JP5508743B2 - Shock absorbing member - Google Patents

Description

  The present invention relates to an impact-absorbing member mainly composed of ceramics. More specifically, the present invention has a feature of extremely high hardness and strength while being lightweight, and has high energy possessed by a high-speed flying object and the like. The present invention relates to an impact-absorbing member that is extremely useful as a constituent material of a protector and exhibits a function of absorbing efficiently.

  2. Description of the Related Art Conventionally, various proposals have been made for members having ceramics as a main constituent material and having excellent impact energy absorption. For example, in Patent Document 1, a plurality of composite fiber bodies formed by coating a long core material made of ceramics with a ceramic material different from the core material are converged into a sheet, and a plurality of sheets are further provided. A laminated shock absorbing member is described. This shock absorbing member is made of lightweight, high hardness and high strength ceramics with a specific shape, thereby greatly improving its fracture toughness and improving the shock absorbing properties of high-speed flying objects. Patent Document 2 proposes a composite absorbent member using a plurality of pellets made of a high-density ceramic material. Specifically, in order to absorb and dissipate kinetic energy from a high-speed flying object, a single inner layer of pellets formed by embedding a plurality of pellets in an elastic material is formed in the composite absorbent member. It is described that they are arranged. Patent Document 3 includes a cellular structure having a plurality of polygonal openings, and a pair of sheets that house inserts of ceramic materials such as boron carbide in the openings and seal the openings. A constructed composite absorbent member is described. And this insert is for converting the kinetic energy of a projectile at the time of an impact, and encloses the fragment waste generated by an impact, and also makes it contain in a cellular structure for structural reinforcement. Yes. Patent Document 4 describes that an impact-resistant reinforcement made of ceramic as a main material is included in the front and back of the helmet in order to improve impact resistance without increasing the weight of the helmet. . Patent Document 5 proposes a protective member having improved impact resistance by multilayering ceramics having different characteristics. Specifically, carbide ceramics with low specific gravity and high hardness are used for the impact receiving part including the impact receiving surface, and ceramics with high fracture toughness are used for the base located on the back side of the impact receiving part. Thus, the kinetic energy of the deformed and fragmented projectile can be absorbed or dissipated.

JP 2004-284874 A JP 2005-114340 A JP 2005-520116 A JP 2002-294512 A JP 2008-275208 A

In the prior art described above, various ceramic materials are used as the impact resistant material. In Patent Document 1, as a combination of materials of the core material and the coating layer, silicon nitride-boron nitride, silicon nitride-silicon carbide, silicon nitride-alumina, (alumina, zirconia) -silicon nitride, silicon nitride-cermet, (alumina, Titanium carbonitride)-(alumina, zirconia) and the like are described. The combination of silicon nitride and boron nitride is preferable from the viewpoint of specific strength (strength with respect to weight). Furthermore, examples of the core ceramic material include boron carbide, silicon carbide, zirconia, silicon nitride, aluminum nitride, boron nitride, titanium boride, and diamond.
In Patent Document 2, as the pellet forming material, oxides, nitrides, carbides, borides, and the like of aluminum, magnesium, zirconium, tungsten, molybdenum, titanium, and silicon are cited.
Patent Document 3 describes alumina, boron carbide, silicon carbide, and silicon nitride as insert materials. Further, Patent Document 4 lists silicon carbide, boron carbide, silicon nitride, and alumina as the main component of ceramics. In Patent Document 5, the receiving part is made of a ceramic containing boron carbide as a main component, further a ceramic containing graphite and silicon carbide, and the base is a ceramic containing silicon nitride as a main component. It is described that it consists of.

