FR2964740A1 - Device for testing resistance of e.g. tube shape elongated element of radiator equipped with air conditioning, heating and ventilating device of motor vehicle, has positioning unit positioning slide in its general plane along orientation - Google Patents

Abstract

The device has an anvil (2) for receiving a structure (1) that is overhung by a guide (5), where the guide receives an impact disk (4) in a sliding manner along a striking direction corresponding to the gravity. The impact disk has a mass (6) and a head (7) to be struck oriented toward the anvil. A positioning unit positions a slide in its general plane along an orientation determined with respect to the anvil, where the slide is integrated to the impact disk.

Description

The invention is within the field of procedures for the investigation of the properties of solid materials by application of a heat-exchanger. a mechanical stress exerted from a single and brief force generated by a weight in free fall. It relates to a device for testing the resistance of an elongated element, such as a tube, plate or the like, that includes a heat exchanger, such as a radiator, a condenser or an air cooler. supercharging for a motor vehicle in particular. The heat exchangers comprise in their generality a bearing frame of a plurality of elongated elements, such as shaped tube, plate or other similar conformation. These heat exchangers, such as a radiator, a condenser or a charge air cooler for example, are currently used in the automotive field to equip a vehicle with a heating, ventilation and / or air conditioning device. the air inside the passenger compartment of the vehicle. The elongate elements that include the heat exchangers are in particular shaped to provide an optimized heat exchange surface with the ambient air and / or to convey a heat transfer fluid. According to a general definition of the conformation of the elongated element, it comprises a first longitudinal dimension of general extension which is significantly greater than at least a second extension dimension of the element. This second dimension is oriented transversely, and more particularly orthogonally, to said first dimension so that the element has a general conformation which extends mainly along the first dimension. A problem lies in the possibility of conducting resistance tests of such elongated elements that include heat exchangers.

A traditional method is to project chippings against the heat exchanger, and to evaluate its resistance according to the impacts recorded as a result of such projections on the elongated elements that it includes. Such a method is complex to implement and induces defects in precision and reliability of the results obtained, because of the low rigidity and randomness of its implementation. It is known in the field of research procedures properties of solid materials, the method of applying a mechanical stress against a specimen, which is exerted from a single and short force generated by a weight in free fall. Such a procedure uses a test device, comprising in its generality a guide which is placed overhanging the test piece and which slidably receives a heavy hammer provided with a striking head. The hammer is initially positioned to place the striking head at a predefined distance above the specimen. The said distance and the mass of the hammer are determined according to the test to be carried out. The hammer is then released and is gravity-driven along the guide, until the knocking head hits the specimen. An observation of the effects of this impact on the specimen is carried out to evaluate its resistance. Such a test method has the advantages of being able to be implemented easily and at a lower cost by operating a simple structure test device.

The obtained evaluation of the resistance of the test piece is reliable and simple to carry out from the observations made by taking into account, or even varying, the mass of the head to be struck and the distance initially separating it from the specimen. However, to obtain an accurate and reliable analysis, the arrangement of the striking head is commonly spherical or even pointed. Such an arrangement of the knocking head and the organization of the test device are not suitable for their operation to search for the resistance properties of a heat exchanger formed from said elongated elements. The object of the present invention is to provide a strength test device of a structure comprising at least one elongated element, and more particularly such an elongated element including shaped like tube, plate or similar elongated conformation. More specifically, the object of the present invention is to provide such a test device organized to enable the resistance test of a heat exchanger formed from a plurality of elongated elements, such as a radiator, a condenser or a charge air cooler for a motor vehicle in particular.

