RU2765508C2 - Firearm silencer system - Google Patents

Abstract

FIELD: weapons and ammunition.SUBSTANCE: silencer system for firearms comprises a pipe-like casing made with possibility of mounting on a barrel of a firearm, a cone, deflectors, a gas outlet, an axial hole for a bullet. Cone is designed to deflect gases coming out of the shaft. There is an axial gap between the barrel and the streamlined cone.EFFECT: increased damping, reduced back pressure, increased service life of silencer.19 cl, 8 dwg

Description

The present invention relates to a silencer system for a firearm, with a pipe-like casing designed to be mounted on the barrel of a firearm, in which a first silencer with an axial through hole is coaxially located.

Silencers of this type are known, for example, from US 2013/0168181 A1 or from US 2014/0231168 A1 and are formed from a stack of deflecting housings. The deflecting housings have, respectively, a streamlined lower part, cone-shaped from the side of the barrel, through which a through hole passes axially, and also, either due to the presence of gaps relative to each other (US 2013/0168181 A1), or due to the presence of gaps in the walls of the housings ( US 2014/0231168 A1) - radial gas outlets. The radial gas outlets are covered by the surrounding tubular casing in the manner of pockets, so that in the direction of the shot a number of gas inlet pockets (“closed elements”) are formed, which progressively reduce the gas pressure leaving the barrel opening to dampen the pop when fired. This is realized due to the gas counterpressure created by the silencer in the weapon, which in automatic weapons can lead to increased wear of the material and, in the worst case, to breakage of the weapon, in addition, increased gas pressure from the ejection window, which has a very negative effect on the shooter . Powder gases irritate the eyes and respiratory apparatus of the shooter, so appropriate protective equipment is required. Known designs of silencers also have the disadvantage that in the closed elements of successive pockets for reducing pressure, more and more powder deposits form over time, so that the silencer "overgrows" and the damping power deteriorates, up to the complete failure of the silencer. .

From WO 2017/151234 A2, a variant of using a meander-shaped deflector on the periphery of a radially ruptured inner tube with a through hole is known to prevent the formation of closed elements. The tubeless design, however, harms damping power.

The invention aims to provide a silencer system with improved damping power, low gas back pressure and extended service life.

This goal is achieved by means of a silencer system for firearms, with a tubular casing made with the possibility of mounting on the barrel of a firearm, in which the first silencer with an axial through hole is coaxially located, the first silencer with the formation of an intermediate first annular space is located in the tubular casing and at its end on the side of the barrel, it has a streamlined cone located with an axial clearance relative to the barrel, through which a through hole passes to deflect the gases exiting the barrel with a divergence into the annular space, which is equipped with deflectors and a gas outlet located behind them.

The silencer system in accordance with the invention hydrodynamically reveals a parallel pattern between the located inside ("first") silencer and the next silencer coaxially implemented around it, which is formed by means of deflectors in the first annular space between the first silencer and the surrounding tubular casing. The streamlined cone at the end on the side of the barrel and on the side of the inlet of the first silencer works as a distributor for the gases exiting the barrel opening. The gases exiting directly into the extension of the barrel axis pass through the through hole of the streamlined cone into the first muffler, while the gases diverging from the axis deviate from the streamlined cone into the annular space and into the deflector-silencer located there. A parallel circuit from an internal, for example, a silencer made in a chamber design and not having a closed element of the deflector-silencer reduces the back pressure for the weapon and the shooter. The axial clearance of the streamlined cone relative to the barrel forms a large-volume pressure relief chamber in a tubular casing, which, on the one hand, is a distributor for parallel connection of the first internal silencer and the external deflector-silencer, and, on the other hand, contributes to the first decrease in the pressure of the powder gases.

Due to the coaxial arrangement of the inner first silencer and the outer deflector-silencer, an extremely compact design with a short length and high damping power is revealed. At the same time, the gas flow in the outer, not having a closed element, deflector-muffler cools the first inner muffler. Since the part of the propellant gas flow located radially outside no longer enters the inner first silencer, it will grow less, while at the same time the risk of movement of the outer silencer deflector due to the passage of the flow through it is reduced, so that the service life of the entire silencer system as a whole , compared with traditional designs, increases.