  In any of the above-described conventional techniques relating to members having excellent impact energy absorption, etc., the ceramics to be formed are selected from the viewpoints of weight reduction, high strength, and high hardness for the purpose of destroying flying objects by the members. doing. In other words, until now, ceramic materials have not been selected from the viewpoint of absorbing the kinetic energy of the flying object in order to reduce the impact of the flying object inside the member. For example, in Patent Document 1 described above, a long composite fiber body is formed of a core material and a covering material made of different ceramic materials, but the composite fiber body is focused into a specific shape as a sheet-like member. By doing so, the flying object that collided with the member is deflected, and the impact can be absorbed. For this reason, this technique has a problem that the manufacturing process is extremely complicated and the manufacturing cost is high. On the other hand, if the impact of the high-speed flying object can be absorbed in a plate shape, the manufacturing can be most easily performed and the manufacturing cost can be reduced.

  Also, in the prior art, when a flying object collides with an impact absorbing member, which is most important under actual use conditions, small pieces or impact stress waves generated by destruction or crushing are lost behind the impact absorbing member. In order to be able to completely prevent this, the thickness of the member has to be extremely increased. However, increasing the thickness of the shock absorbing member causes an increase in weight, which means that energy consumption during movement and transportation during actual use increases, and an excessive burden on human bodies and vehicles, etc. Will be applied. In Patent Document 5, ceramics having different functionalities are multilayered, and a conventional ceramic ceramic is used while improving impact resistance resistance by using carbide ceramics having low specific gravity, high hardness and high impact resistance for the impact receiving portion. However, according to the study by the present inventors, since the carbide ceramic has low fracture toughness, there is a drawback that the impact surface is easily cracked.

  Therefore, the purpose of the present invention is to reliably prevent the shattered pieces and shock stress waves from coming out behind the shock absorbing member at the same time as destroying the high speed flying object when the high speed flying object collides, And it is providing the plate-shaped impact-absorbing member very useful as a constituent material of a protector which is lightweight and can be manufactured simply.

  The above object is achieved by the present invention described below. That is, the present invention is an impact absorbing member in which at least a first plate-like sheet and a second plate-like sheet are laminated, and the first plate-like sheet is made of partially stabilized zirconia. The second plate-like sheet is made of any material of boron carbide, mullite, or alumina, and the first plate-like sheet is disposed on the outermost surface, and the second plate-like sheet is disposed on the back surface thereof. It is an impact-absorbing member characterized in that a plate-like sheet is disposed.

  The following are mentioned as a more preferable form. The impact absorbing member described above, wherein the partially stabilized zirconia contains tetragonal crystals in a range of 70 to 99%. The above-mentioned shock absorbing member in which the first plate-like sheet and the second plate-like sheet are repeatedly laminated. The impact absorbing member, wherein the first plate-like sheet and the second plate-like sheet are laminated via any one of an epoxy resin, a silicone resin, a urethane resin, or a polycarbonate resin. Furthermore, said impact-absorbing member which has the 3rd plate-shaped sheet | seat which consists of high-strength fibers, and the 4th plate-shaped sheet | seat which consists of metals on the opposite side to the outermost surface.

  ADVANTAGE OF THE INVENTION According to this invention, although it is a comparatively thin and lightweight plate-shaped impact-absorbing member, the impact-absorbing member which can fully absorb the kinetic energy from a high-speed flying body is provided. Furthermore, when the high-speed flying object collides with the shock absorbing member, the high-speed flying object can be destroyed, and it is possible to reliably prevent the crushed pieces and shock waves from coming out behind the shock absorbing member, An impact-absorbing member that can be easily manufactured and economically excellent is provided. In particular, by arranging a first plate-like sheet made of partially stabilized zirconia on the outermost surface and combining a second plate-like sheet made of a material selected from boron carbide, mullite and alumina on the back surface, The kinetic energy absorption capacity of the high-speed flying object is higher than the combination of ceramics proposed in the invention described in Patent Document 5, and the outermost surface is less likely to break when the high-speed flying object collides. An impact absorbing member excellent in functionality is provided.

It is a schematic diagram which shows an example of the impact-absorbing member of this invention. It is a schematic diagram which shows another example of the impact-absorbing member of this invention.

