RU2136405C1 - H-shape - Google Patents

Abstract

FIELD: rolled stock production, possibly manufacture of metallic structures in building, machine engineering and other industry branches. SUBSTANCE: H-shape includes in cross section joinings of flanges and web and at least a part of joining line at least of one flange with web that form angles due to crossed axes of flanges, and web and(or) at least a part of web line and(or) at least a part at least of one flange and(or) at least one edge at least of one flange made in the form of fragment of oblique cone section of straight round cone. It provides increased smoothness of transitions of curve portions at maintaining smoothness independently upon roll wear, lowered cost price of H-shape manufacture due to decreased formation degree of shape at rolling process and enhanced wear resistance of rolling rolls. EFFECT: lowered cost price of H-shape, enhanced technological effectiveness, decreased material consumption at maintaining carrying capability in condition of lengthwise axially non-symmetrical compression, torsion or bending. 32 cl, 18 dwg

Description

 The invention relates to the field of rolling production and can be used in construction, engineering and other types of metal structures.

State of the art
Analogs to the proposed device can be considered:
1. "I-beam profile N 19 for a spinal beam" GOST 5267.5-90, containing in cross section two shelves and a wall, the intersection of the shelves with the stack forms an angle.

 The disadvantage of the analogue is the high cost of manufacturing a profile. This is determined by the geometric features of the analog - part of the interface or other parts of the profile are made part of the circle, the characteristic of which is the radius. The implementation of the mates or other parts of the profile in the form of a part of a circle does not allow for a greater smooth transition in the sections of the curves and to reduce the cost of manufacturing the profile by increasing the resource of the rolling rolls.

 The term "pairing" should be understood as a mutual relationship [1].

 The radius of the circle is the segment connecting the point of the circle with the center [2].

 2. "Hot rolled flange profile" by A. S. USSR N 196689 op. 24.2.72 according to MKI B 21 V 1/08, containing in cross section two shelves and a wall, the intersection of the shelves with the wall forms an angle.

 The disadvantage of the analogue is the high cost of manufacturing a profile. This is determined by the geometric features of the analog - part of the interface or other parts of the profile are made part of the circle, the characteristic of which is the radius. The implementation of the mates or other parts of the profile in the form of a part of a circle does not allow for a greater smooth transition in the sections of the curves and to reduce the cost of manufacturing the profile by increasing the resource of the rolling rolls.

 The closest in technical essence to the prototype of the proposed device is the I-beam profile containing in the cross section of the mating shelves ("I-beam profile" A. S. USSR N 1692693, op. 23.11.91, MKI V 21 V 1/08).

 The disadvantage of the prototype is the high cost of manufacturing the profile. This is determined by the geometrical features of the prototype — the mating parts are made by parts of circles whose characteristics are radius. The implementation of the mating parts in the form of parts of circles does not allow for a rational smooth transition in the sections of the profile curves compared to fragments of an oblique conical section of a straight circular cone (fragments of a hyperbola, parabola, ellipse) that degenerate during the production of the profile into each other and reduce the cost of manufacturing the profile by increasing the resource of the rolling rolls.

 In the process of research, the authors established the pattern of degeneration during wear of the curves described by fragments of an oblique conical section of a straight circular cone (parabola, hyperbola, ellipse) into each other, which ensures a smooth transition in the sections of the profile curves (and roll) as they wear during rolling.

 From the point of view of maintaining a smooth transition in the sections of the curves as they wear during the rolling process, it is advisable to use fragments of a hyperbola, parabola and ellipse: these equivalent interchangeable and mutually compatible options exclude the formation of such curves that are most subject to degeneration (chipping) during wear, such as a circle.

 In the process of rolling a profile, an intensive ablation of metal occurs, first of all, from the angular protrusions of the caliber, as the most stressed sections of the roll, and therefore the pairing of shelves and walls as part of a circle becomes impossible without frequent changes in gauges and transshipment of rolls, as well as setting up the stand and mill generally. This in turn requires large material and time costs.

