1. Field of the Invention
The present invention generally relates to break-away couplings for lighting poles or appurtenances mounted along highways and roadways and, more specifically, to such a break-away coupling with enhanced fatigue properties.
2. Description of the Prior Art
Many highway and roadside appurtenances, such as lighting poles, signs, etc., are mounted along highways and roads. Typically, these are mounted on and supported by concrete foundations, bases or footings. However, while it is important to securely mount such roadside appurtenances to withstand weight, wind, snow and other types of service loads, they do create a hazard for vehicular traffic. When a vehicle collides with such a light pole or sign post, for example, a substantial amount of energy is normally absorbed by the light pole or post as well as by the impacting vehicle unless the pole or post is mounted to fail at the base. Unless the post is deflected or severed from the base, therefore, the vehicle may be brought to a sudden stop with potentially fatal or substantial injury to the passengers. For this reason, highway authorities almost universally specify that light poles and the like must be mounted in such a way that they must fail at the support structure upon impact by a vehicle.
In designs of such break-away couplings several facts or considerations come into play. The couplings must have maximum tensile strength with predetermined (controlled) resistance to lateral impact load. Additionally, the couplings must be easy and inexpensive to install and maintain. They must, of course, be totally reliable.
Numerous break-away systems have been proposed for reducing damage to a vehicle and its occupants upon impact. For example, load concentrated break-away couplings are disclosed in U.S. Pat. Nos. 3,637,244, 3,951,556 and 3,967,906 in which load concentrating elements eccentric to the axis of the fasteners, for attaching the couplings to the system oppose the bending of the couplings under normal loads while presenting less resistance to bending of the coupling under impact or other forces applied near the base of the post. In U.S. Pat. Nos. 3,570,376 and 3,606,222, structures are disclosed which include a series of frangible areas. In both cases, the frangible areas are provided about substantially cylindrical structures. Accordingly, while the supports may break along the frangible lines, they do not minimize forces for bending of the posts and, therefore, generally require higher bending energies, to the possible determent of the motor vehicle.
In U.S. Pat. No. 3,755,977, a frangible lighting pole is disclosed which is in a form of a frangible coupling provided with a pair of annular shoulders that are axially spaced from each other. In a sense, the annular shoulders are in the form of internal grooves. A tubular section is provided which is designed to break in response to a lateral impact force of an automobile. The circumferential grooves are provided along a surface of a cylindrical member.
A coupling for a break-away pole is described in U.S. Pat. No. 3,837,752 which seeks to reduce maximum resistance of a coupling to bending fracture by introducing circumferential grooves on the exterior surface of the coupling. The distance from the groove to the coupling extremity is described as being approximately equal to or slightly less than the inserted length of a bolt or a stud that is introduced into the coupling to secure the coupling, at the upper ends, to a base plate that supports the post and to the foundation base or footing on which the post is mounted. The grooves are provided to serve as a stress concentrators for inducing bending fracture and to permit maximum effective length of moment arm and, therefore, maximum bending movement. According to the patent, the diameter of the neck is not the variable to manipulate in order to achieve the desired strength of the part, as the axial (tensile/compressive) strength is also affected.
However, the above mentioned couplings have shown signs of limited fatigue strength and, therefore, premature failure. Fatigue strength is a property of break-away couplings that has not always been addressed by the industry, partly because of the complex nature of the problem and its solution.
U.S. Pat. No. 5,474,408, assigned to Transpo Industries, Inc., the assignee of the present invention, discloses a break-away coupling with spaced weakened sections (Alternative Coupler). The controlled break in region included two axially spaced necked-down portions of smaller diameter and solid cross section. The dimensions of the coupling were selected so the ratio D/L is within the range V/L<=0.3 where L is the axial control breaking region and the necked-portion has a diameter D. The necked-portions have conical type surfaces to assure that at least one of the necked-portions break upon bending prior to contact between any surfaces forming or defining the necked-portions.
A multiple necked-down break-away coupling has been disclosed in U.S. Pat. No. 6,056,471 assigned to Transpo Industries, Inc., in which a control breaking region is provided with at least two axial spaced necked-portions co-axially arranged between the axial ends of the coupling (alternative coupler). Each necked-portion essentially consists of two axially aligned conical portions inverted one in the relation to the other and generally joined at their apices to form a generally hour-glass configuration having a region of a minimum cross section at an inflection point having a gradually curved concave surface defining a radius of curvature. Each of the necked-down portions have different radii of curvature that are at respective inflection points to provide preferred failure modes as a function of a position in direction of the impact of a force.