  Hereinafter, the present invention will be described in more detail with reference to preferred embodiments of the present invention. As a result of intensive studies to solve the problems of the prior art described above, the present inventors can destroy a high-speed flying object by laminating plate-like ceramics of different types (functions), and exercise from the high-speed flying object. We have found that it is possible to provide a shock absorbing member that sufficiently absorbs energy and can reliably prevent the shattered pieces and shock waves from coming out behind the shock absorbing member. .

  According to the study by the present inventors, when a conventionally used metal is replaced with ceramics to form an impact absorbing member, the conventional technology simply uses a ceramic material from the viewpoint of weight reduction, high strength, and high hardness. Was going to choose. On the other hand, in order to make the member capable of exhibiting an excellent function as a protective device while maintaining the lightness, the present inventors efficiently use the impact absorbing member for kinetic energy from the high-speed flying object. It is important to be able to absorb and surely reduce damage to people, vehicles, etc. existing inside the shock absorbing member, which is feared to be generated by crushing fragments generated at the time of high-speed flying object collision I came to realize that. And from this point of view, various studies were made on the ceramic material constituting the shock absorbing member.

  As a result, it was found that partially stabilized zirconia is effective as a material for forming a plate-like sheet located on the outermost surface. Such a material is a high-strength ceramic material as conventionally known, but according to the study by the present inventors, when this is used as the outermost surface material that faces a high-speed flying object, The high-speed flying object can be destroyed at the time of collision, and at the same time, the kinetic energy of the high-speed flying object can be absorbed with high efficiency by utilizing the stress-induced phase transition and elastic deformation. In addition, the outermost surface is highly tough and difficult to break. Furthermore, in order to achieve the object of the present invention, the present inventors have used a high-speed flying object as another sheet material laminated on the back side of the first plate-like ceramic sheet made of partially stabilized zirconia. It has been found that it is effective to use a material that can reduce the fragments generated at the time of collision and convert the kinetic energy of the high-speed flying object into surface energy. That is, in the impact absorbing member of the present invention, a sheet made of any material selected from boron carbide, mullite and alumina (hereinafter also referred to as a material such as boron carbide) is used in combination as the second plate-like sheet. .

  Partially stabilized zirconia, which is a material for forming the first plate-like sheet positioned at least on the outermost surface of the shock absorbing member of the present invention, is a representative material for high-strength ceramics, but has a large specific gravity so far. The use of the product has been avoided because it becomes heavy when it is made into a product. In the impact absorbing member of the present invention, the partially stabilized zirconia is formed into a plate shape (that is, thinned) to reduce the weight. According to the study by the present inventors, the impact absorbing member of the present invention is provided with a partially stabilized zirconia plate-like sheet on the outermost surface, so that the flying object can be destroyed at the time of collision of the high-speed flying object. At the same time, the energy of the flying object can be absorbed with high efficiency by martensite transition and elastic deformation that occur during the collision. The impact-absorbing member of the present invention has a structure in which a first plate-like sheet having the above-described function is combined with a second plate-like sheet made of a ceramic having a low specific gravity selected from boron carbide, mullite, and alumina. By doing so, the following functions are further given. According to the study by the present inventors, a plate-like sheet made of a material such as boron carbide is destroyed at the time of collision with a high-speed flying object, but the crushed pieces at that time are extremely small. Since large energy is required to reduce the size of the fragment, the kinetic energy of the high-speed flying object is converted into surface energy at the time of this destruction. And by laminating these two types of ceramic plate-like sheets having different functions, the shock absorbing member of the present invention achieves extremely high shock absorption and at the same time partially stabilized with high specific gravity. The amount of zirconia used can be reduced. As a result, it is possible to reduce the weight and reduce the overall thickness of the shock absorbing member. As a result of weight reduction, the shock absorbing member of the present invention can reduce energy consumption during movement and transportation during actual use, and can reduce the burden on human bodies, vehicles, and the like. Furthermore, since the shock absorbing member of the present invention having the above-mentioned structure has a simple shape structure, it can be expected to reduce its manufacturing cost as compared with the conventional one, and its practical value is extremely high.

