FR3018353A1 - METHOD OF TESTING THE RESISTANCE TO A PRESSURE LOSS OF A TIRE - Google Patents

Abstract

A method of testing the resistance of a tire to a loss of pressure subsequent to perforation having a first portion performed at an ambient temperature of greater than 10 ° C in which a plurality of perforations is created in the wall of the tire by inserting through the wall a plurality of perforating objects, is rolled the tire comprising the perforating objects at a given distance with a controlled inflation pressure, stopping the rolling, is determined for each perforation a pressure loss resistance index based on an estimate of the leakage rate of said perforation and a second part performed at an ambient temperature of less than 10 ° C. in which a plurality of perforations is created in the wall of the tire or of a similar tire by inserting through the wall a plurality of perforating objects, a pre-resistance index is determined for each perforation at a cold pressure loss based on an estimate of the flow rate of the perforation, is extracted from the wall of the tire the plurality of perforating objects, and is determined for each perforation a cold resistance index to the loss of pressure based on an estimate of the leakage rate of the perforation.

Description

FIELD OF THE DISCLOSURE [0001] The present invention relates to tires, and more particularly to a method for testing the resistance to pressure loss. BACKGROUND OF THE INVENTION following a perforation of a tire. STATE OF THE ART [0002] When the wall of a tire is punctured by a perforating object such as a screw or a nail, or "puncture", the inflation air of the tire can escape through the perforation and the resulting loss of pressure causes a flat tire and a stop of the vehicle. The delay between the perforation and the flat tire is very variable, depending in particular on the size of the perforating object but also the continuation or not of the 15 rolling with the perforating object in place in the wall of the tire. This rolling causes relative movements between the perforating object and the tire wall which often enlarges the perforation and accelerates the leakage flow. [0004] To solve this problem of punctures which dates from the very beginning of the use of tires with inflated tires, the usual solution is to stop and replace the wheel concerned with a spare wheel. Other solutions have been imagined and are available on the market to avoid having to use a spare wheel. [0006] US 5,916,931 discloses an aerosol container comprising an aqueous latex emulsion mixed with various products including fibrous products and a propellant. In the case of a flat tire, this container is intended to be fixed to the valve of the tire and to send into the internal cavity of the tire the propellant gas and the sealing / repair emulsion. The tire is then re-inflated at least partially, the emulsion closes the perforation and can be rolled again, at reduced speed firstly to distribute the emulsion evenly over the entire internal surface of the tire and then normally. . There are also repair kits, offered by some car manufacturers in place of a spare wheel. This has the advantage of reducing the weight of the car 5, so its fuel consumption and free space under the floor of the trunk. [0008] The puncture kit consists of a compressor, a bottle of sealant, an electrical connection cable and an air hose. Once the bottle of product is attached to the compressor, the air hose screwed to the bottle and to the valve of the tire and the electric cable connected to the cigarette lighter of the vehicle, it is only necessary to put the compressor switch to "on", while letting the engine run so as not to discharge the battery. The sealant empties into the tire in about 30 seconds during which the pressure in the air hose will rise to about 6 bar.

Then the air will inflate the tire and the theoretical inflation pressure will be reached within 10 minutes. Once the pressure is reached, all you have to do is turn off the compressor and remove the kit. Once the tire inflated, it is necessary to quickly take the wheel, travel 10 km and check the pressure of the tire with the compressor and the air hose 20 to bring it to the required level. Once the tire flat repaired, it should not exceed 80 km / h and have control or change his tire quickly. The tire repair kit is only a temporary repair. Tire manufacturers have also proposed tires provided on their inner wall or in their structure with a layer of elastic products, viscous or pasty, called "self-sealing products", for sealing the perforations. WO 2008/080556 A1 shows an example of such a tire. These tires are not as such indestructible, but the perforations are normally closed or closed by the self-sealing product. P10-3296 EN - 3 - [0013] The manufacturers of these different solutions all have remarkable results in closing the perforations thanks to their products, in particular during a perforation followed by an immediate withdrawal of the perforating object. But, no test method corresponding to the usual conditions of rolling exists and so it is very difficult to know the real effectiveness of these different solutions and compare them. Brief description of the invention The invention relates to a method for testing the resistance of a tire to a loss of pressure following perforation, characterized in that: in a first part carried out at a temperature ambient greater than 10 ° C: - is created in the wall of the tire a plurality of perforations by inserting through the wall a plurality of piercing objects; the tire comprising the perforating