RU2010154317A - HIGH-DENSITY CERAMIC BLOCKS AND INCLUDING THEIR COMPOSITE ARMOR - Google Patents

Abstract

 1. A high-density ceramic briquette formed as a single piece for use in a ballistic armor plate, said ceramic briquette having a longitudinally extended body part and an impact-receiving end face, in which at least the main part of said body part is either round or hexagonal in cross-section, and the specified shock-receiving end side includes:! - shock proximal segment; and! - distal segment; ! moreover, the specified proximal segment is convexly curved, and the specified distal segment of the specified shock-receiving end side is connected to the nominally indicated upper surface of the specified body part, and the specified distal segment of the specified end side includes side surfaces characterized by:! a region including at least one part that has a concave configuration; or ! an area including a substantially even inclined configuration! the cross-sectional area of the specified distal segment in the area of closure is larger than the cross-sectional area drawn through the nominally indicated base of the specified proximal segment, and the length of the contour line of the outer surface of the distal segment in the longitudinal section is between 5 and 25% of the entire contour line length molded as a single part of the shock-receiving end side in longitudinal section. ! 2. The high-density ceramic briquette according to claim 1, wherein said ceramic briquette has a D / R ratio between the diameter D of said ceramic briquette and the radius

Claims (22)

1. A high-density ceramic briquette formed as a single piece for use in a ballistic armor plate, said ceramic briquette having a longitudinally extended body part and an impact-receiving end face, in which at least the main part of said body part is either round or hexagonal in cross-section, and the specified shock-receiving end side includes: - shock proximal segment; and - distal segment; moreover, the specified proximal segment is convexly curved, and the specified distal segment of the specified shock-receiving end side is connected to the nominally indicated upper surface of the specified body part, and the specified distal segment of the specified end side includes side surfaces characterized by: a region including at least one part that has a concave configuration; or a region including a substantially even inclined configuration, the cross-sectional area of the specified distal segment in the area of closure is larger than the cross-sectional area drawn through the nominally indicated base of the specified proximal segment, and the length of the contour line of the outer surface of the distal segment in the longitudinal section is between 5 and 25% of the entire contour line length molded as a single part of the shock-receiving end side in longitudinal section. 2. The high-density ceramic briquette according to claim 1, wherein said ceramic briquette has a D / R ratio between the diameter D of said ceramic briquette and the radius of curvature R of said convexly curved end face of at least 0.64: 1. 3. The high-density ceramic briquette according to claim 1, wherein the relative H / D / R ratios of height H of said cylindrical briquette, with the exception of the height of said end face, diameter D of said briquette and radius of curvature R of said at least one convexly curved end face, are between about 7.5: 12.8: 9 and 7.5: 12.8: 20. 4. The high-density ceramic briquette according to claim 1, wherein said ceramic briquette is provided with two convexly curved end surfaces. 5. The high-density ceramic briquette according to claim 1, in which the contour of the specified molded as a single part of the shock-receiving end side in longitudinal section includes two convex arcs with different radii, the first of these arcs being placed along the surface of the specified proximal segment; and a second convex arc is located along the surface of the specified distal segment. 6. The high-density ceramic briquette according to claim 1, wherein said briquette has an Al ₂ O ₃ content of at least 85% by weight and a specific gravity of at least 2.5 g / cm ³ . 7. The high-density ceramic briquette according to claim 1, wherein said ceramic briquette has an Al ₂ O ₃ content of at least 90% by weight and a specific gravity of at least 3 g / m ³ . 8. The high-density ceramic briquette according to claim 1, wherein said ceramic briquette comprises boron carbide, titanium diboride, silicon carbide, magnesium oxide, silicon aluminum oxide, aluminum oxide or mixtures thereof. 9. The high-density ceramic briquette according to claim 1, wherein said distal segment has the shape of a truncated cone. 10. The high-density ceramic briquette according to claim 1, wherein said side surfaces are characterized by a region including a substantially even inclined configuration. 11. The high-density ceramic briquette according to claim 1, wherein said smooth inclined region makes an acute angle with said nominally designated upper surface of said body. 12. The high-density ceramic briquette according to claim 1, wherein said substantially convexly curved impact receiving end face comprises a plurality of individual fragments which, when assembled together, take a convexly curved geometric shape. 13. A composite ballistic armor plate comprising a panel provided with a layer of a plurality of high-density ceramic briquettes according to claim 1, wherein said briquettes are arranged in numerous adjacent rows and columns, the main axes of these briquettes being oriented essentially parallel to each other and essentially perpendicular to the impact surface specified panel. 