RU2143608C1 - Laminate rivet - Google Patents

Abstract

FIELD: manufacture of fastening articles, possibly for building, machine engineering and other metallic structures, in aircraft and missile technology, in ship building. SUBSTANCE: laminate rivet includes at least two subareas of materials. At least a part of line of cross section boundary and(or) at least a part of line of boundary of material subareas is in the form of fragment of oblique cone section of straight circular cone. EFFECT: constructionally caused directivity of strength properties, enhanced efficiency of fixation, easy identification of rivet maker. 16 cl, 16 dwg

Description

 The invention relates to the manufacture of fasteners, for example, by rolling, stamping, drawing, machining, extrusion or welding methods, including explosion, and can be used in construction, engineering and other types of metal structures, in aviation and rocket technology, as well as in shipbuilding .

Analogs to the proposed device can be considered the following:
1. A rivet with a semicircular head, GOST 1195 - 41, containing in the cross section of the rod the line of the boundary of the section in the form of a circle.

The disadvantages of the analogue are:
A) the lack of structurally laid directionality of strength properties, for example, when working on bending, which significantly complicates the design of the rivet. When designing structures containing riveted joints, as a rule, their future loading pattern is known, including the plane or planes of the greatest bending moments. The creation of an equally strong rivet design in all directions is irrational in this situation; it makes the rivet and the structure fastened by it in general heavier;
B) low efficiency of fixation when placed in the volume between the rivet body and the part (for example, the skin of the vessel) hardening, for example, compound mass. The rivet rod round in cross section does not contribute to effective adhesion to the compound mass;
C) low reliability of the determination of the manufacturer of the rivet due to the lack of a manufacturer's identifier on its body. Currently used product markings are short-lived, and branding leads to a weakening of the part’s structure, the appearance of zones with stress concentrators and microcracks on it. In the event of a structural failure or accident due to a rivet (defective rivet) that does not have a manufacturer identifier on the case, the process of finding a manufacturer and eliminating the cause of the malfunction is extremely difficult;
D) low corrosion resistance of the rivet operating in aggressive environments, which leads to accelerated wear of the rivet and reduce its strength and as a result of failure of the entire connection.

 2. A rivet with a semi-countersunk head, GOST 1190-41, containing in the cross section of the rod a line of the section boundary in the form of a circle.

The disadvantages of the analogue are:
A) the lack of structurally laid directionality of strength properties, for example, when working on bending, which significantly complicates the design of the rivet. When designing structures containing riveted joints, as a rule, their future loading pattern is known, including the plane or planes of the greatest bending moments. The creation of an equally strong rivet design in all directions is irrational in this situation; it makes the rivet and the whole structure fastened by it heavier.

B) low efficiency of fixation when placed in the volume between the rivet body and the part (for example, the skin of the vessel) hardening, for example, compound mass. The rivet rod round in cross section does not contribute to effective adhesion to the compound mass;
C) low reliability of the determination of the manufacturer of the rivet due to the lack of a manufacturer's identifier on its body. Currently used product markings are short-lived, and branding leads to a weakening of the part’s structure, the appearance of zones with stress concentrators and microcracks on it. In the event of a structural failure or accident due to a rivet (defective rivet) that does not have a manufacturer identifier on the case, the process of finding a manufacturer and eliminating the cause of the malfunction is extremely difficult;
D) low corrosion resistance of the rivet operating in aggressive environments, which leads to accelerated wear of the rivet and reduce its strength and as a result of failure of the entire connection.

 The closest in technical essence the prototype to the proposed device is a rivet containing at least one of the cross sections of the rod line boundary section, GOST 1189-41.

The disadvantages of the prototype are:
A) the lack of structurally laid directionality of strength properties (rigidity), for example, when working on bending, which significantly complicates the design of the rivet. When designing structures containing riveted joints, as a rule, their future loading pattern is known, including the plane or planes of the greatest bending moments. The creation of an equal strength (equal rigidity) rivet design in all directions in this situation is irrational, makes the rivet and the whole structure fastened by it more difficult.