The prior patented steel couplings will be referred to as “Existing” for the one Transpo Industries has used in the field for the last 30 years and “Alternative” for the more recently developed coupling. However, these “Existing” and “Alternative” couplings have shown signs of limited fatigue strength. Therefore, a new coupling design was sought that would show marked improvements in fatigue strength.
It is, accordingly, an object of the present invention to provide a fatigue-enhanced break-away coupling for a highway or roadway appurtenance which does not have the disadvantages inherent in comparable prior art break-away couplings.
It is another object of the present invention to provide a fatigue enhanced break-away coupling which is simple in construction and economical to manufacture. It is still another object of the present invention to provide a break-away coupling of the type under discussion that is simple to install and requires minimal effort and time to install in the field.
It is yet another object of the present invention to provide a fatigue-enhanced break-away coupling as in the aforementioned objects which is simple in construction and reliable, and whose functionality is highly predictable.
It is yet another object of the present invention to provide a fatigue-enhanced break-away coupling as in the previous objects which can be retrofitted to most existing break-away coupling systems.
It is still a further object of the present invention to provide a fatigue-enhanced break-away coupling that minimize forces required to fracture the coupling in bending while maintaining safe levels of tensile and compressive strength to withstand non-impact forces, such as wind load.
It is yet a further object of the present invention to provide fatigue-enhanced break-away couplings of the type suggested in the previous objects which essentially consists of one part and, therefore, requires minimal assembly in the field and handling of parts.
It is an additional object of the present invention to provide a break-away coupling as in the above objects geometrically optimized to enhance the fatigue properties of the coupling.
In order to achieve the above and additional objects a break-away coupling in accordance with the invention is formed of metal and has a central axis and a necked-down central region formed by two inverted truncated cones each having larger and smaller bases. The cones are joined at the smaller bases by a narrowed transition region having an exterior surface formed by a curved surface of revolution having an inflection point of minimum diameter substantially midway of the coupling along said axis, said cones each defining an angle θ1 and θ2, respectively, at each of said larger bases, wherein both θ1 and θ2 are selected to be less than 40°, such as within the range of 20°-40°, and, preferably, within the range of 30°-37°.
Those skilled in the art will appreciate the improvements and advantages that derive from the present invention upon reading the following detailed description, claims, and drawings, in which:
Transpo Industries Inc. has designed and patented two steel couplers in 1985 and 2000. The 1985 Coupler is described in U.S. Pat. No. 4,528,786 and will be referred to as the “Existing” coupler that Transpo Industries has used in the field for the last 30 years. The 2000 coupler is described in U.S. Pat. No. 6,056,471 and will be referred to as “Alternative” for the more recently developed coupler. However, these couplers were designed for enhanced mechanical performance but not specifically for fatigue properties. This application describes a geometry for couplers to enhance their fatigue performance over previous couplers. The geometrical design process recognizes a geometrical design range “interval” where the fatigue performance of couplers is expected to significantly exceed that of the “Existing” and the “Alternative” couplers.
The objective of this work was to design a coupler geometry that significantly increases the fatigue strength of existing couplers. Couplers designed in accordance with the present invention that improve fatigue strength properties will be designated herein as “enhanced fatigue” couplers or “EF” couplers. The process aims to reduce the stress gradients within the necking region. These stress gradients are believed to control the fatigue life of the couplers. High stress gradients result in premature fatigue failure under cyclic loads.
The typical geometry for the necking region of a double cone coupler consists of two cones and a surface of revolution as shown in
In particular, the objective of the design process was to:
1—Determine the significance and select the type of surface of revolution of the necking region. Three types of surfaces of revolution were examined. The three types are elliptic torus, hyperboloid, and catenoid. Different surfaces of revolution yielded different curvature profiles through the depth of the necking region which in turn affected the stress gradients in the necking region.
2—Identify the effect and value(s) of geometric designs including different base angles θ1, θ2. It is explained below how all the other design variables (dimensions) are based on the base angles θ given the problem constraints to keep the base diameter, the neck diameter and the coupler height constant to satisfy other critical requirements of the couplers.
