FI61142B - DETERMINATION OF BREEDING OF MEDICINAL PRODUCTS - Google Patents

Description

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Mj lBJ (11) UTLÄGGNINGSSKRIFT ^ 2 C Patent pending 10 06 1932 ^ Patent eeddelat ^ (51) Ky.lk.3 / lnt.CI.3 B 25 B 17/12 ENGLISH I - FI N LAN D (21) P « * n «lh» k * mu * - P «* nttn» eknlng 762U62 (22) Haktmlspllvl - Arudknlngsdtg 26.08.76 (23) Alkup & lvl - Giltlgh «t * d» g 26.08.76 (41) Become Public - Bllvlt offantllg 09.03 .77

National Board of Patents and Registration .... ...... ...

'(44) Date of publication of the publication. -

Patent- OCh registerstyrelsen Ansttktn utltgd och utl.skrlften publkerad 26.02.82 (32) (33) (31) Requested privilege —Begird prlorltet 08.09.7 5

Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) P 253988U.9 (71) Hilti Aktiengesellschaft, 9 ^ + 9 ^ Schaan, Liechtenstein (LI) (72) Eugen Schilter, Zurich, Switzerland-Schweiz (CH) (7M Leitzinger Oy (5 * The present invention relates to a powder-operated bolt-setting device with a percussion piston mounted in the expansion space at least in the space between the rear firing station and the front end. wherein the silencing chambers are connected in series with the passage openings and in the flow direction the last chamber has an outlet for the gases.

Known bolt-setting devices of the quality mentioned at the beginning have sound-absorbing chambers which provide a throttling effect for the outflowing operating gases, on the one hand only low sound attenuation is achieved and on the other hand the sound-absorbing means are subjected to intense, very harmful heating when the setting device is used.

Experience has shown that in known silencing chambers, only the vortex of the gas flow takes place. Thus, for this purpose, a first tubular damping chamber operates in the direction of flow of the operating gases, into which the operating gases enter through the outlet flow openings. This damping chamber has a second damping chamber formed by a hole sleeve. Thus, the working gases flooded through the boreholes of this sleeve 2 6114 2 to enter the second damping chamber and flow from this through a bore of relatively small cross-section to the ambient air. Due to the multiple reversal of the operating gases, said vortexing takes place, which, however, provides only insufficient sound attenuation.

In addition, the known sound-absorbing chambers are designed to be relatively small with respect to the amount of exhaust gases flowing out, so that the gaseous waste of the exhaust gases will in any case block the boreholes through the exhaust gases, which are, of course, very small.

It is an object of the present invention to provide a bolt setting device having an effective silencing device which eliminates the above-mentioned drawbacks.

To solve this problem, the invention is characterized in that the sound-absorbing chambers are connected to each other by means of spacers provided with openings, the volume of the first chamber in the flow direction being three to ten times the volume of the space between the rear ignition station and the piston discharge opening.

A large first chamber relative to the amount of operating gases flowing out of the expansion space, which corresponds to e.g. seven times the working space, ensures the expansion of the gases entering at high pressure, i.e. the pressure drop. In the first chamber, the expansively expanded gases now have only a fraction of the pressure of the gases coming from the expansion space. This effectively prevents the development of sound, which is primarily dependent on gas pressure. In addition, the pressure drop also causes only a slight heating of the muffler.

Thus, in the chambers adjacent to or otherwise connected to the second chamber in the flow direction, the volume of which may be substantially smaller than in relation to the first chamber, no significant further decrease in the pressure of the gases takes place. Primarily, these chambers cause sound waves to be refracted, preventing the direct, i.e., rectilinear, exit of the gases from the first chamber to the ambient air. In this case, the cross-sectional area of the gas outlet in the last chamber must be as large as possible in order to avoid a throttling effect, so that the pressure of the gases in it corresponds approximately to 61142 atmospheric pressure. With regard to those factors, on the one hand for good sound attenuation, on the other hand for the smallest possible structure of the sound attenuation parts, it has been found to be most advantageous to provide three damping chambers in series.