  As a more preferable form of the shock absorbing member of the present invention, in addition to the above-mentioned first and second types of ceramic sheet, the opposite side of the outermost surface of the shock absorbing member (that is, the inside of the shock absorbing member) And the third and fourth plate-like sheets made of the following materials are further laminated on the side facing the person or vehicle existing in the vehicle. For example, a structure in which a third plate-like sheet made of a high-strength fiber such as an aramid fiber and a fourth plate-like sheet made of a metal having a small specific gravity such as aluminum or magnesium are further laminated. It is preferable to do. In this case, the fourth plate-like sheet made of metal may be a layer farthest from the outermost surface on the side facing the person or the vehicle. These materials are usually provided in a plate shape, and the impact absorbing member of the present invention can be manufactured at a low cost also in this respect.

  The material for forming each sheet constituting the impact absorbing member of the present invention will be described in more detail. The partially stabilized zirconia of the first plate-like sheet forming material generates high strength, low elastic modulus, and stress-induced phase transition. For this reason, the partially stabilized zirconia plate-like sheet employed on the outermost surface with which the high-speed flying object collides can destroy the flying object due to its high strength characteristics. On the other hand, the kinetic energy of the flying object at the time of collision is absorbed by utilizing the stress-induced phase transition between the tetragonal crystal and the monoclinic crystal generated in the crystal phase. Furthermore, since the elastic modulus is small, the kinetic energy of the flying object is absorbed by elastic deformation. As a result, the impact absorbing member of the present invention exhibits extremely high impact absorbability. Furthermore, the impact absorbing member of the present invention combines the first plate with the second plate-like sheet made of any material of boron carbide, mullite, or alumina, so that the second plate-like sheet The impact on the inside (human body, vehicle, etc.) is further reduced, and it is more useful as a component of the protective equipment. As described above, these materials constituting the second plate-like sheet have a high ability to convert the kinetic energy of the flying object into surface energy by becoming fine fragments.

  As partially stabilized zirconia used by this invention, what has the following characteristic is preferable. That is, it is preferable that the strength is 500 MPa or more and the crystal phase mainly contains tetragonal crystals. Specifically, it is preferable to use a crystal whose tetragonal crystal important for stress-induced phase transition is 70 to 99%, particularly 85 to 99%. Moreover, it is preferable to use that whose elasticity modulus is 250 GPa or less. Further, the thickness of the partially stabilized zirconia plate-like sheet is not particularly limited, but is preferably about 2 to 20 mm, more preferably about 5 to 10 mm. As a more preferable form, it is also effective to have a configuration in which a plurality of thin plate-shaped sheets made of partially stabilized zirconia having a thickness of about 2 to 3 mm are stacked. This point will be described later.

A second plate-like sheet (hereinafter referred to as a plate-like sheet of boron carbide or the like) made of any material selected from boron carbide, mullite and alumina, which constitutes the impact absorbing member of the present invention, will be described. As described above, according to the study by the present inventors, by providing a plate-like sheet such as boron carbide, the impact absorbing member of the present invention has a high-speed flying body made of partially stabilized zirconia on the outermost surface. When the plate-like sheet is collided and destroyed, the large kinetic energy of the flying object can be converted into surface energy. That is, a plate-like sheet made of boron carbide or the like is finely crushed by this energy due to a fractured piece or shock wave of a high-speed flying object that has penetrated the partially stabilized zirconia-made plate-like sheet. As a result, the impact on the inside of the shock absorbing member when the high-speed flying object collides with the shock absorbing member of the present invention is remarkably reduced. Accordingly, any material having the above functions can be used. In the impact absorbing member of the present invention, in consideration of its strength, specific gravity, fracture toughness, etc., any one of boron carbide, mullite, and alumina is selected and used. Among these, it is preferable to use a material having a fracture toughness value of 5 MPa · m ^0.5 or less in order to ensure a fine crushed piece. Fracture toughness indicates a resistance value against a unidirectional load of a member having a crack-like defect, and represents a measure of brittleness in a ceramic material.

