RU2572172C2 - Mounting assembly of respirator containing locking mechanism - Google Patents

Abstract

FIELD: rescue equipment.

SUBSTANCE: invention relates to devices for respiratory protection. The mounting assemblies for respirators are claimed, comprising the first and the second components of the respirator and the locking mechanism. The locking mechanism may be engaged with at least one stop element of the respirator component, thus preventing the removal of the first respirator component from engagement with the second component of the respirator. When applying the force to the actuating element at least one retainer can be disengaged from the stop element, thereby enabling to disengage the first component of the respirator with the second component of the respirator. Also the respirator components are disclosed, comprising such locking mechanisms or operating with such locking mechanisms.

EFFECT: improvement of the design.

15 cl, 11 dwg

Description

The invention relates to devices for protecting respiratory organs, in particular to respirator assembly units comprising a locking mechanism for releasably connecting the first respirator component to the second respirator component.

State of the art

Respiratory protection devices are used to provide users with clean air. In some devices, the user is supplied with clean air by passing outside air through a filter located in the filter cartridge. The filter cartridge is attached to the base of the respiratory mask that the user puts on his face over his mouth and nose. In such respiratory protective devices, outside air is drawn in through the filter due to the negative pressure exerted by the user upon inspiration. In other cases, clean air may be supplied to the user under pressure from a blower device that presses outside air through a filter. Such devices are known as electric driven air cleaning respirators. In some other devices, clean air may be supplied to the user from the pressure vessel. Such devices are known as self-contained breathing apparatus. In each of the above devices, a source of clean air (for example, a filter cartridge or hose of an electric respirator or self-contained breathing apparatus) is connected to the base of the mask worn by the user over his mouth and nose. If the user needs full protection of the face and head, then a respiratory protection device can also cover the eyes and head.

In the field of respirator manufacturing, several types of systems have been developed for attaching a clean air source to a respiratory mask. One widely used system is a threaded connection, in which the threaded component is attached to the mating threaded part, see, for example, US Patents 5,222,488; 5,063,926; 5036844; 5,022,901; 4,548,626; 4422861 and 6575165. The threaded filter cartridges typically have an external thread that is screwed into the internal thread of the mating socket or mating sleeve of the mask base. By rotating the filter cartridge in the appropriate direction, you can attach the cartridge to the base of the mask or remove it. To provide an airtight connection, an elastic deformable gasket is usually installed at the interface between the cartridge and the mask base. To hold in place a source of clean air with a threaded part and fix it with the possibility of removal, clamps are used - see, for example, US patent 6575165.

Instead of threaded mechanisms for attaching clean air sources to respirators, bayonet-type connections are also used. In the bayonet connection there are locking protrusions and reciprocal cutouts that ensure the components are fixed to each other. When installing the cartridge, its locking protrusions are combined with cutouts in the opening of the base of the mask. When the filter cartridge is rotated in the desired direction, the cartridge engages reliably with the mask base — see, for example, US Pat. Nos. 6,216,693 and 5,924,420. An advantage of the bayonet coupling is that the cartridge can be quickly mounted on the mask base by rotating the cartridge, usually less than half a turn.

In bayonet systems, a device is often used to soundly indicate that the filter cartridge is properly seated on the front respiratory mask — see, for example, US Pat. in the form of an edge on the cartridge, bending or deforming it. When the cartridge rotates relative to the face mask in the locked position, the cam and rib deform or bend until the rib comes off the edge of the cam. Sudden operation of the locking mechanism causes an audible click.

Respirators with snap-on filter cartridges have also been developed. Examples of such cartridges are described in US Pat. No. 5,579,761 (Yushack et al.). In this solution, the filter cartridge is immediately engaged with the base of the mask by pressing the cartridge with force to the responsive design of the base of the mask. No rotation of the filter cartridge is required.

Also known are devices for respiratory protection in which threaded parts of a source of clean air and a reciprocal structure are used, having a thread with a large pitch, an integrated clamp and an abutment. The emphasis prevents excessive screwing of the source of clean air into the base of the mask when they are fixed to each other. An example of such a fastening is described in US patent 7320722 (Mittelstadt et al.).

SUMMARY OF THE INVENTION

In one embodiment of the present invention, there is provided an assembly of a respirator comprising first and second components of a respirator. The first component of the respirator has a receiving surface including a first axial passage located therein. The second component of the respirator has at least one retaining element and a second axial passage, having a configuration and dimensions that ensure its fluid connection with the first axial passage so that the second component of the respirator forms a tight connection with the receiving surface of the first respirator component. The respirator assembly further includes a locking mechanism attached to the first component of the respirator and comprising an elastic element, at least one latch protruding inward toward the first axial passage, and a latch drive element. Said at least one retainer may engage with said at least one locking element, thereby preventing the first component of the respirator from disengaging from the second component of the respirator. When a force is applied to the drive element, said at least one retainer can disengage from the locking element, thereby allowing the first respirator component to disengage from the second respirator component.