objects is rolled over a given distance with a regulated inflation pressure; - stop the rolling; and for each perforation, a heat loss pressure resistance index based on an estimate of the leakage rate of the perforation is determined; - In a second part carried out at an ambient temperature of less than 10 ° C: - is created in the wall of the tire or similar tire a plurality of perforations by inserting through the wall a plurality of perforating objects; for each perforation, a cold resistance pre-index is determined for the loss of pressure based on an estimate of the flow rate of the perforation; the plurality of piercing objects is extracted from the wall of the tire; and for each perforation, a cold resistance index is determined for the loss of pressure based on an estimate of the leakage rate of the perforation. By similar tire means a tire of the same characteristics as the tire initially tested. Both tires are equivalent. This test method has the advantage of analyzing the resistance to perforation of one or more similar tires under conditions close to the wide use conditions, hot and cold. The first part with a rolling, so hot, is very selective and the second part performed at a low temperature, or cold, complete the analysis. This second part does not include rolling but simply insertion and removal of piercing objects. Indeed, more selective results have been observed following this procedure. The fact of rolling tires in a cold environment provides little additional information, in fact, we tend to find the results of the hot test method, because of the heating of the tire during the test. rolling. The first part is very selective because of the rolling performed in the presence of a plurality of piercing objects. This rolling causes relative displacements of the perforating objects and the wall of the tire which can widen the perforations and make it much more difficult for them to be closed or to maintain their filling. The use of a plurality of perforating objects of various types and diameters coupled with controlled pressure rolling makes it possible, with a single tire or a very small number of similar tires, to obtain numerous results of resistance to perforation and therefore to limit the number of tests required. It is advantageous to regulate the inflation pressure of the tire under test to compensate for any leaks that may appear during taxiing, particularly in the case of perforating object ejection. This makes it possible to study the perforation performance related to the other perforating objects present in the tire. This test method is particularly useful for tires comprising a self-sealing product, for example a layer of self-sealing product disposed on its inner wall or in its wall. When the tire has no self-sealing product, in the first part, when stopping the rolling and before determining the resistance to loss of pressure index, it is put in place in the internal cavity of the pneumatic shutter product. Similarly, in the second part of the test, cold, after inserting and tearing the perforating objects, is placed in the internal cavity of the tire 25 a filling product, it brings, if necessary, the tire at the temperature of the test of the second part, and the index of resistance to the loss of pressure is determined. This test method allows to test under realistic conditions all the alternatives of a spare tire in case of puncture, including puncture-resistant bombs and repair kits. Of course, this setting up of a sealing product inside the internal cavity of the tire is to be carried out according to the procedure specific to each sealing solution tested. The test method according to an object of the invention comprises two parts. Preferably, in the second part, cold, the plurality of perforating objects consists of tapered objects and smooth walls such as nails. Advantageously, the whole of the second part is produced when the tire under test is at a temperature of between -20 ° C. and + 10 ° C. The test temperature is to be adapted according to the conditions of use provided for the tires. [0025] The first part of the test method according to an object of the invention comprises several phases, each phase using different types of perforating objects as well as adapted test conditions. The applicants have indeed found that the performance of a self-sealing product or a layer of self-sealing product may be different depending on the shape of the obturating objects. It is found that when the perforating objects are tapered smooth wall objects such as nails, the performance is constant at low speed and then gradually decreases from a certain speed threshold. The first phase of the first part of the test method with such nails as perforating objects has the advantage of testing the perforation resistance performance at a speed sufficient for the test to be selective but insufficient to cause a significant ejection of piercing objects. Preferably, the driving speed V1 for this first phase is fixed and greater than 80 km / h, very preferably between 90 and 120 km / h. Below 80 km / h, the test method does not classify close self-sealing product solutions and beyond 120 km / h, the proportion of ejected nails becomes too important. Indeed, it has been found that the performance of a self-sealing product or a self-sealing layer after ejection of the perforating object, and particularly nails, is very random. It is not therefore possible to have a selective and reproducible test in the presence of numerous ejections piercing objects. The test method comprises in its first part a second phase