14. The composite armor of claim 13, wherein said columns are substantially perpendicular to said rows, and in which in each of said rows of ceramic briquettes of said each row are offset, and in each of said columns ceramic briquettes of said each column are offset relative to each other so that each of most of these ceramic briquettes is in contact with two briquettes in the first adjacent row and two briquettes in the second adjacent row so that each of the majority of briquettes is in contact with four, and only with four adjacent briquettes, and where in each row the centers of neighboring ceramic briquettes in each specified row are displaced essentially by a first distance relative to each other, and in each column the centers of adjacent ceramic briquettes in each specified column are offset relative to each other essentially by a second distance, the first distance being different from the second distance. 15. The composite armor of claim 14, wherein one of said first and second distances is greater than the other one of said first and second distances by a factor of at least 1.1 to 1.5. 16. The composite armor of claim 14, wherein said ceramic briquettes are embedded in an elastic material. 17. The composite armor of claim 13, wherein said panel has an inner and outer surface, said outer surface facing the strike side, and said ceramic briquettes arranged in numerous adjacent rows, the cylinder axes of said briquettes being substantially parallel to each other and perpendicular panel surfaces, with convex curved end surfaces directed to the outside. 18. The composite armor of claim 13, further comprising an inner layer adjacent to said inner surface of said panel, wherein said inner layer is formed of a plurality of adjacent layers, each layer comprising a plurality of unidirectional anti-ballistic fibers embedded in the same plane embedded in a polymer matrix, moreover, the fibers of adjacent layers are oriented at an angle from about 45 ° to 90 ° relative to each other. 19. The composite armor of claim 13, further comprising an inner layer adjacent to said inner surface of said panel, said inner layer being formed from a plurality of adjacent layers, each layer containing ballistic material. 20. A composite ballistic armor plate comprising a panel provided with a layer of a plurality of high-density ceramic briquettes according to claim 1, wherein said briquettes are arranged in numerous adjacent rows and columns, the main axes of these briquettes being oriented essentially parallel to each other, and each of the majority of these The briquettes are in direct contact with six neighboring briquettes, while the sides of three adjacent briquettes form a contact cavity between them. 21. The composite ballistic armor plate according to item 13, in which each of the majority of these briquettes is essentially in contact with at least three adjacent briquettes, further characterized in that the gaps formed between these adjacent cylindrical briquettes are only partially filled with material for preventing the flow of soft metal from striking flying objects at specified intervals, and the specified flow preventing material is formed as a single part as part of an internal insert briquette, wherein said insert briquette is in the form of a cylinder provided with protrusions extending only partially in the spaces formed between the sides of six adjacent cylindrical briquettes and overlapping the main part of the cross section of these spaces, each of these protrusions being in a position remote at least at least from one of the two adjacent cylinders, in the direction of which he stands, and moreover, these briquettes are connected and held together with the formation of the plate with verzhdaemogo material, said hardenable material and said plate are elastic. 22. A method of obtaining a high-strength ceramic briquette according to claim 1, the method comprising the steps of: d. ceramic powder is placed in the mold, said mold comprising: i. a removable segmented upper pressure punch, the punch including: 1. an end segment having a proximal and distal part relative to the direction of application of pressure through the specified punch, the proximal part is concave curved, and the distal part is characterized by: but. lateral regions comprising at least one portion that has a convex configuration; or b. side regions having a substantially even inclined configuration; and ii. clip, and the clip is essentially cylindrical in shape and has at least one flat or round lower end, sides and upper end, moreover, the specified upper pressure punch is inserted into the specified holder of the specified mold with the possibility of extraction; and from. inserting said upper pressure punch into said mold and applying pressure to said mold through said upper pressure punch; as a result of applying the specified pressure to the specified mold receive high-density ceramic briquette according to claim 1. 23. Ceramic briquette for use in a ballistic armor plate, wherein said ceramic briquette includes: - body part having: axis; a cross-sectional shape that is symmetrical about an axis; and an end portion representing the extremity of the indicated body portion, said end portion having an outer surface including a first and second section, in which: - the specified first section has a convex curvature; said first section is distant from said case, and said first section comprises an axis of the case passing through it; and - the specified second section extends around the specified axis of the body part, and the specified second section is placed between the specified first section and the specified body part; and said second section has a first annular edge at said first section or adjacent to it, and a second annular edge at said said hull or adjacent to it; wherein said second section has such a configuration that essentially every intersection between the specified second section and the planes including the axis of the body part, passes in a straight line, or such a configuration that essentially every intersection between the specified second section and the planes including the specified axis body part, passes along a line that has a concave curvature, if viewed from the outside of the specified briquette; - and end part; however, the average radial distance from the specified axis of the housing to the specified first annular edge of the specified second section is at least 5% less than the average radial distance from the specified axis of the housing to the specified second annular edge of the specified second section. 