DE2930858A1 - INFLATING DEVICE, EXAMPLE FOR LIFE VEST - Google Patents

Description

Mr. Glenn H. MACKAL Buena Vista Drive
Ringwood. / New Jersey 07 ^ 56 USA

Inflation device, e.g. for life jackets

The invention relates to a manually and automatically operating inflation device, for example for life jackets, with a housing of a pressurized gas-filled capsule, a pull cord for manual operation, one for the capsule Relatively adjustable bolt for opening the capsule, a locking mechanism in the automatically working part to secure a distance between the piercing bolt and the capsule in the bolt position and with a tensionable Compression spring in the automatically operating part to effect the relative movement of the piercing pin and the capsule in the Operating position of the device. The inflator should be operable both automatically and manually be. The automatic actuation should be when touched

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take place with water, as occurs when a life jacket with a designed according to the invention Airmen carrying an inflator, using an emergency waterway or jumping with a parachute dives into the water.

Automatically operating inflators are already known and for example in the American patents 1,329,990, 2,894,658, 3,242,514, 3,494,506 and 3,997,079. Of these writings the show U.S. Patents 3,494,506 and 3,997,079 also have automatic inflators which can be operated manually at the same time are. When the subject of US-PS 3,494,506 are a lever operated Cam, a water sensitive automatic working mechanism and a gas capsule is provided, which is movable against a stationary needle pin. The manual operation by means of the lever-operated cam can stop the operation of the automatically operating part trigger the inflator, which is neither necessary nor desirable. In the subject matter of U.S. Patent 3,997,079 the automatically operating part of the device is also in series with the manually operated part of the Device arranged. The needle pin and part of the automatically operating part of the device are in arranged a first movable part of the housing, while another part of the automatically operating Part of the inflator is arranged in a second part of the housing and remains therein when the first

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Part of the housing is removed and the inflator is only operated by hand. This device has the disadvantage that when the first housing part is removed, the second housing part is exposed and is freely exposed to mechanical or atmospheric influences.

The invention is based on the object, avoiding the above-mentioned known devices to provide both automatically and manually actuated inflator that operates efficiently and as a separate, easily attachable accessory to a hand-operated, self-contained inflation device is trained.

The object set is achieved according to the invention with an inflation device of the type mentioned at the outset in that the automatic actuation mechanism as an additional part that can be attached later in a separate housing is arranged and that the locking mechanism is formed from a plurality of radially pivotable segments There is a sleeve which is arranged coaxially over a piston acted upon by the compression spring, that the segments have inwardly protruding teeth, which in the locking position in a matching annular groove or shoulder of the piston intervene and that around the segments an annular body preventing their radial pivoting from a through water destructible material is placed, on the outer jacket between the individual segments press clamping parts.

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The automatically actuated inflation device designed according to the invention can be used separately as an additional device traded and easily accessible by a buyer with an existing hand-operated inflator can be combined, or the automatically operated inflator can already be operated with a manually operated Inflator combined can be marketed and sold as a combination unit. It is structured in such a way that it ensures safe operation and the automatic and the arbitrary operable Part of the entire inflator cannot influence or impair one another.

Features resulting in advantageous developments of the subject matter of the invention are listed in the subclaims.

Exemplary embodiments of the subject matter of the invention are described in more detail below with reference to the accompanying drawings explained.

Show in detail:

Fig. 1 is a plan view of a first execution

example of an automatically operated inflator designed according to the invention, attached to part of a wall of an inflatable object, along with a manually operated part of the inflation device, for which the automatically operated part is designed as an additional part is;

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2 shows an end view of the housing of the automatically actuated inflator, which can be attached to the manually operated inflator, from one in FIG. 8 with the line 2-2 indicated viewing plane;

3 shows an end view of the hand-operated part of the inflation device with a viewing direction from left to right in Fig. 1 showing the end of the hand-operated part at which the end of the automatically actuatable part of the inflator shown in FIGS. 2 and 4 is set;

FIG. 4 is an end view of the one shown in FIG. 1

shown device in the direction of view from left to right in Fig. 1;

Fig. 5 is an end view of a double-slotted intermediate bolt, which with the Piercing bolt of the hand-operated part of the inflator cooperates and the one Forms part of the automatic operating mechanism;

Fig. 6 is an axial longitudinal section through the in the

Fig. 1 and 4 shown along the line 6-6 in Fig. 4, with the automatic Operating mechanism in its locking position;

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FIG. 7 shows a longitudinal section corresponding to FIG. 6

by the device upon response of the automatic operating mechanism;

Fig. 8 is an exploded view of the automatic

Inflator actuation mechanism;

Fig. 9 is an end view of the locking part of the automatic operating mechanism in the direction of view from left to right in FIG. 8;

FIG. 10 is an end view of the in FIG. 9

locking mechanism shown in the viewing direction from right to left in Fig. 8;

11 shows a partial view of FIG. 9 in an enlarged manner

Scale, with a moisture-sensitive element that holds the locking part in its Holds locked position;

Figure 12 is a plan view of a second embodiment of an inflator attached on part of a wall of an inflatable object and consisting of a manually operated part to which an automatic operating mechanism is added;

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13 shows an axial longitudinal section through the

automatic inflator actuation mechanism of Fig. 12 in their locking position;

Fig. 14 is a cross-section through the automatic

Actuator mechanism taken along line 14-14 in Figure 13;

Fig. 15 is an end view of the automatic

Actuating mechanism in the right-to-left direction in Fig. 16;

Figure 16 is a partial view, partly in pages

view and partly in the axial longitudinal section, of the combined hand-operated and automatically actuated inflator according to FIG. 12 with the parts in a position which they would after manual actuation ingest of the device;

FIG. 17 shows a diagram corresponding to FIG. 16

position with the parts in a position that they are automatically actuated occupy the inflator;

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Fig. 18 is a side view of a third embodiment

example of an inflator, arranged on part of a wall of an inflatable And composed of a hand-operated part to which an automatic operating mechanism is added is;

19 shows an axial longitudinal section through the

automatic inflator actuation mechanism of Fig. 18;

Fig. 20 is a partial illustration of the inflator

according to Fig. 18 in axial longitudinal section, with the automatic actuating mechanism in its locked position;

FIG. 21 shows a representation corresponding to FIG. 20

with the parts in a position that they can after manual actuation of the inflator take in;

FIG. 22 shows a representation corresponding to FIG. 20

with the parts in a position that they after an automatic actuation of the Occupy the inflator.

