IT202000026756A1 - SYSTEM FOR CARRYING OUT SHOCK TESTS, PARTICULARLY AT HIGH ACCELERATIONS - Google Patents

Description

TITLE: ?SYSTEM FOR CARRYING OUT SHOCK TESTS, PARTICULARLY AT HIGH ACCELERATIONS?

DESCRIPTION

Technical field

The present invention refers to a system for carrying out shock tests, in particular at high accelerations.

Technology background

Systems are known in the field for carrying out shock tests, for the purpose of measuring the effects of an impact on an assembly, such as a structure or an apparatus, in which these effects are due to a high acceleration caused, for example, by a? explosion, fall or collision.

An example of such a system uses low velocity impacts? in which high accelerations are used, for example having a value of about 10kG, which however operate for a reduced duration, for example for a time between 30?s and 100?s. Typically, these are systems that act by means of the fall of the assembly that you want to subject to impact, in which this fall is? possibly assisted by elastic organs.

Another example of such systems uses a gun, such as a cannon, to launch the assembly to be impacted against a surface, as if it were a projectile being fired. In this example, these systems take advantage of a higher speed? imprinted on the whole and the entity? of? impact ? significantly influenced by the surface against which the assembly is launched and, to mitigate the impact, soft areas are used by carrying out a so-called ?soft recovery?.

However, these systems are not without drawbacks to which? desirable to remedy.

For example, in such systems, the duration in which the test apparatus is subjected to the imposed acceleration? limited and ? therefore it is desirable to increase its duration.

Summary of the invention

An object of the present invention ? that of realizing a system which is of an improved type and which is capable of solving the drawbacks of the prior art.

According to the present invention this and other objects are achieved by means of a system having the technical characteristics mentioned in the annexed independent claim.

Furthermore, according to advantageous embodiments of the present invention, it is possible to increase the duration in which the system is subjected to the desired acceleration, for example up to 10ms.

? it is to be understood that the annexed claims form an integral part of the technical teachings provided herein in the detailed description which follows regarding the present invention. In particular, some preferred embodiments of the present invention which include optional technical features are defined in the attached dependent claims.

Further characteristics and advantages of the present invention will become clear from the detailed description which follows, given purely by way of non-limiting example, with particular reference to the attached drawings, summarized hereinafter.

Brief description of the drawings

Figure 1 ? a schematic view representing a block diagram referring to a system made according to an exemplary embodiment of the present invention. A technician in the sector will understand? which drawings to which ? referenced herein are not drawn to scale, instead emphasis being placed on illustrating the principles in accordance with the present invention.

For completeness, ? The following is a list of the alphanumeric references used to locate the parts, elements and components shown in the drawings summarized above, together with the relative English translation of the terms used to define such parts, elements and components.

10. System - System

12. Carrier ? Carrier

14. Together ? assembly

16. Tubular guide ? Tubular guides

18. End? ? end

20. Other end? ? Other end

22. Cavity? internal ? Inner cavity

24. Thrust tank ? Thrust tank

26. First room? First chamber

28. Second chamber? Second chamber

30. Release device - Release device

32. Return tank ? Return tank

34. Stop device ? Stop device

36. Retaining element ? Retaining element

38. Pawl element ? Paw element

Detailed description of the invention

With reference to figure 1, ? indicated as a whole with 10 a system for carrying out shock tests, in particular at high accelerations. Such a system? made in accordance with an exemplary embodiment of the present invention.

The system 10 includes a vector 12 which ? intended to house an assembly 14 to be subjected to a shock test.

Furthermore, the system 10 comprises a tubular guide 16 having a pair of ends 18 and 20. The tubular guide 16 defines a cavity? internal 22 through which ? mobile in a guided way the vector 12 between the extremities? 18 and 20.

Furthermore, the system 10 comprises a thrust tank 24 containing a thrust fluid under pressure and connected with the cavity? internal 22 near? of a? extremity? 18 of the tubular guide 16 and in a position situated upstream of the carrier 12. The thrust fluid ? capable of pushing the carrier 12 through the tubular guide 16 towards the other end? 20. In this way the vector 12 ? subjected to a thrust acceleration, suitable for simulating the effects of a shock suffered by assembly 14.

