 90 of the filter cartridge 32 (34) and the filtration medium 92 depending on the vital capacity of the user. Inhale into the face mask chamber 84. As described with reference to FIG. 4, when the user exhales, the intake valve 80 is pressed against the valve seat 86, and excess pressure in the face mask chamber 84 is released from the exhaust port 28 (see FIG. 1). .
[0031]
If the user isolates the air conduit 36 from the positive pressure air source 38 and the respiratory protection device 20 is operating in negative pressure mode, the check valve 40 in the air conduit 36 causes the contaminated air to flow into the air conduit. To prevent inhalation. In the embodiment shown in FIG. 1, the check valve 40 is located adjacent to a quick release mechanism 42 that allows the user to separate the respiratory protection device 20 from the positive pressure air source 38.
[0032]
FIGS. 6A and 6B show an example of a method for manufacturing the positive / negative pressure adapters 22 and 24. The main components of the adapter are a base 100, a cover 102, a porous member 54, and a gasket 55. The base 100 includes a female plug connector 60F that engages with a plug connector 60 'of the face mask 26. The base 100 further comprises a hook connector 104 with a snap ring or other acceptable securing means for holding the air conduit 36. To hold the air conduit 36 to the hooked connector 104, a tension leaf spring and a retaining clip may be added. The base 100 and the cover 102 can be formed from various polymer materials such as polyethylene, polypropylene, and polystyrene. For this application, polypropylene 6323 available from Himont, Minneapolis, Minnesota is preferred.
[0033]
The air conduit 36 generally has an inner diameter of 6 mm, which corresponds to the outer diameter of the hook connector 104, although an air conduit with an inner diameter of 3 mm is also preferably used. For applications using small powered air purifiers, an air conduit with a 25 mm hole diameter is generally required. The outer diameter of the hook connector 104 can be manufactured to accept an air conduit of any size. In this application, a tube formed from a 50/50 mixture of Shell Kraton G2701 and G2705 available from Shell Chemical Company of Houston, Texas can be used.
[0034]
FIG. 6 (b) shows an example of a method of attaching the air conduit 36 to the connector 104 and a method of forming an airtight seal between the base 100 and the cover 102. The adapter housing 23 attached to the air conduit 36 is placed in a mold and coated with the polymeric material 106. A variety of polymeric materials 106 can be used in this application, but the suitability of certain polymeric materials has been found to produce chemical bonds that form ideal mechanical strength and hermetic seals. For example, the polymeric material sold under the trade name Monprene 2850M available from Quality Service Technology of St. Albans, Vermont, the aforementioned Kraton, or polypropylene is a base 100 and cover 102 made of polypropylene, and from Kraton or Monprene. Specially adapted to the air conduit 36.
[0035]
FIGS. 7A and 7B show the use of a coating molding technique for forming a Y connector 37 for connecting a pair of adapters 22, 24. The Y fixture 110 is attached to three parts of the air conduit 36. Next, the Y fixture 110 and the air conduit 36 are covered and molded using the above materials as shown in FIG.
8 and 9 show a modified example of the respiratory protection device 20. In this variation, the air conduit 36 extends behind the face mask 26. As shown in FIG. 9, the air conduit 36 extends toward the back of the user so as not to interfere with the user's activities.
[0036]
FIG. 10 shows another modification of the respiratory protection device 20. In this modification, the filter cartridges 32 and 34 are removed, and valve lids 112 and 114 are attached instead. In the configuration shown in FIG. 10, the respiratory protection device 20 operates only as a positive pressure respiratory protection device substantially corresponding to FIG.
FIG. 11 shows a full face mask respirator 20 'as a modification. The apparatus includes a pair of positive / negative pressure adapters 22 ′, 24 ′ connected to a positive pressure air source 38. The full face mask type respiratory protection device 20 'generally covers the mouth, nose and both eyes of the user.
[0037]
The various embodiments described above are not intended to limit the scope of the invention, and various other modifications of the invention will be apparent to those skilled in the art from the foregoing description. The above description exemplifies specific embodiments for clarifying the invention, and the present invention is not limited to the above embodiments and specific elements, dimensions, materials, and shapes included therein. . Various modifications and variations of the present invention are included in the claims.
[Brief description of the drawings]
FIG. 1 is a schematic diagram of a respiratory protection device comprising a positive / negative pressure adapter connected to a positive pressure air source.
FIG. 2 is a side view of the respiratory protection device of FIG.
FIG. 3 is a cutaway perspective view of a positive / negative pressure adapter.
FIG. 4 is a cross-sectional side view of a respiratory protection device comprising a positive / negative pressure adapter connected to a positive pressure air source.
FIG. 5 is a diagram of the respiratory protection device of FIG. 4 with the positive pressure air source reduced or terminated.
6A is a cross-sectional side view of a positive pressure / negative pressure adapter before coating molding, and FIG. 6B is a cross-sectional side view of the positive pressure / negative pressure adapter after coating molding.
7A is a perspective view of a Y attachment for a positive pressure / negative pressure adapter before coating molding, and FIG. 7B is a perspective view of a Y attachment for a positive pressure / negative pressure adapter after coating molding. is there.
8 is a view showing a modification of the respiratory protection device of FIG. 1. FIG.
9 is a side view of the respiratory protection device of FIG. 8. FIG.
10 is a view showing a modification of the respiratory protection device of FIG. 1 with the filter cartridge removed.
FIG. 11 is a diagram showing a modified form of a full face mask type respiratory protection device including a positive / negative pressure adapter connected to a positive pressure air source.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 20 ... Respiratory protection device 22, 24 ... Positive pressure / negative pressure adapter 26 ... Face mask 32, 34 ... Filter cartridge 36 ... Air conduit 38 ... Positive pressure air source 40 ... Check valve 54 ... Porous member 66 ... Positive pressure valve 80 ... Suction valve

Claims (3)

In a pneumatic adapter for connecting a positive-pressure air source to a portable respiratory protection device worn by a user so that fluid can flow,
An adapter housing that can be directly connected to the respiratory protection device, wherein an inlet portion that can be connected to the positive pressure air source, and an inlet / outlet region that can be connected to the respiratory protection device so as to allow fluid flow, are provided inside the adapter housing. Adapter housings connected to each other so as to allow fluid flow therethrough,
A porous member interposed between said inlet portion and said entrance region, while reducing the air conduit noise, and the porous member to allow the flow of air into said output inlet area from the inlet portion,
A pneumatic adapter comprising: In a positive / negative pressure adapter for fluidly connecting a positive pressure air source to a respiratory protection device comprising a filter cartridge,
An inlet / outlet region for connecting the filter cartridge to the respiratory protection device so as to allow fluid flow, an inlet portion for connecting the positive pressure air source to the inlet / outlet region, and a positive pressure from the positive pressure air source. A positive / negative pressure adapter comprising an adapter housing having a first check valve in response to restricting air flow from the inlet / outlet region to the filter cartridge. A portable respiratory protection device worn by a user and used with a positive pressure air source,
A face mask having an exhaust port and at least one suction port;
An adapter housing that can be connected to the at least one suction port so that fluid can flow, and an inlet portion that can be connected to the positive pressure air source, and an inlet / outlet region that can be connected to the face mask so that fluid can flow. An adapter housing which is connected to each other so as to allow fluid flow therein;
A porous member interposed between said inlet portion and said entrance region, while reducing the air conduit noise, and the porous member to allow the flow of air into said output inlet area from the inlet portion,
A respiratory protection device comprising:

Images