  In particular, boron carbide is suitable for the use of the present invention because it is lightweight and exhibits a low fracture toughness value and more finely crushed when subjected to an impact. The present inventors have developed a method for economically firing boron carbide at normal pressure (see WO / 2008/153177), and if this technique is used, a plate-like sheet of boron carbide can be made cheaper. This is also advantageous because it can be expected to be provided. The thickness of the plate-like sheet such as boron carbide is not particularly limited, but is about 2 to 20 mm, more preferably about 5 to 10 mm. As a more preferable form, a plate-like sheet of thin boron carbide or the like having a thickness of about 2 to 3 mm is repeatedly laminated with a plurality of, for example, partially-stabilized zirconia plate-like sheets. Is also effective.

  The impact absorbing member of the present invention has a first plate-like sheet made of partially stabilized zirconia and a second plate-like sheet made of boron carbide or the like, and the outermost surface thereof is from the first plate-like sheet. However, it is preferable that these are sequentially or directly laminated via a cushioning material. Specifically, there may be at least one combination of a plate sheet made of partially stabilized zirconia and a plate sheet made of boron carbide or the like, and a plate sheet made of partially stabilized zirconia and boron carbide or the like. It is also a preferable form to repeat the combination in which the plate-like sheets are sequentially laminated. The number of repetitions varies depending on the thickness of each sheet and its use and is not particularly limited, but can be, for example, about 3 to 30.

  Examples of a method of sequentially laminating a partially stabilized zirconia plate-like sheet and a plate-like sheet of boron carbide or the like include the following methods. For example, it is possible to sequentially laminate only these plate-like sheets by means of placing them in a mold, or between these plate-like sheets, it is made of a resin such as an epoxy resin, a silicone resin, a urethane resin, or a polycarbonate resin. It is good also as a form which pinches | interposes a shock absorbing material. By sandwiching such a cushioning material, it is possible to more effectively absorb the kinetic energy of the flying object by elastic deformation made by the plate sheet made of partially stabilized zirconia. Moreover, if these buffer materials are materials having adhesive ability, it is also possible to integrate a plate sheet made of partially stabilized zirconia and a plate sheet such as boron carbide through the buffer material. In the case of bonding, it is preferable to perform point bonding instead of bonding over the entire surface in order to make the functions of both sheets better.

  As a more preferable form of the shock absorbing member of the present invention, a plate sheet made of partially stabilized zirconia and a plate sheet made of boron carbide or the like are sequentially laminated, and further, on the side opposite to the surface side having the outermost surface. And a plate-like sheet made of a backup material as described below. For example, it is preferable to have a structure in which a third plate-like sheet made of high-strength fibers such as aramid fibers and a fourth plate-like sheet made of metal are laminated. As the metal, it is preferable to use a metal having a small specific gravity such as aluminum or magnesium from the viewpoint of reducing the total weight of the shock absorbing member of the present invention. Moreover, it is good to make the plate-shaped sheet | seat which consists of metals into the layer most distant from the outermost surface. By providing a plate-like sheet made of these materials as a back-up layer, the remnants of broken high-speed flying objects, crushed pieces of plate-like sheets such as finely broken boron carbide, and partially stabilized zirconia It is possible to prevent the crushed pieces of the manufactured plate-like sheet from penetrating the back side of the plate-like sheet such as boron carbide. In FIG. 1, as an example of the impact absorbing member of the present invention, a first plate sheet made of partially stabilized zirconia, a second plate sheet made of boron carbide or the like, and a third plate made of aramid fibers. The schematic diagram of the thing formed by laminating | stacking this sheet | seat and the 4th plate-shaped sheet | seat which consists of aluminum was shown. By comprising in this way, each sheet | seat plays the following role with each function which the material has, and shows the outstanding impact absorption as a result. The first plate-like sheet disposed on the outermost surface destroys the high-speed flying object at the time of collision, and has energy absorption ability due to energy absorption and elastic deformation of the high-speed flying object due to phase transition. In addition, the second plate-like sheet laminated on this is finely shattered by the remnants of the high-speed flying object that penetrates the first plate-like sheet and shock waves, so that the kinetic energy of the flying object is surface energy. It has the function to convert to. Further, the third plate-like sheet and the fourth plate-like sheet as backup materials for these layers have a function not to penetrate the crushed pieces of the first and second plate-like sheets that have been crushed. Have Furthermore, by setting it as the said structure, the impact-absorbing member of this invention becomes a weight reduction remarkably compared with the thing which has a conventional equivalent function.