The deflectors of the external muffler placed in the annular space can be made by any method known in the art, for example, in the form of meander-shaped guide plates, ribs, flaps, etc. In a first preferred embodiment of the invention, the baffles are formed by deflecting sheets arranged in the axial direction one behind the other and displaced relative to each other in the direction of the periphery, preferably deflecting sheets having the shape of an annular sector. This forms a meander-shaped gas flow in the annulus along the first muffler, which combines a sufficient level of pressure reduction with a good permeability and cooling effect.

The inner first silencer can be made by any method known in the art, as well as in the form of a "classic" chamber silencer. In accordance with a particularly preferred embodiment of the invention, the first silencer comprises, in particular, a stack of deflector housings, which have respectively cone-shaped streamlined lower parts on the side of the barrel, through which the through hole extends axially. Along the through hole, the stack of deflecting bodies forms a series of pressure reduction chambers located, respectively, in a circle around the through hole, to which, respectively, parts of the shock wave passing from the outside are supplied.

In this case, it is particularly advantageous if the streamlined lower parts are provided with gas outlets in the direction of the next deflector body, respectively, preferably of a ring of axially parallel through holes. As a result, the pressure reduction chambers formed by the deflecting housings are no longer closed elements, and due to the presence of gas outlets, respectively, part of the compressed gases pass through them, which complicates the deposition of powder deposits in the chambers and further increases the life of the silencer system.

In addition, the stack's first deflector body on the barrel side can be provided with radial gas outlets towards the annulus. As a result, the next part of the flow of propellant gases is deflected into the coaxial outer deflector-silencer, so that the back pressure is further reduced, and the cooling effect is further increased.

The streamlined cone for separating the gas between the inner and outer mufflers can be implemented in various ways. In the first variant, the streamlined lower part of the first deflecting body on the side of the shaft forms a streamlined cone itself, which reduces the cost of structural elements. In an alternative second embodiment, a separate streamlined cone is mounted on the first deflecting body from the side of the barrel, as a result of which a sharper angle of the streamlined cone can be obtained than for the streamlined lower part.

If the inner first silencer is implemented by means of a stack of deflecting bodies, then it is particularly advantageous if each deflecting body has one or more deflecting sheets on its outer periphery. As a result, the design of the silencer system acquires a modular structure. By appropriately selecting the number of deflector housings, on which the deflector plates for the outer baffle-silencer are respectively located, the most varied number of chambers, structural lengths and, therefore, damping capacities can be realized with a reduced set of structural elements.

The gas outlet of the external deflector-silencer can be carried out in a variety of ways. For example, the annular space between the inner first silencer and the tubular casing can be simply opened at the end, for example if the silencer in the tubular casing is only supported by baffles. In a preferred embodiment, the gas outlet of the first annulus may, however, also have axially parallel outlets in the end ring, which closes the annular space at the end facing away from the barrel. By appropriately sizing the outlets in the end ring, the counter pressure of the deflector-muffler can be adjusted. Alternatively or additionally, the gas outlet of the first annulus may also have axially perpendicular outlets in the tubular casing. The presence of such axially perpendicular outlets does not result in recoil of the weapon, which generally reduces the recoil of the weapon when fired.

The silencer system according to the invention can be mounted on the barrel of a firearm in a variety of ways. According to a first embodiment, the tubular casing is threaded for mounting on the barrel of a firearm, in particular when it is specified for mounting in front of a mounting system or in a mounting system on a firearm's barrel. In this case, the thread of the tubular casing is located at the opposite end of the tubular casing.

In an alternative, particularly preferred embodiment, the silencer system according to the invention is implemented as an "above-barrel" system, that is, the barrel is inserted into the silencer system to a certain extent. The annular space thus revealed between the barrel and the tubular casing can then be used in a particularly advantageous manner for the installation of a second silencer baffle.

For this purpose, in the preferred embodiment, in the tubular casing coaxially and with the formation of the second annular space, a sleeve is placed, which is located with an axial clearance relative to the first muffler, the second annular space is also equipped with deflectors and, preferably, a gas outlet located behind them. The second deflector-silencer in the second annular space is also aerodynamically connected in parallel to both other silencers, namely the first coaxial inner silencer and the first outer deflector-silencer. At the same time, the deviation of the flow of powder gases in the “above-barrel” located second deflector-muffler, that is, against the direction of the shot, reduces the recoil of the weapon.