 Costs can be reduced by profiling the roll, in particular its curved sections, taking into account the minimization of future ablation of the material during rolling using fragments of oblique conical sections degenerating into each other (fragments of a hyperbola, parabola, ellipse).

 In addition, the prototype and analogues the task of increasing the bearing capacity with non-axisymmetric longitudinal compression, torsion or bending is solved only by increasing the thickness of the shelves and walls, which is irrational.

 So, to increase the carrying capacity of the profile under non-axisymmetric longitudinal compression, it is advisable to increase the mass of metal in the mating region closest to the point of application of force using fragments of oblique conical sections degenerating into each other (fragments of a hyperbola, parabola, ellipse).

 With transverse bending in a plane parallel to the longitudinal planes of the section of the shelves, it is advisable to increase the mass of metal at the edges of the shelves and reduce on the wall, as well as in the areas of conjugation of the shelves with the wall using fragments of oblique conical sections degenerating into each other (fragments of hyperbola, parabola, ellipse) .

 When torsion, it is advisable to increase the mass of metal in the central part of the wall and reduce it at the edges of the shelves using fragments of oblique conical sections degenerating into each other (fragments of a hyperbola, parabola, ellipse).

SUMMARY OF THE INVENTION
The objective of the invention is to reduce the cost of manufacturing an I-beam by extending the service life of the rolls by maintaining a smooth transition in sections of the profile curves (roll) during wear by using a combination of fragments of oblique conical sections of a straight circular cone degenerating into each other (fragments of a hyperbola, parabola, ellipse) , increasing the manufacturability of manufacturing through the use of a combination of fragments of oblique conical sections of a straight circular cone, degenerating into each other and e emanating from the projected before rolling parameters, reducing material while maintaining the bearing capacity under nonaxisymmetric longitudinal compression, torsion or bending through the use of the combination of conic sections slanting fragments of a right circular cone, degenerate each other and provide rational configuration profile for the predicted loading schemes.

 During profile rolling, fragments of oblique conical sections of a straight circular cone due to ablation of material from the working surface of the roll degenerate into each other (fragments of hyperbola, parabola, ellipse), however the process of ablation of material from the working surface of the roll is predicted in advance and taken into account when designing and calculating the configuration profile and does not go beyond the definition of an oblique conical section of a straight circular cone.

 The specified technical result of the invention is achieved by the fact that the I-beam profile contains in cross section the interface between the shelves and the wall and at least a part of the interface line of at least one shelf with the wall, which form corners at the intersection of the axis of the shelves and the wall, and / or at least part of the wall line , and / or at least part of the line of at least one shelf, and / or at least one edge of at least one shelf is made in the form of a fragment of an oblique conical section of a straight circular cone. This ensures a smooth transition from a fragment to a fragment of the cross-sectional profile, consisting of fragments of oblique conical sections that degenerate into each other (fragments of a hyperbola, parabola, ellipse) during the rolling process, which reduces the cost of manufacturing the profile by reducing the profile shape during rolling and increase the wear resistance of the rolls.

 In addition, the shape of the profile to a greater extent meets the requirements of the criterion: providing a given strength with a minimum mass of the profile.

 The term "axis of the shelf" should be understood as an imaginary straight line passing through the section of the shelf, characteristic of a given section of the shelf, for example, the smallest axial moment of inertia.

 The term "wall axis" should be understood as an imaginary straight line passing through a wall section, characteristic of a given wall section, for example, the smallest axial moment of inertia.

 The term "oblique conical section" should be understood as the line formed by the surface of the straight circular cone and the secant plane that does not pass through its top, provided that the angle between the secant plane and the axis of the direct circular cone is different from the right angle [2].

 The I-beam profile may contain in cross section a portion of the line connecting the shelf with the wall, forming the intersection of the axes of the shelf and the wall with an angle made in the form of a fragment of an oblique conical section of a direct circular cone (a fragment of a hyperbola, parabola, ellipse), and fragments of an oblique conical section of a direct circular cone can degenerate into each other during the production of the profile. This ensures greater smoothness of the interface between the shelf and the wall, consisting of fragments of oblique conical sections that degenerate into each other during the rolling process, reducing the cost of manufacturing the profile by reducing the work of forming the profile during rolling and increasing the wear resistance of the rolling rolls.

