DE2160884A1 - Impact test machine with pneumatic drive - Google Patents

Description

DR. HANS ULRICH MAY D 8 MÖNCHEN 2, OTTOSTRASSE 1 a TELEGRAMS: MAYPATENT MUNICH

TELEPHONE CO8113 693682

CP 404/1011 Munich, the -8. Dec J97f

Dr-M./ro

B 3842.3 PG

Commissariat ä L * Energie Atomique, in Paris / France

Test hammer mechanism with pneumatic drive

The invention relates to an impact test mechanism with a pneumatic drive, which is used to generate mechanical shocks acting on a specimen in the course of tests, the generated Shock waves have a variable amplitude and strength and in particular a sawtooth profile with an initial peak or very steep acceleration sfront and subsequent slow deceleration, possibly straight, or a more complicated rectangular, trapezoidal, semi-sinusoidal or other profile.

Known test hammer mechanisms generally consist of a plate, which carries the sample to be examined, is guided by one or more vertical columns and in free fall or according to a another law of acceleration falls on an anvil, the "impactor" or "Prall-Bock" is called and its shape accordingly the profile of the shock wave to be generated is selected. The commonly used impact blocks can be made of a suitable elastic Be made materially, a hydraulic or a pneumatic one

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Have compression or experience plastic deformation. The known test hammer mechanisms, however, have several disadvantages on, in particular, they require a considerable height of fall, vas a takes up excessive space. On the other hand, the sample itself cannot have too large dimensions, since the upper part of the The retaining plate is not completely free from the guide pillars. After all, considerable transverse forces arise in such striking mechanisms, if the center of gravity of the moving part is not strictly in the axis of the striking mechanism. From these different For reasons, the known impact test mechanisms are difficult to use for generating variable shock wave profiles, in particular sawtooth profiles with a very steep initial front, which is an air or Underwater shock wave or a shock on materials more changeable Hardness, such as concrete, a floor, water, etc. simulated.

The invention now provides a test impact mechanism with pneumatic Drive created which overcomes these disadvantages · This purpose is served by a test hammer mechanism with pneumatic drive, which is a has movable arrangement, which consists of a hollow cylinder, one end plate of which is a holding plate for a to under searching sample forms and through its other end plate the rod of a displaceable in the hollow cylinder and two separate therein Inner chambers of depending on the position of the piston in the cylinder in reverse bounding variable volume Piston is guided, which is characterized according to the invention by a housing which guides the movable arrangement during displacement with a stop for the end of the piston rod and with one located outside the cylinder, coaxial with it Inner sleeve, against which a on the outer wall of the cylinder

or collar see, to the cylinder axis perpendicular annular bead / rests, wherein

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this annular bead with the fixed housing and the inner sleeve delimits two outer chambers lying outside the cylinder, the volume of which changes according to the displacement of the movable arrangement, and is further characterized by a device which supplies the inner and outer chambers with a pneumatic working medium having different pressures, and means for generating a sudden change in pressure in one of the outer chambers to effect the rapid displacement of the movable assembly.

In a preferred embodiment of the invention, the displaceable Piston calibrated bores, which are provided in the hollow cylinder, on one side and the other of this piston connect the two inner chambers with each other. In other modified embodiments, the by the sliding Piston leading connecting bores have a controllable cross section or can be closed.

Further details of a test hammer mechanism according to the invention, its mode of operation and advantages emerge from the following explanatory description of an exemplary embodiment with reference to FIG the attached single figure, which shows such a machine in longitudinal section.

As can be seen from this figure, the impact test mechanism in the The main thing is a fixed housing 1, which consists of a lateral annular body 2 of substantially cylindrical as a whole Form consists of two at its upper and lower ends

is

End plates 3 and 4 closed on the fixed housing are attached by means of Scliraubbolzen 5. The top end plate 3 v ~ -is a central bore 6 in which a hollow cylinder 7 is free

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can be moved into the interior of the housing. This hollow cylinder 7 consists of a cylindrical sleeve 8, which at its upper and lower end portions by two closure plates or plugs 9 or 10 is closed, which are screwed into threads 11 and 12 of the sleeve 8. Also are between the different parts of the hollow cylinder ring seals 13 and 14 are provided to him normally to be sealed against the environment. The hollow cylinder 7 is guided with respect to the housing 1 by bearings, one of which from the edge of the central bore 6 provided with a sliding seal 15 and the second from an annular bead 16 of the housing ring 2 and a same sliding seal 17 arranged therein is formed.

According to the invention counteracts the hollow cylinder 7 having disposed in its interior displaceable piston 18 together, on the one hand, formed a provided on its outer surface with an annular seal 20 the piston head through the densely inside the sleeve 8 between the stopper 9 and 10 two mutually sealed chambers and on the other hand has a piston rod 21 which is guided through a bore 22, provided with an annular seal 23, of the closure plate 10 of the hollow cylinder. The lower end 24 of the piston rod 21 is formed so that it is formed with a projecting collar formed in the end plate 4

25 cooperates in the displacement of the cylinder 7 as a Fixed stop for the piston rod is used. The piston 18 separates so the interior of the hollow cylinder 7 in two adjacent chambers

26 or 27, the volumes of which vary in the opposite sense (complementary) according to the displacement of the piston 18 relative to the cylinder changes. Finally, in the embodiment shown, bores 28 are provided in the piston 18, whereby the chamber 26

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with the chamber 27 is in communication. However, the volume of the chamber 26 always remains considerably less than the volume of the chamber 27 * Bs. It should be noted that in other modified designs, as explained below, the calibrated bores 28 can be designed so that their cross-section can be changed as desired , or that they can also be partially or completely closed.