To increase the strength properties (stiffness) of a rivet with a known pattern of its loading in the structure and, in particular, with a known plane of action of the maximum bending moment, it is advisable to constructively direct the direction of strength properties (stiffness) of the cross section of the rod. That is, it is advisable to produce a rivet with a cross section of the rod not in the form of a circle, but, for example, in the form of an ellipse, the moment of inertia of which is maximum in the direction of the larger axis. When assembling the structure, the rivet with its larger axis of the ellipse is oriented in the plane of action of the maximum bending moment;
B) low efficiency of fixation when placed in the volume between the rivet body and the fastened parts of the hardening, for example, compound mass. The rivet shaft round in cross section does not contribute to effective adhesion to the compound mass.

To increase the efficiency of fixation, it is advisable to perform rivets with a cross-section of the rod that is different from the circle, for example in the form of an ellipse, which increases the perimeter of the cross-section, and therefore the contact surface of the rivet with the compound mass;
C) low reliability of the determination of the manufacturer of the rivet due to the lack of a manufacturer's identifier on its body. Currently used product markings are short-lived, and branding leads to a weakening of the rivet design, the appearance of zones with stress concentrators and microcracks on it. In the event of a structural failure or accident due to a rivet (defective rivet) that does not have a manufacturer identifier on the body, the process of finding a manufacturer and eliminating the cause of the malfunction is extremely difficult.

To increase the reliability of the determination of the rivet manufacturer, part of the line of the border of the cross section can be made in the form of a fragment or combination of fragments of an oblique conical section of a straight circular cone, i.e. section of the line, which forms the surface of a straight circular cone and secant plane, not passing through its top. Moreover, for the identification of a particular manufacturer, it does not matter the particular particular case of the execution of this line, i.e. whether it is an ellipse, a hyperbola or a parabola. So, for example, to identify one of the manufacturers, the first quarter of the section line can be selected, and the second quarter to identify another manufacturer. In addition, depending on the specific manufacturer (its features), the first quarter will be made from a section of an ellipse, hyperbola or parabola. Any section of curves, united by the concept of "conical section", is uniquely identified using well-known mathematical methods [1-5];
D) low corrosion resistance of the rivet operating in aggressive environments, which leads to accelerated wear of the rivet and reduce its strength and as a result of failure of the entire connection.

 The objective of the invention is to create a layered rivet, providing a structurally laid directionality of strength properties (rigidity) during operation, for example, in bending, increased fixing efficiency when placed in the volume between the rivet body and the part hardening, for example, compound mass, high corrosion resistance, as well as increased reliability determination of the manufacturer of the rivet by constructively laying identification properties during its manufacture.

 The specified technical result of the invention is achieved in that the laminated rivet contains at least two subregions of materials, while at least part of the boundary line of the section and / or at least part of the boundary line of the subregions of materials is made in the form of a fragment of an oblique conical section of a straight circular cone.

This provides:
A) structurally incorporated orientation of the strength properties (rigidity) of the rivet, for example, when working on bending. The structurally incorporated directivity of the strength properties of the rivet cross section is formed during the shaping operations in the process of manufacturing the rivet.

 When designing structures containing riveted joints, as a rule, their future loading pattern is known, including the plane or planes of the greatest bending moments. The creation of an equal-strength (equal-rigid) rivet design in all directions is irrational in this situation; it makes the rivet and the whole structure fastened by it heavier.

To increase the strength properties (stiffness) of a rivet with a known pattern of its loading in the structure and, in particular, with a known plane of action of the maximum bending moment, a constructive laying of the directivity of the strength properties (stiffness) of the cross section of the rivet rod is formed. Those. a rivet with a cross-section of the rod is made not in the form of a circle, but, for example, in the form of an ellipse, the moment of inertia of which is maximum in the direction of the larger axis. When assembling the structure, the rivet with its larger axis of the ellipse is oriented in the plane of action of the maximum bending moment;
B) increased fixing efficiency when placed in the volume between the rivet body and the fastened parts of the hardening, for example, compound mass. The rivet bar, which is not round in cross section, contributes to more effective adhesion to the compound mass due to the increased lateral surface.