The organization of the device is sought particularly suited to the strength tests of said elongated elements, providing test results that are relevant, reliable and easy to analyze. The device is also sought to be of a simple and easy to implement structure, such simplicity and ease of implementation should not affect the relevance and reliability of essentially required test results. The device of the present invention is a device for testing the strength of a structure from the application against this structure of a single and short force generated by a weight in free fall. The test device comprises an anvil for receiving the structure which is overhung by an elongate guide slidably receiving a hammer in a strike direction corresponding to the gravity. The hammer comprises a mass and a striking head oriented towards the anvil, the mass being capable of being composed of a plurality of interchangeable elementary masses. Such a device makes it possible to place the overhanging guide of the structure to be subjected to the test, then to guide to this structure the hammer which is driven by gravity according to the strike direction. The hammer, whose mass is determined according to the test to be carried out, is moved by gravity from an overhang position of the structure to a predefined distance according to the test to be performed, to a test position in which the head to strike the structure to be tested. According to the present invention, such a test device is mainly recognizable in that the striking head is shaped as a blade and in that the device comprises means for positioning the blade in its general plane in a specific orientation. compared to the anvil. [000si The conformation of the head to strike blade, and the maintenance of this blade 30 in its general plane in a specific orientation, allows to conduct tests on organized structures heat exchanger comprising a plurality of elongated elements arranged in tube and / or plate. In particular, the device makes it possible to carry out a resistance test for a structure consisting of a heat exchanger placed on the anvil, by applying against one of the elongated elements that it comprises a striking force from the hammer and by means of the blade, the latter being oriented in its general plane transversely, and more particularly orthogonally to the general direction of extension of the elongated member struck during the test. The effect of deterioration of the structure undergoing the test is relevant with respect to said elongated element, and reliable analysis subsequently performed by an operator is simple and quick to perform. The relevance and reliability of the test are not affected by the simplicity of the structural organization of the test device and the ease of its implementation of the test device. The test device makes it possible to carry out a heat exchanger resistance test procedure quickly and inexpensively. The conformation of the cutting edge and the arrangement of the wire of the blade are likely to be arbitrary, being adapted according to the resistance test to be carried out. In particular, the blade is likely to be single-edged or double-edged beveled indifferently to one of the edges of his wire or on both sides of his wire. In particular, the wire of the blade is likely to be straight or inclined with respect to the striking direction. In particular, finally, the cutting edge of the blade can be indifferently to continuous wire, or be toothed and / or microdentured to hit the elongated element following localized impact zones in addition to its degradation along the whole of the width of the blade. According to one embodiment, the blade is integrated with the hammer being for example mounted, sealed, assembled and / or integrated molding on the mass that includes the hammer. The blade positioning means comprise cooperating members which are respectively formed on the hammer and the guide, to maintain the blade in its general plane during the sliding of the hammer on the guide without preventing this sliding. The cooperating members maintain the blade in its general plane in a specific orientation relative to the guide, which is itself provided with installation means overhanging the anvil in a specific position. For example, the device comprises a frame on which the anvil and the guide are mounted in determined relative positions. The means for positioning the blade are transverse retaining means of the hammer relative to the strike direction which do not prevent its sliding along the guide. According to an advantageous embodiment because of its simplicity of structure, said cooperating members are constituted by a slide and a rail which are respectively arranged indifferently on the guide and on the hammer. Such an arrangement of the positioning means provides a holding position of the blade in its general plane and a said transverse retention of the hammer along the guide as it slides. According to a simple arrangement of the positioning and sliding guide means of the blade, one of said cooperating members is arranged in groove which is formed longitudinally on the guide and which slidably receives a tongue forming the other member. cooperating that involves the hammer. According to another embodiment, the blade is disjoined from the hammer and is carried by a base plate indifferently on the structure or on the anvil. The blade comprises a member for receiving a striking force exerted by the hammer, which has a surface advantageously extended. The base is advantageously provided with means for positioning the blade in its general plane, comprising a base forming at its base a passage for the blade and means for holding the blade in its general plane along a said orientation determined by compared to the anvil. The base is a relative positioning member between the base and the anvil, and therefore between the blade and the anvil. The base is more particularly a relative positioning member between the base and the structure to be tested, which is itself for the test immobilized on the anvil in a desired position via appropriate fastening means equipping the anvil. According to an alternative embodiment, said holding means are formed of a fixed mounting of the blade on the base, which constitutes said receiving member of the striking force. More particularly, the face of the base which overhangs the base and which is oriented towards the guide forms an extended surface against which the hammer easily exerts the striking force. To allow a relative displacement in the direction of striking between the blade and the anvil, and more particularly the blade to the structure undergoing the test, the base is compressible in the direction of striking. The capacity of the base to be compressed corresponds in particular to a tolerated and predefined stroke of the blade against the structure undergoing the test. The compressible nature of the base is preferably imparted by an elastically deformable structure of the base, according to a high coefficient of elasticity so as not to significantly impede the striking force exerted by the hammer against the base, and therefore against the structure undergoing the test. For example, the base is constituted and / or incorporates at least one elastically deformable member. For example still and according to a preferred embodiment due to a structural simplicity of the desired base, the compressibility of the base is obtained by means of the material from which it is derived. According to another embodiment, the blade is movably mounted in translation on the base according to the striking direction, between a retaining position and a test position. The holding position corresponds to a position of the blade contained in the space delimited by the base, which is non-compressible in this case. The test position corresponds to a position of emergence of the blade out of said space towards the anvil, and more particularly towards the structure undergoing the test which is immobilized on the anvil. According to an advantageous exemplary embodiment because of its simplicity of structure, the said holding means comprise a guide slot sliding the blade through the base according to the strike direction. Said slot is not only a member for maintaining the blade in its general plane according to a said orientation determined relative to the anvil, but also a guide member of the blade according to the striking direction between the two said retaining positions and test. The blade is guided in translation on the base by means of the slot, in a translational stroke corresponding to a tolerated and predefined stroke of the blade against the structure. The blade is for example placed in the retaining position from the natural support that it