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FIGS. 1-11 thus show a first, FIGS. 12-17 a second and FIGS. 18-22 a third exemplary embodiment of an exemplary embodiment which can be operated both manually and automatically Inflator.

The first embodiment shown as a whole from FIG. 1 consists of a hand-operated inflator part 10, as is described in US Pat. No. 3,809,288 by the same applicant. The inflator part 10 is fastened to an inflatable object by means of a socket 11, generally designated by the reference numeral 11, of which part of its wall 12 is shown. A capsule 14 is screwed onto the housing 20 of the inflator part 10 _{and contains a gas under pressure, such as CO 2} , and is sealed off from the housing. The neck of the capsule is closed by means of a seal, not shown. When this seal is pierced, the gas can flow out of the capsule 14 into a chamber of the housing 20, from where it passes through the socket 11 inserted tightly into an opening 13 of the housing 20 into the object to be inflated. The capsule 14 of the manually operated inflation device 11 is pierced by pivoting a lever 15 mounted in the housing 20 by means of a pull cord 17. A cam 16 formed on the lever 15 causes the capsule seal to penetrate by means of a piercing bolt. The pull cord 17 is provided with a handle 19 on which the pull cord can be pulled.

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The automatic operating mechanism, which is similar to the manually operated Added to inflator part 10 is indicated generally by reference numeral 21. He consists of a cylindrical housing 22 from which two cheeks 24, 24 'protrude to the right in FIG. 1, which are arranged in mirror image to one another at a distance which is only slightly greater than the thickness of the housing of the hand-operated inflator part 10. FIG. shows the dimensions of the housing 20. The automatic one The actuation mechanism is connected to the housing 20 of the hand-operated inflator part 10 by means of a Pin 18 attached, the originally shorter axle pin 18 '(Fig. 3) of the hand-operated inflator part 10 replaced. The pin 18 protrudes through the holes in the cheeks 24, 24 'and through the holes in the housing 20, which are provided to accommodate the shorter axle pin 18 '. This is how the automatic actuation mechanism works 21 firmly attached to the housing 20 of the hand-operated inflator part. A mutual Adjustment movement is excluded because the flat end face 25 between the cheeks 24, 24 »of the housing 22 in closer contact with the flat end face 27 of the housing.

The housing 22 has two diametrically arranged slots 29, 29 '. The one of these slots which lies deeper after the housing 22 has been assembled with the housing 20 (FIGS. 1 and 6), takes the lever 15 on when it clockwise out of his

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position shown is pivoted into an approximate vertical position when he forms the piercing bolt a hole in the seal of the capsule 14 has driven. The lower edge 30 of the slot 29 '(Fig. 6) forms one Stop for the lever 15 in its fully swung End position.

As Fig. 6 shows, the hand-operated inflator portion is 10 provided with a piercing bolt 31, which has an end portion 32 of larger diameter with a rounded rear end face 33 on which the cam 16 acts. In the end section 32 is in an annular groove an O-ring 34 for sealing the piercing bolt 31 arranged opposite its receiving bore in the housing. The piercing bolt is in this location hole 31 can be longitudinally displaced between the position shown in FIG. 6 and the position shown in FIG. Between the front end of the end section 32 of the piercing bolt and an annular shoulder of the receiving hole for the piercing bolt A helical compression spring 35 is clamped in, which biases the piercing bolt 31 in its from Fig. evident rest position granted. In the helical compression spring 35 is a section 36 with a smaller diameter of the Piercing bolt 31 is inserted, to which the active piercing end 37 of the piercing bolt 31 is connected. The stinging 37 of the stud is in the rest position shown in Fig. 6 at a distance from the central part of a

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Sealing membrane 39, with which the in the housing 20 screwed neck of the capsule 14 is spanned. If the piercing bolt according to FIG. 7 either by hand by actuation of the inflator part 10 or by the automatic Actuating mechanism 21 is moved to the right, the piercing end 37 of the piercing bolt 31 pierces a hole in the Sealing membrane 39 and remains in this hole in any case. Because the movement of the lever 15 is clockwise is limited by the edge 30 of the slot 29 'when the inflator is operated manually, the can Cams 16 are shaped in accordance with US Pat. No. 3,809,288 and need not be curved in a circle behind the highest cam point.

The automatic operating mechanism 21 has a cross-slotted intermediate pin 40, a front circular cylindrical section 41, a rearward adjoining this section 41 flange 42 and a having rear end portion 44. The diameter of the section 41 of the intermediate pin 40 is chosen so that it fits into a bore 45 (FIGS. 3 and 6) of the housing 20 with a sliding fit. So that the intermediate pin 40 in the Bore 45 can be inserted so far that its front end 50 on the rear face 33 of the Piercing bolt 31 rests and thus the intermediate bolt 40 both against the pin 18 and the cam supporting end of the lever 15 is reciprocable,

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the intermediate bolt 40 is cross-slotted, as in FIG. 5 shows. A first slot 46, which is shorter in the axial direction, is in the front section 41 of the intermediate pin 40 formed and ends shortly before the flange 42. This slot 46 serves to accommodate the one pivot axis forming pin 18. The second slot 47 extending at right angles to the slot 46 extends in the longitudinal direction of the intermediate bolt 40 from its front end through the flange 41 through to one Place near the rear end of the intermediate bolt. However, there remains an unslotted part 49 of the rear End portion 44. The slot 47 serves to receive the rear end of the lever 15 and that carried by it Cam 16. The intermediate pin 40 is guided at its front end in the bore 45 of the housing 20. Rear End portion 44 of the intermediate pin 14 protrudes into a central bore 43 of a flange 38 of the housing part 22 of the automatic operating mechanism. The flange 41 of the intermediate bolt 40 comes into contact with the flange 38 and thus limits the backward movement of the intermediate pin 14 to the position shown in FIG.

At the rear end, the housing 22 merges into a thin-walled sleeve 51 with an external thread 52. There is one on it Cap 54 with a sleeve-shaped, one internal thread 56 having end portion 55 screwed. As can be seen from FIGS. 1 and 4, the cap 54 is on the outside in Ribbed longitudinally so that it can be more easily grasped for screwing onto the sleeve 51.