In a second embodiment of the invention, there is provided a respirator assembly including a first respirator component having an opening for detachably connecting the first respirator component to the second respirator component. The opening has a receiving surface having a first axial passage located therein and a fixing mechanism attached thereto. The locking mechanism comprises an elastic element, at least one latch protruding inward toward the first axial passage, and a locking drive element. When a force is applied to the drive element, said at least one lock can be displaced away from the first axial passage.

In yet another embodiment of the invention, there is provided a respirator assembly including a first respirator component having an opening for detachably connecting the first respirator component to the second respirator component. In this embodiment, the opening includes a protrusion having an axial passage located therein, a retaining shelf located on the outer surface of the protrusion, and a sealing element located on the outer end of the annular protrusion.

Brief Description of the Drawings

The present invention will be better understood from the following detailed description of its various embodiments, accompanied by the accompanying drawings.

FIG. 1. An assembly of a respirator in accordance with one embodiment of the present invention.

FIG. 1A. An enlarged view of a fragment of the respirator assembly shown in FIG. one.

FIG. 2A. An assembled respirator assembly in accordance with yet another embodiment of the present invention.

FIG. 2B. View of the respirator assembly shown in FIG. 2A, from the opposite side.

FIG. 2C. The respirator assembly shown in FIG. 2A and 2B, partially assembled.

FIG. 2D. A sectional view of the opening of the respirator assembly in accordance with the first embodiment of the present invention.

FIG. 3A. The assembly of the respirator in accordance with another embodiment of the present invention, in a disassembled form.

FIG. 3B. View of the respirator assembly shown in FIG. 3A, on the opposite side.

FIG. 4. The assembly of the respirator in accordance with another embodiment of the present invention, in a disassembled form.

FIG. 5. The assembly of the respirator in accordance with another embodiment of the present invention, in a disassembled form.

FIG. 6. The assembly of the respirator in accordance with another embodiment of the present invention, in a disassembled form.

The drawings are not necessarily drawn to scale. Similar item numbers in the drawings correspond to similar components. In this case, however, it is understood that the use of a position number for any component in one drawing does not necessarily limit its designation to the same position number in another drawing.

DETAILED DESCRIPTION OF THE INVENTION

All scientific and technical terms used in this application have the meanings generally accepted in the art, unless otherwise indicated. The above definitions are given to facilitate understanding of the terms often used in the present description, and do not imply any limitations on the scope of the present invention.

Unless otherwise indicated, all values of element sizes, quantities and physical properties used in the present description and in the claims, in all cases should be understood in combination with the term "about". Unless otherwise specified, in the present description and in the attached claims, the mention of the elements in the singular implies that the above information applies to all such elements in embodiments in which there are several such elements. In the present description and in the appended claims, the term “or” is generally used in the sense of “and / or” unless the context clearly indicates otherwise.

In FIG. 1 shows a respirator assembly 10 in accordance with one embodiment of the present invention. In this embodiment, the respiratory assembly 10 is an individual respiratory protective device operating on the principle of negative pressure. The respirator assembly 10 includes a first respirator component 12 (in this case it is the base of the mask), a second respirator component 14 (in this case it is a source of clean air, for example a filter element or a filter cartridge). The respiratory protection device shown in FIG. 1 is commonly referred to as a negative pressure respirator or mask, since air passes through the mask mainly due to the vacuum created by the user's lungs, as opposed to positive pressure devices in which air is supplied by a fan or from a source of compressed air. As mentioned above, respirators or masks operating on the principle of positive pressure are supplied with air or oxygen from an external source, for example, a fan or from a pressure tank. In systems operating on the principle of positive pressure, clean air is supplied through a hose or other suitable duct attached to the respirator. Examples of such devices are described in US patent 6250299, 6186140, 6014971, 5125402, 4965887, 4462399 and 4280491. In such systems, air is blown under pressure through a filter unit that the user can wear, for example, on the belt. In addition, in US patent 6478025, 4886056, 4586500 and 4437460 described examples of self-contained breathing apparatus.

In FIG. 1, the first component 12 of the respirator is shown as a body part of a full-face respiratory mask worn at least over the nose, mouth and eyes of the user — see, for example, US Pat. No. 5,924,420 (Reischel et al.). Moreover, the use of a “half-face” mask worn only over the user's mouth and nose is also included in the scope of the present invention. An example of such a mask is described, for example, in US patent 7320722 (Mittelstadt et al.). The first component 12 of the respirator may include a soft element 16 in contact with the face, a rigid structural element 18 and one or more elements 20 located thereon, receiving one or more fastening straps or ribbons holding the respirator assembly 10 on the user's head while using the respirator. The rigid structural element 18 may include at least one expiratory opening 24 through which exhaled air can be removed from the internal gas space of the mask. In this case, the internal gas space is defined as the space between the base of the mask and the face of the user. On the basis of the mask 12, an exhalation valve may be provided (in the embodiment in the drawing it is closed by a valve cover 27), which prevents the ingress of external air into the internal gas space during inhalation and ensures the rapid removal of exhaled air from the internal gas space during exhalation. Examples of exhalation valves that can be used in the respirator assembly of the present invention include valves with a flexible shutter that opens quickly under the action of exhaled air.