  The impact-absorbing member of the present invention includes, in addition to the above-described sheets made of the above materials, further laminated sheets of materials or structures that have been reported to efficiently absorb the energy of high-speed flying objects, such as those listed below. It may be made. For example, a sheet made of rubber exhibiting fluidity utilizing rheology (dilatancy) characteristics, or a sheet made of metal or ceramics having a honeycomb structure can be used as the laminated material.

  The following are mentioned as another preferable form of the impact-absorbing member of this invention. In the example shown in FIG. 1, four layers of materials having different characteristics are combined one by one to have a structure that absorbs energy with high efficiency. Here, the energy of the high-speed flying object varies greatly depending on its speed, material and shape. Depending on the thickness of each sheet constituting the shock absorbing member of the present invention, for example, a high-speed flying body several times the speed of sound, a high-speed flying body having an elongated shape, a high-speed flying made of lead or a carbide material In the body, it cannot be said that the structure shown in FIG. According to the study by the present inventors, in order to obtain a more efficient energy absorber while maintaining the light weight of the shock absorbing member, as shown in FIG. 2, the first made of partially stabilized zirconia is used. It is possible to provide a shock-absorbing member with more excellent characteristics by using a plurality of plate-like sheets and a plurality of second plate-like sheets such as boron carbide and repeatedly laminating these sheets. Become. For example, a combination of a first plate-like sheet having a thickness of about 2 mm and a second plate-like sheet having a thickness of about 4 mm is repeated from, for example, 5 to 10 to be fired from various devices. It can handle extremely high-speed flying objects. In addition to this, the impact absorbing member is lighter and more economical than the conventional one in terms of its ability. In addition, in conventional impact-resistant products intended to withstand high-speed flying objects, it was necessary to use locally soft members or extremely heavy members. In contrast, the impact absorbing member of the present invention can be applied.

The present invention will be described in more detail with reference to examples of the present invention.
[Example 1]
(Preparation of first plate-like sheet)
A high-purity partially stabilized zirconia powder containing 3% yttria is filled in a 9 cm square mold, pressed at 600 kg / cm ² , and then hydrostatically pressed at 1 ton / cm ² to obtain a thickness of 6 mm. A molded body was produced. Next, the obtained molded body was fired by holding at 1550 ° C. for 2 hours in an air atmosphere. Then, the obtained fired body was ground using a diamond grindstone to obtain a plate-like sheet having a thickness of 4 mm and 7 cm square. The obtained sheet was extremely dense with almost theoretical density. The obtained partially stabilized zirconia was quantitatively analyzed for the crystal phase by XRD and Raman spectroscopy. As a result, the sintered body was almost (at least 80%) tetragonal.