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In the one enclosed by the sleeve 51 and the cap 54 A piston, which extends in the longitudinal direction and which has a central shaft 57, is arranged concentrically in the space and a disk-shaped head 59 at the front end of the shaft 57. In the one shown in FIG In the locked position of the piston 57/59, the outer end of the shaft protrudes with play into a guide opening 60 in the end of the cap 54. In the opening 60 there are semicircular edge openings so that through the Opening 60 and the semicircular openings 61 provide access to the interior of the housing formed by the parts 51 and 54 b stands. The outer end face 58 of the shaft 57 can be provided with an identification color, so that easily it can be determined whether the automatic operating mechanism is in its locked position (Fig. 6), in which the end face 58 is in the vicinity of the outer end face of the cap 54 or is in alignment with it, Ia the actuation position (Fig. 7) of the automatic Actuating mechanism, however, the end face 58 of the shaft 57 of the piston is clearly within the openings u.id 61 at the end of the cap 54. When the piston 57/59 II is in its locking position shown in FIG is located, there is a clear gap 62 between the

> rderen end of the head 59 of the plunger 57/59 and the j! slotted portion 49 of the rear Enüabschnittes 44 dis intermediate pin 40. Thus, it is possible that the

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Piston under the driving force a spring mechanism described below a sufficient impact speed can develop after its unlocking before the head 59 on the rear end portion of the intermediate bolt meets.

In its locking position shown in FIG. 6 is the piston 57/59 by a compressed helical compression spring 66 continuously biased in the left-to-right direction. A locking mechanism 65, which is in an annular groove engages the shaft 57 of the piston, holds the piston in its locking position. The latch mechanism 65, which can be seen in detail from FIGS. 8-11, is arranged in an inner ring seat of the cap 54 and is 6 pushed over the shaft 57 of the piston.

The locking mechanism 65 shown in FIGS. 8-11 is made in a preferred embodiment from plastic material, for example from a ^{plastic material (acrylic resin) sold under the trade name 11} DeIrIn ". It consists of a short outer sleeve 69, at the rear end of which (FIG. 10) protrude inwardly several short radial supports 70 distributed at regular intervals over the circumference of the sleeve, which are formed in one piece with the outer sleeve 69. A thin radial web 71 extends from each support in the axial direction, which connects to the front edge of the outer sleeve 69 ends. Several separate, axially extending segments 72,

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which are arranged at a distance from one another in the circumferential direction are, but together form an axially slotted coaxial inner sleeve to the outer sleeve 69, are on their rear ends connected to one another and lie between successive radial supports 70. The attachment points the rear ends of the segments 72 with the radial supports 70 are denoted by the reference numeral 74. At Each segment 72 has a radially inwardly extending tooth 75 formed thereon, with a noticeable axial spacing from the fastening points 74. The annular groove 64 in the shaft of the piston has inwardly sloping edges, and the shape of the teeth 75 is adapted to the cross section of this annular groove 64, so that the teeth fit into this annular groove in the locked position of the piston, as in FIG. 6 shows.

The front ends 76 of the segments 72 lie in the axial direction in front of the front edge of the outer sleeve 69 and the Radial webs 71, as can be seen from FIG. 8. The front ends 76 of the segments 72 have a beveled one Outer edge section 77 »while the outer edges 78 located behind the inclined outer edge sections 77 of the Segments run in a straight line and in the from Fig. 6, 8-11 position together to form a circular cylinder jacket. Between the outer edges 78 of the segments and the radial inner edges of the radial webs 71 an annular gap 79.

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In the annular gap 79 a thin, sleeve-like roll of water-soluble paper is inserted, which in dry State and supported by the radial webs 71 between the radial outer edges 78 of the segments 72 has a sufficient strength to the segments in FIG. 6 can be seen To hold position against the outward force acting on it through the interaction of the sloping wall of the Annular groove 64 of the shaft 57 of the spring-loaded piston and the corresponding beveled edge of each tooth 75 occurs when the automatic operating mechanism is locked. The paper roll 80 is both under Train as well as under pressure. The tension is created by the adjacent outer edges 78 of the segments 72, and the pressure stems from the fact that the paper roll between the radial inner edges of the radial webs 71 and the two directly adjacent segments 72 is constrained.

If the inflator is immersed in water, as is the case, for example, when an aviator wearing a Mae West life jacket lands in the water, water penetrates into the interior of the housing formed by the parts 51 and 54 and softens the paper roll 80 so strongly on that the compressive force of the helical compression spring 66 can move the piston 57/59 forward so that it hits the intermediate pin 40 drives, which in turn moves the piercing bolt 31 into the position shown in FIG. When moving forward of the piston 57/59, the teeth 75 emerge from the annular groove 64 and the inner sleeve, which is through the

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Segments 72 is formed is deformed (see Fig. 7). The outer end of the shaft 57 can then freely to the teeth 75 of the segments 72 that are pushed close to the side slide by.

A second embodiment of an inflator is shown in Figures 12-17.

The inflator of the second embodiment has a longer screw connection between the body of the automatic operating mechanism and the sleeve of the cap than in the first embodiment of the Case is, whereby the cap can be installed on the housing before the helical compression spring of the automatic Operating mechanism receives a noticeable bias. This allows the device to be stored without the paper roll is exposed to a noticeable load before the object is used. The user of the Inflator can lock the automatic operating mechanism by itself. So he doesn't have to already be locked in the manufacturing facility.

The locking mechanism used in the second embodiment is arranged reversely compared with the first embodiment. The latch mechanism no longer lies against the closed end of the cap, as in the first exemplary embodiment, but is now on

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axially inner end of the sleeve-shaped end portion the cap arranged.

The locking mechanism with the ring that can be destroyed by water is exchangeable in the second embodiment. It is the only part that must be replaced after the automatic operating mechanism has been used.

There is at least one set of interlocking ribs and grooves on the locking body and housing of the automatic Actuating mechanism provided that a storage of the locking mechanism in the housing of the automatic Prevents operating mechanism upside down.

The cap, the piston and the compression spring are together as a unit by snapping a plastic cap on the outside Attached to the end of the piston skirt. When the cap is removed from the housing of the automatic operating mechanism so all these parts stay together and can be used while replacing a used locking mechanism and the installation of a new locking mechanism in the housing is not lost.

An inner end section with a reduced diameter at the inner end of the piston takes the place of the at first embodiment in the piston skirt formed groove. By using one now practically only

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One-sided limited groove allows the complete removal of the locking mechanism and a replacement of this Realize locking mechanism in the housing of the automatic operating mechanism.