in which the plurality of piercing objects is composed of tapered objects and walls with a thread, such as screws. It can be seen that the self-sealing performance in the presence of such perforating objects is less good at standstill and at low speed, but evolves positively as a function of the speed at which the rolling is carried out. In the presence of such screw-type perforating objects, it is found that a preheating of the tire between 50 and 60 degrees Celsius at the time of insertion of these objects improves the performance before the rolling and also after rolling. Advantageously, such preheating can be part of this second phase as far as the conditions of use are concerned: the majority of cases of punctures occur when the tire is being driven, and therefore hot. The rolling of the second phase is preferably carried out at a speed below 80 km / h. This makes it possible to clearly differentiate the behavior of different anti-blocking solutions in the presence of perforations in the crown of the tire due to screws. Advantageously, the running speed V2 is between 50 and 75 km / h. Advantageously, this second phase of the test method is completed by performing a test with screw-type perforating objects and higher fixed speed V2-2, greater than 80 km / h. This makes it possible to assess for each solution the slope of the improvement of the anti-blocking performance as a function of the speed. The test method thus described allows to appreciate the resistance to pressure loss of a hot self-sealing solution in two complementary cases of perforating objects. It can be seen that the rankings of the solutions are independent of each other in these two cases. Advantageously, the first part of the test method further comprises a third phase with the following steps: - creating in the wall of said tire a plurality of perforations by inserting through said wall a plurality of piercing objects; Extracting from the wall of said tire the plurality of piercing objects; P10-3296 EN -7- - roll the tire after extracting piercing objects at a speed V3 greater than 120 km / h over a given distance with a regulated inflation pressure; - stop taxiing; and - determining for each perforation a pressure loss resistance index based on an estimate of the leakage rate of said perforation. Preferably, the speed V3 is fixed and less than 180 km / h. This third phase of the first part has the advantage of characterizing the performance of a self-sealing solution in a third case independent of the first two already described. It is a question of testing the high-speed mechanical resistance of the plugs of self-sealing product which fill the perforations after the perforating object has been extracted. The results of this third phase are complementary to those of the first two. The driving distance for each phase of the test method is preferably greater than 200 km and very advantageously greater than 500 km. Of course, depending on the circumstances and the number of piercing objects used for each phase, one can use the same tire for the three phases of the first part of the test method or several similar tires, each equipped with the same self-sealing solution, to test this self-sealing solution. [0042] Advantageously, the first part of the test method comprises a complementary computation step for each phase of a mean pressure loss resistance index (IM1, Im2, IM3) for all the perforations. These indices complete the similar index of resistance to the average cold pressure loss that can be calculated for the second part. It is also advantageous to determine each index by combining the notations 25 of the perforating objects and weighting them with a frequency curve of appearance of the objects in customer. For example, one can refer to the distribution curve of the diameters of nails and / or screws observed in a given country. This makes it possible to get closer to the real conditions of use in a given country. P10-3296 EN - 8 - The three indices thus obtained Iml, Im2, hin make it possible to characterize very selectively the hot resistance to the loss of pressure following a perforation of a tire, that this tire is equipped with from the beginning of a self-sealing product or not. The rolling of the tire can be performed on a steering wheel. Preferably, the tire is inflated before inserting the perforating objects through its wall. This facilitates the insertion of piercing objects. During the two parts of the test and in particular during rolling, the inflation pressure of the tire is preferably regulated and very preferably regulated at a pressure of between 1.8 and 5 bar depending on the type of tire being tested. Advantageously, the plurality of perforating objects comprises screws and nails of diameters and / or of various lengths. The diameter of the perforating objects is preferably 3 to 5 mm. Advantageously, the plurality of piercing objects comprises from 10 to 50 piercing objects, preferably between 20 and 40. The perforating objects can be inserted into the crown of the tire from the outer surface of the carving grooves. of the tire. They can also be inserted into the sculpture patterns of the tire. [0055] Advantageously, a surfactant is used to visualize and qualitatively assess the leakage rate of each perforation. The following scale may be used to assess the leakage rate of a perforation: 100: no bubble is visible, no leakage; - 80: nano-leakage, very small bubbles of diameter less than 0.1 mm, visible only with a magnifying glass; - 60: micro-leakage, small bubbles visible to the naked eye, with a diameter of between 0.1 and 1 