3—Examine the significance of using unequal base angles θ1, θ2 on the stress gradients in the necking region. This included developing two sets of design variables (dimensions) for the two halves of the necking region. In this study, elliptic torus surface of revolution is selected as a case study for creating the surface of revolution. However, similar findings could be observed for all surfaces of revolution with unequal base angles.
Geometrical Considerations
Several geometric variables were defined for the design effort. These variables include the base angle (θ), the constants of the surface curvature, the depth of the cone (h1), and half the depth of the surface of revolution (h2). Assuming that the origin is located at the mid height and width of the necking region, there are three other characteristic points that determines the geometry of the necking region. These are A, B, and D. Geometrical relationships were developed for each type of surface of revolution as discussed in this section. To develop these relationships, three geometrical constraints were imposed to all necking region geometries. These constraints are described below.
The development of the surface of the necking region was obtained by rotating a tangent line and elliptic torus 360° about the couplers longitudinal axis as shown in
Definition of horizontal-to-vertical axes ratio
a/b=0.65, or 1.5 (3)
Base angle is the slope of the tangent
m=tan θ (4)
Total depth of necking region is 0.57″
h1+h2=0.57″ (5)
Points B (xB, h2) and Point D (0.812,0.57) satisfies the tangent equation
yD=m·xD+c (6)
yB=m·xB+c (7)
Points B (xB, h2) satisfies the elliptic torus equation
Tangency condition at point B.
The geometry of the necking region of the coupler was obtained by solving the aforementioned seven simultaneous equations (Eqns 3 to 9) to find the seven geometrical parameters (a,b,c,xB,h1,h2,m). Table (1) to (3) show the calculated geometrical parameters for some base angles with different a/b ratios while
(b) Equal Hyperboloid
The development of the surface of the necking region was obtained by rotating a tangent line and a hyperbola 360° about the coupler's longitudinal axis as shown in
Definition of horizontal-to-vertical semi-axes ratio
c/d=3,4 or 5 (10)
Base angle is the slope of the tangent
m=tan θ (11)
Total depth of necking region is 0.57″
h1+h2=0.57″ (12)
Points B (xB, h2) and D (0.812,0.57) satisfies the tangent equation
yD=m·xD+n (13)
yB=m·xB+n (14)
Points B (xB, h2) satisfies the elliptic torus equation
Center of Symmetry of hyperbola point k (xk,0)
xk+c=0.291 (16)
Tangency condition at point B.
The geometry of the necking region of the coupler was obtained by solving the aforementioned eight simultaneous equations (Eqns 10 to 17) to find the eight geometrical parameters (c,d,n,xB,h1,h2,xk). Table (4) to (6) show the calculated geometrical parameters for some base angles with different c/d ratios while
(c) Equal Catenoid
The development of the surface of the necking region was obtained by rotating a tangent line and a catenary curve 360° about the couplers longitudinal axis as shown in
Base angle is the slope of the tangent
m=tan θ (18)
Total depth of necking region is 0.57″
h1+h2=0.57″ (19)
Points B (xB, h2) and D (0.812,0.57) satisfies the tangent equation
yD=m·xD+c (20)
yB=m·xB+c (21)
Points B (xB,h2) satisfies the elliptic torus equation
Vertex location at point A (0.291,0) requires that.
a=xk+0.291 (23)
Tangency condition at point B.
The geometry of the necking region of the coupler was obtained by solving the aforementioned eight simultaneous equations (Eqns 18 to 24) to find the eight geometrical parameters (c,a,xB,h1,h2,m,xk). Table (7) shows the calculated geometrical parameters for some base angles while
(d) Unequal Elliptic Tori
This case is similar to case (a) except that there are two different lines and two different elliptic tori that are used to create the necking region. The development of the surface of the necking region in this case was obtained by rotating the two tangent lines and the two elliptic tori 360° about the couplers longitudinal axis as shown in
Objective Function
The main objective is to reduce or to minimize the stress gradient within the cone and the surface of revolution. In particular, the stress gradients through the necking region need to be reduced or minimized. Two cases are considered in this investigation as discussed herein; equal base angles and unequal base angles.
