This application is a national stage filing under 35 U.S.C. 371 of PCT/US2014/050817, filed Aug. 13, 2014, which claims priority to Great Britain Application No. 1314885.3, filed Aug. 20, 2013, the disclosure of which is incorporated by reference in its/their entirety herein.
Personal respiratory protection devices, also known as respirators or face masks are used in a wide variety of applications where it is desired to protect the human respiratory system from air borne particulates or noxious or unpleasant gases. Generally such respirators are in either a moulded cup-shape, such as those discussed in U.S. Pat. No. 4,827,924, or flat-folded format, such as those discussed in EP 814 871.
Moulded cup-shaped masks typically comprise at least one layer of a filter media supported by either an inner and/or an outer support shell. A gasket is provided around the inner edge of the cup-shape to ensure a good fit against the face of the wearer. The gasket is usually formed from a flexible material such that it moulds around the facial features of the wearer, providing a seal and good engagement between the mask and the face of the wearer. The quality of the fit of such respirators should be high, since it is essential that as much air as possible passes through the filter media and not around the edges of the respirator in use. Such respirators may also be provided with a valve to aid breathing.
The gasket itself is therefore a key factor in achieving reproducible, reliable fit of the respirator. Given the variation in facial features of wearers the gasket needs to be flexible enough and sized accordingly to fit around many different contours. One problematic area is around the nose of the wearer, where the respirator needs to fit closely and firmly against the skin to ensure minimal movement of the respirator during use as well as an airtight fit. To aid with fit, respirators are typically provided with a nose clip, such as a strip of metal, provided on the outer surface of the respirator and designed to be bent around the nose of the wearer to hold the respirator in place. One alternative to providing a nose-clip is to use a foamed in place gasket that fills the gap around the edge of the nose of the wearer, thus providing an improved fit. Such a solution is discussed in EP 1 614 361, where a rubber-like edge bead is moulded around the edge of the respirator, with deformable flanges included in the nasal region.
However, various issues may still arise with the use of a nose clip or other gasket: firstly, the inclusion of a nose clip may create additional manufacturing costs; secondly, the nose clip may be uncomfortable for some wearers since facial features and sizes vary greatly across the population of wearers; and thirdly, the fit achieved when not using a nose clip may be poorer in general without such close contact between the gasket and the skin of the wearer. Further, where fit is less than ideal, additional problems are encountered by wearers who also require eyewear to perform tasks, such as safety eyewear or prescription eyewear. For example, it may be difficult to wear safety glasses in the correct or a comfortable position if the base of the lenses or the frame impinges on the upper edge of the respirator or gasket. Even if worn in the correct position, a poorly fitting gasket encourages moist breath to escape the respirator and travel under the frame or lens of the eyewear, causing the eyewear to fog.
It would be desirable therefore to be able to deal with all of these issues by providing a gasket that gives optimum fit for all facial types and sizes, at minimal cost increase compared with current products, or, ideally, at a lower manufacturing cost.
The present invention aims to address at least some of these issues by providing a personal respiratory protection device for use by a wearer, comprising: a respirator body having a periphery, a filter media, forming at least part of the respirator body, and a gasket, the gasket being located at the periphery and extending along at least a portion of its length, wherein the gasket is formed of a vapour impermeable flexible elastomeric material and is contoured, the contour comprising a ridge that projects away from the periphery, and wherein the ridge acts as a barrier to exhalation vapours.
The flexibility of the gasket and the contouring create an adaptable structure that confirms easily and fully to the facial features of the wearer. By acting as a barrier to exhalation vapours misting of eyewear is reduced.
Preferably, the ridge causes the personal respiratory device to sit at an angle to the face of the wearer.
Preferably, the ridge is provided with an indent adapted to accommodate the nose of a wearer.
The device may further comprise a headband means to secure the personal respiratory device onto a wearer such that the gasket flexes and conforms to the facial features of the wearer. The headband means are preferably adjustable, such that when the adjustable headband means are adjusted the gasket flexes and conforms to the facial features of the wearer.
Preferably, the ridge is deformable such that the gasket fits substantially flush against the nose and cheeks of a wearer.
Preferably, the gasket extends along substantially the entire periphery.
Preferably, the gasket fits substantially flush against the nose, cheeks and chin of a wearer.
The ridge may be formed from a local increase in thickness of elastomeric material.
Preferably, the ridge is formed in the region of the gasket that contacts the nose of a wearer during use.
The contour may be substantially V-shaped.
Preferably, the gasket comprises a thermoplastic elastomer (TPE). The gasket may be injection moulded.