In order to ensure that no gas entanglement occurs in the damping chambers associated with the first damping chamber, the cross-sectional area of the openings of the baffle arranged in the first chamber is preferably equal to or smaller than the total cross-sectional area of the openings of each subsequent baffle. In this case, the openings themselves can have an arbitrary shape, in which case it is irrelevant whether there are one or more openings in the spacers.

In order to avoid constriction of gases entering the ambient air in the flow direction from the last chamber, it is proposed according to the invention that the cross-sectional area of the outlet opening of the last chamber is two to ten times the cross-sectional area of the spacer fitted to the first chamber.

In order to ensure that the gases from the first chamber could not flow in a straight line into the free space, in contrast, the openings of the adjacent spacers have been moved in the projection relative to each other. This results in a multiple change of direction of the gas flow from one chamber to another, which contributes significantly to the damping effect in the immediate area of the discharge opening.

The invention will now be explained in more detail with reference to an exemplary drawing.

The bolt setting device shown is in the striking position. It comprises a housing 1, which is mounted axially displaceably in the piston guide 2 through the housing of the injected pin Ia and the piston guide two twisted-high all 2a clamped between the compression spring 3 ensures that the piston guide 2 is set when the device is separated from the fixing material 4 is moved forward in the housing 1, ie. in the direction of impact and as a result, the powder charge 6 in the cartridge housing 5 comes out of the range of the impactor 7. Other parts of the ignition mechanism, such as a return spring for the striker 7, are known per se and are not shown here for simplicity. The housing 1 has an ejection and insertion opening Ib for the powder charge 6. A piston 8 is sealed and displaceably mounted on the piston guide 4 61142 to strike the bolt 9 into the fastening material 4. In the operating position shown, the piston 8 just begins to release the discharge opening 2b of the piston guide 2. The operating gases compressed into the working space 2c behind the percussion piston 8 can then flow through the discharge opening 2b into the first damping chamber 10a of the substantially tubular damping body 10 and expand there. In the example shown, the volume of the first damping chamber 10a is approximately five times the volume of the working space 2c behind the percussion piston 8. After the pressure drop of the gases in the first damping chamber 10a, they pass through the central opening 11a in the spacer 11 to the second damping chamber 10b. In this case, the gases meet the second spacer plate 12 and since its openings 12a are made offset with respect to the opening 11a, they will change direction and rotate. The gases then enter through the openings 12a into the third damping chamber 10c, from where they repeatedly change direction through the discharge opening 13a of the cover 13 to a free space. In order to avoid any choking effect in the third damping chamber 10c, the cross-sectional area of the discharge opening 13a is considerably larger than, for example, the cross-sectional area of the central opening 11a of the spacer 11.

The damping piece 10 is suitably mounted on the handle le and connected to the housing 1, for example by a threaded connection.

In principle, it is possible, without interfering with the damping effect, to form the damping body in other ways as well and to connect it, for example, to the body of the percussion device.

Claims (3)

5,61142 A powder-operated bolt setting device having a percussion piston mounted in the expansion space between an axially displaceable rear ignition station and a front end station, and in the expansion space there are discharge openings at least partially in communication with at least two last muffler chambers, the muffler chambers the chamber (10c) has an outlet (13a) for gases, characterized in that the sound-absorbing chambers (10a, 10b, 10c) communicate with each other via spacers (11, 12) provided with openings (11a, 12a), whereby in the flow direction the first chamber (10a) ) is three to ten times the volume of the space (2c) between the rear ignition position and the position for releasing the discharge openings (2b) of the percussion piston (8). Positioning device according to claim 1, characterized in that the cross-sectional area of the opening (11a) of the spacer (11) arranged in the first chamber (10a) is equal to or smaller than the total cross-sectional area of the openings (12a) in each subsequent spacer (12) . Setting device according to Claim 1 or 2, characterized in that the openings (11a, 12a) of the adjacent spacer plates (11, 12) are displaced relative to one another in projection.