The second deflector-silencer can, if necessary, also be made without a gas outlet, for example, if the escape of gases near the shooter's face is to be prevented. If necessary, however, in this case, too, a gas outlet can be provided, in particular in the form of an axially perpendicular outlet in the tubular casing, to ensure purging.

Preferably, in this case, the sleeve is made with the possibility of fitting onto the barrel and, at its end facing the first muffler, has a thread for fastening to the barrel, so that the “above-barrel” part with the second muffler deflector can freely rotate relative to the barrel.

Such a second baffle-silencer can, however, also be implemented in another way, in particular also without a "over-the-barrel" installation. To do this, in the preferred embodiment, in the tubular casing, coaxially and with the formation of a second annular space, a second muffler is placed, which is located on the side of the barrel of the first muffler with an axial clearance relative to it, and the second annular space is also equipped with deflectors and, preferably, a gas outlet located behind them. In this embodiment, the silencer system in accordance with the invention contains four silencers connected aerodynamically in parallel to each other, and, moreover, the first internal silencer, the first deflector-silencer surrounding it, located in front of it, the second silencer directly attached to the barrel and the second deflector surrounding it -muffler. As a result, a particularly high damping power can be achieved with a particularly low back pressure. And in this embodiment, part of the gases deflected into the second deflector-silencer and acting against the direction of the shot reduces the recoil of the weapon.

The second internal silencer can also be implemented in any manner known in the art. In accordance with a preferred embodiment, the second silencer also comprises at least one or even several, i.e. a stack of deflecting housings, so that the same structural elements can be used as for the first silencer. Thanks to this, the following modular design of the silencer system is revealed.

In all embodiments with a sleeve or an internal second silencer, around which a second deflector-silencer is implemented, the tubular casing may additionally have between the first silencer and the sleeve or between the first and second silencers - preferably a cone-shaped - dividing wall with a central hole. The additional dividing wall deflects part of the gases leaving the barrel with a divergence directly in the direction of the second muffler deflector. By means of an appropriate embodiment of the dividing wall and the size of its central opening, the gas distribution between the first silencer and the first internal silencer deflector on the one hand and the second silencer deflector on the other hand can be controlled.

An additional separating wall can also be used to support a sleeve or a second muffler on it through a pipe section slotted in the radial direction, to increase mechanical strength.

Such a support can be obtained alternatively and without the use of a dividing wall due to the fact that the sleeve or the second muffler, through the pipe section having slots in the radial direction, will rest directly on the streamlined cone of the first muffler.

By using axially perpendicular outlets in the tubular casing for the gas outlet of the first and/or second baffle-muffler, these outlets can be offset relative to the perpendiculars, respectively, in the same direction of the periphery. When fired, in this way, due to the recoil of the gases emerging from the exhaust holes, a torque is created around the longitudinal axis of the silencer system, which can be used to ensure that the threads by which the silencer system is fixed to the barrel are automatically tightened with each shot.

The invention is explained further in more detail on the basis of the embodiments presented in the attached drawings, which show the following:

fig. 1 is a first embodiment of a silencer system according to the invention, in longitudinal section,

fig. 2 shows the interior of the silencer system of FIG. 1, in perspective view,

fig. 3 shows one of the interior modules of FIG. 2, in perspective view,

fig. 4 is a cross section along the line IV-IV of the section of FIG. one,

fig. 5-8 are other embodiments of the silencer system according to the invention, respectively, in longitudinal section.

Fig. 1-4 show a first embodiment of a silencer system 1 for mounting on a firearm, of which only the barrel 2 is shown in section. The firearm can be of any type, such as a handgun or a rifle. The longitudinal axis of the silencer system 1, which is located in line with the longitudinal axis of the barrel 2, is indicated by the reference position A.

The silencer system 1 has a tubular casing 3, which is provided at the end with a thread 4 for screwing onto the corresponding mating thread on the muzzle of the barrel 2. The thread 4 can be implemented, for example, in a threaded sleeve 5, which is inserted into the end cap 6 and the end sleeve 7 tubular casing 3.

The first silencer 8 is located in the tubular casing 3 with an axial clearance d relative to the barrel 2. The silencer 8 has an axial through hole 9 for passing the bullet exiting the barrel 2. Due to the presence of an axial gap d between the silencer 8 and the barrel 2, inside the tubular casing 3, a pressure-reducing distribution chamber 10 is revealed for the gases that have escaped from the barrel 2 during firing, which are ahead of the bullet or follow it.