To increase the efficiency of fixation, it is advisable to make a rivet with a line, the border of the cross section of the rod, different from the circle, for example in the form of elements of an ellipse, hyperbola or parabola, i.e. in the form of fragments or combinations of fragments of an oblique conical section of a straight circular cone;
C) the high reliability of the manufacturer’s determination of the rivet due to the presence of the manufacturer’s identifier on its body (shaft). For this, part of the border line of the cross section of the rod is made in the form of a fragment or combination of fragments of an oblique conical section of a straight circular cone, i.e. section of the line, which forms the surface of a straight circular cone and secant plane, not passing through its top. Moreover, for the identification of a particular manufacturer, it does not matter the particular particular case of the execution of this line, i.e. whether it is an ellipse, a hyperbola or a parabola, or a combination of fragments thereof. So, for example, to identify one of the manufacturers, the first quarter of the section line can be selected, and the second quarter to identify another manufacturer. In addition, depending on the specific manufacturer (its features), the first quarter will be made from a section of an ellipse, hyperbola or parabola. Any part of the curves, united by the concept of "conical section", is uniquely identified using well-known mathematical methods [1-5].

 The proposed identifiers favorably differ from the markings and branding currently used due to the simplicity of their measurement by known metrological methods and their unambiguous recognition by known mathematical methods. Markings on products are short-lived, and branding leads to weakening of the rivet design, the appearance of zones with stress concentrators and microcracks on it. In the event of a structural failure or accident due to a rivet (defective rivet), the identifier on its body will uniquely identify the manufacturer, which helps to quickly eliminate the cause of the malfunction.

 It should be noted that at present, product identification with labels with bar, sign, digital, letter codes, as well as identifier sensors made in the form of oscillatory LC circuits is widespread. The combination of letters, numbers, as well as the tuning frequency of the LC circuit in the code is an identifier and uniquely identifies an object.

The mentioned identifiers and methods for applying them to objects are described in detail in the descriptions of Russian patents:
N 2045780, G 06 K 11/00, 10/10/95;
N 2074696, A 61 H 39/00, 03/10/97;
N 2102246, B 42 D 15/00, 01/20/98;
N 2106689, G 06 K 17/00, 03/10/98;
N 2112958, G 01 N 21/64, 06/10/98,
as well as in the descriptions of the utility model certificates:
N 0005883, G 09 F 3/02, 01/16/98;
N 0006461, G 09 F 3/02, 04/16/98.

However, the use of the above inventions to identify the produced rivet due to the specifics of the application of the latter is impractical and inefficient;
D) increased corrosion resistance of the rivet, working in aggressive environments, is achieved by performing a rivet layered, containing in the cross section of the smooth part of the rod at least two subregions of materials. The implementation of the outer layer of the rivet laminated from a corrosion-resistant material will significantly increase the corrosion resistance of the rivet laminated as a whole.

 Thus, the goal of the invention is achieved.

 In the process of developing materials for the invention and, in particular, the technical result and the independent claim, the applicant assessed the novelty of the invention according to the general principles and assessed the inventive step according to the general principles, as well as the "negative" and "positive" rules using the Rules for compiling, filing and consideration of applications for the grant of a patent for an invention (dated September 20, 1993) and Recommendations on the examination of applications for inventions and utility models (2nd edition, 1997).

 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. No solutions have been identified that have features that coincide with the distinguishing features of the invention, and the popularity of the influence of the distinctive features on the specified set of technical results is not confirmed. Therefore, the claimed invention meets the criterion of "inventive step".

 A laminated rivet can be made in cross section with a variable linear size of at least one of the subregions of the material, which will ensure structurally laid directionality of the strength properties. A change in the linear size in the cross section of at least one of the subregions of the rivet material can be achieved during forming operations.

 A laminated rivet can be made in cross section with a thickness of at least one of the material subregions, decreasing towards the center of mass of the cross section of this subregion, which will ensure rational stiffness of the rivet.

 A laminated rivet can be made in cross section with a thickness of at least one of the material subregions, increasing to the center of mass of the cross section of this subregion, which will ensure rational stiffness of the rivet.

 A laminated rivet can be made in cross section with a linear dimension in the cross section of at least one of the subregions of the material, varying, increasing and decreasing many times, which will ensure structurally laid directionality of the strength properties (in different directions).