mm; - 0: leakage, evolutionary bubbles of diameter greater than 1 mm, or no bubble due to too much air flow. P10-3296 EN - 9 - Description of the Figures [0057] The accompanying figures illustrate various aspects of the method for testing the resistance to pressure loss of a tire in the case of a tire comprising a self-sealing layer on a tire. its inner wall: - Figure 1 shows some perforating objects; FIG. 2 is a curve, in cumulative frequency, of the distribution of nail diameters observed in China and in the United States; - Figure 3 is a partial top view of a tire crown with three perforations; FIG. 4 illustrates the case of a perforation with zero leakage rate; FIGS. 5 (a) and (b) illustrate the case of a perforation with a very low leakage rate; FIG. 6 illustrates the cases of a perforation with a low leakage rate; FIGS. 7 (a) and (b) illustrate the cases of rapid leakage perforation; and FIG. 8 schematically shows the influence of the rolling speed on the performance of a self-sealing solution. DETAILED DESCRIPTION OF THE INVENTION A tire 1 of dimension 205/55 R 16 Michelin Energy Saver is tested with a layer of self-sealing product as presented in the aforementioned application WO 2008/080556 A1. The first part of the pressure loss resistance test of this tire will now be described. Figure 8 shows very schematically the influence of the rolling speed on the performance of a given self-sealing solution. The driving conditions are those of the different phases of the test method according to an object of the invention. [0061] Graph (a) shows the case of nail-like perforating objects, tapered objects whose side wall is smooth (phase 1). The performance is excellent at low driving speed but then gradually decreases with speed beyond a speed of the order of 70 km / h. The graph (b-1) illustrates the case of perforating objects of the screw type, tapered objects whose side wall comprises a thread (phase 2). The screws are inserted into the top of the cold tire, that is to say at ambient temperature, of the order of 20 degrees Celsius. The performance is not good at standstill and at low speed but then gradually improves with it. The graph (b-2) illustrates the case of perforating objects of the screw type, when the insertion of the screw-type perforating objects is carried out hot, that is to say when the tire has been brought to a top temperature of the order of 50 to 60 degrees Celsius. There is an improvement in the performance of resistance to pressure loss, which is noticeable over the entire speed range of the test. Finally, the graph (c) illustrates the performance obtained during a run performed after extraction of the perforating objects immediately after their introduction in the crown of the tire (phase 3). We find an excellent performance at low speed and it is only beyond a high speed of the order of 130 km / h that the average performance can begin to decline. This characterizes the high-temperature mechanical resistance of self-sealing product plugs. Figure 1 shows some examples of perforating objects commonly used for the test method. They are nails 21 with a diameter of 3 mm, nails 22 with a diameter of 4 mm and nails 23 with a diameter of 5 mm, and screws with a diameter of 3.5 mm and a length of 30 or 40 mm. The diameters of these perforating objects are quite realistic piercing objects encountered in real rolling conditions. Figure 2 presents the cumulative frequency of the distribution of nails observed on roads in China and the United States. It can be seen that all nails with diameters less than or equal to 5 mm correspond to more than 90% of the objects encountered. After having mounted the tire 1 on a suitable wheel and having inflated it at 2.5 bars, the tire and the wheel are rigidly attached to a rotary hub (not shown) and inserted through the crown 3 of the tire 1. a plurality of piercing objects. [0068] FIG. 3 shows in partial plan view the apex 3 of a tire 1. The sculpture of this tire comprises three longitudinal grooves, inner, central 7 and outer 30 9 and an outer shoulder 5 with a set of transverse grooves or recesses 11. For internal or external use, reference is made to the side of the tire intended to be mounted towards the inside of the vehicle or towards the outside of the vehicle, the sculpture of this tire being asymmetrical . In Figure 3, there are three perforations by nails 21 disposed in the central longitudinal groove 7 (SC), the outer longitudinal groove 9 (SE) and in the transverse hollow (CT) 11 of the outer shoulder 5. [0069 ] For the first phase of the test method or "protocol nails", twelve nails with a diameter of 3 mm and a length of between 45 and 60 mm, six nails with a diameter of 4 mm and length, were inserted over the entire top. similar and six nails 5 mm in diameter and similar length. For the second phase of the test method or "protocol screw", after bringing the top of the tire to a temperature of the order of 50 to 60 degrees Celsius, it was inserted on the entire top twelve screws diameter 3.5 mm and length 30 mm and twelve screws with a diameter of 3.5 mm and a length of 40 mm. Piercing objects are regularly distributed over the circumference of the summit. The tire assembly and inflated wheel are then fixed on the hub of a rolling machine having a development of five to six meters. The rolling conditions are as follows: the inflation pressure is regulated, for example at 2.5 bar, the applied load is of the order of 70% of the load capacity of the tire, the temperature in the The caster's enclosure is regulated at approximately 20 ° C and the rolling is a