(Preparation of second plate-like sheet)
A commercially available boron carbide powder was filled in a 9 cm square mold, pressed at 200 kg / cm ² , and then hydrostatically pressed at 1 ton / cm ² to produce a molded body having a thickness of 6 mm. A boron carbide powder having an average particle size of 0.8 μm and a purity of 99.5% (excluding oxygen content of 1.2% and nitrogen content of 0.2%) was used. The boron carbide molded body obtained above was fired by placing aluminum and silicon in a firing furnace and holding at 2,200 ° C. for 4 hours under normal pressure while flowing argon gas. The obtained fired body was ground using a diamond grindstone to obtain a plate-like sheet having a thickness of 4 mm and a 7 cm square. The obtained plate-like sheet made of boron carbide was extremely dense with a relative density of 96.8%.

  A commercially available mullite powder was molded in the same manner as boron carbide, and then fired at 1650 ° C. for 2 hours in an air atmosphere. The obtained fired body was processed in the same manner as boron carbide to obtain a plate-like sheet having the same shape. The alumina sheet was prepared in the same manner as mullite, except that a commercially available 99% grade alumina powder was used and the firing temperature was 1630 ° C.

(Preparation of backup material)
A 3 mm thick 7 cm square third plate-like sheet composed of a plurality of 1 mm thick sheets made of a commercially available aromatic aramid resin Kevlar (Kevlar: registered trademark, manufactured by DuPont). Prepared. Moreover, a 4 mm thick, 7 cm square aluminum metal plate was prepared as a fourth plate-like sheet.

(Evaluation method and evaluation result of each sheet constituting the shock absorbing member)
An impact test was performed using a gas accelerator. This apparatus is a system in which the pressure of compressed air is transmitted to a flying object through a predetermined medium, and the flying object passes through the inside of the launch tube and collides with a sample. The experiment was performed at almost the speed of sound using a flying body of 4 mmφ bearing steel. Each of the partially stabilized zirconia, boron carbide, alumina, and mullite sheets obtained above was individually subjected to an impact fracture test.

  As a result, for the partially stabilized zirconia, the flying object was broken into pieces, while the partially stabilized zirconia had lateral cracks. For the partially stabilized zirconia sample after the test, the crystal phase was identified using a micro-Raman spectrometer for the part where the projectile collided and the part where the projectile collided. It was confirmed that a stress-induced phase transition occurred. Also, when shooting with a high-speed video camera before and after the flying object collided, it was found that the time from the collision of the flying object to the occurrence of a lateral crack was longer than other ceramics. From this, it was found that partially stabilized zirconia exhibits a behavior that hinders the amount of elastic deformation and crack propagation at the time of collision of a high-speed flying object. From the above results, it was confirmed that the partially stabilized zirconia has the ability to destroy the flying object and absorb the kinetic energy of the flying object by stress-induced phase transition and elastic deformation.

  In the results for the boron carbide, mullite, and alumina plate-like sheets, both the high-speed flying object and the plate-like sheet were broken into pieces. Each sample had lateral cracks and cone cracks, and the volume removed by the cone cracks was larger in the order of mullite, boron carbide, and alumina.

(Preparation and evaluation of impact absorbing member of Example 1)
The first plate-like sheet made of the partially stabilized zirconia prepared above is used as the outermost surface, the second plate-like sheet made of boron carbide is laminated on the lower layer, and the lower layer is made of an aramid fiber. A third plate-like sheet and an aluminum metal plate as a fourth plate-like sheet were sequentially laminated to obtain an impact absorbing member of this example (see FIG. 1). The impact test similar to the above was performed on the impact absorbing member of this example obtained in this way. As a result, the high-speed flying object was destroyed by the first plate-like sheet. Moreover, the 2nd plate-shaped sheet of the lower layer was crushed into the small pieces about 0.1 to several mm square. Furthermore, it was confirmed that the fragments of the high-speed flying object and the small pieces of the boron carbide plate did not reach the outside of the metal plate.