As shown further in FIG. 1 and 1A, the first respirator component 12 in this embodiment includes an opening 30 for releasably connecting the first respirator component 12 to the second respirator component 14. The opening 30 may include a receiving surface 32, in which there is a first axial passage 34. On the receiving surface 32 may be located the first protrusion 36, the configuration and dimensions of which can be such that it will cover the first axial passage 34. It is preferable that the first protrusion 36 had a generally annular shape. The respirator assembly 10 includes a locking mechanism 40. The locking mechanism 40 in this embodiment is attached to the first component 12 of the respirator. However, in other embodiments, it may be attached to the second respirator component 14. The locking mechanism 40 includes an elastic element 42, at least one latch 44, protruding inwardly towards the first axial passage 34, and the locking actuator 46. The locking mechanism 40 is configured so that when a force is applied to the drive element 46, the at least one latch 44 can exit the first axial passage 34. In this embodiment, the drive element 46 comprises the free ends of the locking mechanism 40, and the required force can be applied by pressing the free ends of the locking mechanism against each other, as shown by arrows F in FIG. 1A. Other embodiments and additional elements of the locking mechanisms in accordance with the present invention will be described in detail below with reference to FIG. 2A-4.

As shown in FIG. 1 and 1A, the second respirator component 14 may be a filter cartridge having a housing 50 in which a filter element may be contained (filter element not shown). In other embodiments, a filter element without a housing may be used. On the front face of the second respirator component 14, there may be a housing cover or mesh 52 covering and protecting the filter element. The cover 52 of the cartridge may have a plurality of openings 54 through which air from the external gas space may pass through the cover 52 for subsequent filtering by the filter element during inspiration. The filter element may be a filter for gases and / or particles, or may include such a filter. Examples of such filters are described in US patents 6743464 (Insley et al.), 6627563 B1 (author Huberty), 6454986 (Eitzman et al), 6660210, 6409806 and 6397458 (Jones et al), 6406657 (Eitzman et al), 6391429 (Senkus et al.), 6,375,886 (Angadjivand et al.), 6214094 (Rousseau et al.), 6139308 (Berrigan et al.), 6119691 (Angadjivand et al.), 5763078 and 5033465 (Bran et al.), 549262685 and 5ble. Gas filters may include granular activated carbon, for example, in the form of a compressed plate or in a bound form. Particle filters may include electrically charged microfibers, for example, a nonwoven fibrous web can be used.

The second respirator component 14 includes an opening 60 for releasably connecting the second respirator component 14 to the first respirator component 12. The aperture 60 includes a second axial passage 62, which is fluidly connected to the outside air through the filter element, whereby when the user takes a breath, the outside air is sucked through the openings 54 in the cartridge cover 52, passes through the filter element, and then into the second axial passage 62. The second axial passage 62 has a configuration and dimensions at which it can be fluidly coupled to the first axial passage 34 of the first respirator component 12 when the second respirator component 14 is attached to the first component 12 respirators. In this case, the second component 14 of the respirator forms a tight connection with the receiving surface 32 of the first component 12 of the respirator.

The second component 14 of the respirator also includes at least one retaining element 66, which in some embodiments may be located on the second protrusion 64. The second protrusion 64 may have a configuration and dimensions at which it will cover the second axial passage 55. The second protrusion 64 preferably has ring-shaped. Said at least one locking element 66 has a configuration in which at least one latch 44 can interact with said at least one locking element 66, thereby preventing the first respirator component 12 from engaging with the second respirator component 14. On the other hand, by applying force to the locking drive member 46, said at least one locking member 44 can disengage from at least one locking member 66, thereby allowing the first respirator component 12 to mesh with the second respirator component 14.

It will be apparent to one skilled in the art that the embodiments of the present invention described in this application are susceptible to various modifications, which nevertheless fall within the scope of the present invention. So, for example, various elements depicted as part of the first component 12 of the respirator (for example, one or more openings 30, the receiving surface 32, the fixing mechanism 40, and others) can be made in the form of parts of the second component 14 of the respirator, and vice versa.