(a) Equal Base Angles
In this case it is assumed that the two base angles in the necking region are equal. This would yield symmetric necking region about X and Y axes as shown in
The stress gradients between points A & B (SG_AB) and points B & D (SG_BD) were calculated based on the gradient of Von Mises stress obtained by EF simulation as described by Eqn. (25) & Eqn. (26) respectively. The objective function “F” is defined as a multi-objective function combining the two functions ƒ1 and f2 from Eqn. (25) and Eqn. (26) respectively.
The objective function “F” is formulated as a weighted sum of the two stress gradients as described by Eqn. (27).
F=w1·ƒ1+w2·ƒ2 (27)
where w1 is the weight of the stress gradient between A & B, w2 is the weight of the stress gradient between B & D. In this study, w1 and w2 are chosen to be ⅔ and ⅓ respectively. The preference made for SG_AB over SG_BD because our prior observations of fatigue behavior of the couplers (Phase I and Phase II of this study) showed that failure usually occurs in the necking region (AB). The base angle(s) θ with the lowest objective function value represents optimal design(s).
(b) Unequal Base Angles
In this case, it is assumed that the two base angles differ which would result in different dimensions between the top and bottom halves. This in turn will differ the stress gradients between the two halves. Two elliptic tori and cones were used with unequal base angles to define the surface of revolution region as shown in
Results and Analysis
The range of base angles θ was determined for each surface of revolution so that it achieves the geometrical considerations. Based on the geometrical consideration, the elliptic torus has a base angle ranging between 20° and 46° while the hyperboloid and catenoid has a base angle ranging between 30° and 46°. It is important to note that the current design for Alternative (AL-1) couplers is based on base angle of 45°.
The change in couplers dimensions as a function of base angle is depicted in
It is also observed in
Von Mises stresses at the two ends of the surfaces of revolution (points A & B) and the cone (points B & D) are presented in
The stress gradients SG_AB and SG_BD are shown in
There exists two objectives: reducing the two stress gradients A-B and B-D. It is obvious from
The effect of unequal base angles on the stress gradients and objective functions is evident in Table (9). The table shows two objective functions for each case, one objective function for each half of the necking region. It is important to consider the maximum objective function for each case since it represents the critical stress gradient upon which the fatigue failure occurs. In this context, the table shows that the highest maximum objective function of 203 ksi/inch belongs to case 1 (θ1=θ2=45° while the lowest maximum object function of 44 ksi/inch belongs to case 6 (θ1=θ2=32°). The cases 2 to 5 vary in their maximum objective function between case 1 and case 6. For instance, case 3 (θ1=45°, θ2=32° exhibits maximum objective function of 89 ksi/inch. It is evident from these results that in order to reduce the maximum objective function, the two base angles should lie within the optimal range (θ=30-37°). It is also evident that the two base angles do not have to be equal to achieve suitable or optimal performance as long as they both lie within the optimal range.
The design process was performed using three types of surface of revolution (elliptic torus, hyperboloid, and catenoid) and a wide range of base angles. The representative surfaces of revolutions cover all possible surfaces given the coupler geometry. The base angle of the coupler denoted “θ” was defined as the independent design variable. The relationships with other geometrical dependent variables were developed. A set of constraints for acceptable design of the coupler was defined. A combined multi-objective function to reduce the stress gradients in the surface of revolution and the cone areas was defined. The effect of unequal base angles on the stress gradient was also investigated.
The design showed that the objective function is substantially insensitive to the type of surface of revolution. The optimization also showed that the objective function is sensitive to the base angle θ. A base angle range between 30 to 37° represents a good working range for minimizing the objective function and improving the fatigue strength of the coupler. Within this interval or range the stress gradients are less than ⅓ of stress gradients developed with the current (Existing) or alternative (ALT-1) design angle of θ=45°. In addition, it is evident that preferred fatigue performance can be obtained using unequal base angles as long as both angles are within the optimal range. The current designs, known as Existing or Alternative couplers, are obviously not a design that addresses and improves fatigue performance.
Breakaway couplers in accordance with the present invention include base angles and geometry within the range of 30°-37° (an angle of 32 degree might be considered). The new coupler design will have improved fatigue strength compared with Existing and Alternative (AL-1) couplers and have been referred to as “Enhanced-Fatigue” or “EF” Coupler. The “EF” coupler is designed to meet AASHTO requirements for highway couplers.