 A laminated rivet can be made in cross section with a linear dimension in the cross section of at least one of the material subregions, changing repeatedly and periodically, which will allow for a structurally incorporated change in its strength properties.

 A laminated rivet can be made in cross section of at least one of the material subregions with a stepped part of the length of the section boundary line, which will improve the manufacturability of assembly of structures using rivets.

 A layered rivet can be made with steps along the length of the boundary line of at least one of the subregions of the material, which can have an increase or decrease in the linear size in the rivet section when moving from one step to another, which will increase the manufacturability of assembly of structures using rivets.

 A laminated rivet can be made with at least one recess on a part of the length of the section line of at least one of the subregions of the material, which will improve the manufacturability of the assembly of structures using rivets.

 A laminated rivet can be made with at least one protrusion on a part of the length of the sectional boundary line of at least one of the material subregions, which will improve the manufacturability of assembly of structures using rivets.

 A laminated rivet can be made with at least part of the length of the sectional boundary line of at least one of the material subregions containing fragments and / or combinations of polygon fragments in the section, which will improve the accuracy of assembly of structures using rivets when connecting a protrusion, for example, rivets and recess details.

 A laminated rivet can be made with at least part of the length of the sectional boundary line of at least one of the material subregions containing fragments or combinations of oblique conical section fragments passing into each other in the section, which will improve the accuracy of the rivet identification.

 A laminated rivet can be made with at least one linear dimension gap in the cross section of at least one of the material subregions. Moreover, linear size gaps in the cross section can be performed repeatedly and periodically, which will improve the manufacturability of assembly structures using rivets.

 The terms used in the application for the invention.

 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 [6].

 The term "oblique conical section" is used in this context throughout the description, including the claims.

 The term "identification" should be understood as establishing the correspondence of both a batch of objects and a piece object (product) to its individual identification mark. Identification can be carried out by applying the identifier (label) to the product or by entering the identifier into the product (on its surface), for example, an information signal about the rivet manufacturer in the form of the shape of the side surface of the smooth part of the rivet core.

 The term "identification" is used in this context throughout the description, including the claims.

 The term "rivet" means a fastener, usually a rod with a head.

 The term "rivet" is used in this context throughout the description, including the claims.

 The term "rod" means a structural element, the transverse dimensions of which, as a rule, are small in comparison with the length.

 The term "rod" is used in this context throughout the description, including the claims.

 The term "strength properties" should be understood to mean the ability of a material and its structure to resist fracture, as well as shape change, including irreversible shape change (plastic deformation) under the action of external loads, in the narrow sense - only fracture resistance. The strength properties of solids are ultimately determined by the forces of interaction between the atoms and ions that make up the body. The concept of "strength properties" is broader than strength, and combines strength itself, rigidity and stability. Strength properties depend not only on the material itself, the shape of its cross-section or longitudinal section, but also on the type of stress state (tension, compression, bending, etc.), on operating conditions (temperature, loading speed, duration and number of loading cycles, exposure to the environment environment, etc.). Depending on all these factors, various strength measures have been taken in the technique: tensile strength, yield strength, fatigue strength, etc. An increase in the strength properties of materials is achieved by heat and mechanical treatment, the introduction of alloying additives in alloys, radiation, the use of reinforced and composite materials, and the formation of cross (longitudinal) section with the maximum possible moment of inertia in the plane of action of the bending (torque) moment.

 The term "strength properties" is used in this context throughout the description, including the claims.

 The term "stiffness" in the narrow sense refers to the characteristic of a structural element that determines its ability to resist deformation (tensile, bending, torsion, etc.); depends on the geometric characteristics of the cross section and the physical properties of the material (elastic moduli).

 The term "rigidity" is used in this context throughout the description, including the claims.

 The term "deformation" (from Latin deformatio - distortion) refers to a change in the relative position of the points of a solid, at which the distance between them changes as a result of external influences. A deformation is called elastic if it disappears after removal of the impact, and plastic if it does not completely disappear. The simplest types of deformation are tension, compression, bending, torsion.

 The term "deformation" is used in this context throughout the description, including the claims.

 The term "plane" refers to the simplest surface. The concept of a plane (like a point and a straight line) is one of the basic concepts of geometry. A plane has the property that any line connecting its two points entirely belongs to it. The intersection of the planes forms a line.