24. The briquette according to item 23, in which the cross-sectional shape of the specified body portion is round or hexagonal. 25. The briquette according to item 23, in which the specified outer surface of the specified end portion is formed essentially completely specified by the first section and the specified second section. 26. The briquette of claim 23, wherein said first and second annular edges are round. 27. The briquette of claim 23, wherein said first and second annular edges are hexagonal. 28. The briquette according to item 23, in which the specified first section of the specified outer surface consists of many individual fragments, which, when assembled together, take a convex curved geometric shape. 29. A composite ballistic armor plate comprising a panel provided with a layer of a plurality of briquettes according to claim 23, wherein said briquettes are arranged in numerous adjacent rows and columns, the main axes of said briquettes being oriented substantially parallel to each other and substantially perpendicular to the impact surface of said panel . 30. The composite armor of claim 29, wherein said columns are substantially perpendicular to said rows, and in which ceramic briquettes of said each row are offset from each other in each of said rows, and ceramic briquettes of said each column are offset in each of said columns relative to each other so that each of the majority of ceramic briquettes is in contact with two briquettes in the first adjacent row and two briquettes in the second adjacent row so that each of the majority of briquettes is contact with four and only four adjacent briquettes, and where in each row the centers of neighboring ceramic briquettes in each specified row are displaced essentially by the first distance from each other, and in each column the centers of adjacent ceramic briquettes in said each column are displaced from each other essentially a second distance, the first distance being different from the second distance. 31. The composite armor of claim 29, wherein one of said first and second distances is greater than the other one of said first and second distances by a factor of at least 1.1 to 1.5. 32. The composite armor of claim 29, wherein said ceramic briquettes are embedded in an elastic material. 33. The composite armor of claim 29, wherein said panel has inner and outer surfaces, said outer surface facing the strike side, and said ceramic briquettes are arranged in numerous adjacent rows, the cylinder axes of said briquettes being substantially parallel to each other and perpendicular panel surfaces, with convex curved end surfaces directed to the outside. 34. The composite armor of claim 29, further comprising an inner layer adjacent to said inner surface of said panel, said inner layer being formed of a plurality of adjacent layers, each layer comprising a plurality of unidirectional anti-ballistic fibers embedded in the same plane embedded in a polymer matrix, moreover, the fibers of adjacent layers are oriented at an angle from about 45 ° and 90 ° relative to each other. 35. A composite ballistic armor plate comprising a panel provided with a layer of a plurality of briquettes according to claim 23, wherein said briquettes are arranged in numerous adjacent rows and columns, the main axes of said briquettes being oriented essentially parallel to each other, and each of the majority of said briquettes is in direct contact with six adjacent briquettes, while the sides of three adjacent briquettes form a contact cavity between them. 36. The composite ballistic armor plate according to clause 29, in which each of the majority of these briquettes is essentially in contact with at least three adjacent briquettes, further characterized in that the gaps formed between these adjacent cylindrical briquettes are only partially filled with material for preventing the flow of soft metal from striking flying objects at specified intervals, and the specified flow preventing material is formed as a single part as part of an internal insert briquette, wherein said insert briquette is in the form of a cylinder provided with protrusions extending only partially in the spaces formed between the sides of six adjacent cylindrical briquettes and overlapping the main part of the cross section of these spaces, each of these protrusions being in a position remote at least at least from one of the two adjacent cylinders, in the direction of which he stands, and moreover, these briquettes are connected and held together with the formation of the plate with verzhdaemogo material, said hardenable material and said plate are elastic. 37. A method of obtaining a high-strength ceramic briquette according to claim 1, wherein the method comprises the steps of: but. ceramic powder is placed in the mold, said mold comprising: i. a removable segmented upper pressure punch, the punch including: 1. an end segment having first and second parts relative to the direction of application of pressure through the specified punch, the first section being placed proximally relative to the specified direction of application of pressure, and the specified second section is placed distally relative to the specified direction of application of pressure, and said first section is concave curved, and and the second section is characterized by: but. lateral regions comprising at least one portion that has a convex configuration; or b. side regions having a substantially even inclined configuration; and ii. clip, and the clip is essentially cylindrical in shape and has at least one flat or round lower end, sides and upper end, moreover, the specified upper pressure punch is inserted into the specified holder of the specified mold with the possibility of extraction; and f. inserting said upper pressure punch into said mold and applying pressure to said mold through said upper pressure punch; as a result of applying the specified pressure to the specified mold receive high-density ceramic briquette according to item 23.