straight run, without torque, drift or camber applied. [0073] The speed conditions depend on the protocol: - for the nails protocol, the rolling time is six hours at Vi = 100 km / h; at this speed, there is practically no ejection of nails; for the screw protocol, the rolling is carried out for six hours at a speed V2 = 70 km / h; then, after analyzing the results of the first rolling, a second taxiing is carried out for six hours at a speed V2_2 = 130 km / h; - for the third phase or "traffic jam protocol", the taxi is six hours at 150 km / h. It is possible that the largest nails are ejected during taxiing. The analytical conditions of the test (new nail, not rusty, planted upright) favor the appearance of ejection. In this case, the ejected nail is not taken into account in the calculation of the final notes. The screws are not expelled while driving, the thread increases the effort required to extract them. After rolling, a cooling phase of at least two hours is respected. The analysis of the results is carried out half-vertex by half-vertex. The course of the second part of the test is now described taking as an example a first cold test temperature of 0 ° C and a second cold test temperature of -10 ° C. Four tires similar to the tire (s) tested are selected in the first part, they are mounted on four wheels and inflated to their recommended inflation pressure, here 2.5 bars. The four tire / wheel assemblies are installed in a cold room or a refrigerated container. The temperature of the container is lowered to a temperature of 0 ° C. and this temperature is maintained for a minimum of 4 hours. 24 nails are implanted in each tire: 8 of diameters 3 mm, 8 of diameters 4 mm and 8 of diameters 5 mm. The nails are hammered regularly: 12 in the central longitudinal grooves (SC) 7 and 12 in the outer longitudinal grooves (SE) 9 of the four tires 1. [0082] For the four tires, the first notation of the this temperature 01, the nails being in place, notation to TO. Then, for the first two tires, it performs a second log leaks, nails in place at TO + 1 hour. [0084] At Ti, the nails of the first two tires are torn off, again at the temperature 01 of 0 ° C. and a first rating is made, then a second at Ti + 10 minutes minimum. The temperature of the refrigerated container is then lowered to a temperature of -10 ° C. and the last two tires are left at this temperature for at least four hours. P10-3296 EN - 13 - [0086] Then, at T2, a log of the leaks, nails in place. At T3, the nails are torn off and a log of the leaks is made at T3 and preferably a second at T3 + 10 minutes minimum. The result of the test is a qualitative observation of the leaks of each perforation, before extraction, after extraction and about 10 minutes after the extraction. Leaks are evaluated with the aid of a surfactant, for example an aerosol can of the brand "1000 bubbles". The product is projected on the perforation and the observer notes the presence, the size and the number of the bubbles with the aid of a magnifying glass and under a strong lighting. [0090] Figures 4 to 7 illustrate the different cases observed with the perforating objects in place (Fig. 4, 5 (a), 6 and 7 (a)) and after its extraction or ejection (Fig. 5 (b)). , 7 (b)). In FIG. 4, we see a nail 21 passing through a perforation 41 disposed in the longitudinal groove 9 of the tire. We do not see any bubbles, there is no leak, the perforation is noted 10 or 100%. In FIG. 5 (a), there is seen a perforating object 21 passing through a perforation 51 disposed in the longitudinal groove 9 of the tire. The application of the surfactant product makes it possible to display a large number of very very small bubbles 51, only visible with a magnifying glass and with a diameter of less than 0.1 mm. This is a very low leak, rated 8 or 80%. [0093] In FIG. 5 (b), a perforation 52 made by a perforating object which has been expelled or extracted is seen. The perforation 52 is also located in the outer longitudinal groove 9 of the tire. The application of surfactant product also makes it possible to display a large number of very very small bubbles 51, visible with a magnifying glass and with a diameter of less than 0.1 mm. We give the same notation 8 or 80%. In Figure 6, there is a perforating object 21 through a perforation 61 disposed in the outer longitudinal groove 9 of the tire. There, the application of the surfactant product makes it possible to visualize a set of small bubbles 63 of diameter substantially between 0.1 mm and 1 mm. This is a low leak rated 6 or 60%. In Figure 7 (a), there is an obj and perforating 21 through a perforation 71 always disposed in a longitudinal groove of the tire. The application of the surfactant product makes it possible to display a single large bubble 73 with a diameter greater than 1 mm. We are in the presence of a leak rated 0 or 0%. [0096] In FIG. 7 (b), the longitudinal groove of the tire shows a perforation 72 of the perforating object has been expelled during rolling or extracted after stopping. In the same way, we see only one large bubble 73 with a diameter greater than 1 mm. This is a leak rated 0 or 0%. The following tables present the results of the protocol nails. Table 1: protocol before rolling nails Notes before rolling 03 mm 03 mm 05 mm 04 mm Positions SC SE CT SC SE CT SE CT SC SE CT Notes With: 10 - SE: nail placed in the outer groove 9; - SC: nail placed in the central groove 7; and - CT: nail placed in a transverse hollow 11. [0098] No leak is observed for the 12 nails incorporated in the half of the crown block of the tire 1, the performance is 100%.