 The term "plane" is used in this context throughout the description, including the claims.

 The term "bending" refers to a type of deformation characterized by a curvature (change in curvature) of the axis or the middle surface of an element (beam, rod, plate, etc.) under the influence of an external load. There are bends: clean, transverse, longitudinal, longitudinally-transverse.

 The term "bend" is used in this context throughout the description, including the claims.

 The term "line" refers to (from Lat. Linea) the common part of two adjacent surface areas. A moving point describes a line during its movement. In analytical geometry on the plane, lines are expressed by equations between the coordinates of their points. In a rectangular coordinate system, the lines are divided depending on the type of equations. If the line equation has the form F (x, y), where F (x, y) is an nth degree polynomial with respect to x, y, then the line is called an nth order algebraic curve. The 1st order line is a straight line. Conical sections refer to lines of the 1st and 2nd order. Examples of non-algebraic lines are graphs of trigonometric functions, logarithmic functions, exponential functions.

 The term "line" is used in this context throughout the description, including the claims.

 The term "combination" is understood (from late Lat. Combinatio - connection) combination, relative position of something (for example, a combination of fragments of lines).

 The term "combination" is used in this context throughout the description, including the claims.

 The term "forming operations" should be understood as bending, twisting, rolling, straightening, drawing, hood molding, rolling, etc. [7].

 The term "forming operations" is used in this context throughout the description, including the claims.

 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 a rivet laminated; in FIG. 2-6 illustrate examples of the structural embodiment of the cross section of a laminate rivet; in FIG. 7-16 depict examples of the structural embodiment of the cross-sectional parts of a laminate rivet.

 The rivet laminated (Fig. 1) contains in cross section at least two subregions 1 and 2 of the material with the borders of the outer 3 and inner 4 sides, and at least part of the line of the sectional boundary of at least one of the subregions of the rivet material on the border 3 of the outer side and / or on the border 4 of the inner side of at least one of the subregions of the cross-section of the rivet material made in the form of a fragment of an oblique conical section 5 of a straight circular cone.

 In examples of the structural embodiment of the laminate rivet shown in FIG. 1-14, one of the subregions 1 (2) of the rivet material is made of variable thickness.

 In an exemplary embodiment of the layered rivet shown in FIG. 2, the thickness of the subregion 2 of the rivet material increases toward the center of mass of the 6th section.

 In an exemplary embodiment of the layered rivet shown in FIG. 3, the thickness of the subregion 1 of the rivet material decreases to the center of mass 6 of the section.

 In examples of the structural embodiment of the laminate rivet shown in FIG. 4-6, the thickness of subregions 1 and 2 of the rivet material varies many times, increasing and decreasing.

 In an exemplary embodiment of the layered rivet shown in FIG. 3, the thickness of the subregions 1 and 2 of the rivet material varies repeatedly and periodically.

 In an exemplary embodiment of the layered rivet shown in FIG. 7, a part of the length of the boundary line of the outer side 3 is made with steps 7. Steps 7 can be made (FIG. 8) both with an increase in the thickness of the subregion of the rivet laminated upon transition from one step to another, and with a decrease.

 In an exemplary embodiment of the layered rivet shown in FIG. 9, a part of the length of the boundary line of the outer side 3 of the sub-region 1 of the rivet material is made with a recess 8.

 In an exemplary embodiment of the layered rivet shown in FIG. 10, a part of the length of the boundary line of the front side 3 of the sub-region 1 of the rivet material is made with a protrusion 9.

 In an exemplary embodiment of the layered rivet shown in FIG. 11, the sub-area 2 of the rivet material is made of metal, and the sub-area 1 is made with non-metallic part 10 and with the metal part 11.

 In an example embodiment, the rivets of the laminate shown in FIG. 12, a cavity 12 is formed between the sub-regions 1 and 2 of the rivet material.

 In an exemplary embodiment of the layered rivet shown in FIG. 13, between the sub-regions 1 and 2 of the rivet material, periodic cavities 12 are made.