Figure 12 shows a hand-operated inflator portion 110 according to applicant's U.S. Patent 3,809,288. Of the Inflator part 110 is attached to a socket 111 to an inflatable object, one of which Part of its wall 112 is shown. A capsule 14 containing pressurized gas such as COp is screw-necked into the housing 120 of the inflator part 110 screwed in and sealed against the housing. Will be a seal spanning the neck of the capsule 15 pierced, gas passes from the capsule into a chamber, from which it passes through the socket 111, which is in an opening of the housing 120 is attached, flows therethrough. Puncturing the capsule 114 using the hand-operated inflator part is by pivoting a lever by means of a pull cord 117 around a bearing pin 118 of the Housing 120 causes a cam 116 formed on the lever moves a piercing bolt and through the Seal the capsule propels. The pull cord 117 is provided with a handle 119 on which it is pulled can be.

The automatic actuation mechanism associated with the hand-operated inflator is generally similar to FIG

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Reference numeral 121 denotes. The automatic actuation mechanism has a circular cylindrical housing 122, from which two parallel cheeks 124, 124 extend to the left in FIG. 12, of which only cheek 124 in FIG. 12 can be seen. The two cheeks are arranged in mirror image to each other with a distance that is only slightly is greater than the thickness of the housing 120 of the hand-operated inflator part 110. The automatic Actuating mechanism 121 is attached to housing 120 by means of bearing pin 118 which passes through openings 128 in the cheeks and through aligned holes in the Housing 120 protrudes. The automatic actuation mechanism is held firmly and securely on the housing 120 because As in the embodiment according to FIG. 1, planar boundary surfaces of the two housings are in contact with one another come.

The housing 122 is provided with diametrically arranged slots 123, 123 ', of which the overhead slot (Fig. 13 " and 17) can accommodate the lever 115 when it moves clockwise from its rest position shown in Fig. 12 in the actuating position shown in FIG. 16 is pivoted. The top right edge of slot 123 '(Fig. 16) forms a stop for the lever 115 in its full swung operating position.

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The stud assembly of the hand-operated inflator part 110 is exactly the same as in the embodiment of FIGS. 1-11. The stud 125 can be seen from FIGS. 16 and 17. Its rear right end section I3I has a larger one Diameter and a rounded end face on which the cam 116 acts. One in a groove of the stud arranged O-ring seals the stud against its mounting hole in which it between the two end positions shown in FIGS. 16 and 17 can be moved back and forth. On the stud A helical compression spring 126 acts between the piercing bolt 125 and an annular shoulder its mounting hole is clamped. The helical compression spring causes the stud to be permanently pretensioned into the position according to FIG. 16. In the helical compression spring 126 there is a smaller diameter Section of the piercing bolt inserted, which merges into the piercing tip 127 at its front end. The end of I3I the piercing tip 127 is in the rest position at a distance in front of the central part of a sealing membrane 129, with which the neck of the capsule 11A is closed.

¥ ¥ If the stud is either manually operated (Fig. 16) or moved to the left by using the automatic actuation mechanism (Fig. 17), penetrates the piercing tip 127 of the stud the sealing membrane 129

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and remains in the hole formed, as FIGS. 16 and 17 show. As with a manual operation the lever 115 is stopped in its clockwise movement by the edge of the slot 123 ' the cam 116 has a shape according to U.S. Patent 3,809,288 have and need not run in the shape of a circular arc behind its highest point.

The automatic operating mechanism 121 has a cross-slotted intermediate pin 132, the one front (left) circular cylindrical section 34, a flange I36 in the middle part and a rear (right) Has end portion 135. The diameter of the section 134 of the intermediate pin 132 is chosen so that that it can be pushed into the longitudinal bore of the housing 120 for guidance, in which the piercing bolt 123 is longitudinally displaceable is. So that the intermediate bolt 132 can penetrate this hole so far that its front Section 134 meets the rear end of the piercing bolt 125 and that the intermediate bolt is also opposite the Hinge pin 118 and the end of the lever 115 carrying the cam can be displaced, is the intermediate pin 132 slotted crosswise. A first, axially shorter slot in the front end section of the intermediate bolt 132 ends just before the flange I36 and serves for receiving the bearing pin 118. The second, below formed at right angles to the first slot

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The longer slot extends from the front end of the intermediate bolt beyond the flange 136 into the rear end portion 135 of intermediate bolt 132, where it leaves a short unslotted bolt area. The longer slot is used to receive the rear end of the lever 115 with the cam 116. The intermediate pin 132 is with its front part in the longitudinal bore of the body 120 guided. The rear end portion 135 protrudes into a central bore of a Flange 137 of the housing part 122 of the automatic Actuating mechanism from 121. The flange I36 of the intermediate pin 132 forms a stop with the flange 137 and limits the rearward movement of the intermediate bolt to the position shown in FIG.

The housing 122 ends at the rear in a thin-walled, with an external thread 140 provided sleeve 139. On this sleeve 139 is a cap I56 with an internal thread 159 having sleeve section 157 screwed on. As can be seen from Fig. 12, the cap 156 is on their outside ribbed lengthways to make them easy to grip when screwing on and unscrewing.

Inside by the sleeve 139 and the sleeve section O limited housing space is concentrically arranged a piston which has an end portion 166 with a large diameter

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and has an inner end portion 167 of smaller diameter. The two end sections 166 and 167 of the piston merge into one another via a strongly inclined frustoconical shoulder 169. The end section and the shoulder 169 of the piston act with a locking mechanism 141 together, which in the illustrated embodiment sbeispiel the same structure as in the previous one described first embodiment has. The locking mechanism 141 is in a seat 142 in the housing part 122 arranged. The bottom of this seat is through the flange 137, its circumference through the inner wall of the sleeve 139 »which is attached to this flange connects, formed.

The locking mechanism 141 has an outer ring body 144, shown in FIG. 13, at the left end thereof a plurality of segments 145 forming a thin sleeve are attached. Each of the segments 145 carries a tooth 146. The Teeth of the segments are aligned transversely to the locking mechanism and optionally act with the shoulder 169 of the piston together. The segments 145 are in place 147 with the outer ring body 144 of the latch mechanism 141 connected. The connection point 147 and the structure of the segments 145 are chosen so that when a Movement of the piston 165 to the left (FIG. 17) by means of a helical compression spring 171, the teeth 146 of the segments radially are pushed outwards and the stronger end portion of the piston slides past them.