In the illustrated exemplary embodiment, the cavity? inside 22 of the tubular guide 16 ? divided by the vector 12 into two chambers, in particular, a first chamber 26 located upstream of the vector 12 and a second chamber 28 positioned downstream of the vector 12. Operationally, these chambers 26 and 28 are placed at different pressures, so as to generate the force necessary to accelerate the vector 12. In particular, the thrust tank 24 ? connected to the first chamber 26 in which the thrust fluid flows and acts. Therefore the first chamber 26 tends to expand due to the effect of the pressure of the thrust fluid which exerts the aforementioned thrust acceleration on the vector 12, particularly by pushing it through the tubular guide 16 away from the thrust tank 24.

In the illustrated exemplary embodiment, the system 10 comprises a release device 30 configured to assume a locked condition and an unlocked condition. In the locked condition, the release device 30 locks the carrier 12 in the tubular guide 16, in particular, preventing it from moving towards the other end. 20 (thus opposing the pressure exerted by the thrust fluid). In the unlocked condition, the release device 30 releases the vector 12 in the tubular guide 16, in particular allowing it to move towards the other end. 20 (therefore without opposing the pressure exerted by the thrust fluid).

In the operation of the system 10, when the release device 30 is brought from the locked condition to the unlocked condition, the pressure assumed by the thrust fluid contained in the first chamber 24 is no longer released. opposed by the release device 22. Therefore the vector 12 ? free to be accelerated to the other end? 20 due to the effect of the pressure exerted on it by the thrust fluid.

In the illustrated embodiment, the system 10 further comprises a return tank 32 containing a further pressurized return fluid. The return tank 32 ? connected with the cavity? internal 22 near? of? the other extremity? 20 of the tubular guide 16 and in a position located downstream of the vector 12. The return fluid contained in the return tank 24 has a lower pressure than that of the push fluid contained in the push tank 18. In particular, the return tank 32 ? connected to the second chamber 28 into which the return fluid flows and acts.

Operatively, the carrier 12 subjected to the greater pressure exhibited by the thrust fluid contained in the thrust tank 18 and acting in the first chamber 26 is, in a first initial phase, accelerated towards the other end. 20 of the tubular guide 16. During this initial phase, the pressure exhibited by the return fluid contained in the return tank 24 and acting in the second chamber 28 gradually increases, while the pressure exhibited by the aforementioned thrust fluid decreases accordingly. Indeed, as the vector 12 moves through the cavity? internal 22 towards the other end? 20 of the tubular guide 16, the thrust fluid expands and the pressure in the first chamber 26 decreases, while the return fluid compresses and the pressure in the second chamber 28 increases.

In a second phase, subsequent to the first initial phase, the pressure assumed by the return fluid acting in the second chamber 28 becomes higher than the pressure assumed by the thrust fluid acting in the first chamber 26. Therefore, the vector 12 is accelerated in a direction opposite to that of the initial phase, moving towards the? extremity? 18 of the tubular guide 16. In this way the vector 12 is brought back in proximity? from its initial position, near? of? end? 18.

In the illustrated embodiment, the system 10 further includes a stop device 34 configured to stop the carrier 12 in the vicinity of the of? end? 18 of the tubular guide 16 when it is pushed (and brought back) near? of? end? 18. This condition occurs as a result of the pressure in the return fluid acting downstream of the carrier 12 (second chamber 28) exceeding the pressure in the thrust fluid acting upstream of the carrier 12 (first chamber 26).

Preferably, vector 12 ? a container or envelope that can be closed after the assembly 14 has been inserted inside it.

Conveniently, the container made by the vector 12 is made by a plurality of components that can be assembled together in a removable and reversible way.

In particular, vector 12 ? configured to seal the fluid? assembly 14 that ? intended to contain, for example by means of suitable sealing gaskets closed between the components of the carrier 12 when it is closed. The fluid tightness of vector 12 ? clearly suitable for preventing the passage of the thrust fluid and the return fluid inside it.

Further the vector 12 ? slidably mounted in the fluid-tight tubular guide 16 in such a way as to guarantee the fluidic separation of the chambers 26 and 28, both in an initial static phase, after unlocking the device 30, and in the dynamic phase, i.e. sliding inside the guide 16.