Outside the hollow cylinder 7, the stationary housing 1 is covered a sleeve 29 coaxial to the hollow cylinder, which is fastened by a thread 30 to the inner wall of the ring 2, so that it with this forms a cavity 31 which drives the piston 18 which is made up of the hollow cylinder 7 and the piston 18 which is displaceable therein moving part of the test hammer mechanism. In the outer wall the sleeve 8 is a perpendicular to the cylinder axis extending annular collar 32 is provided with a against the inner surface of the coaxial sleeve 29 pressing sliding seal 33 is provided. In this way are through the annular collar 32 between the outer surface the sleeve 8, the sleeve 29 and the ring 2 two further, separate chambers 34 and 35 are formed, which against each other sealed and arranged outside the hollow cylinder 7 opposite the chambers 26 and 27 located in its interior. the Chamber 34 is connected by a channel 36 through the ring 2 to a valve 37, whereby in this chamber a desired amount a pressurized gaseous working medium can be introduced. Likewise, the chamber 35 and thus above the upper edge of the sleeve 29 communicating cavity 31 through a channel 38 connected to a valve 39, whereby also a suitable pressure of pressure medium can be generated in this chamber and in this cavity.

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Finally, the outer chamber 34 stands with the inner chamber 27 of the hollow cylinder 7 through a bore 40 of very small diameter in connection, and the outer chamber 34 can suddenly sventil 41 of a considerable passage cross-section through a quick opening connected to the outside atmosphere.

The described Prüfschlagverk works as follows: When the valve 41 is closed, the chamber 34 through the valve 37 and the channel 36 and from there through the connecting bore 40 and the bores 28, the inner chambers 26 and 27 filled with a pressurized working medium. In chambers 26, 27 and

34 there is a certain pressure P _Q. Correspondingly, through the valve 39 and the channel 38, the cavity 31 and the associated outer chamber 35 are filled with the same working medium, the pressure P _{1 of which,} however, is lower than P _Q. Among these Conditions and because of the higher pressure P ₀ in the chamber 34 compared to the pressure P ₁ in the chamber 35, the hollow cylinder 7 is pressed upward in the drawing until the annular collar 32 strikes the underside of the end plate 3 closing the fixed housing 1. Furthermore the piston 18 is pressed against the closure plate 10 of the hollow cylinder, since the pressure P ₀ prevailing in the chamber 27 affects the entire surface of the piston head 19, while the same pressure in the chamber 26 only decreases by the cross-section of the piston rod 21 Area contrary to virkt.

After the Prüfschlagverk is ready for operation, the On top of the closure plate 9 of the hollow cylinder 7, a sample A to be tested is arranged, which can be fastened directly to this plate or carried by a holder (not shown), which is itself attached to the cylinder.

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In the following operating phase, the chamber 34 is emptied very quickly by suddenly opening the valve 41. The pressure P- acting on the upper side of the annular collar 32 provided on the outer surface of the sleeve 8 acts on the hollow cylinder and immediately drives it downward _{with respect to the stationary housing 1 at a high speed V 0.} It should be noted that the pressure Pq prevailing in the chamber 27 cannot drop rapidly enough to the pressure prevailing in the chamber 34 because of the very small diameter of the connecting bore 40. During the downward movement of the hollow cylinder 7 under the specified conditions, the piston rod 21 of the piston 18 strikes at a certain point in time against the collar 25 of the lower end plate 4 of the stationary housing 1, which forms a stop for it. As a result of inertia, the hollow cylinder 7 and thus the sample A carried by its upper closure plate 9 continue their movement, whereby the volume of the chamber 26 increases and that of the chamber 27 decreases accordingly. Through the connecting bores 28 leading through the head 19 of the piston 18, the working medium contained in the chamber 27 can now increasingly fill the chamber 26 and generate an increasing pressure P · therein. This pressure P 'acts against the lower closure plate 10 of the hollow cylinder, which has a surface S · which is smaller than the area S of the piston head 19 in the chamber 27, and thus generates a force P'qS ¹ that acts on the upper closure plate 9 acting essentially constant force P _Q S is opposite.

Therefore, the resulting force P _Q S - P'qS ¹ decreases and creates a deceleration on the movable assembly:

ρ C _ pi q t

«- - ^ ^
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where M is the sum of the masses of the hollow cylinder 7 with its upper, the closure plate 9 carrying the sample A and its lower closure plate 10 and the piston 18. The speed of the movable arrangement is reduced to zero and can even be reversed.