In FIG. 2A shows a respirator assembly 100 in accordance with another embodiment of the present invention. In FIG. 2B is a rear view of the same respirator assembly 100 for better displaying elements that are not visible in FIG. 2A. In FIG. 2C shows yet another view of the same respirator assembly 100 on which some components are already assembled with each other. This respirator assembly 100 includes a first respirator component 120 (shown schematically as a fragment of a respiratory mask) and a second respirator component 180 (shown schematically as a part of a filter cartridge). This first respirator component 120 includes an opening 130 for releasably connecting the first respirator component 120 to the second respirator component 180. The opening 130 includes a receiving surface 132, in which there is a first axial passage 134. On the receiving surface 132 there is a first protrusion 136, the shape and dimensions of which are such that it covers the first axial passage 134. The first protrusion preferably includes segments 136a in the form of walls generally cylindrical forms. The first protrusion may further include one or more elements that ensure the correct position and / or prevent mutual rotation of the connected components of the respirator, for example, made in the form of one or more tides 136b. In addition to this or alternatively, the receiving surface 132 may have a recess extended around the first axial passage.

This second respirator component 180 includes an opening 160 for releasably connecting the second respirator component 180 to the first respirator component 120. The aperture 160 includes a second axial passage 162, the dimensions and configuration of which provide fluid communication with the first axial passage 134 of the first respirator component 120 when the second respirator component 180 is connected to the first respirator component 120. The second protrusion 164 is sized and configured so that it spans the second axial passage 162. In some embodiments, the configuration of the first protrusion 136 is such that it is received by the second protrusion 164. The second protrusion 164 may have a generally annular shape. The second protrusion may have one or more elements 164a ensuring correct alignment and / or preventing rotation, the configuration of which ensures their conjugation with mating elements 136b of the first protrusion 136. In one embodiment, one or more elements 164a ensuring correct alignment and / or preventing rotation, can be made in the form of one or more recesses, the configuration of which ensures the reception of one or more tides 136b. Other configurations of elements ensuring correct alignment and / or preventing rotation are also included in the scope of the present invention. Both the first and second components of the respirator may contain at least one anti-rotation element. Such elements of the first and second components are located in close proximity to the first and second annular protrusions, respectively, and mate with each other.

The second component 180 of the respirator also includes at least one locking element 166, for example, made in the form of one or more shelves or shoulders, which can be located on the second protrusion 164 shown in FIG. 2A-2C around the second passage 162. In other embodiments, one or more of the locking elements may comprise a plurality of protrusions arranged around a circumference of a side surface of the second axial passage, for example, on a second protrusion 164. In some embodiments, the opening 130 of the first respirator component 120 comprises a sealing element 132a depicted in FIG. 2D. In the shown embodiment, the sealing element 132a includes an oil seal located on the receiving surface 132. The oil seal preferably covers the first axial passage 134. The sealing element 132a may be configured to interact with the sealing element of the opening 160 of the second respirator component 180, for example, with an inclined sealing profile surface 168.

The sealing member may be made of rubber or other flexible materials such as rubber, or may include such a material. Examples of suitable materials include thermoplastic elastomers, such as Kraton® or Monprene® block copolymers, thermoplastic volcanoes, such as Santoprene®, or various thermoset rubbers, such as natural latex rubber, polyisoprene, nitrile, EPDM, butyl or silicone rubber. The sealing element 132a may be removably attached to any component of the respirator assembly (or otherwise assembled with this component), or the sealing element 132a may be molded over such a component or permanently glued to such a component. Alternative embodiments of the sealing member may include a compressible pad, for example, located on the receiving surface 132, or a flexible cell element with closed cells. Another alternative embodiment of the sealing element may be an O-ring, pressed against the surface 132, or sliding and radially compressible between the mating, radially extended surfaces of the first and second respirator components. The sealing element of any of the types mentioned may be located in any suitable place on the first component of the respirator, the second component, or both of them.

The respirator assembly 100 further includes a locking mechanism 140. The locking mechanism 140 in this embodiment may be removably or permanently attached to the first respirator component 120. So, for example, the opening 130 can be inserted into the opening 122 of the first respirator component 120 so that at least part of the opening is on one side of the opening, and at least one more part is on the other side of the opening. So, for example, the opening 130 may have a flat flange made around its perimeter and preventing the passage through the hole. A locking mechanism 140 may be inserted into the opening 130, and a cover 150 may be attached to the opening 130 over the locking mechanism 140, for example by snapping, holding the opening 130 and the locking mechanism 140 on the first respirator component 120.

The locking mechanism 140 includes an elastic member 142, as well as a first and second retainer 144a and 144b protruding inside the first axial passage 134 when the locking mechanism 140 is assembled with the first respirator component so that they engage with at least one locking member 166, thereby preventing the first component 120 of the respirator from disconnecting from the second component 180 of the respirator. The first latch 144a is located on one side of the axial bore 134, while the second latch 144b is located on the other side of the axial bore 134, preferably opposite the first latch 144a.