In particular, the surface or external geometry of the vector 12 ? such as to interface correctly both with the release device 30 and with the stop device 34. For example, a support or a mechanical coupling is achieved between mating portions of the carrier 12 and of the relative device(s) 30 and/ or 34.

Preferably, the surface or internal geometry of vector 12 ? able to firmly constrain the assembly 14 placed inside it. For example, the presence of clearances or gaps between the inner surface of the vector 12 and the outer surface of the assembly 14 is substantially avoided, overall attenuating the vibrations that could exist during use. In particular, the vector 12 pu? be suitably equipped with mechanical adapters that can be interposed between the inner surface of the vector 12 and the outer surface of the assembly 14.

By way of example, the assembly 14 pu? be any structure or any apparatus for which it is desirable to conduct a shock test. For example, the assembly 14 pu? include an electromechanical type apparatus or device to be subjected to such a shock test. How ? clear to a person skilled in the sector, the geometry of the assembly 14 advantageously allows anchoring within the vector 12, for example by means of one or more? of the expedients described above (in particular, the use of suitable mechanical adapters).

The tubular guide 16 ? preferably made in one piece, in particular of metallic material.

For example, the internal cross section of the tubular guide 16 ? advantageously circular in shape with a substantially homogeneous diameter along its entire length.

Furthermore, the external shape of the tubular guide 16 is determinable according to the mechanical strength requirements and interface with fixing and support systems (not shown) intended to be associated with it.

Between the carrier 12 and the tubular guide 16, suitable shoes can be advantageously configured to create an interface which ? on the one hand - reduces the friction between this carrier 12 and this tubular guide 16 during their relative sliding and ? on the other hand, keeps the chambers 26 and 28 separate in the operation of the system 10 in a fluid-tight manner.

Preferably the booster tank 24 contains compressed air or nitrogen. In particular, the initial pressure of the fluid contained in the booster tank 24 can reach up to 200bar. For example, the volume of the booster tank 24 can? be a few tens of litres. Advantageously, the tank 24 and the first chamber 26 can communicate through a passage having a passage section substantially the width of the tubular guide 16.

The release device 30 preferably comprises a retaining element 36 interposed between the vector 12 and the tubular guide 16. The retaining element 36 is shaped to keep the vector 12 rigidly constrained to the tubular guide 16 and ? configured to be subjected to breakage of at least a portion thereof, in particular such a portion being mechanically weakened to allow breakage thereof. Advantageously, the release device 30 allows the carrier 12 to reduce the transverse stresses or jamming in the tubular guide 16, as well as any damage to the carrier 12 itself, during its release by breaking the retaining element 36. By way of example As a non-limiting example, the release device 30 comprises an actuator or striker device (not numbered) operable to effect the breaking of the connecting element 36. The actuator or striker device can? operate, for example, by pneumatic actuation.

Preferably, where the return tank 32 is present, it has a reduced number of litres. In particular, the return tank 32 can contain compressed air, or nitrogen, at an initial pressure of about 10bar.

Advantageously but not necessarily, the interface between the return tank 32 and the second chamber 28 has a passage section substantially comparable to the width of the cross section of the guide 16.

Conveniently, can one or more be provided? gasket assemblies (not shown) housed between the vector 12 and the tubular guide 16 (or forming part of at least one of the vector 12 and the tubular guide 16) which allow the first chamber 26 and the second chamber 28 to be kept isolated from each other , while allowing the carrier 12 to slide in the tubular guide 16.

Preferably, the stop device 34 comprises a pawl element 38 which, with the vector 12 (for example, with a suitably shaped external profile of the latter) essentially forms a one-way ratchet device. The pawl element 38, for example, ? constrained to the tubular guide 16. Furthermore, the pawl element 38 is configured to prevent a movement of the vector 12 directed towards the? 18 and instead allow a shift of the vector 12 towards? The other end? 20. Optionally, the one-way ratchet device realized between the pawl element 38 and the vector 12? normally deactivated, but ? which can be activated selectively, for example by bringing the pawl element 38 to an active position or condition capable of interfering with the movement of the carrier 12. In particular, the one-way ratchet device is? fluidly activated by the pressure difference intended to develop between the chambers 26 and 28 when the carrier 12 moves through the tubular guide 16 (in particular, when the carrier 12 is released from the release device 30). Pi? in particular, the one-way ratchet device ? activated by the use of an irreversible pneumatic system.