takes against the corresponding face of the structure, and comprises an abutment member limiting its travel in translation under the effect of the application of the striking force by the hammer against the blade at its emergent end out of the base and facing the hammer. Preferably, the blade emerges from the base in the direction of the hammer and is provided with said receiving member of the striking force. For example, such a receiving member is arranged in platinum or the like integral with the end of the blade facing the hammer. The plate extends in a plane oriented orthogonally to the striking direction and is secured to the blade indifferently by assembly, assembly, sealing and / or integration of molding and / or forging. Such a receiving member arranged in platinum is advantageously said stop member limiting the stroke of the blade. Exemplary embodiments of the present invention will be described in connection with the figures of the accompanying plate, wherein: Fig.1 is a schematic overall illustration of a test device of the present invention . Fig.2 is an illustration of a slidably mounted hammer inside a guide that comprises a test device according to an embodiment of the present invention. Fig.3 and Fig.4 are illustrations of respective embodiments of a base and a knock head that comprises a test device of the present invention. In Fig.1, a test device is organized to analyze the strength of a structure 1, by applying a mechanical stress exerted from a single and short force generated by a weight in free fall . This device comprises an anvil 2 on which is maintained the structure 1 to be tested by appropriate means 3 fixing and holding in position. The device of the present invention is organized to analyze the resistance of elongated elements that includes a heat exchanger of the type fitted to motor vehicles. Such elongate elements include plates or the like providing a substantial surface heat exchange, or tubular elements for conveying a fluid. According to the implemented procedure of the test device, the structure 1 is installed on the anvil 2 to undergo a collision applied by a hammer 4 in a strike direction (F) oriented according to gravity. The hammer 4 is slidably guided inside a guide 5 which is placed overhanging the anvil 2, and more particularly overhanging the structure 1 installed on the anvil 2. On the embodiment illustrated , the guide 5 is arranged in tube inside which the hammer 4 circulates for its sliding guide. Other similar solutions for guiding the hammer 4 along a guide 5 are capable of being implemented. The hammer 4 comprises a mass 6 subdivided into a plurality of elementary masses, to allow to adjust its weight depending on the test to be performed. This hammer 4 is provided with a striking head 7 which is oriented towards the anvil 2 to apply the strike against the structure 1. According to various embodiments of the present invention, the striking head 7 is capable of to be secured to the hammer 4, or to be disjoined from the hammer 4 being disposed near the structure 1 via a base. The striking head 7 is arranged in a blade of dimensions corresponding to those of an elongated element undergoing the impact. The hammer 4 is initially placed at a determined distance from the anvil 2, then is released to cause its natural fall to the anvil 2 to hit the structure 1 via the striking head 7. As an indication , the initial separation distance between the hammer 4 and the structure 1 is between 12 cm and 23 cm, the mass 6 of the hammer 4 can be adjusted between 20 gr and 800 gr, and the width of the blade forming the head to hit 7 is of the order between 0.5 cm and 7 cm. Such values are to be perfected according to the structure 1, and more particularly according to the structural characteristics of the elongated elements that this structure 1 comprises. For example, it has been found by experimentation that it was desirable to use a blade of a width of the order of 1 cm, for a drop height of the hammer 4 of the order of 15 cm. For such characteristics of blade width and fall distance of the hammer 4, it is desirable to give the hammer 4 a mass of the order of 50 gr for a heat exchanger of the radiator type and of the order of 700 gr for a heat exchanger of the charge air cooler type. In order to strike the structure 1 satisfactorily, the test device is arranged to arrange the blade in its general plane in a specific orientation with respect to the anvil 2 and consequently with respect to the structure 1. [0026] On the fig.2 to fig.4, various solutions are proposed for providing the test device with relative positioning means between the striking head and the anvil, so that a blade 8 forming the striking head is oriented in its direction. general plan depending on the position of the structure installed on the anvil. In fig.2, the blade 8 is integral with the hammer 4, and more particularly the mass it comprises. The means for positioning the blade 8 in its general plane comprise cooperating members 9, 10 which are respectively formed on the hammer 4 and on the guide 5. In the exemplary embodiment illustrated, the hammer 4 is equipped with a rail 9 arranged in rigid tongue which flows along a slider 10 arranged in a groove that includes the guide 5 and which extends in the direction of striking (F). The hammer 4 is guided radially in its fall and the general plane of the blade 8 is maintained oriented transversely, and more particularly orthogonally, to the general direction of extension of the elongated element to undergo the collision. In Fig.3 and Fig.4, the test device comprises a seat base 11 on the anvil, or by analogy and preferably on the structure itself installed and fixed on the anvil. This base 11 comprises a base 12 which delimits at its base a space providing a passage 13 for the blade 8, which is mounted on the base 11 by means of holding means, so that the general plane of the blade 8 is oriented in the direction of striking and orthogonal to the general direction of extension of the elongate element that includes the structure. The blade 8 is mounted on the base 11 extending in the said passage 13 perpendicularly to the base plane of the base 11 defined by the bearing surface of the base 12 on the structure. An operator positions the base 11 on the structure, the blade 8 being oriented orthogonally to the extension direction of the elongate member. In Figure 4 the blade 8 is provided with a member 14 for receiving the striking force exerted by the hammer, which provides an extended surface oriented orthogonal to the strike direction to avoid a wobbling and / or buckling of the blade 8. [0029] In FIG. 3, the blade 8 is mounted integral with the base 11. The wire of the blade 8 and the bearing surface of the base are flush, so that the base 11 is installed by the operator on the structure, the wire of the blade 8 is in contact with the elongated element to undergo the collision. The base 11 is used to form the receiving member 14 of the striking force on its opposite side to the base 12 and directed to the hammer. The base 12 is compressible under the effect of the striking force exerted by the hammer against the base 11, being formed from blocks of flexible material elastically deformable, including synthetic material. The compressible nature of the base 12 provides its erasure under the effect of the striking force to allow the blade 8 to hit the structure. In fig.4, the blade 8 is mounted movably in translation on the base 11 according to the striking direction, between a retaining position in which the blade 8 is contained in the passage 13 defined at the base of the base 11 by the non-compressible base 12 in this case and a test position in which the blade 8, pushed by the hammer towards the anvil, emerges out of said passage for its forced application against the structure. The means for holding the blade 8 in its general plane, and the guide means in translation of the blade 8 inside the base 11, are formed of a slot 15 formed through the base 11 inside the which slot 15 the blade 8 is slidably mounted. The blade 8 emerges from the base 11 in the direction of the hammer, and has at its corresponding end the receiving member 14 of the striking force. In the exemplary embodiment illustrated, this receiving member 14 is shaped in platinum integrated with the blade 8. The blade 8 is retained in the initial position from the natural support that it takes by gravity against the corresponding face of the structure installed on the anvil. During the test, the application of the striking force by the hammer moves the blade 8 in translation inside the slot 15, until the force-receiving member is put into operation. 14 arranged in platinum against the corresponding face of the base 11.