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As FIG. 14 shows, between two segments following one another in the circumference there is one in the axial direction extending and radially inwardly directed thin web 149 is arranged. Between the radially inner edge the webs 149 and the outer ends of the segments 145 is in a narrow annular groove 151 in the outer ring body 144 of the locking mechanism 141, a wound, water-destructible tape 150 is arranged. The coiled Paper tape 150 holds segments 145 of the latch mechanism in the position shown in Figure 13 until the inflator is immersed in water. Then the paper tape 150 disintegrates so that the segments 145 are pressed outwards and the piston can move to the left (Fig. 17) in the manner described above.

The cap 156 is provided with an end wall which forms its end and has a central through opening 161. This opening 161 is aligned with a concentric inner sleeve 162 which is formed in one piece with the cap 156 is. The helical compression spring 171 is on the inner sleeve the cap 156 pushed on and extends between a spring seat 170 on the piston, which widens at this point and the inside of the end wall 160 of the cap 156.

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The piston 165 has an axially outer end portion 172 of reduced diameter which extends through a central opening of an inwardly directed end flange of the inner sleeve 162 extends therethrough and is longitudinally displaceable therein is led. The outer end of the piston end portion 172 is provided with a head 174 which slides along the inner wall of the inner sleeve 162 and serves to the piston, the spring and the cap as Hold the unit together when the cap is unscrewed from the housing part of the automatic operating mechanism will. The head 174 has an outer diameter that corresponds to the Diameter of the largest section 172 and thus also the diameter of the opening in the end flange of the inner sleeve exceeds. The head 174 can be made of a material having a color that is different from the color of the cap 156 clearly differs, so that differences in the position of the piston, as shown in FIGS. 13 and 17 can be seen, are easily recognizable from the outside.

So that the locking mechanism 141 can only be assembled in the position shown, there is at least one set of interlocking adjustment parts on the circumference of the ring body 144 of the locking mechanism and on the inner wall the sleeve 149 is formed. In the illustrated embodiment there are two sets of such interlocking adjustment parts that are diametrically opposed to each other

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are formed opposite one another, so that the locking mechanism is correctly mounted in the sleeve by turning it by a maximum of 180 ° in relation to the sleeve. Every sentence the cooperating adjustment parts has a narrow groove 151 and a wide groove 152 on Perimeter of the outer ring body 144 and a narrow web 154 and a wide web 155 on the inner wall of the sleeve 139. The narrow web 154 must therefore be in the narrow groove 151 and the wide web 155 must fit into the wide groove 152.

The axial lengths of the threads on the sleeves 139 and 157 are chosen so that the cap 156 on the sleeve in Screw approach can be brought without the helical compression spring I7I is already tensioned and that water sensitive tape 150 is exposed to a noticeable load. The I7I helical compression spring developed when fully compressed to place piston 166 in a locking position, a compressive force, which is dimensioned so that the automatic operating mechanism can be screwed on by one person the cap I56 on the housing up to one of Fig. I3 apparent position is easy to lock.

After an automatic actuation of the inflator, as shown in FIG. 17, the used locking mechanism 141 from the automatic operating mechanism

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can be easily removed by unscrewing the cap. The cap, the piston and the helical compression spring are then detachable as a unit from the housing of the automatic actuation device. Only the locking mechanism has to be replaced 141, whereupon the cap, the piston and the helical compression spring are put back together on the end of the sleeve of the housing part 122 are screwed on so far that the threads interlock.

FIGS. 18 to 22 show a third embodiment of an inflator.

It consists of a hand-operated inflator portion 210 according to applicant's US Pat. No. 3,809,288. The inflator part 210 is connected by means of a holder 211 to an inflatable object, a part of its wall 212 of which is shown. A capsule 214 filled with pressurized gas, such as CO ₂ *, is arranged inside the hollow main housing 224. The main housing is attached to and sealed against the housing 220 of the hand-operated inflator part 210 in the manner described below. The neck of the capsule 14 is again covered with a pierceable sealing membrane, after which the gas can flow out into the housing 22 and further through the holder 211 after it has been pierced. The holder 211 is inserted tightly into an opening 213 of the housing 220. The penetration of the sealing membrane of the capsule 214 by hand is carried out by pivoting a on a bearing pin 218 in the housing

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mounted lever 215 is effected by means of a pull cord 217. A cam formed integrally with lever 215 moves a piercing bolt against the sealing membrane. The pull cord 217 is provided with a handle 219, with which the rip cord can be pulled, whereby a breakable safety pin 221 is broken through aligned holes in the housing 220 and in the lever 215 is passed. The manual operation of the The inflation device can be seen from FIG. 21, which shows the lever 215 in the pivoted-out state. Here the automatic actuation mechanism for moving the capsule remains locked against a bolt and ineffective.

The automatic actuation mechanism 222 consists of the essentially of a main housing 224 which is hollow cylindrical over its greatest length and which is frustoconical Has portion 225 at its axially inner end. This truncated cone section 225 ends in an externally threaded collar 226. The outside diameter the capsule 214 is slightly smaller than the inner diameter of the main housing 224, so that the Can insert the capsule freely into the main housing 224. FIG. 19 shows the capsule 214 in its inserted position Position before the automatic actuation mechanism on the housing 220 of the hand-operated inflator steeply 210 is screwed on. 19 shows that the generally frustoconical neck portion

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of the capsule on a series of radially inwardly directed knobs 223 in the truncated cone section 225 of the main housing with the externally threaded neck 227 of the capsule fully within the threaded neck Collar 226 of the main housing 224 is located.

As can be seen from FIGS. 20, 21 and 22, the housing 220 of the hand-operated inflator part an internally threaded opening 229 into which the collar 226 of the main housing 224 of the automatic operating mechanism 222 can be screwed. One, in general The seal designated by the reference number 230 serves to seal the collar 226 with respect to the housing 220 and for sealing the inner end of the neck 227 of the capsule 214 from the housing 220. This seal however, allows the capsule 214 to slide in the right-to-left direction when the automatic Actuating mechanism is deployed and the capsule 214 moves against the piercing pin 235 of the inflator. Around To fulfill functions, the seal 230 has a radially outer, axially thinner ring part 233, which against the axially inner end face of the collar 226 of the main housing 224 rests when the main housing is in the internally threaded opening 229 of the housing 220 of the hand-operated inflator 210 is screwed. The seal 230 has a radially inner, axially thicker ring portion 238, the

030008/0 * 7

P 3567 - 44 -

is aligned with the end face of the neck 227 of the capsule 214 and extends in the axial direction from the ring part and is pushed into the collar 226 of the main housing. When the gas capsule 214 is moved to the left into the position shown in FIG. 22, the seal 230 seals both the main housing 224 and the gas capsule 214 from the housing 220 of the hand-operated inflator part 210, so that no gas escapes to the outside at this connection point can.