One or both of the retainers 144a and 144b may have an arcuate shape in which they bend around the first axial passage 134, as well as an annular protrusion 136 (if any). In one embodiment, each of the latches 144a and 144b comprises a lever having a free end 146a and 146b, respectively. The levers can be connected to each other in one place and intersect with each other in another place. So, for example, in the shown embodiment, the clips 144a and 144b are connected to each other by means of an elastic element 142. The elastic element 142 may be a separate part connecting the levers to each other, or a region made integrally with the levers, or may be any other part the locking mechanism 140. In one embodiment, the entire locking mechanism can be considered as an elastic element 142. The elastic element 142, being sufficiently flexible, allows the latches 144a and 144b to bend and move far enough from the first axial passage and 134 of the first component 120 of the respirator by applying force to its drive element 146, as a result of which the locking mechanism 140 can be disengaged from the locking element 166 of the second component 180 of the respirator. On the other hand, the resilient member 142 must have sufficient resilience to return to its original position after release of the force.

In one embodiment, the latches 144a and 144b are offset relative to each other under the influence of elasticity. In particular, in the initial state of the locking mechanism 140 shown in FIG. 2A and 2B, the levers of the latches 144a and 144b of the locking mechanism 140 intersect at a location closer to their common end than when the locking mechanism 140 is inserted into the opening 130, as shown in FIG. 2C. When the locking mechanism 140 is inserted into the opening 130, the protrusion 137 is located between the levers of the latches 144a and 144b and holds the levers in a bent state until the force is applied to the actuator 146. In some embodiments, the locking mechanism 140 may be secured to a recess 135 formed in the connector 130 of the first respirator component 120 using a pin 145. In such embodiments, the first and second levers may be rotatable around the pin 145. The locking mechanism 140 may be assembled together with the opening 130 by inserting the pin 145 into the recess 135. The presence of the displacement of the first and second latches 144a and 144b relative to each other under the action of an elastic force allows you to further guarantee a reliable connection between first and second components of the respirator. Returning to its original position after connecting the components of the respirator, under the action of the elastic force, the retainers remain in the locking position, all the while in mesh with the locking element 166, until the user deliberately disconnects the components of the respirator.

The locking actuator 146 in this embodiment includes two free ends 146a and 146b of the levers, acting as the latches 144a and 144b. In such embodiments, the first and second levers can intersect in close proximity to their free ends, providing an additional reinforcing effect in the drive mechanism. The locking mechanism 140 may operate as follows. When at least one, and preferably both, free ends 146a and 146b are exerted in the direction of the opposite free end, indicated by arrows F in FIG. 2a, the latches 144a and 144b are extended apart from the first axial passage 134. Once the latches 144a and 144b are disengaged from the locking element 166, the second respirator component 180 can be disengaged from the first respirator component 120. Conversely, when no force is applied to the drive element 146 or the applied force is insufficient to disengage the latches 144a, 144b with one or more locking elements 166, one or more latches is held by one or more locking elements, thereby preventing the first component 120 from exiting respirator meshing with the second component 180 of the respirator.

One or more components of the locking mechanism in accordance with the present invention may be made of polymeric materials, resins, metals, or combinations thereof, or may include such materials. In some embodiments, the locking mechanism may be made of thermoplastic resins, for example, polycarbonate, nylon, polybutylene terephthalate, polypropylene or acrylonitrile butadiene styrene, or may include such materials. In some embodiments, it may be preferable to manufacture one or more components, for example, one or more retainers and / or an elastic element, from a metal, such as spring steel, in order to reduce the size of the component.

In FIG. 3A shows an exploded view of an assembly 200 in accordance with yet another embodiment of the present invention. In FIG. 3B is a rear view of the same respirator assembly 200 for better display of elements that are not visible in FIG. 3A. The respirator assembly 200 includes a first respirator component 220 and a second respirator component 280. In this embodiment, the first respirator component 220 includes an opening 230 for releasably connecting the first respirator component 220 to the second respirator component 280. The opening 230 includes a receiving surface 232 with a first axial passage 234 disposed therein. On the receiving surface 232 there is a first protrusion 236, the configuration and size of which is such that it encompasses the first axial passage 234. In addition to this or as an alternative, the receiving surface 232 may have a recess located around the first axial passage.

In this embodiment, the second respirator component 280 includes an opening 260 for releasably connecting the second respirator component 280 to the first respirator component 220. The aperture 260 includes a second axial passage 262, the configuration and dimensions of which allow fluid communication with the first axial passage 234 of the first respirator component 220 when the second respirator component 280 is attached to the first respirator component 220. The configuration and dimensions of the second protrusion 264 are such that it spans the second axial passage 262. In some embodiments, the configuration of the first protrusion 236 is such that it can be received by the second protrusion 264, which has a generally annular shape.

Each of the components of the respirator - the first and second - contain at least one mating element that prevents rotation, located in close proximity to the first and second protrusions of an annular shape, respectively. The second respirator component 280 includes at least one locking element 266, which may be located on the second protrusion 264, shown as an annular area around the second axial passage 262. The opening of the second respirator component 280 may also include a sealing element 268, which may be a beveled surface located on the outermost surface of the second protrusion 264. In addition to this or as an alternative, the opening 230 of the first respirator component 220 may include a sealing element, For example gland similar to that described above and illustrated in FIG. 2D. An oil seal may be located on the receiving surface 232 of the first respirator component 220.