Claims (1)

CLAIMS1.- A device for testing the strength of a structure (1) from the application against this structure (1) of a single and short force generated by a weight in free fall, this test device comprising an anvil (2) for receiving the structure (1) which is overhung by a guide (5) slidably receiving a hammer (4) in a striking direction (F) corresponding to the gravity, the hammer (4) comprising a mass (6) and a striking head (7) facing towards the anvil (2), characterized in that the striking head (7) is shaped like a blade (8) and in that the device comprises positioning means (9,10,11,12,15) of the blade (8) in its general plane in a specific orientation relative to the anvil (2). 2.- Device according to claim 1, characterized in that the blade (8) is integrated with the hammer (4) and in that said positioning means comprise cooperating members (9,10) which are respectively formed on the hammer (4) and on the guide (5). 3.- Device according to claim 2, characterized in that said cooperating members are constituted by a slide (10) and a rail (9) respectively arranged indifferently on the guide (5) and on the hammer (4) . 4.- Device according to any one of claims 2 and 3, characterized in that one of said cooperating members is arranged in groove (10) which is formed longitudinally on the guide (5) and which slidably receives a tongue (9) forming the other cooperating member that includes the hammer (4). 5.- Device according to claim 1, characterized in that the blade (8) is disjoint hammer (4) and is carried by a base (11) indifferently on the structure (1) or on the anvil ( 2), the blade (8) comprising a member (14) for receiving a striking force exerted by the hammer (4). 6.- Device according to claim 5, characterized in that the base (11) is provided with said positioning means comprising a base (12) providing at its base a passage (13) for the blade (8) and means of maintaining (11,15) the blade (8) in its general plane along a said determined orientation relative to the anvil (2). 7.- Device according to claim 6, characterized in that said holding means are formed of a fixed mounting of the blade (8) on the base (11) which constitutes said receiving member (14) of the force of strikes, and in that the base (12) is compressible according to the striking direction (F). 8.- Device according to claim 6, characterized in that the blade (8) is mounted movably in translation on the base (11) in the strike direction (F), between a retaining position in which the blade (8) is contained in the space (13) delimited by a non-compressible base (12), and a test position in which the blade (8) emerges out of said space (13) in the direction of the anvil (2). 9.- Device according to claim 8, characterized in that said holding means comprise a slot (15) slidably guiding the blade (8) through the base (11) in the strike direction (F). 10.- Device according to any one of claims 8 and 9, characterized in that the blade (8) emerges from the base (11) in the direction of the hammer (4) and is provided dut said receiving member (14) of the strike force.25