Table 2: protocol after rolling nails in place after rolling 10 10 10 10 10 10 10 10 10 10 10 10 03 mm 03 mm 05 mm 04 mm Positions SC SE CT SC SE CT SE CT SC SE CT 6 6 Notes 10 10 10 10 8 10 6 10 10 8 [0099] After six hours of driving at 100 km / h, none of the twelve nails were ejected. A very low leakage is observed for a nail with a diameter of 3 mm; a low leak noted 6 and a very low leak noted 8 for nails 4 mm in diameter and two low leakage noted 6 for nails 5 mm diameter. The performance thus decreases by 97% for nails with a diameter of 3 mm to 80% for those with a diameter of 4 mm and 73% for those with a diameter of 5 mm. Table 4 above shows the results observed when placing screws 40 mm in length in the crown of the tire. Twelve screws were inserted on a 1/2 tire. Hot notations are made ("hot tire" line) and then after cooling of the tire ("cold tire" line). It should be noted that the insertion of the screws leads in this example to the systematic appearance of more or less important leaks. The performance index is 25% hot tire and 30% after cooling the tire. All or part of these leaks will disappear during taxiing. P10-3296 EN 10 Notes to TO 10 Notes to T10 - 15 - Table 3: Post-extraction Stud Protocol [00101] Table 3 above shows the results observed after tearing off the nails. Two phases of notations are performed: immediately after tearing (TO) and 10 minutes later (T10). Note that some notes can evolve between 5 TO and T10. The results are good between 80 and 90%. An overall score "nails in place" can be calculated from the results of Table 2, by weighting the different nail diameters with a frequency curve appearance of nails customers. Likewise, an overall rating of "torn nails" can be calculated from the results of Table 3. [00103] The following tables present the results of the screw test. Table 4 - vis - notes protocol before rolling length 40 length 40 length 40 length 40 Positions SC SE CT SC SE CT SC SE CT SC SE CT Hot tire 0 0 6 6 0 0 0 0 0 6 6 6 Cold tire 0 0 6 6 0 0 0 0 6 6 6 6 03 mm 03 mm 05 mm 04 mm Check after rolling and removing nails Positions SC SE CT SC SE CT SC SE CT SC SE CT 10 8 8 8 8 8 8 8 8 8 10 8 8 10 8 8 10 8 10 10 8 10 - 16 - Table 5: vis - notes protocol after rolling at 70 km / h Notes after rolling length 40 length 40 length 40 length 40 Positions SC SE CT SC SE CT SC SE CT SC SE CT rolling 70 km / h 0 0 6 8 0 0 0 0 0 10 8 6 [00105] Table 5 presents the results observed at the end of the first test run of the protocol vis à 70 km / h. The index obtained is very close to the two preceding before the rolling: 32%. Table 6: vis - notes protocol after running at 130 km / h Notes after rolling length 40 length 40 length 40 length 40 Positions SC SE CT SC SE CT SE CT SC SE CT rolling 130 8 pulling TO 8 pulling out 8 T10 [00106] Table 6 above shows the results observed at the end of the second run at 130 km / h. Note on this case that the notes have increased significantly between the first and second rolling with the screws in place: Im = 60%. Table 6 also shows the results observed at the end of the tearing of the screws. As for nails, two phases of notations are performed: immediately after tearing (TO) and 10 minutes later (T10). The scores obtained after tearing of the screws are 72% for TO and 90% for T10. [00108] The following tables present the results of the cork test Table 7: protocol corks - notes after placement and tearing Notes before rolling 0 8 10 0 10 10 0 6 10 0 10 8 8 8 6 8 6 6 10 0 8 10 10 10 8 10 10 6 8 10 10 8 10 05 mm 04 mm 05 mm 05 mm Positions SC SE CT SC SE CT SC SE CT SC SE CT Wick? After pulling away 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 7 TABLE 7 above shows the results observed after the setting and removal phases of the nails. If a note is 0, the hole is wicked and a new insertion is made a little further on the top of the tire. Table 8: protocol plugs - notes after rolling at 150 km / h [00110] It is mainly 5mm diameter nails which are used: it is desired to reveal the possible weaknesses of the tested product on the most unfavorable cases. [00111] Table 8 above shows the results observed at the end of rolling. Two phases of notations are performed: immediately after tearing (TO) and 10 minutes later (T10). Note that the majority of the scores are at 10. [00112] Table 9 below presents the results of the second part of the puncture resistance test, at a temperature of 0 ° C. The notes are average scores obtained for the first two tires at a temperature of 01 0 ° C. Since, surprisingly, no net influence of nail diameter was observed, this table does not detail the results obtained as a function of this nail diameter. Table 9: Test part 2 at 0 ° C Average rating at 01 = 0 ° C 94% Note after placing nails (TO) 99% Note 1 hour after placing nails (TO + 1h) 93% Note after tearing of nails (Ti) 86% Note 10 mm after tearing of nails (Ti + 10 min) 93% [00114] After placing nails, only a nano-leak was noted for