Test Results
Scope of Testing
The EF couplers were tested with the objective to evaluate the fatigue strength of the EF coupler and compare it with the Existing and Alternative couplers. Twenty couplers were tested under cyclic loading with different mean stress levels and different stress ranges and determining the number of cycles to failure. The equivalent Stress-Number of Cycles to failure (S-N) curves and report the types of fracture were observed. Moreover, two additional modified-optimized steel couplers were tested: EF-Mod-A and EF-Mod-B, shown in
Four couplers of each type were tested under cyclic loading then the fatigue life was compared with Existing, Alternative, and EF couplers.
Referring to
Fatigue Tests Description
The purpose of the fatigue test is to determine the number of cycles to failure and develop equivalent Stress-Number of Cycles to failure (S-N) curves to allow comparison of the fatigue behavior of the three types of galvanized steel couplers. The word “equivalent” here is used to describe the S-N curves as establishing the “true” S-N curves for the couplers requires testing very high number of specimens (>30 specimens). The “EF” coupler is examined under cyclic loading. The modified-EF, EF-Mod-A, and EF-Mod-B couplers are shown in
Tension Fatigue Tests
Four test protocols were performed on a total of 25 specimens of EF couplers. Each test protocol was cyclic load controlled with a frequency of 1 Hz. The mean tension loads and stresses vary in the four test protocols as follows:
Furthermore, 8 specimens of the modified-EF couplers, EF-Mod-A and EF-Mod-B, were tested under Test protocol-4.
The couplers were kept under tension-tension fatigue cycles during all test protocols 1 through 4. All stress values reported represent the average stress over the area of the smallest diameter of the coupler as shown in
Fatigue Test Results
All couplers tested under test protocol-1 and test protocol-2 did not fail. All the couplers failed in test protocol-3 and test protocol-4 fractured at the threads section and not at the coupler's neck. This indicates that the coupler's neck does not govern fatigue of the couplers any further. This proves the significantly different performance of the EF couplers compared with Existing and Alternative couplers where neck failure was dominant in fatigue.
The object of the design effort was to experimentally compare the fatigue strength/life of EF couplers with both Existing and Alternative couplers. Twenty EF Transpo couplers were tested under 4 testing protocols to identify the fatigue strength of the couplers. These protocols included varying mean stress values.
All the tests showed that the fatigue strength of the EF Transpo coupler is higher (twice to six times) than that of the Alternative couplers under tension fatigue loads. All tested couplers did not fail under mean stresses of 17.98 ksi and achieved endurance limit of 1.7 million cycles. Fracture surfaces of EF couplers were recorded and no failure took place at the coupler's neck. Failures in the outer thread were observed at much high fatigue strength compared with Existing or Alternative Couples. It is evident that the EF coupler has superior fatigue strength compared with Existing and Alternative Transpo couplers.
Furthermore, it is also evident that the modified-EF couplers, (Mod-A) and (Mod-B), have superior fatigue performance that is one order of magnitude higher in fatigue life than Existing couplers and about 4 times higher in fatigue life compared with Alternative couplers. Some of the modified-EF couplers did not fail under the test protocol #4 used. The modified-EF couplers showed a fatigue life about 75% of that of the EF couplers. Nevertheless, the fatigue life shown by the modified-EF is superior for all intended applications and is an order of magnitude higher than Existing couplers used today in field applications.
The foregoing is considered as illustrative only of the principles of the invention. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation shown and described, and accordingly, all suitable modifications and equivalents may be resorted to, falling within the scope of the invention.
Number | Name | Date | Kind |
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3570376 | Overton, III et al. | Mar 1971 | A |
3606222 | Howard | Sep 1971 | A |
3637244 | Strizki | Jan 1972 | A |
3755977 | Lewis | Sep 1973 | A |
3837752 | Shewchuk | Sep 1974 | A |
3951556 | Strizki | Apr 1976 | A |
3967906 | Strizki | Jul 1976 | A |
5474408 | Dinitz et al. | Dec 1995 | A |
6056471 | Dinitz | May 2000 | A |
7228935 | Schlessmann | Jun 2007 | B2 |
Number | Date | Country | |
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20160024729 A1 | Jan 2016 | US |
Number | Date | Country | |
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Parent | 13454267 | Apr 2012 | US |
Child | 14838803 | US |