Preferably, the filter media is in the form of a cover, and the respirator body comprises an inner cup shaped support and the filter media is overlaid on the inner cup shaped support. The cover and the inner cup shaped support may be joined at the periphery of the respirator body. The respirator body may comprise at least two panels.
Preferably, the gasket extends along the entire periphery of the respirator body.
Preferably, the device is a maintenance-free respirator device.
The gasket may comprise a sheet-like elastomeric material.
Preferably, the gasket is provided with an aperture adapted to accommodate the nose and mouth of a wearer.
The present invention will now be described by way of example only, and with reference to the accompanying drawings, in which:
To create an improved fit without the use of nose clips, and to avoid issues resulting from poor fit, such as misting of eyewear, the present invention employs a contoured gasket formed from a vapour impermeable flexible, elastomeric material. The gasket is attached to the periphery of the personal respiratory device, and extends along at least a portion of its length. The contour comprises a ridge that projects away from the periphery, and the ridge acts as a barrier to exhalation vapours, such as moist breath. This flexibility enables the gasket to deform around the nose, cheeks and chin of a wearer, ensuring contact with the skin at all points along the gasket and therefore around the periphery of the device where it extends. Preferably the gasket extends along the entire periphery, thus creating an extremely good fit, regardless of the shape and size of the wearers' facial features. By combining good fit and a vapour impermeable material, the gasket effective prevents the fogging or misting of any eyewear worn alongside the personal respiratory protection device.
Headband means 11a-d are provided to secure the device 1 onto a wearer such that the gasket 6 flexes and conforms to the facial features of the wearer. The headband means 11a-d are secured to the device 1 at the periphery 3 by means of ultrasonic welding. An additional lip may be provided at the periphery 3, extending around at least a part, preferably all of, the periphery, forming a base to which the headband means 11a-d may be attached, if desired. Preferably the headband means 11a-d are welded to the periphery 3, by means of ultrasonic welding, although other suitable and equivalent techniques may be used. The headband means 11a-d are adjustable, such that when they are adjusted the gasket 6 flexes and conforms to the facial features of the wearer. When the adjustable headband means 11a-d are pulled tight, the gasket 6 flexes towards the face of the wearer, about the flexion point 10, pulling the indent 9 into contact with the nose. The headband means 11a-d each comprise a plastic buckle, through which a length of elastic material is threaded, and can be pulled through to be lengthened and shortened as desired. Two head bands (not shown) join each of two buckles, the head bands being formed from widths of elastic material. The structure of the buckle prevents easy movement in one direction thus holding the elastic material tightly in position. Alternatively, non-adjustable headband means may be used, such as strips of braided elastic, which may be glued, welded or stapled to the periphery 3.
The region of the gasket 6 at and adjacent the indent 9 contacts the nose and cheeks of the wearer intimately, creating a good fit. This is aided by the ridge 7 being deformable such that the gasket 6 fits substantially flush against the nose and cheeks of the wearer. The ridge 7 forms a cushioning means for the gasket 6, that in use, the ridge deforms against the face of the wearer, creating a cushioning effect such that the facial features are cushioned against the periphery 3. Since the components of the device 1 are welded together, as discussed below, the periphery 3 may feel hard and uncomfortable against the face of the wearer when the adjustable headband means 11a-d are pulled tight to create an airtight fit for the device in use. By providing a deformable ridge 7 on the gasket 6 this is effectively avoided and the device feels comfortable and well-fitting to the wearer regardless of the size and shape of the wearers' facial features. In this example, the gasket 6 extends substantially the entire periphery 3, such that the gasket 6 fits substantially flush against the nose, cheeks and chin of a wearer.
The inner cup-shaped support 4 is preferably formed from a thermally bonded polyester non-woven air-laid staple fibre material, although may optionally be polyolefin, polycarbonate, polyurethane, cellulose or combination thereof fibre material. The outer cover web 5 is preferably formed from spun bond polypropylene bi-component fibre non-woven materials. An inner cover web, not shown, may optionally be provided between the outer cover web 5 and inner cup-shaped support 4, and is preferably also formed from spun bond polypropylene bi-component fibre non-woven material. The inner-cup shaped support 4, outer cover web 5 and gasket 6 are welded together at the periphery 3. Preferably, ultrasonic welding is used, however, thermal and other welding techniques are equally suitable. Although in this embodiment of the present invention an internal cup-shaped support is used, it may be preferable to use a different type of support or for the support to be absent altogether. For example, an external cup-shaped support may be used, with an internal filter layer, forming the respirator body 2.