 In an exemplary embodiment of the layered rivet shown in FIG. 14, a part of the outer 3 and inner 4 borders of the subregions 1 and 2 of the cross section of the layered rivet contains a circle 13. In the rivet layered, at least part of the length of the border of the side of section 3 (4) of at least one of the subregions of the material may contain fragments and / or a combination of fragments: a polygon (square 14, rectangle 15, trapezoid 16, rhombus 17, triangle 18, etc., etc.), a conical section of a straight circular cone (circle 13, ellipse 19, etc., etc. .P.).

 In an exemplary embodiment of the layered rivet shown in FIG. 15, the thickness of the sub-region 1 of the rivet material has a gap of 20.

 In an exemplary embodiment of the layered rivet shown in FIG. 16, gaps 20 of subregion 1 are made repeatedly and periodically.

 Thus, the use of this laminated rivet will achieve the objectives of the invention.

Literature
1. Bronstein I.N., Semendyaev K.A. Handbook of Mathematics - Moscow: Nauka, 1980 .-- 975 p.

 2. Yusupov R.M. Statistical methods for processing the results of observations - M .: Moscow, 1984. 557 p.

 3. Vygodsky M.Ya. Analytical Geometry - Moscow: Fizmatgiz, 1963 .-- 468 p.

 4. Ermakov S. M. Mathematical theory of the optimal experiment - M .: Nauka, 1987. - 317 p.

 5. Demidenko E.Z. Linear and nonlinear regression - M .: Finance and statistics, 1981. - 291 p.

 6. Mathematical Encyclopedic Dictionary - M .: "Soviet Encyclopedia", 1988, 847 p.

 7. V.A. Masters, V.S. Berkovsky. The theory of plastic deformation and metal forming - M .: Metallurgy, 1989, 399 p.

Claims (16)

 1. The rivet is laminated, containing in the cross section of the smooth part of the rod at least two subregions of materials, characterized in that at least part of the line of the boundary of the section and / or at least part of the boundary line of the subregions of materials is made in the form of a fragment of an oblique conical section of direct circular cone.  2. A rivet laminated according to claim 1, characterized in that at least one of the subregions of the material of the latter is made of variable thickness.  3. The rivet laminated according to claim 2, characterized in that the thickness of at least one of the subregions of the material of the latter increases toward the center of mass.  4. The rivet is layered according to claim 3, characterized in that the thickness of at least one of the subregions of the material of the latter decreases to the center of mass.  5. The rivet is layered according to any one of claims 1 to 4, characterized in that the thickness of at least one of the subregions of the material of the latter changes, repeatedly increasing and decreasing.  6. The rivet is layered according to any one of claims 1 to 5, characterized in that the thickness of at least one of the subregions of the material of the latter changes repeatedly and periodically.  7. The rivet is layered according to any one of claims 1 to 6, characterized in that a part of the length of the boundary line of at least one of the subregions of the material of the latter is made stepwise.  8. The rivet is layered according to claim 7, characterized in that the steps can be performed both with an increase in the thickness of the layer of the subregion of the material during the transition from one step to another, and with a decrease.  9. The rivet is layered according to any one of claims 1 to 8, characterized in that a part of the length of the boundary line of at least one of the subregions of the material of the latter is made with at least one recess.  10. The rivet is layered according to any one of claims 1 to 9, characterized in that a part of the length of the boundary line of at least one of the subregions of the material of the latter is made with at least one protrusion.  11. The rivet is layered according to any one of claims 1 to 10, characterized in that at least one of the subregions of the material of the latter is made of metal, and any part of any other subregion of the material is made of metal or nonmetallic.  12. The rivet is layered according to any one of claims 1 to 11, characterized in that a part of the length of the boundary line between at least two adjacent sub-regions of the material of the latter is made with at least one cavity.  13. The rivet laminated according to item 12, wherein the cavities are made periodic.  14. The rivet is layered according to any one of claims 7 to 13, characterized in that at least part of the length of the section boundary of at least one of the subregions of the material of the latter is made from a group containing fragments and / or combinations of fragments in the section: polygon, conical section straight circular cone.  15. The rivet is layered according to any one of claims 1 to 14, characterized in that the thickness of at least one of the subregions of the material of the latter has at least one gap.  16. The rivet is layered according to claim 15, characterized in that the thickness gaps are made repeatedly and periodically.

Images