 |
Claims  |
|
|
I claim:
1. An expansion anchor assembly comprising an axially extending anchor bolt
and an axially extending expansion sleeve, said anchor bolt having a first
end and a second end, said anchor bolt has a cylindrically shaped outside
surface for an axial portion thereof extending from the first end, and a
frusto-conicaly shaped outside surface extending from adjacent the second
end toward the first end with said frusto-conically shaped surface
tapering inwardly toward the first end, a cylindrically shaped annular
recess in said anchor bolt extending from the smaller diameter end of said
frusto-conically shaped surface toward the first end, said recess has a
smaller diameter than the cylindrically shaped outside surface extending
from the first end, said expansion sleeve is a hollow cylinder and is
positioned in said annular recess and encircles said anchor bolt, said
expanion sleeve has an inside surface and an outside surface and said
expansion sleeve has an axially and circumferentially extending region in
the inside surface thereof recessed outwardly from the surface of said
annular recess forming a reduced thickness wall section acting as a
predetermined breaking location for said expansion sleeve, wherein the
improvement comprises that said inside surface of said expansion sleeve is
cylindrically shaped and fits closely around said cylindrically shaped
annular recess in said anchor bolt, in the circumferentially extending
region of said reduced thickness wall section a projection is formed
extending radially outwardly from the cylindrically shaped outside surface
of said expansion sleeve.
2. An expansion anchor assembly, as set forth in claim 1, wherein said
projection extends in the axial direction of said sleeve along said
reduced thickness wall section.
3. An expansion anchor assembly, as set forth in claim 2, wherein two
diametrically oposite reduced thickness wall sections are provided in said
expansion sleeve with one said projection associated with each of said
reduced thickness wall sections.
4. An expansion anchor assembly, as set forth in claim 2, wherein said
projection is in the form of a web having a smaller dimension in the
circumferential direction of said expansion sleeve than said reduced
thickness wall setion.
5. An expansion anchor assembly, as set forth in claim 3, wherein said
reduced thickness wall sections divide said expansion sleeve into two half
sections, and a hinge provided in each said half section spaced between
said reduced thickness wall sections, and said hinges each form a swivel
axis extending parallel to the axis of said expansion sleeve.
6. An expansion anchor assembly, as set forth in claim 2, wherein said
reduced thickness wall sections are formed by axially extending grooves
provided in the inside surface of said expansion sleeve.
7. An expansion anchor assembly, as set forth in claim 6, wherein said
grooves are substantially rectangular in cross-section extending
transversely of the axial direction of said expansion sleeve.
8. An expansion anchor assembly, as set forth in claim 7, wherein one
generally radially extending side of said groove is longer than the other
radially extending side of said groove so that the reduced thickness wall
section remaining varies in thickness across the circumferential direction
of said groove in said expansion sleeve.
9. An expansion anchor assembly, as set forth in claim 2, wherein said
projection has a dimension in the circumferential direction of said
expansion sleeve substantially equal to the comparable dimension of said
reduced thickness wall section.
10. An expansion anchor assembly, as set forth in claim 2, wherein said
projection has a saw-tooth like configuration.
11. An expansion anchor assembly, as set forth in claim 10, wherein said
projection is secured to said sleeve at the opposite axial ends thereof
and is separated from said sleeve between said ends. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
SUMMARY OF THE INVENTION
The present invention is directed to an expansion anchor assembly made up
of an essentially cylindrically shaped anchor bolt and an expansion sleeve
encircling and secured in an annular recess in the anchor bolt. The anchor
bolt has an axially extending frusto-conical section extending from the
annular recess and widening in the direction away from the recess. The
expansion sleeve is a hollow cylinder and has reduced thickness sections
which form predetermined breaking regions. The reduced thickness sections
are formed in the side surface of the expansion sleeve so that the inside
surface of the reduced thickness section is spaed radially outwardly from
the surface of the annular recess in the anchor bolt.
Expansion anchor assemblies of this type are used in large numbers, because
of their economical construction and the ease with which they can be set.