The muffler 8 has, in the firing direction S along its through hole 9, a succession of pressure-reducing chambers 11-15 arranged one behind the other, in which the shock wave of the propellant gases is successively reduced, which will be described in more detail below. Silencer 8 could be implemented, however, not only in the form of such a silencer with chambers, but, in principle, could be implemented for any known type of technology.

The outer periphery 16 of the silencer 8 is located with a radial clearance relative to the inner periphery 17 of the tubular casing 3, so that a first annular space 18 is formed between them. The muffler deflector 19 comprises an annular space 18, a deflector 20 located in it (see also Figs. 2 and 3) and a gas outlet located aerodynamically after the deflector 20. The gas outlet is formed in the example shown by means of axially parallel outlets 21 in the end ring 22 at the barrel-facing end of the tubular casing 3 and/or axially perpendicular outlets 23 in the tubular casing 3.

The muffler 8 at its end facing the barrel 2 is equipped with a streamlined cone 24 with a through hole 9. The streamlined cone 24 works as a distributor for gases or a shock wave exiting the barrel 2 in the pressure-reducing chamber 10 due to the fact that it contributes to the entry of the central, exiting in the direction And the axis, part of the gases into the through hole 9 and, thereby, into the silencer, and rejects the outer part of the gases coming out with expansion from the barrel 2 along the outer surface of the cone into the annular space 18 and, thereby, into the deflector-muffler 19. By means of By appropriate selection of the size of the through hole 9 in the streamlined cone 24 and the angle of the streamlined cone 24, the distribution between those gases that enter the internal silencer 8 and those gases that enter the deflector-muffler 19 can be controlled.

Fig. 2 and 3 show the construction of the muffler 8 and deflector 20 in detail. The muffler 8 is made of a stack of deflecting housings 25, which, respectively, slightly overlap each other with their edges 26 and, for example, are inserted into each other by means of a clamp connection, screwed or welded to each other. Each deflecting body 25 has a cone-shaped streamlined lower part 27 with an axially passing through hole 9 located on the side of the barrel, that is, protruding against the direction S of the shot. holes 9, annular pockets 28 (Fig. 1), in which the shock wave of gases is damped and, due to this, is gradually extinguished.

In addition, the streamlined bottoms 27 can be provided with through holes 29 for gas, respectively, in the direction of the next deflecting body 25 in the package, as a result of which the pockets 28 are no longer closed structures, but through them can pass and be cleaned penetrating through holes 29 powder gases, in order to further prevent the formation of deposits in the pockets 28 of powder deposits. The through holes 29 for gas can be implemented, for example, in the form of a ring of axially parallel through holes.

The streamlined cone 24 of the muffler 8 can be in the form of a separate structural element mounted on the first deflecting body 25 from the side of the barrel (Fig. 1, 8) or the streamlined lower part 27 of the first deflecting housing 25 from the side of the barrel directly itself forms a streamlined cone 24 (Fig. 5-7).

In addition, one or more deflector housings 25 can also be provided with radial gas through holes 30 towards the annular space 18 of the deflector-muffler 19, in particular the first deflector housing 25 from the table side, as shown in the embodiment of FIG. 5.

Instead of the modular design of the muffler 8 made in the form of a package of cases, made from separate deflecting cases 25, the muffler 8 could alternatively also be made from a solid pipe, into which the streamlined lower parts 27 are separately inserted; the end of such a pipe could then be made in the form of a streamlined cone 24.

As detailed in FIG. 2 and 3, the silencer 8 can also be used to position the deflectors 20 of the deflector-silencer 19 in the annular space 18. a plurality of deflector sheets 31, which form baffles 20. The deflector plates 31, for example, have the shape of a ring sector (in this case, respectively, more than 60°), are arranged in the direction U of the periphery one after another and, in this case, are correspondingly offset relative to each other friend. Other types of deflectors 20 are also possible, for example, in the form of a spiral, in the form of a meander and/or in the form of deflecting sheets with gaps, etc. In the example shown, on each deflector housing 25 in the first axial position there is a set of three deflecting plates 31 shaped as a sector of a ring 31 and – with an axial clearance a – in the second axial position there is a further set of three shaped sector rings in 60° deflecting sheets 31 which, respectively, in the direction U of the periphery are offset by 60° relative to the deflecting sheets 31 of the first set.