 The I-beam profile may contain in cross section a portion of the line of the shelf made in the form of a fragment of an oblique conical section of a straight circular cone (fragment of a hyperbola, parabola, ellipse), and fragments of an oblique conical section of a direct circular cone can degenerate into each other during the production of the profile. This ensures a rational shape of the shelf, consisting of fragments of oblique conical sections, and fragments of the oblique conical section of a straight circular cone can degenerate into each other during the rolling process, reducing the cost of manufacturing the profile by reducing the work of forming the profile during rolling and increasing the wear resistance of the rolling rolls.

 The I-beam profile may contain in cross section a part of the wall line made in the form of a fragment of an oblique conical section of a direct circular cone (fragment of a hyperbola, parabola, ellipse), and fragments of an oblique conical section of a direct circular cone can degenerate into each other during the production of the profile. This ensures a rational shape of the wall, consisting of fragments of oblique conical sections, and fragments of the oblique conical section of a straight circular cone can degenerate into each other during the rolling process, reducing the cost of manufacturing the profile by reducing the work of forming the profile during rolling and increasing the wear resistance of the rolling rolls.

 The I-beam profile may contain in cross section the edge of the shelf, made in the form of a fragment of an oblique conical section of a straight circular cone (a fragment of a hyperbola, parabola, ellipse), and fragments of an oblique conical section of a direct circular cone can degenerate into each other during the production of the profile. This ensures a rational shape of the edge of the shelf, consisting of fragments of oblique conical sections, and fragments of the oblique conical section of a straight circular cone can degenerate into each other during the rolling process, reducing the cost of manufacturing the profile by reducing the work of forming the profile during rolling and increasing the wear resistance of the rolling rolls.

 The combination of the elements of the cross section of the profile in the form of fragments of oblique conical sections of a straight circular cone (fragments of a hyperbola, parabola, ellipse) that can degenerate into each other during the production of the profile ensures the achievement of a rational shape of the profile. At the same time, the cost of manufacturing the profile is reduced by reducing the work of profile shaping during rolling and the wear resistance of the rolling rolls is increased.

The I-beam profile can be made with the formation of the axes of the shelves and wall angles from 15 ^o to 165 ^o , which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with a shelf length different from one another, which will expand the technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with the length of the parts of at least one shelf from the place of mating with the wall to the edge, different from one another, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with shelves of various thicknesses, which will increase the local strength characteristics of the profile.

 The I-beam profile can be made with the thickness of the parts of at least one shelf from the place of mating with the wall to the edge different from one another, which will increase the local strength characteristics of the profile.

 The I-beam profile can be made with a variable wall thickness, which will increase the local strength characteristics of the profile.

 The I-beam profile can be made with increasing wall thickness in the direction from one shelf to another, which will increase torsion resistance relative to the longitudinal axis passing through the interface of the shelf with the wall in the place of its greater thickness.

 The I-beam profile can be made with increasing wall thickness in the direction from the shelves to the inner part of the wall, which will increase torsion resistance relative to the longitudinal axis passing through the central part of the wall.

 The I-beam profile can be made with a decrease in wall thickness in the direction from the shelves to the inner part of the wall, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with a stepped wall, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with a wall having a bend, which will expand technological capabilities when assembling structures from profiles.

The term "bend" should be understood to bend the section at an angle of up to 180 ^o .

 The I-beam profile can be made with a wall having multiple folds, including a change in concavity to the opposite, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with shelves of variable thickness, which will expand the technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with a variable thickness of at least one of the parts of at least one shelf from the point of interface with the wall to the edge, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with parts of at least one shelf from the place of mating with the wall to the edge, the thickness of one of which increases towards the edge, and the thickness of the other decreases, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with a step of at least one of the parts of at least one shelf from the interface with the wall to the edge, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with steps of the shelf and / or wall, which can have an increase or decrease in the thickness of the shelf and / or wall during the transition from one step to another, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with bending at least the edge of one of the parts of at least one shelf from the place of interface with the wall to the edge, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be performed with bending the edge of a part of at least one shelf from the place of mating with the wall to the edge toward the wall or away from the wall, and on both parts of the shelf with different size and / or direction of the bend and / or distance from the edge of the part shelves, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with repeated bending of a part of at least one shelf from the place of mating with the wall to the edge, including changing the concavity to the opposite, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with at least part of the internal line of coupling of at least one of the shelves with a convex wall relative to the coupling, which will increase torsion resistance relative to the longitudinal axis passing through this coupling.