[Comparative Example 1]
(Evaluation results for each plate-like sheet used in the comparative example)
For use in comparative examples, plate-like sheets composed of stabilized zirconia and silicon nitride having the same shape as used in the examples were prepared, and impact tests similar to those described above were performed on these plate-like sheets. Went. As a result, the flying object was destroyed even in the stabilized zirconia sheet, and lateral cracks and cone cracks were generated. However, as a result of microscopic Raman spectroscopy analysis of the part where the projectile collided and the part where it did not, no stress-induced phase transition was observed. This indicates that stabilized zirconia does not have the ability to absorb the kinetic energy of flying objects due to phase transition. In addition, the flying object was destroyed even with a silicon nitride plate-like sheet, and lateral cracks and cone cracks were generated. However, the size of the cone crack was small compared to any of the plate sheets of boron carbide, mullite, and alumina. From this, it was found that the energy absorption capacity of the high-speed flying object is smaller in the silicon nitride plate-like sheet than in the plate-like sheet such as boron carbide.

(Preparation of member of comparative example and its evaluation)
A plate-like sheet made of stabilized zirconia prepared above is used as the outermost surface, and a plate-like sheet made of silicon nitride is laminated on the lower layer thereof. Were laminated as a backup layer to obtain a member of this comparative example. When the obtained member was subjected to the same impact test as described above, the high-speed flying object was destroyed by the plate-like sheet made of stabilized zirconia and the plate-like sheet made of silicon nitride. Damage was seen. Damage to the metal plate was found to be a slab that was thought to have penetrated several tens of millimeters of fragments that seemed to be silicon nitride. It is thought that.

[Example 2]
A plate-like sheet made of partially stabilized zirconia similar to that prepared in Example 1 and a plate-like sheet made of boron carbide were used. And the impact-absorbing member of the present example was obtained in the same manner as in Example 1 except that these combinations were repeatedly laminated 5 times (see FIG. 2). When the same impact test as described above was performed on the obtained impact absorbing member, the high-speed flying body was broken, and all of the five plate-like sheets made of boron carbide were about 0.1 to 0.1. It was broken into small pieces with a size of several mm square. In particular, the way to break the first to third sheets was remarkable. Furthermore, also in the present Example, it confirmed that the fragment | piece of a high-speed flying body and the small piece of a boron carbide board did not reach an outer side rather than a metal plate.

  The shock-absorbing member of the present invention exhibits a high shock-absorbing property equivalent to that of the conventional one, and at the same time is lighter than that of the conventional one, and its thickness can be reduced. Is preferred. As an application example of the present invention, various impacts that can be exerted on human bodies, vehicles, etc. from various high-speed flying bodies can be mitigated reliably and in a manner that reduces the burden on human bodies, vehicles, etc. It is conceivable to provide products economically.

1: First plate-like sheet 2: Second plate-like sheet 3: Third plate-like sheet 4: Fourth plate-like sheet

Claims (5)

An impact absorbing member in which at least a first plate-like sheet and a second plate-like sheet are laminated,
The first plate-like sheet is made of partially stabilized zirconia containing tetragonal crystals in the range of 70 to 99% , and
The second plate-like sheet is made of any material of boron carbide, mullite or alumina;
Furthermore, the impact-absorbing member, wherein the first plate-like sheet is disposed on the outermost surface and the second plate-shaped sheet is disposed on the back surface thereof. The first or second plate-shaped sheets, each made from a single material, the shock-absorbing member according to claim 1 that thickness Ru 2~20mm der.   The impact absorbing member according to claim 1 or 2, wherein the first plate-like sheet and the second plate-like sheet are repeatedly laminated.   The first plate-like sheet and the second plate-like sheet are laminated via any one of an epoxy resin, a silicone resin, a urethane resin, or a polycarbonate resin. The impact-absorbing member described in 1.   The impact according to any one of claims 1 to 4, further comprising a third plate-like sheet made of high-strength fibers and a fourth plate-like sheet made of metal on the side opposite to the outermost surface. Absorbing member.

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