The gasket 6 is formed from a vapour impermeable flexible elastomeric material, preferably a thermoplastic elastomer (TPE). Suitable materials include Evoprene® G 967 and G 953, both available from AlphaGary Limited, Beler Way, Leicester Road Industrial Estate, Melton Mowbray, Leicestershire LE13 0DG, UK. Preferably the thermoplastic elastomer material is injection moulded to create the gasket 6. A two-part mould is preferably pressure-filled from at least one injection point on the face of the mould, resulting in the final gasket 6 having the at least one injection point on a surface, rather than an edge. Injecting onto the face of the mould, rather than into an edge, results in excellent resistance to tearing and mechanical strength of the finished gasket 6.
The gasket 6 has a nominal thickness of 1.67 mm in the region of the ridge 7, 0.80 mm at the periphery 3 and 0.65 mm at the remainder of the gasket 6. Hence the ridge 7 is formed by a local increase in thickness of the elastomeric material.
The ridge 7 acts as a barrier to exhalation vapours, due to its vapour impermeable nature. This is particularly advantageous for wearers who also need to wear eyewear at the same time as the personal respiratory protection device 1. Since the gasket 6 forms a close fit around the nose and cheeks of the wearer by fitting substantially flush with the nose and cheeks, moist air breathed out by the wearer is substantially prevented from exiting the device 1 around the edges of the gasket 6. As little or no moist air contacts the inner or outer surfaces of eyewear being worn simultaneously with the device 1, fogging or misting of the eyewear does not occur. This is illustrated schematically in
In order to determine the effectiveness of the present invention, the fogging of a pair of typical safety eyeglasses was evaluated in conjunction with a personal respiratory protection device having a gasket as described above. This was done using the following test method.
A breathing machine was connected through a humidifier to a Sheffield dummy head. In order to prevent excess water spilling out of the dummy's mouth, the dummy head was inclined slightly such that any water ran away from the mouth. Excess water was collected in a trap if required. The breathing machine was switched on and set to 25 strokes per minute and 2 litres/stroke, and switched off again. The humidifier was then switched on and left to warm up for 30 minutes. The breathing machine was then switched back on and whilst running the temperature of the exhaled air at the mouth of the dummy head was checked using a fast response thermometer. The temperature should ideally be 37° C.+/−2° C.). Strips of cobalt chloride paper were then attached to the inside of the lens on a pair of 3M 2700 over-spectacles (available from 3M United Kingdom PLC, 3M Centre, Cain Road, Bracknell RG12 8HT), ensuring that any excess paper was trimmed. The spectacles were scribed with a grid of squares based on a template of 8 squares by 4 squares across the surface of the glasses, to enable measurement of the surface area of any fogging. Before testing, the over-spectacles were placed in a dessicator to ensure that any pre-existing moisture was removed.
Once this set-up was completed, the personal respiratory protection device 1 was fitted onto the dummy head. Masking tape was used to seal the device to the dummy head, taking care to minimise coverage of any filter material or issues with poor fitting of the gasket. The over-spectacles were then positioned on the dummy head such that the bridge of the over-spectacles coincided with the indent on the device. The breathing device was then run for 3 minutes and the amount of moisture present on the cobalt paper recorded. After this the over-spectacles and cobalt paper were returned to the dessicator, and the test repeated a further 4 times, giving 5 sets of results in total. The total grid area on the lenses of the over-spectacles was 5698 mm2, therefore the percentage area of lens covered by exhaled air (fogged lens) is given by:
(measured lens area/5698)×100=percentage area
In addition, the weight of the over-spectacles both fogged (after testing, fogged test weight) and unfogged (after dessicating, clear test weight) was measured.
Test results are shown in Table 1 below:
It can be seen from these results that only a small percentage of the surface area of the lenses of the over-spectacles was fogged, with an average of 1.9%, indicating that the gasket performs very well as a moisture barrier. A commercially available cup-shaped mask was also tested under the same conditions and gave an average of 21.3% of the surface area of the lenses of the over-spectacles as fogged.
In the above example, the device 1 is cup-shaped, with the gasket 6 extending along the entire periphery 3 of the respirator body 2. However, it may be desirable to include the gasket on a device that is not cup-shaped. For example, the respirator body 2 may comprise at least two panels, thus forming a flat fold respirator device. Preferably, the device 1 is a maintenance-free respirator device. In either case, the device may also include a valve 15. Alternatively, the device may be a reusable respirator.
Number | Date | Country | Kind |
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1314885 | Aug 2013 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/US2014/050817 | 8/13/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/026587 | 2/26/2015 | WO | A |
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