 The I-beam profile can be made with at least part of the inner line of the interface of at least one of the shelves with a wall concave relative to the interface, which will reduce the metal consumption of the interface.

 The I-beam profile can be made at least on a part of the interface between at least one of the shelves with the wall with a recess, which will prevent cracking during bending of the wall.

 The I-beam profile can be made with at least one gap in the thickness of at least one shelf and / or wall. Moreover, thickness gaps can be performed repeatedly and periodically, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with at least one recess on a part of the surface length of at least one shelf and / or wall, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with at least one protrusion on part of the surface length of at least one shelf and / or wall, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with at least one recess on at least one edge of at least one of the shelves, which will expand the technological capabilities when assembling structures from profiles.

 An I-beam can be made with at least one protrusion on at least one edge of at least one of the shelves, which will expand technological capabilities when assembling structures from profiles.

 The I-beam profile can be made with part of at least one of the interface lines of at least one shelf to the wall, and / or part of the length of the surface of the shelf, and / or part of the length of the surface of the wall, and / or part of the edge of the shelf containing fragments and / or combination of fragments: polygon, conical section of a straight circular cone, which will improve the accuracy and accuracy of the assembly of structures from profiles by connecting the protrusion into the recess.

 The analysis of the prior art showed that the claimed combination of essential features set forth in the claims is unknown. This allows us to conclude that it meets the criterion of "novelty."

 To verify the conformity of the claimed invention with the criterion of "inventive step", an additional search was carried out for known technical solutions in order to identify features that match the distinctive features of the claimed technical solution from the prototype. It is established that the claimed technical solution does not follow explicitly from the prior art. Therefore, the claimed invention meets the criterion of "inventive step".

Information confirming the possibility of carrying out the invention
The invention and the possibility of its practical implementation is illustrated by drawings, where in Fig.1 shows a cross section of an I-profile, in Fig. 2-14 illustrate examples of a structural embodiment of a cross-section of an I-profile, FIG. 15-18 illustrate examples of constructive implementation of parts of the cross-section of the I-beam profile.

 The I-beam profile (Fig. 1, 2) contains a cross section in conjunction, including along part of line 1, of shelves 2 and 3 with wall 4, forming at the intersection of axes 5 and 6 of shelves 2 and 3 and axis 7 of wall 4, corners 8 and 9, wherein part of line 1, and / or at least part of line 10 of wall 4, and / or at least part of line 11 (12) of at least one shelf 2 (3), and / or at least one edge 13 (14, 15, 16) of at least one shelf 2 (3) are made in the form of a fragment 17 of an oblique conical section of a straight circular cone.

In examples of the structural embodiment of the I-beam profile shown in FIG. 1, 2, formed by the shelves 2 and 3 and the wall 4, the angles 8 and 9 can be from 15 ^o to 165 ^o .

 In examples of the structural embodiment of the I-beam profile shown in FIG. 2 - 8, 10, 11, 13, 14, the length of shelves 2 and 3 is different from each other.

 In examples of the structural embodiment of the I-beam profile shown in FIG. 7, 8, 10, 11, 13, 14, shelves 2 and 3 are made of various thicknesses.

 In examples of the structural embodiment of the I-beam profile shown in FIG. 5 - 8, shelf 2 is made of variable thickness, in figure 3, shelves 2 and 3 are made of variable thickness.

 In examples of the structural embodiment of the I-beam profile shown in FIG. 5 - 8, shelf 2 and wall 4 are made of variable thickness.