The membrane-like seal 224, which extends over the neck of the capsule, has a thinner central one Part that can be pierced by the end 241 of the piercing bolt 235. The piercing bolt 235 is axial with one inner end slidably mounted in a bore 236 of the housing 220 and there by means of an O-ring sealed. A helical compression spring 239 is pushed over the shaft 240 of the piercing bolt 235, which the widened, axially inner end portion of the stud in abutment against the cam 216 holds. The stinging 241 of the The stud is frustoconical and has a bevel Cutting edge. The cam 216 is rounded off in the shape of a circular arc behind its highest point, so that when pivoting of the lever 215 in the position shown in FIG. 21, the piercing end 241 of the piercing bolt 235 in the neck part of the Capsule 214 remains. The gas flows through from the capsule

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the annular gap between the inner edge of the Seal 224 incised hole and the side surfaces of the piercing tip 241 of the piercing bolt. Fig. 22 shows the same gas discharge path.

The automatic actuation mechanism 222 includes a piston 244 with a flexible outer sealing lip for sealing against the inner wall 242 of the main housing 224. The main housing 224 is through a Cap 246 completed, which is provided with a plurality of axially extending grooves 248, the end in openings 247 which in the axial direction outside of a continuous circular cylindrical sleeve part 254 the cap. The piston 244 has an outwardly extending central shaft with a smooth circular cylindrical one Section 249 and an adjoining outer end section 250. The end section extends axially outward through an opening between three equally spaced ones extending guide parts 251 exists when the automatic operating mechanism in its from FIGS. 20 and 21 can be seen Is locked position. The stem 249/250 can be a well different from the cap 246 Color so that the locking position of the automatic operating mechanism can be easily controlled.

... 46

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The cap 246 is attached to the main housing 224 by the Snapping held by hook-like, radially outwardly directed projections 252 at the end of the main housing. the Projections 252 protrude into the openings 247 in the jacket of the cap, where they shoulders 255 at the inner ends of the openings 247 cooperate. The sleeve portion 254 fits loosely over the outer end of the main housing 224, so that water can penetrate. A not shown axial expansion of the gap between successive Projections 252 of the main housing 224 prevent foreign objects from entering the interior of the main housing. The inner end face of the piston 244 is partially spherical, so that in this end face the rounded end of capsule 214 fits. As can be seen from Fig. 19, there is the rounded outer end of the capsule 214 at some distance from the spherical end face of the locked piston 244, as long as the automatic operating mechanism in its locking position and the combination of main housing and capsule 214 is not yet on the hand-operated inflator steep 210 is mounted.

When the piston 244 is in the locking position shown in FIG. 20, there is a noticeable effect Gap between the membrane-like seal 234 Mt

... 47

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P 3567 - 47 -

2930358

of the gas capsule 214 and the piercing end 241 of the piercing bolt 235. This allows the piston 244 and the Gas capsule 214 under the influence of the spring mechanism described below after unlocking gain sufficient speed in their movement against the piercer before the piercing end of the stud 235 hits the seal 234.

In the locking position shown in FIG. 20, the piston 244 is compressed by a Helical compression spring 262 continuously biased in a right-to-left direction. The screw compression spring 262 is between a spring seat 264 of the piston 244 and a spring seat 265 of a locking mechanism 261 clamped. The locking mechanism works with an annular groove 259 of the piston section 249 together to hold the piston 244 in its locked position when the helical compression spring 262 is compressed. The locking mechanism 261 is the same as in the two embodiments described above and is mounted in an annular seat 269 of the cap 246, the outer edge of a main part 266 of the locking mechanism 261 rests against an annular shoulder 270 of the cap. The locking mechanism 261 is via the Sections 249 and 250 of piston 244 are pushed as shown in FIG.

... 48

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In a preferred embodiment, the locking mechanism 261 is made of plastic material, for example from a material sold under the brand name "Delrin ¹¹ by the company Du Pont, and has a short sleeve 271, of the rear end (FIG. 21) several evenly over the Circumferentially distributed supports protrude radially inward and are formed integrally with the sleeve 271 and the main part 266 of the locking mechanism 261. Recesses in the main part 266 facilitate the flow of water inwards to the water-sensitive part of the locking mechanism 261.

A thin, radially directed web goes from each support eus, which ends at the front in the same face as the sleeve. Several separate, axially extending Segments 275 spaced from one another in the circumferential direction are arranged and together form an axially slotted inner sleeve coaxial with the sleeve 271, are connected to each other at their rear ends and lie between successive supports. the rear ends of the segments 275 are connected to these supports. Each segment 275 has a radial inwardly extending tooth 277, which is at some distance in the axial direction from the attachment points of the Segments are formed with the supports. The annular groove in the section 249 of the piston 244 has beveled End faces, and teeth 277 have one on these

... 49

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2330358

Groove cross-section adapted shape so that they fit into this groove 259 in the locked position of the piston, as Fig. 20 shows.

The front ends of the segments 275 protrude beyond the front edges of the sleeve 271 and the webs 272, as Fig. 21 shows The front ends of the segments have beveled ends, which then merge into straight edges, which are in the rest position of the segments on a circular cylinder jacket. Between the radially outer edges of the Segments 275 and the radially inner edges of the webs there is an annular gap.

A thin, sleeve-like roll 284 made of water-soluble paper is inserted into said annular gap, the when dry, between the radially outer edges of the segments 275 through the radially inner edges of the webs 272 is clamped and has sufficient inherent rigidity to allow the segments in the in Fig. 20 against the outwardly directed position and on it by a cooperation between the inclined wall of the groove 259 of the spring-loaded piston part 249 and the correspondingly beveled Edge of each tooth 277 to hold the resulting force. The paper roll 284 is both under tension and under tension Pressure. The tension is created by its abutment against the edges of the segments 275 and the pressure is created by that the winding 284 between the radially inner edges of the webs 272 and the immediately adjacent segments is clamped.

... 50

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When the inflator is immersed in the water, the water enters the interior of the main housing 224 and weakens the paper roll 284 and dissolves it to an extent that it can no longer withstand the force of the helical compression spring 262. The helical compression spring drives the Piston 244 forwards so that it pushes the gas-filled capsule 214 against the piercing pin 241 into the position shown in FIG apparent position drives. As the piston 244 moves forward, the teeth 277 become out of the annular groove 259 moves out and deforms the ring formed by the segments 275, as FIG. 22 shows. The outer The end 250 of the piston 244 can then slide past the teeth of the segments 275 which have been pushed aside.