The baffles 20, for example deflecting sheets 31, can alternatively also be mounted on the inner periphery 17 of the tubular casing 3 or, as a separate part, be pushed into the annular space 18.

Fig. 4 shows that the firing directions or the J-axis of the outlets 23 of the tubular casing 3 perpendicular to the A-axis can be shifted respectively with respect to the verticals R in the (same) periphery direction U, i.e. the J-axes of the outlets 23 are respectively perpendicular gap z about axis A. The gases leaving the outlets 23 thus create a torque M on the tubular casing 3, which can be used to tighten the thread 4 to secure the muffler system 1 to the barrel 2; the silencer system 1 will therefore be automatically tightened at the same time with each shot.

Fig. 5 shows a second embodiment of a muffler system 1 for "above-barrel" mounting on the barrel 2, which opens up the possibility of installing a second muffler deflector 32. a sleeve 34 is placed, which again is located with an axial clearance d relative to the first silencer 8, to form a distribution and pressure-reducing chamber 10. The pressure-reducing chamber 10 now distributes powder gases not only to the first silencer 8 and to the first deflector-silencer 19, but also additionally also on the second deflector-muffler 32.

The second silencer deflector 32 is provided with deflectors 35 in the annular space 33, for example in the form of deflector plates similar to deflector plates 31 of the first silencer deflector 19. The second silencer deflector 32 can additionally have a gas outlet located behind the deflector 35, for example in the axially perpendicular outlets 36 in tubular casing 3. The outlets 36 may be as shown for the outlets 23 in FIG. 4 are offset relative to the perpendiculars R.

The sleeve 34 can be on its inner end facing the first silencer 8 equipped with a thread 37 for screwing onto the barrel 2. The “over-barrel” part 38 of the silencer system 1 shifted above the barrel shortens, thereby, the constructive length of the combination of the silencer system 1 and firearms. In addition, part 38 is free to rotate if sleeve 34 is designed to have a radial clearance relative to barrel 2.

Fig. 6 shows a further embodiment of a muffler system 1, similar to that of FIG. 5, however, with an additional separating wall 39 between the first muffler 8 and the bushing 34. The separating wall 39 is preferably, even if not required, cone-shaped, with a section 40 of the cone flared against the shot direction S and with a central opening 41. the wall 39 directs the outer part of the shock wave into the pressure-reducing chamber 10 towards the second deflector-silencer 32 and allows the inner part of the shock wave to pass through its opening 41 towards the first silencer 8 and the first deflector-silencer 19. Due to the appropriate selection of the size of the opening 41 and the angle of the cone 40 can be adjusted distribution ratio.

On the separating wall 39, the sleeve 34, as shown, can be supported through a pipe section 42 having slots in the radial direction. However, the pipe section 42 may also be omitted, in which case the sleeve 34 in the firing direction S ends at a distance from the dividing wall 39.

In the embodiment of FIG. 7, a second coaxial internal silencer 43 is used instead of bushing 34 to form a second annulus 33 for the second deflector-silencer 32. The second silencer 43 is positioned - forming an annular space 33 - in the firing direction S with a gap d in front of the first silencer 8, whereby again a pressure reducing chamber 10 is formed. The second muffler 43 can be a conventional muffler or - as shown in FIG. 7 - it can be carried out similarly to the first muffler 8 from the package of deflecting housings 25, but with a rotation of 180°. In the simplest case, only one single deflecting body 25 can be used here (Fig. 8).

The second silencer 43 can also - as shown in FIG. 6 for bushing 34, rest on dividing wall 39 through slotted pipe section 42, if necessary. Also in the embodiment of FIG. 7, a partition wall 39 could be used without the pipe section 42.

Fig. 8 shows a further embodiment of a muffler system 1 with a first muffler 8, a first muffler baffle 19, a second muffler 43 and a second muffler baffle 32, the second muffler 43 in this case resting directly on the streamlined body 24 of the first muffler via a slotted pipe section 42 eight.