According to exemplary embodiments of the present invention, at least one of the tubular guide 16, the booster tank 24 and the return tank 32 are configured to house or include electromechanical sensors and transducers and to be capable of interfacing with commercial pneumatic components.

Naturally, the principle of the invention remaining the same, the embodiments and construction details can be widely varied with respect to what is described and illustrated purely by way of non-limiting example, without thereby departing from the scope of the invention as defined in the attached claims.

Claims (8)

1. System (10) for carrying out shock tests, in particular at high accelerations; said system including: - a vector (12) that ? intended to house an assembly (14) to be subjected to a shock test; - a tubular guide (16) having a pair of ends? (18, 20) and defining a cavity? internal (22) through which ? movable in a guided way said vector (12) between said ends? (18, 20); - a thrust tank (24) containing a pressurized fluid and connected to said cavity? internal (22) near? of a? extremity? (18) of said tubular guide (16) and in a position located upstream of said carrier (12); said pressurized fluid being able to push said vector (12) through said cavity? internal (22) towards the other end? (20) of said tubular guide (16), subjecting said vector (12) to a thrust acceleration suitable for simulating the effects of a shock suffered by said assembly (14). The system according to claim 1, further comprising a release device (30) configured to take a blocking condition, in which the release device (30) blocks said carrier (12) in the cavity? inside (22) of said tubular guide (16) near? of that extremity? (18) opposing a displacement of the vector (12) towards said other extremity? (20), e an unlocking condition, in which said release device (30) releases said vector (12) in the cavity? inside (22) of said tubular guide (16) allowing the displacement of the carrier (12) towards said other end? (20). The system according to claim 1 or 2, further comprising a return tank (32) containing a return fluid and connected said cavity? internal (22) near? of? the other extremity? (20) of said tubular guide (16) and in a position located downstream of said carrier (12); said return fluid contained in said return tank (32) having a lower pressure than that of said thrust fluid contained in said thrust tank (24). The system according to claim 3, further comprising a stop device (34) configured to stop said carrier (12) in the vicinity of the of that extremity? (18) of said tubular guide (16) when said carrier (12) is pushed towards said end? (18) due to the exceeding of the pressure in said return fluid acting downstream of said vector (12) with respect to the pressure in said thrust fluid acting upstream of said vector (12). 5. Method for carrying out shock tests, in particular at high accelerations; said method comprising the following operational steps: - make available an assembly to be subjected to a shock test; - house said assembly in a mobile mounted carrier in a cavity? inside of a tubular guide between a pair of ends? of said tubular guide; - move said carrier through said cavity? internal through the connection of a thrust tank containing a pressurized fluid near? of a? extremity? of said tubular guide and in a position situated upstream of said vector, in such a way as to push said vector towards the other end? of said tubular guide, subjecting said vector to a thrust acceleration suitable for simulating the effects of a shock suffered by said assembly. The method according to claim 5, further comprising the operational steps of: - block said carrier (12) in the cavity? inside (22) of said tubular guide (16) near? of that extremity? (18), contrasting a shift of the vector (12) towards said other extremity? (20), e - free said carrier (12) in the cavity? inside (22) of said tubular guide (16) allowing the displacement of the carrier (12) towards said other end? (20). 7. A method according to claim 5 or 6, wherein the displacement of said vector (12) through said cavity? internal (22) towards said other extremity? (20) also takes place by connecting a return tank (32) containing a return fluid and connected to said cavity internal (22) near? of? the other extremity? (20) of said tubular guide (16) and in a position located downstream of said carrier (12); said return fluid contained in said return tank (32) having a lower pressure than that of said thrust fluid contained in said thrust tank (24). The method according to claim 7, further comprising the operational step of stopping said carrier (12) when said carrier (12) is pushed near the of that extremity? (18) of said tubular guide (16) due to the exceeding of the pressure in said return fluid acting downstream of said vector (12) with respect to the pressure in said thrust fluid acting upstream of said vector