030008/0711

Claims (1)

Claims 1. Manually and automatically operated inflation device, for example for life jackets, with a housing, one capsule filled with pressurized gas, one pull cord for manual operation, one movable relative to the capsule Piercing bolt for opening the capsule, a locking mechanism in the automatically working part to secure a Distance between the piercing bolt and the capsule in the bolt position and with a tensionable compression spring in the automatic working part for causing the relative movement of the piercing bolt and the capsule in the actuating position of the device, characterized in that, that the automatic actuation mechanism (21, 121, 222) as a subsequently attachable additional part in one separate housing (22, 122, 224) is arranged and that the locking mechanism (65, 141, 261) consists of one a plurality of radially pivotable segments (72, 145, 275) formed sleeve, which coaxially over one of the compression spring (66, 171, 262) acted upon piston (57/59, 165, 244) is arranged that the segments inwardly protruding teeth (75, 146, 277) which in the locking position in a matching annular groove (64, 167, 259) or shoulder of the piston engage and that around the segments their radial pivoting preventing ring body (80, 150, 284) made of a water-destructible material is placed on the Press the outer jacket between the individual segments of the clamping parts (71, 149, 272). 030008/0711 P 3567 -Z- Z. inflator according to claim 1, characterized in that the locking mechanism (65, 141, 261) has an outer sleeve (69, 144, 271) with which the segments (72, 145, 275) via radial supports (eg 70) on one End of the segments are connected that the teeth (75, 146, 277) are arranged away from the radial supports and that the water-destructible ring body (80, 150, 284) surrounds the segments at least at their other end. 3. Inflator according to claim 1 and 2, characterized in that the on the destructible by water Ring body (284) from the outside pressing clamping parts from several, on the body of the locking mechanism (261) attached thin webs (272), each arranged between successive segments (275) are. 4. Aul blowing device according to one of claims 1 to 3, characterized in that the locking mechanism (65, 141, 261) with the exception of the ring body (80,150,284) is formed in one piece. 5. Inflator according to claim 4, characterized in that the locking mechanism is in one piece is molded from plastic material. 030008/0711 6. Inflator according to claim 1, characterized in that the capsule containing compressed gas (214) is housed in a housing (224), one end of which is attached to the housing (220) of the hand-operated Inflator (210) is attached and the other end of which is closed by a cap (246) that the Capsule (214) in the housing (224) is arranged to be longitudinally displaceable, that the piston (244) with a The sealing lip (245) rests against the inner wall of the housing (224) and is designed to rest against one end of the capsule is to move them against a stud (235), and that a central shaft (250) of the Piston (244) extending through a central opening of the cap (246) and the locking mechanism (261) in one Ring seat (269) of the cap (246) is arranged and interacts with the piston shaft (249/250). 7. Inflator according to claim 6, characterized in that the cap (246) openings (247) for Has entry of water to the locking mechanism (261) arranged within the cap. 8. Inflator according to one of claims 1 to 7, characterized in that it comprises parts which pushing away the capsule (214) from the housing (220) having the piercing bolt (235) in the case of manual displacement of the stud (235) in the direction of the capsule (214). 030008/0711 P 3567 - 4 - 9. inflator according to one of claims 1 to 8, characterized in that the piercing bolt (235) during the use of the automatic actuating mechanism (222) is held stationary relative to the housing (220) by a compression spring (239) that the pressurized gas-filled The capsule (214) can be loaded in the direction of the piercing bolt (235) by a prestressable compression spring (262) that the a locking mechanism which normally prevents the capsule (214) from sliding against the stud bolt (235) is held in its locking position by a water-sensitive element (284) and the locking mechanism operates independently of the manually operated inflator (210) and can be released. 10. Device according to one of claims 1 to 9, characterized characterized in that that including the capsule (214) and the automatic actuation mechanism (222) Housing coaxial to the piercing bolt (235) on the housing (220) of the manually operated inflator Stell s (210) is attached and the piercing bolt (235) by means of a manually operable pivot lever in the direction of the Capsule (214) is longitudinally displaceable. 11. Inflator according to claim 10, characterized in that the pivot lever (215) rotatable about an axle pin (218) the manually operated inflation device (210) is provided with a cam (216) which is placed on the piercing bolt (235) acts and runs in a circular arc behind the highest cam point, and that the piercing tip (241) of the piercing bolt (235) is shaped so that between the pierced hole in the capsule and the one remaining in the hole There remains a piercing gap for the gas to flow out. O30008 / 0711 12. Inflator according to claim 10, characterized in that when the automatic actuating mechanism is used (222) the cam (216) of the pivot lever (215) of the hand-operated inflator (210) one Forms stop for the piercing bolt (235). 13. Inflator according to one of claims 10 to 12, characterized in that the piercing tip (241) of the Stud (235) is designed in the form of a truncated cone which tapers towards the rear. 14. Inflator according to one of claims 1 to 13, characterized in that the automatic actuation mechanism (121) in its housing (122) has a that in the housing (120) of the hand-operated inflator part (110) longitudinally displaceable grooving bolts (125) aligned intermediate bolts (132) has, under the influence of the locking mechanism (141) and in abutment against a rear end of the The piercing bolt (125). 15. Inflator according to claim 14, characterized in that that the hand-operated inflator (110) is pivotable about a bearing pin (118), with a on the piercing bolt (125) acting cam (116) provided lever (115) and that the intermediate bolt (132) has a first longitudinal slot through which the bearing pin (118) protrudes and which has a longitudinal displacement of the intermediate pin opposite the stationary bearing pin (118). 010008/0711 16. Inflator according to claim 14 and 15, characterized characterized in that the intermediate bolt (132) has a second slot extending at right angles to the first slot Has slot in which the cam (116) carrying part of the lever (115) of the manual operating mechanism can immerse. 17. Inflator according to one of claims 14 to 16, characterized in that the housing (122) of the automatic operating mechanism (121) with the housing (120) of the manual operating mechanism (110) is connected and the intermediate bolt (132) partly in a housing (122) and partly in the other Housing (120) is guided. 18. Inflator according to one of claims 14 to 17, characterized in that in the housing (122) of the automatic triggered by the action of water Actuating mechanism (121) a piston (165) is arranged coaxially to the intermediate pin (132), which by means of a spring (171) is biased towards the intermediate pin (132), and that the locking mechanism (141) acts on the piston (165). 