Personal respiratory protection device

Abstract

The present invention relates to a personal respiratory protection device, in particular, such a device 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.

Claims

1. 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 forms a central aperture, wherein the gasket is formed of a vapour impermeable flexible elastomeric material and is contoured, the contour comprising a ridge and a flexion point disposed on the ridge, and wherein the flexion point is formed from a local reduction in thickness of the flexible elastomeric material, wherein the ridge projects away from the periphery and the central aperture, wherein at least a portion of the ridge is angled towards the periphery, wherein the ridge acts as a barrier to exhalation vapours, and further wherein the ridge is adapted to deform against the face of the wearer.

2. Device of claim 1, wherein the ridge causes the personal respiratory device to sit at an angle to the face of the wearer.

3. Device of claim 1, wherein the ridge is provided with an indent adapted to accommodate the nose of a wearer.

4. Device of claim 1, further comprising 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.

5. Device of claim 4, wherein the headband means are adjustable, such that when the adjustable headband means are adjusted the gasket flexes and conforms to the facial features of the wearer.

6. Device of claim 1, wherein the ridge is deformable such that the gasket fits substantially flush against the nose and cheeks of a wearer.

7. Device of claim 1, wherein the gasket extends along the entire periphery of the respirator body.

8. Device of claim 7, wherein the gasket fits substantially flush against the nose, cheeks and chin of a wearer.

9. Device of claim 1, wherein the ridge is formed from a local increase in thickness of elastomeric material.

10. Device of claim 1, wherein the ridge is formed in the region of the gasket that contacts the nose of a wearer during use.

11. Device of claim 1, wherein the contour is substantially V-shaped.

12. Device of claim 1, wherein the gasket comprises a thermoplastic elastomer (TPE).

13. Device of claim 12, wherein the gasket is injection moulded.

14. Device of claim 1, wherein 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.

15. Device of claim 14, wherein the cover and the inner cup shaped support are joined at the periphery of the respirator body.

16. Device of claim 1, wherein the device is a maintenance-free respirator device.

17. Device of claim 1, wherein the gasket comprises a sheet-like elastomeric material.

18. Device of claim 1, wherein the ridge is adapted to deform towards the periphery.

19. Device of claim 1, wherein the gasket is adapted to flex about the flexion point.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The present invention will now be described by way of example only, and with reference to the accompanying drawings, in which:

(2) FIG. 1 is a perspective view of a personal respiratory device comprising a gasket in accordance with the present invention;

(3) FIG. 2 is a side view of a personal respiratory device comprising a gasket in accordance with the present invention;

(4) FIG. 3 is a plan view of a gasket indicating a number of cross-sections;

(5) FIG. 4a is a cross-section along A-A′ in FIG. 3

(6) FIG. 4b is a cross-section along B-B′ in FIG. 3;

(7) FIG. 4c is a cross-section along C-C′ in FIG. 3;

(8) FIG. 4d is a cross-section along D-D′ in FIG. 3;

(9) FIG. 4e is a cross-section along E-E′ in FIG. 3;

(10) FIG. 4f is a cross-section along F-F in FIG. 3;

(11) FIG. 4g is a cross-section along G-G′ in FIG. 3;

(12) FIG. 4h is a cross-section along H-H′ in FIG. 3; and

(13) FIG. 5 is a schematic side view of a wearer wearing a personal respiratory protective device in accordance with the present invention in conjunction with eyewear.

DETAILED DESCRIPTION

(14) 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.

(15) FIG. 1 is a perspective view of a personal respiratory device comprising a gasket in accordance with the present invention. The personal respiratory device 1 is generally cup-shaped, with a respirator body 2 having a periphery 3, and comprises an inner cup-shaped support 4 and a filter media in the form of an outer cover 5, the filter media being overlaid on the inner cup-shaped support 4, forming at least part of the respirator body 2. A gasket 6 is provided at the periphery 3 of the device 1, and in this embodiment, and extends around the entire periphery 3 of the device 1. The gasket 6 is formed from a vapour impermeable flexible elastomeric material. The gasket 6 is contoured, as illustrated by the contoured region, with the contour comprising a ridge 7 that projects away from the periphery 3. The ridge acts as a barrier to exhalation vapours. The ridge is deformable, and preferably forms a cushioning means for the gasket 6. The contour is substantially V-shaped. The ridge 7 is formed in the region of the gasket 6 that contacts the nose of the wearer during use, and is formed from a local increase in thickness of the elastomeric material of the gasket 6. The gasket 6 forms a central aperture 8, substantially elliptical in shape, for receiving the oro-nasal region of the wearer, such that the gasket 6 contacts the nose, cheeks and chin of the wearer. At the uppermost point, where, in use, the gasket 6 contacts the bridge of the nose of the wearer, the gasket 6 is provided with an indent 9. The indent 9 is adapted to accommodate the nose of the wearer. A flexion point 10 is disposed on the ridge 7, generally corresponding with the position of the indent 9, such that the indent 9 forms the flexion point 10. The flexion point 10 is formed from a local reduction in thickness of the elastomeric material of the gasket 6. The gasket 6 is adapted to flex about this flexion point 10.