The respirator assembly 200 further includes a locking mechanism 240. In this embodiment, the locking mechanism 240 is attached to the first respirator component 220. The locking mechanism 240 includes an elastic element 242, which in this embodiment has an arcuate shape. The first and second latches 244a and 244b protrude inward toward the first axial passage 234 when the locking mechanism 240 is assembled with the first respirator component so that they engage with at least one retaining element 266, thereby preventing the first respirator component 220 from being disconnected from second component 240 respirator. The first latch 244a is located on one side of the axial passage 234, while the second latch 244b is located on the other side of the axial passage 234, preferably opposite the first latch 244a.

One or both of the retainers 244a and 244b may have an arcuate shape in which they bend around the first axial passage 234, as well as an annular protrusion 236 (if any). Each of the latches 244a and 244b comprises a lever having a first free end 246a ₁ and 246b _1, respectively, and a second free end 246a ₂ and 246b _2, respectively. The first and second arms can intersect proximally with respect to the first free ends, similar to the embodiment in FIG. 2A-2C, and the first free ends can act as a drive element 246.

In this embodiment, the levers of the latches 244a and 244b are connected to each other by means of an elastic element 242, preferably located in close proximity to the second free ends 246a ₂ and 246b ₂ . The elastic element 242 may be a separate part attached to the levers, or it can be made integral with the levers. Being sufficiently flexible, the resilient member 242 allows the latches 244a and 244b to bend and move far enough away from the first axial passage 234 of the first respirator component 220 by applying force to its actuating member 246, as a result of which the locking mechanism 240 can be disengaged from the locking member 266 the second component 280 of the respirator. On the other hand, the resilient member 242 must have sufficient resilience to return to its original position after relieving the force. The second free ends 246a ₂ and 246b ₂ can be connected to each other, for example, due to the presence in each of these second free ends of the hole, the configuration of which ensures reception and retention of the pin 235 of the first respirator component 220 therein. That is, the first and second levers can be made to rotate about an axis 245.

The locking mechanism 240 may operate similarly to the locking mechanism 140. In particular, when at least one, and preferably both of the first free ends 246a ₁ and 246b _{1 are} applied in the direction of the opposite first free end, as shown by the arrows F in FIG. 3A, the latches 244a and 244b extend apart from the first axial passage 234. Once the latches 244a and 244b are disengaged from the locking member 266, the second respirator component 280 can be disengaged from the first respirator component 220. Conversely, when no force is applied to the drive member 246 or the applied force is insufficient to disengage the latches 244a, 244b with one or more locking elements 266, one or more latches is held by one or more locking elements, thereby preventing the first component 220 from exiting respirator out of engagement with the second component 280 of the respirator.

The opening may further include channels 238a and 238b, the configuration of which provides reception and retention of the latches 244a and 244b, respectively. To attach the locking mechanism 240 to the opening 230, it is necessary to insert the pin 235 into the holes of the second free ends 246a ₂ and 246b _{2 of the} latches 244a and 244b of the locking mechanism 240 and insert the latches 244a and 244b into the channels 238a and 238b. To facilitate installation and ensure that the latches 244a and 244b are in the correct position, protrusions 237 and 239 may be located on the opening 230.

In FIG. 4 shows an exploded view of a respirator assembly 300 in accordance with yet another embodiment of the present invention. The respirator assembly 300 includes a first respirator component 320 and a second respirator component 380. In this embodiment, the first respirator component 320 includes an opening 330 for releasably connecting the first respirator component 320 to the second respirator component 380. The opening 330 includes a receiving surface 332 with a first axial passage 334 located therein. On the receiving surface 332 there is a first protrusion 336, the configuration and size of which is such that it covers the first axial passage 334. The second respirator component 380 includes an opening 360 for releasably connecting the second component 380 respirators to the first component of 320 respirators. The aperture 360 includes a second axial passage 362, the configuration and dimensions of which allow fluid communication with the first axial passage 334 of the first respirator component 320 when the second respirator component 380 is attached to the first respirator component 320. The configuration and dimensions of the second protrusion 364 are such that it encompasses the second axial passage 362. In some embodiments, the configuration of the first protrusion 336 is such that it can be received by the second protrusion 364. The second respirator component 380 also includes at least one stop element 366.

The respirator assembly 300 further includes a locking mechanism 340 attached to the first respirator component 320. In particular, the locking mechanism 340 can be held onto the first respirator component 320 by a cap 350. The locking mechanism 340 includes first and second latches 344a and 344b protruding inwardly toward the first axial passage 334 when the locking mechanism 240 is assembled with the first respirator component, so that they engage with at least one locking member 366, thereby preventing the first respirator component 320 from detaching from the second respirator component 340. In this embodiment, the first and second clips 344a and 344b are parts of a U-shaped structure made of an elastic material. Other forms of retainers are also included in the scope of the present invention, for example a V-shape or other shape with straight sides. The first latch 344a is located on one side of the axial passage 334, while the second latch 344b is located on the other side of the axial passage 334, preferably opposite the first latch 344a. In this embodiment, each of the clips has a free end 346a and 346b, respectively.