one of the 20 nails of diameter 3 mm. P10-3296 EN 0 5 mm 04 mm 05 mm 05 mm TO 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 T10 Notes after rolling Positions SC SE CT SC SE CT SC SE One hour later, there were 8 nano-leaks distributed according to the three diameters of the nails, hence the lowest score of 93%. Immediately after the tearing of the nails, at Ti, there were two leaks marked 0, seven nano-leaks noted 8 and 15 perforations well closed, hence the score of 86%. Finally, 10 minutes after tearing of the nails (Ti + 10 min), it was observed only a leak rated 0, a micro-leak noted 6, two nano-leaks noted 8 and twenty perforations well closed, d ' where the rating of 93%. One of the leaks had become a micro-leak and seven nano-leaks had closed on their own. The assembly gives a mean resistance index at 0 ° C. of 94%. Table 10 below shows the results of the second part of the puncture resistance test, at a temperature of -10 ° C. [00120] The notes are average scores obtained for the last two tires at a temperature 02 of -10 ° C. Since, surprisingly, no net influence of nail diameter was observed, this table does not detail the results obtained as a function of this nail diameter. Table 10: Second part test at -10 ° C Average rating at 02 = -10 ° C 96% Note after placement of nails (TO) at 01 99% Note 4 hours after placement (T2 + 4) of 02 99% Note after removal of nails (T3) at 02 89% Note 10 mm after tearing of nails (T3 + 10mn) at 02 89% [00121] After placing nails, it was noted only a nano-leak for one of the nails of diameter 3 mm, note: 99%. [00122] After lowering the temperature to 02 as described earlier and awaiting thermal stabilization, no evolution was observed, hence the identical score of 99%. Immediately after the tearing of the nails, at T3, there was observed a leak rated 0, eight nano-leaks noted 8 and 15 perforations well closed, hence the score of 89%. P10-3296 EN - 19 - [00124] Finally, 10 minutes after tearing off the nails (T3 + 10 min), the same leak noted 0 was observed, the same eight nano-leaks noted 8 and the same twenty perforations well closed, hence the same rating of 89%. The set gives an average resistance index at -10 ° C of 96%. As there is no rolling, this second part of the test gives high average resistance indices but can track the influence of temperature on this resistance and thus characterize the performance of these tires in a wide range. range of uses. [00127] The test described concerned a tire equipped during its manufacture of a layer of self-sealing product. As already indicated, the described test also makes it possible to test other solutions such as puncture-resistant bombs and repair kits. [00128] Tests have been carried out with these other solutions. It can be seen that the shutter performance is practically 100% for all the solutions during a puncture with instantaneous removal of the perforating object. On the other hand, when running with a perforating object in place, from 200 to 300 km of rolling, the performance of the puncture-resistant bombs becomes zero, the product exits through the perforations. As far as the repair kits are concerned, their performance is better but they also decrease very strongly with the length of the rolling carried out with the perforating objects in place. [00129] The test thus described has the advantage of being very selective and complete. It also has the advantage of being based on the analysis of the leak rates of each perforation and not on a loss of pressure, which makes it possible to obtain numerous results with a single tire or with a very small number of tires. Similar. P10-3296 EN

Claims (22)

REVENDICATIONS1. A method of testing the resistance of a tire to a loss of pressure subsequent to perforation, characterized in that: in a first part carried out at an ambient temperature of greater than 10 ° C: the wall of said tire is created in the plurality of perforations by inserting through said wall a plurality of piercing objects; the tire comprising the perforating objects is rolled over a given distance with a regulated inflation pressure; - stop the rolling; and - for each perforation a pressure loss resistance index based on an estimate of the leakage rate of said perforation is determined; - In a second part carried out at an ambient temperature of less than 10 ° C: - is created in the wall of said tire or a similar tire a plurality of perforations by inserting through said wall a plurality of piercing objects; for each perforation, a pre-index of cold resistance to the pressure loss based on an estimation of the flow rate of said perforation is determined; the plurality of piercing objects is extracted from the wall of said tire; and for each perforation, a cold resistance index is determined for the loss of pressure based on an estimation of the leakage rate of said perforation. 2. Test method according to claim 1, wherein in the second part, the plurality of piercing objects is composed of tapered objects and smooth walls such as nails. 