The invention is not limited to the embodiments shown, but includes all variations, modifications and combinations that fall within the scope of the appended claims. In particular, represented respectively in the embodiments of FIG. Features 1-4, 5, 6, 7 and 8 can also be combined in various ways to form a silencer system 1.

Claims (19)

1. Silencer system for firearms with a tubular casing (3) configured to be mounted on the barrel (2) of a firearm, in which the first silencer (8) is coaxially located with an axial through hole (9), the first silencer (8) forming the intermediate first annular space (18) is located in the tubular casing (3) and at its end on the side of the shaft has a streamlined cone (24) located with an axial clearance (d) relative to the shaft (2), through which a through hole (9) passes, for deviations of the gases exiting with expansion from the barrel (2) into the annular space (18), which is equipped with deflectors (20) and a gas outlet (21, 23) located behind them, characterized in that the first muffler (8) contains a package of deflecting housings (25 ), which have, respectively, streamlined lower parts (27) tapered from the side of the barrel, through which a through hole (9) passes axially, and the streamlined lower parts (27) are provided with ha call releases (29) in the direction, respectively, of the next deflecting body (25). 2. Silencer system according to claim 1, characterized in that the baffles (20) are formed by deflecting sheets (31) arranged in the axial direction one after the other and displaced relative to each other in the direction of the periphery. 3. Silencer system according to claim 1, characterized in that each of the gas outlets (29) is made in the form of a ring of axially parallel through holes. 4. Silencer system according to claim 1, characterized in that the first deflecting body (25) of the package on the barrel side is provided with radial gas outlets (30) towards the first annulus (18). 5. Silencer system according to claim 1, characterized in that the streamlined lower part (27) of the first deflecting housing (25) on the side of the barrel forms a streamlined cone (24). 6. Silencer system according to claim 1, characterized in that a streamlined cone (24) is mounted on the first deflecting housing (25) from the side of the barrel. 7. Silencer system according to claim 1, characterized in that each deflecting body (25) has one or more deflecting sheets (31) on its outer periphery. 8. Silencer system according to claim 1, characterized in that the gas outlet of the first annular space (18) has axially parallel outlet holes (21) in the end ring (22), which closes the annular space (18) at the end facing away from the barrel. 9. Silencer system according to claim 1, characterized in that the gas outlet of the first annulus (18) has axially perpendicular outlets (23) in the tubular casing (3). 10. Silencer system according to claim 1, characterized in that the tubular casing (3) is equipped with a thread (4) for mounting on the barrel (2) of a firearm. 11. The silencer system according to claim 1, characterized in that in the tubular casing (3) coaxially and with the formation of the second annular space (33) is placed a bushing (34), which is located with an axial clearance (d) relative to the first silencer (8), moreover, the second annular space (33) is also provided with baffles (35). 12. Silencer system according to claim 11, characterized in that the sleeve (34) is designed to fit onto the barrel (2) and has a thread (37) at its end facing the first silencer (8) for fastening to the barrel (2). 13. Silencer system according to claim 1, characterized in that in the tubular casing (3) coaxially and with the formation of the second annular space (33) a second silencer (43) is placed, which is located on the side of the barrel of the first silencer (8) with an axial clearance ( d) relative to it, and the second annular space (33) is also provided with baffles (35). 14. Silencer system according to claim 13, characterized in that the second silencer (43) comprises one or more stacks of deflecting housings (25). 15. Silencer system according to claim 11 or 13, characterized in that the tubular casing (3) comprises between the first silencer (8) and the sleeve (34) or between the first silencer (8) and the second silencer (43) a separating wall (39) with central hole (41). 16. Silencer system according to claim 15, characterized in that the sleeve (34) or the second silencer (43) rests on the separating wall (39) via a radially slotted pipe section (42). 17. Silencer system according to claim 11 or 13, characterized in that the sleeve (34) or the second silencer (43) rests on the streamlined cone (24) of the first silencer (8) through a pipe section (42) slotted in the radial direction. 18. Silencer system according to claim 11 or 13, characterized in that the second annular space (33) is provided with a gas outlet (36) located after the baffles (35), and the gas outlet of the second annular space (33) has axially perpendicular outlet openings in tubular casing (3). 19. Silencer system according to claim 9, characterized in that the axially perpendicular outlets (23) of the tubular casing are offset relative to the perpendiculars (R), respectively, in the same direction (U) of the periphery.

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