(16) 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.

(17) 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.

(18) 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.

(19) FIG. 2 is a side view of a personal respiratory device comprising a gasket in accordance with the present invention. This illustrates the shape of the contour in more detail. The contour is substantially V-shaped, with the apex of the “V” corresponding to the ridge 7. When the headband means 11a-d are pulled tight in the direction of arrows A, A′, the gasket 6 flexes downwards at the flexion point pushing the regions 12a, 12b on either side of the flexion point 10 and indent 9 against the cheekbones of the wearer. The portion of the gasket 6 at the periphery 3 opposite the indent 9 is pulled tight against the chin of the wearer simultaneously. This creates an airtight fit around the entire periphery 3 of the device 1.

(20) 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.

(21) FIG. 3 is a plan view of a gasket indicating a number of cross-sections. These cross-sections show the contour and ridge 7 in more detail. FIG. 3 shows one half of the gasket 6, and it should be understood that the contouring on the half not shown is a mirror image of that in cross-sections A-A′ to H-H′. FIG. 4a is a cross-section along A-A′ in FIG. 3, and shows the thickness of the gasket 6 at the region of the indent 9 and flexion point 10. Although the nominal thicknesses below are given, these should be understood to be preferred values within a range determined by manufacturing tolerances of ±0.2 mm. In addition, both the nominal values and tolerances may change with the grade and composition of the TPE material used to manufacture the gasket 6.

(22) 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. FIG. 4b is a cross-section along B-B′ in FIG. 3, and FIG. 4c is a cross-section along C-C′ in FIG. 3. Here the nominal thickness of the gasket 6 at the ridge 7 is 2.04 mm and 1.73 mm respectively, indicating that the flexion point is formed from a local reduction in thickness of the elastomeric material. The thickness of the material forming the ridge 7 decreases moving away from the indent 9, as indicated in FIGS. 4d (1.50 mm) and 4e (1.14 mm). Where the ridge 7 is angled towards the periphery 8 at sections F-F′ and G-G′, as shown in FIGS. 4f and 4g, the thickness increases slightly (1.34 mm and 1.67 mm respectively), where the gasket 6 contacts the jawbone of the wearer around the edges of the mouth. Finally, the portion of the gasket 6 that fits across the chin of the wearer, as shown at section H-H′ in FIG. 4h, has approximately the same nominal thickness as the remainder of the gasket away from the ridge 7 and periphery 3, that is 0.65 mm. From FIGS. 4b and 4c in particular it can be seen how the variation in thickness of the gasket 6 allows it to deform and contact the nose and cheeks of the wearer, yet remain structural enough at the ridge 7 to form an airtight seal. Unlike prior art devices, the gasket comprises a sheet-like elastomeric material, with the performance characteristics being determined by the variations in thickness of the material and contours formed by injection moulding.

(23) 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 FIG. 5. In FIG. 5, eyewear 13 is worn in conjunction with the device 1. The gasket 6 is substantially flush with the cheeks and chin of the wearer. Arrows B indicate the direction of exhaled air within the device 1. It can be seen that when the wearer breathes out, air is prevented from escaping around the gasket 6 by the fit and through the gasket 6 by the use of vapour impermeable flexible elastomeric material to form the gasket 6. Air is therefore forced to flow out of the device 1 via the cover 5 and/or the valve 15.

EXAMPLES

(24) 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.

(25) 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.

(26) 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 mm.sup.2, therefore the percentage area of lens covered by exhaled air (fogged lens) is given by:
(measured lens area/5698)×100=percentage area

(27) In addition, the weight of the over-spectacles both fogged (after testing, fogged test weight) and unfogged (after dessicating, clear test weight) was measured.

(28) Test results are shown in Table 1 below:

(29) TABLE-US-00001 TABLE 1 Fogged Sample Weight (clear) g Weight (fogged) g Clear lens % lens % 1 0.4580 0.4532 99.0% 1.0% 2 0.4611 0.4530 98.2% 1.8% 3 0.4614 0.4453 96.5% 3.5% 4 0.4674 0.4584 98.1% 1.9% 5 0.4599 0.4532 98.5% 1.5%

(30) 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.

(31) 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.