The latches 344a and 344b are connected to each other by an elastic element 342, which completes the shown U-shaped structure. The elastic element can be attached to the levers or can be made integral with the levers. In this embodiment, the actuating element 346 (made in the form of a button) is located on one side of the locking mechanism 340, which is opposite to the side on which the free ends 346a and 346b of the latches 344a and 344b are located. The drive member 346 may be coupled to the latches via an elongated adapter 347. In the assembled state of the locking mechanism 340, the adapter 347 may be located in a channel defined by the walls 329. The free ends 346a and 346b may be configured to engage with a stop 347 that bends the latches 344a and 344b apart when a force is applied to the drive element in the direction F.

The locking mechanism 340 may work as follows. When force is applied to the drive member 346 in the direction shown by arrow F, the free ends 346a and 346b of the latches 344a and 344b are guided by the inclined sides of the stop 347 away from the first axial passage 334, and accordingly, the latches 344a and 344b are moved apart from the first axial passage 334 As soon as the latches 344a and 344b disengage from the locking member 366, the second respirator component 380 can be disengaged from the first respirator component 320. Conversely, when no force is applied to the drive member 346 or the applied force is insufficient to disengage the latches 344a, 344b with one or more locking elements 366, one or more latches is held by one or more locking elements, thereby preventing the first component 320 from exiting respirator out of engagement with the second component 380 of the respirator.

In FIG. 5 shows yet another embodiment of a respirator assembly 400 in accordance with the present invention. In this embodiment, the respirator assembly 400 includes an individual respiratory protection device operating on the principle of positive pressure. The respirator assembly 400 includes a first respirator component 420 (in this case it is a source of clean air) and a second respirator component 480 (in this case it is a headgear). The second component 480 of the respirator includes a shapeless cap 412. However, in other embodiments, the element 412 may be a shape-retaining cap or a hard hat providing shockproof protection, or may include such a cap or such a helmet. The second component 480 of the respirator further includes a head mount 414, adjustable in one or more sizes to securely fit the device on the head 416 of the user 418. The cap 412 may be sized to fit at least over the front and upper parts of the user's head, or it may fully cover the user's head.

The respirator assembly 400 may further include a duct 402, preferably shape retaining. The duct can be removably supported by a head mount 414 at several points of attachment 404. The head mount and duct can be permanently or removably fastened to each other by suitable mechanical fasteners, such as latches, clips, latches, or two-piece mechanical fasteners (for example, "Velcro" ) Air duct 402 has an inlet pipe 406 fluidly coupled to a plurality of other air pipes 407 and 408. The air supply nozzles may have one or more outlet openings, and at least some of them are located in close proximity to the face of the user 418. The cap 412 includes a visor 436 located in front of it, through which the user can see.

The inlet pipe 406 of the duct 402 is extended through the air inlet port 438 of the headgear 480 and is fluidly connected to a clean air source 420 including the breathing air source 422 itself, connected through a hose 424 to the inlet pipe 406. The air source 422 may be a vessel with compressed air suitable for breathing, an electrically driven air-purifying respirator or other source of breathing air from those known in the art. In this embodiment, the locking mechanism 440 is attached to the second respirator component 480 and detaches the first respirator component 420 from the second respirator component 480. The locking mechanism 440 may include any number or any combination of suitable elements described or shown in this application. The locking mechanism 440 is preferably located near the air inlet 406. However, in other embodiments, the locking mechanism 440 may be located elsewhere or may be attached to the first respirator component 420.

In FIG. 6 shows yet another embodiment of a respirator assembly in accordance with the present invention. In this embodiment, the respirator assembly 500 includes components of a respiratory protection device operating on the positive pressure principle. The respirator assembly 500 includes a first respirator component 520 (in this case, a turboblock) and a second respirator component 580 (in this case, a hose). A typical turbo block in its housing contains a fan, an engine driving the fan, a power source for the engine, and one or more filters. When the device is operating, the fan draws in the outside air inside the turbo block, where the air is filtered by one or more filters before being supplied to the user through a hose 580.

In this embodiment, a locking mechanism 540 is attached to the first respirator component 520 and detachably fastens the first respirator component 520 to the second respirator component 580. The locking mechanism 540 may include any number or any combination of suitable elements described or shown in this application. The locking mechanism 540 is preferably located near the air intake port 506. However, in other embodiments, the locking mechanism 540 may be located elsewhere or may be attached to the second respirator component 580.