The acceleration thus imparted to sample A shows a sawtooth profile with a starting point. With a suitable choice of the pressures P ₀ and P ₁ , this initial peak can have a very steep rise front. In addition, by choosing a suitable diameter of the bores 28 leading through the head 19 of the piston 18, the profile after the initial tip can have a substantially straight slope. It should be noted that the force producing the acceleration is reversed in all cases when the head 19 of the piston 18 no longer presses against the closure plate 10 of the cylinder, i.e. when the end 24 of the piston rod 21 against the collar 25 of the closure plate which forms a stop 4 strikes. The duration of the rise front of the acceleration profile is therefore also dependent on the rigidity of these stops. In addition, the maximum level of acceleration can be regulated simply by changing the pressure P _Q , while the duration of the profile can be regulated _{by changing the pressure P 1.}

As a result of these arrangements, the impact test mechanism according to the invention Depending on the case, complex joint profiles, in particular rectangular or trapezoidal profiles, are generated by in particular the connection bores leading through the head of the movable piston are partially or completely closed. Likewise, a semi-sinusoidal profile can be created by placing between the end of the piston rod and the end that serves as a stop Collar of the fixed housing a spring or more elastic

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Body is arranged.

Of course, the invention is not particular to the above described embodiment but also includes modifications » In particular, the movable arrangement interacting with the displaceable piston can be used solely for programming of butts with a sawtooth profile with a starting point in currently used impact testing machines. It should also be noted that the position of the test hammer mechanism is not subject to any conditions and this can be arranged both vertically and horizontally and in the latter case as a push programmer on a horizontal catapult can work.

Regardless of the particular application, the inventive Impact test machine numerous advantages. As there is no part Used with elastic or plastic deformation, the number of possible impacts is practically unlimited. The leadership of the moving Partly with respect to the stationary housing allows a little decentering of the sample and the overall load arrangement without Risk of lateral forces occurring. The drive distance of the moving part is relatively limited, but the Upper space for placing the specimen completely free of restrictions. After all, the impact velocity for a given impact is the lowest possible, since the velocity of the moving part itself changes direction during impact to have an asymmetrical profile, such as a sawtooth profile Initial tip to generate.

Finally, the impact test mechanism according to the invention can be used for numerous testing or investigation purposes, in particular for investigations on different materials, whereby the sawing

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tooth profile has the particular advantage of a constant damage potential in a very large frequency band and that of sawtooth profiles with an end tip or semi-sinusoidal Is superior to profiles. In addition, the impact test mechanism according to the invention allows actual impacts to which the examined Materials can be subjected to simulate under highly approximated conditions.

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Claims (8)

PATENT CLAIMS U .j Prüfschlagwerk rait pneumatic drive for generating mechanical shocks with variable amplitude and strength, with a movable arrangement consisting of a hollow cylinder, one of which is a closure plate for a sample to be examined and through the other closure plate the rod in the hollow cylinder displaceable and therein two inner chambers is passed through according to the position of the piston in the cylinder complementary to each other changed volumes delimiting piston, characterized by a the movable arrangement during its displacement guiding fixed housing (1) with a stop (25) for the end (24) of the Piston rod (21) which has an inner sleeve (29) which is outside the hollow cylinder and is coaxial with it, an annular collar (32) provided on the outer surface of the hollow cylinder and perpendicular to its axis, which rests against the inner sleeve (29) and with this and the fixed housing two a Outside the hollow cylinder lying outside chambers (34, 35) are limited, the volumes of which change according to the displacement of the movable arrangement (7), and characterized by devices (36, 27; 38.39; 40, 28) through which different pressures of a pneumatic working medium can be generated in the inner chambers (26, 27) and outer chambers (34, 35), as well as a device (41) for suddenly changing the pressure in one of the outer chambers (34) for the purpose of bringing about it the rapid displacement of the movable assembly. 2. Impact test mechanism according to claim 1, characterized in that the displaceable piston (19) has calibrated bores (28) which open the inside of the hollow cylinder on both sides of the piston (19 209826/069 1 connect lying two inner chambers (26,27) with each other. 3.) test impact mechanism according to claim 2, characterized in that the connecting bores leading through the displaceable piston (19) (28) have a variable cross-section or are partially or completely closed. 4.) test hammer mechanism according to one of claims 1 to 3, characterized in that that the hollow cylinder is displaced by bearings carried by the inside of the fixed housing (1) (6,16). 5.) test hammer mechanism according to one of claims 1 to 4, characterized in that that one of the outer chambers (34) lying outside the hollow cylinder with one of the inner chambers (27) through an in the Wall of the hollow cylinder (8) formed hole (40) of very small diameter is in communication. 6 «) test impact mechanism according to claim 5, characterized in that the outer chamber (34) connected to the inner chamber (27) with the ambient atmosphere through a quick opening valve (41) is connected with a large passage cross-section. 7.) Impact test mechanism according to one of claims 1 to 6, characterized in that that the inner chamber (26) through which the rod (21 of the displaceable piston goes ^ a considerably smaller volume than that of the other inner chamber (27). 8.) Impact test mechanism according to one of claims 1 to 7 »characterized in that that between the displaceable piston (19) and the stop (25) carried by the stationary housing, a spring or elastic body is attached. 209826/0691