19. Inflator according to one of claims 14 to 18, characterized in that the backward movement of the Intermediate bolt (132) through stops (flange 137) is limited and that in the locked position of the piston (165) a gap between the facing Ends of the intermediate pin (132) and the piston (165) consists. 030008/0711 P 3567 - 7 - 20. Inflator according to one of claims 14 to 19, characterized in that the housing (122) for the automatic operating mechanism (121) at one end of the housing (120) for the manually operated inflation mechanism (110) is attached, that the cam (116) is arranged in the vicinity of one end of the housing (120) is that it has a third slot for receiving the cam (116) and the lever (115), and that the other housing (122) has one aligned with the third slot has fourth slot into which the lever (115) can dip when pivoting out. 21. Inflator according to one of claims 14 to 20, characterized in that the piercing tip (127) of the Stud (125) is frustoconical and ends in a front cutting edge with the largest! diameter of the piercing point (127), and that the fourth Slot in the housing (122) with its base as a stop for the lever (115) of the manually operated inflation mechanism (110) is used. 22. Inflator according to one of claims 14 to 21, characterized in that the housing (120) for the manually operated mechanism (110) flat with parallel mutually extending main sides is formed that the housing (122) for the automatic actuation mechanism (121) laterally overlaps the housing (120) with cheeks (124, 124 ») and at this point through the bearing pin (118), which penetrates the housing (120) and the two cheeks (124, 124), with the housing (120) connected is. 03000Ö / 0711 23. Inflator according to one of claims 14 to 22, characterized in that the housing (122) for the automatic operating mechanism (121) is sleeve-like is formed and on the housing (120) for the hand-operated mechanism (110) in the distal end a cap (156) ends that the cap (156) has a seat (142) for the locking mechanism (141), the is annular, and that the piston (165) with a central portion through the annular Latch mechanism (141) protrudes and interacts with a counter surface with it. 24. Inflator according to one of claims 14 to 23, characterized in that a helical compression spring (I7I) is provided as the spring member, which between a head part of the piston (165) and the locking mechanism (141) is arranged. 25. Inflator according to claim 24, characterized in that the annular locking mechanism on its inside has teeth (146) which engage on a shoulder (169) of the piston (165) to the piston to be held in its locking position when the helical compression spring (I7I) is tensioned. Γ.6. Inflation device according to claim 25, characterized in that that the shoulder (169) of the piston (165) is the inclined edge of an annular groove in the piston skirt. 0 3 0 0 0 8/0711 27. Inflator according to one of claims 1 to 26, characterized in that the housing (22) for the automatic actuating mechanism (21) consists of a sleeve (51) with an external thread (52) on which the cap (54) with a one End section (55) having internal thread (56) can be screwed on, that the concentrically arranged inside sleeve (51) and cap (54)
Piston (57/59) with a free end nearby
of the end provided with an end wall
Sleeve (51) ends so that the water-sensitive locking mechanism is arranged at the opposite end in an annular seat (67) of the sleeve (51) concentric to the shaft (57) of the piston (57/59), and that the biasing element between the cap (54) and part of the
Piston (57/59) is clamped. 28. The inflator according to claim 27, characterized in that that the capsule (14) and the piercing bolt (3Ό are arranged to be movable). 29. Inflator according to claim 27 and / or 28,
characterized in that the locking mechanism (65) has an outer sleeve (69) which is arranged concentrically within the cap (54) and on the outer sleeve (69) and on the end portion (55) of the cap (54) axially extending grooves and matching webs are formed which prevent the locking mechanism from being pushed in the wrong way into the housing (22). ... 10 030008/0711 P 3567 - 10 - 30. Inflator according to one of claims 27 to 29, characterized in that the length of the sleeve (51), of the end section (55) of the cap (54), the helical compression spring (66) and the external thread (52) and the Internal thread (56) are dimensioned so that the sleeve (51) and cap (54) are already in threaded engagement with one another can be brought before the helical compression spring (66) through the screwed-on cap Experiences bias. 31. Inflator according to one of claims 27 to 30, characterized in that the piston (57/59) has a Head (59) with a larger diameter and a shaft (57) that the piston in its shaft (57) a with the locking mechanism (65) cooperating shoulder, and that the piston with an end portion can be pushed into the locking mechanism or moved out of it, depending on whether the The locking mechanism is in its locking position or in its release position. 32. Inflator according to one of claims 27 to 31, characterized in that the locking mechanism (65) has an annular body which can be pushed onto the free end of the piston shaft (57) and which consists of Axially extending segments (72) is formed which have teeth (75) on their inside with which they engage on the shoulder of the piston shaft (57) in the locked position, and that the segments bendable in the axial direction and normally from a ring (coil 80) made of water-destructible material are enclosed, which holds the teeth (75) in engagement with the shoulder of the piston shaft (57). ... 11 0-50000 / 0711 P 3567 - 11 - 33. Inflator according to one of claims 27 to 32, characterized in that the piercing bolt (31) in the Housing (20) for the manual operating mechanism (10) is mounted, with which the compressed gas-containing Capsule (14) is firmly connected, and that the automatic actuation mechanism (21) with the locking mechanism (65) is arranged in a separate housing (22) which can be releasably attached to the first-mentioned housing (20). 34. Inflator according to one of claims 1 to 33 »characterized in that the manually operated Mechanism (10) and the automatic actuation mechanism (21) can be actuated independently of one another. 35. Inflator according to one of claims 27 to 34, characterized in that the helical compression spring (35) is pushed over the outer end of the piston shaft (57) and between the cap (54) and the head (59) of the Piston is clamped, that the piston is mounted longitudinally displaceably in the cap and that the bearing arrangement is chosen so that the piston (57/59), helical compression spring (66) and cap (54) when Unscrewing the cap from the sleeve (51) remain held together. ... 12 050008/0711 36. Inflator according to claim 35, characterized in that the bearing arrangement for the piston (57/59) in the cap (54) an inwardly protruding sleeve-like body which is attached to the end face of the cap (54) is formed, and an inner flange with a central guide opening (60) at the axially inner end of the annular body, and that the axially outer end of the piston shaft (57) is mounted in the central guide opening (60) of the inner flange and with a guide part is provided, the outer diameter of which is larger than the diameter of the guide opening, so that the piston (57/59), the helical compression spring (66) and the cap are held together when the cap is unscrewed. 37. Inflator according to claim 36, characterized in that the guide body is separate from the piston and is designed so that it can be retrofitted. ... 13 0300ÖÖ / Ö711