It will be obvious to a person skilled in the art that the structures, elements, their structure, configurations and the like described in this application in various embodiments can be replaced, modified and / or used in various combinations with each other. So, for example, the locking mechanisms described in this application can be used in a variety of alternative respirator assembly assemblies. The inventors believe that all such variations and combinations are included in the scope of the present invention. Therefore, it is understood that the scope of the present invention is not limited to the specific structures described in this application, but rather, it is limited to the structures formulated in the claims and their equivalents. If there are discrepancies between this application and any document referred to, it should be guided by the contents of this application.

Claims (15)

1. An assembly of a respirator comprising:
a first respirator component comprising a receiving surface comprising a first axial passage;
a second respirator component comprising at least one retaining element and a second axial passage configured and sized to allow fluid communication with the first axial passage to permit the second respirator component to form a sealed connection to the receiving surface of the first respirator component, and
a locking mechanism attached to the first component of the respirator and containing an elastic element, first and second levers located on opposite sides of the first axial passage and having parts protruding inward towards the first axial passage, and a drive element containing one end of each of the levers: the first and the second, and the first lever crosses the second lever proximally with respect to the ends of the first and second levers;
wherein said first and second levers are adapted to engage with said at least one locking element and prevent the first respirator component from disengaging from the second respirator component; and
wherein said first and second levers are configured to disengage from the locking member and disengage the first respirator component from the second respirator component by applying force to the drive element. 2. The respirator assembly according to claim 1, characterized in that the second component of the respirator further comprises an annular protrusion, wherein the locking element is located on the annular protrusion and a sealing element is located between the receiving surface and the annular protrusion. 3. The respirator assembly according to claim 2, characterized in that the first component of the respirator further comprises an annular protrusion located on the first receiving surface and spanning the first axial passage, while the annular protrusion of the first respirator component is configured and dimensioned to enable receiving an annular protrusion of the second component of the respirator. 4. The respirator assembly according to claim 1, characterized in that the first and second components of the respirator each contain an element that prevents rotation. 5. The respirator assembly according to claim 3, characterized in that the first and second components of the respirator each contain a mating anti-rotation element located in close proximity to the first and second annular protrusions, respectively. 6. The respirator assembly according to claim 1, characterized in that the retaining element comprises a protrusion, recess, or a combination thereof. 7. An assembly of a respirator comprising:
the first component of the respirator having an opening for detachable connection of the first component of the respirator to the second component of the respirator, wherein the opening contains a receiving surface comprising a first axial passage and a fixing mechanism attached thereto, the fixing mechanism comprising an elastic element, first and second levers located on opposite sides of the first axial passage and having parts protruding inward towards the first axial passage, and a drive element containing one end of each of levers: the first and second, and the first lever crosses the second lever proximally with respect to the ends of the first and second levers,
wherein said first and second levers are biased away from the first axial passage by applying force to the drive element. 8. The respirator assembly according to claim 7, characterized in that the opening further comprises an annular protrusion located on the first receiving surface and covering the first axial passage. 9. The respirator assembly according to claim 8, characterized in that the opening further comprises at least one tide located in close proximity to the annular protrusion. 10. The respirator assembly according to claim 7, characterized in that the opening further comprises a recess covering the first axial passage. 11. Respirator assembly according to claim 7, characterized in that the flexible element comprises a flexible bracket having two open ends, and the first and second levers comprise first and second opposite sides of the bracket located proximally to the open ends of the bracket. 12. The respirator assembly according to claim 7, characterized in that the drive element comprises a button. 13. An assembly of a respirator comprising:
the first component of the respirator containing an opening for detachable attachment of the first component of the respirator to the second component of the respirator, wherein the opening contains a receiving surface comprising a first axial passage and a fixing mechanism attached thereto, while the locking mechanism comprises an elastic element, at least one latch protruding inward towards the first axial passage, and a locking drive element,
however, when a force is applied to the drive element, said at least one lock can be displaced away from the first axial passage,
wherein the locking mechanism comprises first and second levers located on opposite sides of the first axial passage and having parts protruding inward toward the first axial passage,
while the drive element contains one end of each of the levers: the first and second, and
wherein the first and second levers are rotatable around the pin. 14. The respirator assembly according to claim 13, characterized in that the elastic flexible element has an arcuate shape. 15. An assembly of a respirator comprising:
the first component of the respirator containing an opening for detachable attachment of the first component of the respirator to the second component of the respirator, wherein the opening contains a receiving surface comprising a first axial passage and a fixing mechanism attached thereto, while the locking mechanism comprises an elastic element, at least one latch protruding inward towards the first axial passage, and a locking drive element,
however, when a force is applied to the drive element, said at least one latch is movable away from the first axial passage,
wherein the locking mechanism comprises first and second levers located on opposite sides of the first axial passage and having parts protruding inward toward the first axial passage,
while the drive element contains one end of each of the levers: the first and second, and
wherein the first lever crosses the second lever proximally with respect to the ends of the first and second levers.

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