 In examples of the structural embodiment of the I-beam profile shown in FIG. 4 to 8, wall 4 is made of variable thickness.

 In an example of structural design of the I-beam profile shown in FIG. 4, the wall 4 is made with increasing thickness in the direction from the shelf 3 to the shelf 2.

 In an example of structural design of the I-beam profile shown in FIG. 6, the thickness of the shelf 2 decreases in the direction from the place of mating with the wall 4 to the edges 13 and 14, the wall 4 is made with increasing thickness in the direction from the shelves 2 and 3 to the inner part of the wall. The thickness of the shelves can vary in different directions: increase and / or decrease to the edge of the shelf.

 In an example of structural design of the I-beam profile shown in FIG. 7, the wall 4 is made with a decrease in thickness in the direction from the shelves 2 and 3 to the inner part of the wall.

 In an example of structural design of the I-beam profile shown in FIG. 8, the wall 4 and the shelf 2 are made with steps 18. The steps can be performed both with an increase in the thickness of the shelf 2 (3) or with the wall 4 when moving from one step to another, or with a decrease.

 In examples of the structural embodiment of the I-beam profile shown in FIG. 9 - 12, the shelf 2 (3) and / or the wall 4 is made with bends 19. The bends 19 of the shelf 2 (3) and / or the walls 4 can be made including with a multiple change in concavity to the opposite, with different sizes and / or the direction of the hem and / or the distance from the interface between the shelf 2 (3) and the wall 4.

 In an example of structural design of the I-beam profile shown in FIG. 13, a part of the mating of the shelf 2 with the wall 4 is made with a bulge 20 relative to the place of mating of the shelf 2 with the wall 4.

 In an example of structural design of the I-beam profile shown in FIG. 14, a part of the interface between the shelf 2 and the wall 4 is made with a recess 21 relative to the interface between the shelf 2 and the wall 4, and in FIG. 15, a part of the internal interface line 1 of the shelf 2 with the wall 4 is made with a recess 21.

 In an example of structural design of the I-beam profile shown in FIG. 16, part of the length of the surface of the shelf 2 (3) or wall 4 is made with recesses 22 and protrusions 23. In addition, the thickness of the section has a gap 33.

 In an example of structural design of the I-beam profile shown in FIG. 17, the edge 13 (14, 15, 16) of the shelf 2 (3) is made with recesses 24 and a protrusion 25.

 In an example of structural design of the I-beam profile shown in FIG. 18, the edge 13 (14, 15, 16) of the shelf 2 (3) contains a circle 31. A portion of at least one of the interface lines of at least one shelf with a wall, and / or a portion of a portion of the surface length of the shelf, and / or a portion of a portion the length of the wall surface, and / or part of the portion of the edge of the shelf may contain fragments and / or combinations of fragments: a polygon (square 26, rectangle 27, trapezoid 28, rhombus 29, triangle 30, etc., etc.), a conical section a straight circular cone (circle 31, ellipse 32, etc., etc.).

 Thus, the use of this design I-beam profile will achieve the objectives of the invention.

Literature
1. Explanatory dictionary of the Russian language. M. Az, 1993, 960s.

 2. Mathematical Encyclopedic Dictionary. M. "Soviet Encyclopedia", 1978, 847s.

Claims (32)