3. Test method according to any one of the preceding claims, wherein the assembly of the second part is performed when the tire is at a temperature between -20 ° C and + 10 ° C. 4. Test method according to any one of the preceding claims, wherein the first part comprises two phases such that: in the first phase, the plurality of piercing objects is composed of tapered objects and with smooth walls such as nails and the rolling is carried out so that the objects are not ejected during taxiing; and in the second phase, the plurality of perforating objects is composed of tapered but walled objects having a thread such as screws and the rolling is carried out at speeds below 80 km / h. 5. Test method according to claim 4, wherein the insertion of the perforating objects of the second phase of the first part is performed when the tire is at a temperature of the order of 50 to 60 degrees Celsius. 6. Test method according to one of claims 4 and 5, wherein the rolling of the first phase of the first part is performed at a fixed speed Vi between 90 and 120 km / h. 15 7. Test method according to one of claims 4 to 6, wherein the rolling of the second phase of the first part is performed at a fixed speed V2 between 50 and 75 km / h. 20 8. Test method according to any one of the preceding claims, wherein the second phase of the first part further comprises a second test at a fixed speed V2_2 greater than 80 km / h. 9. Test method according to any one of claims 4 to 8, further comprising in the first part a third phase with the following steps: - creating in the wall of said tire a plurality of perforations by inserting through said wall a plurality of piercing objects; extracting from the wall of said tire the plurality of piercing objects; rolling the tire after extracting the piercing objects at a speed V3 greater than 120 km / h over a given distance with a regulated inflation pressure; - stop taxiing; and P10-3296 EN-22- determining for each perforation a pressure loss resistance index based on an estimation of the leakage rate of said perforation. The test method of claim 9, wherein the speed V3 is fixed and less than 180 km / h. 11. Test method according to any one of the preceding claims, wherein, the tire does not include a self-sealing product, in the first part, at the end of the rolling and before determining the indices of resistance to loss. pressure, is placed in the internal cavity of the tire a sealant. 12. Test method according to any one of the preceding claims, wherein, the tire having no self-sealing product, in the second part, after inserting and tearing the perforating objects, it is put in place in the internal cavity. From the tire a sealant, the tire is, if necessary, returned to the test temperature of the second part, and the pressure loss resistance index is determined. A test method according to any one of the preceding claims, wherein in the first part, the rolling distance of the tire having a plurality of perforations through its wall is greater than 200 km and preferably greater than 500 km. . 14. Test method according to any one of the preceding claims, wherein, in the first part, the rolling of said tire is performed on a steering wheel. A test method according to any one of the preceding claims, wherein the tire is inflated prior to inserting the plurality of piercing objects through the wall of said tire. 30 P10-3296 GB- 23 - 16. Test method according to any one of the preceding claims, wherein the inflation pressure during the different parts of the test is regulated at a pressure of between 1.8 and 5 bar depending on the type of tire. 17. Test method according to any one of the preceding claims, wherein the plurality of piercing objects comprises screws and nails of various diameters and / or lengths. 18. Test method according to any one of the preceding claims, wherein the plurality of piercing objects comprises from 10 to 50 perforating objects, preferably between 20 and 40. 19. Test method according to any one of the preceding claims, wherein the diameter of the perforating object or objects is 3 to 5 mm. 15 20. Test method according to any one of the preceding claims, wherein the perforating object or objects are inserted into the crown of the tire. 21. A test method according to any one of the preceding claims, wherein a surfactant is used to qualitatively visualize and assess the leakage rate of each perforation. 22. Test method according to claim 21, wherein the following scale is used to assess the leakage rate of a perforation: 25 - 100: no bubble is visible, no leakage; - 80: nano-leakage, very small bubbles less than 0.1 mm in diameter, visible only by magnifying glass; - 60: micro-leakage, small bubbles visible to the naked eye, with a diameter of between 0.1 and 1 mm; 30 - 0: leakage, evolutionary bubbles of diameter greater than 1 mm, or no bubble due to too much air flow. P10-3296 EN