 1. An I-beam profile comprising, in a cross-section, the interface between the shelves and the wall, characterized in that at least a part of the interface line of at least one shelf with the wall, forming angles at the intersection of the axes of the shelves and the wall, and / or at least part of the wall line, and / or at least part of the line of at least one shelf, and / or at least one edge of at least one shelf is made in the form of a fragment of an oblique conical section of a straight circular cone. 2. The I-beam profile according to claim 1, characterized in that the angles formed by the axes of the shelves and walls are from 15 to 165 ^o .  3. I-beam profile according to claim 1 or 2, characterized in that the length of the shelves is different from each other.  4. I-beam profile according to any one of claims 1 to 3, characterized in that the lengths of the parts of the shelf of at least one of the shelves from the point of interface with the wall to the edge differ from each other.  5. I-beam profile according to any one of claims 1 to 4, characterized in that the shelves are made of various thicknesses.  6. I-beam profile according to any one of claims 1 to 5, characterized in that the parts of the shelf of at least one of the shelves from the point of interface with the wall to the edge are made of different thicknesses.  7. I-beam profile according to any one of claims 1 to 6, characterized in that the wall is made of variable thickness.  8. I-beam profile according to claim 7, characterized in that the wall is made with increasing thickness in the direction from one shelf to another.  9. The I-beam profile according to claim 7, characterized in that the wall is made with increasing thickness in the direction from the shelves to the inner part of the wall.  10. The I-beam profile according to claim 7, characterized in that the wall is made with a decrease in thickness in the direction from the shelves to the inner part of the wall.  11. I-beam profile according to claim 7, characterized in that the wall is stepped.  12. I-beam profile according to any one of claims 1 to 11, characterized in that the wall is made with a hem.  13. I-beam profile according to claim 12, characterized in that the wall bend can be made multiple, including with a change in concavity to the opposite.  14. I-beam profile according to any one of claims 1 to 13, characterized in that at least one of the parts of at least one shelf from the point of mating with the wall to the edge is made of variable thickness.  15. I-beam according to claim 14, characterized in that the thickness of one of the parts of at least one shelf from the point of mating with the wall to the edge increases towards the edge, and the thickness of the other decreases.  16. An I-beam profile according to any one of claims 1 to 15, characterized in that at least one of the parts of at least one shelf from the point of interface with the wall to the edge is made stepped.  17. The I-beam profile according to claim 16 or 11, characterized in that the steps can be performed both with an increase in the thickness of a part of the shelf and / or wall during the transition from one step to another, and with a decrease.  18. I-beam profile according to any one of claims 1 to 17, characterized in that at least the edge of one of the parts of at least one shelf from the point of interface with the wall to the edge is made with a hem.  19. The I-beam profile according to claim 18, characterized in that the bending of a part of at least one shelf from the place of mating with the wall to the edge can be performed toward the wall or away from the wall, and on both parts of the shelf with different sizes and / or the direction of the hem and / or the distance from the edge of the shelf part.  20. I-beam profile according to claim 19, characterized in that the bending of a part of at least one shelf from the point of mating with the wall to the edge can be performed multiple times, including changing the concavity to the opposite.  21. I-beam profile according to any one of claims 1 to 20, characterized in that at least a portion of the interface line between the shelf and the wall is convex relative to the interface.  22. The I-beam profile according to any one of claims 1 to 20, characterized in that at least a portion of the interface line of at least one shelf to the wall is made concave relative to the interface.  23. An I-beam according to any one of claims 1 to 22, characterized in that the thickness of at least one of the shelves and / or wall has at least one gap.  24. The I-beam profile according to claim 23, wherein the thickness gaps are made repeatedly and periodically.  25. I-beam profile according to any one of claims 1 to 20, characterized in that at least part of the interface section is made with a recess.  26. An I-beam according to any one of claims 1 to 25, characterized in that a part of the surface length of at least one shelf and / or wall is made with at least one recess.  27. An I-beam according to any one of claims 1 to 26, characterized in that a part of the surface length of at least one shelf and / or wall is made with at least one protrusion.  28. I-beam profile according to any one of claims 1 to 27, characterized in that at least one edge of at least one shelf is made with at least one recess.  29. An I-beam according to any one of claims 1 to 28, characterized in that at least one edge of at least one shelf is made with at least one protrusion.  30. An I-beam according to any one of paragraphs.25 to 29, characterized in that a part of at least one of the interface lines of at least one shelf to the wall, and / or part of a portion of the length of the surface of the shelf, and / or part of the portion of the length of the wall surface , and / or a part of the portion of the edge of the shelf contain fragments and / or combinations of fragments: a polygon of a conical section of a straight circular cone.  31. An I-beam profile according to any one of claims 1 to 30, characterized in that the thickness of at least one shelf and / or wall changes many times, increasing and decreasing.  32. I-beam profile according to p. 31, characterized in that the thickness varies periodically.

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