These anchor assemblies are used in a great many different fields. High
strength concrete is usually the receiving material into which the anchor
assemblies are set.
In this type of expansion anchor assembly, the expansion sleeve which
encloses the anchor bolt in an annular recess formed in the bolt, is
radialy expanded to achieve the anchoring effect. Accordingly, the
expansion sleeve has a slot which extends over its full axial length. To
achieve as uniform as possible a radial widening, the expansion sleeve is
also provided with a reduced thickness or weakened section opposite the
slot, and this reduced thickness section forms a predetermined breaking
line when the sleeve is expanded.
The setting procedure is effected by inserting the expansion anchor
assembly so that the expansion sleeve is located within a cylindrical bore
in a receiving material. When the anchor bolt is subsequently retracted or
pulled out of the bore, such as by means of a nut screwed onto a threaded
end section of the anchor bolt projecting out of the bore, the
frusto-conical section of the bolt moves into the expansion sleeve which
is temporarily held in the bore, such as by a prestressing action. The
expansion sleeve experiences radially directed stress and breaks along the
reduced thickness or weakened section. If breakage occurs, the separated,
half-shell shaped sections are pressed against the wall of the bore by the
frusto-conical section of the anchor bolt as the anchor bolt is retracted
or pulled out of the bore.
Based on experience, it has been noted that the predetermined breaking
locations do not respond reliably in the known expansion anchor
assemblies. In some instances, the expansion sleeve remains intact when
the frusto-conical section of the bolt moves into the sleeve. The surface
of the expansion sleeve has uneven contact as it continues to expand, that
is, it is deflected toward the surface of the bore primarily in the region
between the slot and the reduced thickness section. An uneven distribution
of the anchoring pressure results.
In hard receiving materials, such as conentional concrete, only relatively
low anchoring values can be attained, since there is only a partial
application of force relative to the capacity of the receiving material.
Due to this pressure distribution characteristic, and also when the
expansion anchor assembly is used in low strength receiving materials as
compared to conventional concrete, only low anchoring values are achieved
relative to the specified force capacity of the expansion anchor assembly.
The uneven pressure distribution leads to locally excessive stresses on
the receiving material so that the receiving material tends to spall
causing the anchor to be displaced out of the bore.
Therefore, it is the primary object of the present invention to provide an
expansion anchor assembly which is easy to set in place and is
distinguished by a uniform application of force against the surface of the
bore into which it is placed so that high anchoring values can be achieved
in receiving materials of different strength.
In accordane with the present invention, in the region of the reduced
thickness or weakened cross-section, a projection is provided extending
outwardly from the cylindrical outer surface of the expansion sleeve.
Preferably, one or more cam-like shaped projections are provided extending
along the weakened cross-sectional regions of the sleeve at its outer
cylindrical surface. When the expansion anchor assembly is inserted into a
bore, the projections contact the bore surface. Subsequently, when the
frusto-conical section of the bolt is drawn into the expansion sleeve, of
necessity, the projections press radially inwardly against the reduced
thickness or weakened cross-sectional areas providing a reliable breakage
of the sleeve. The axially extending sleeve sections formed in this manner
are pressed uniformly against the surface of the bore during the
continuous expansion of the sleeve. As a result, a uniform application
force over the entire circumference of the expanding sleeve takes place
within the bore.
When this expansion anchor assembly is used in conventionally hard
concrete, a comparatively higher anchoring value can be achieved due to
the pressure distribution over a large surface. In lower strength
receiving materials, the uniform pressure distribution permits a higher
expanding force which creates comparatively high anchoring values.
When the cross-sectional weakening or reduced thickness sections extend
over the entire or major part of the axial length of the expansion sleeve,
then it is preferable if the projection also extends along the length of
the weakened section. Where a projection extends continuously over the
full length of the cross-sectionally weakened section, it increase the
certainty that the sleeve breaks along its entire length at the
predetermined breaking location. After the sleeve breaks along the
weakened section, the weakened section along with the projection move
radially inwardly into the resulting slot-like open space between the
sleeve sections. Accordingly, the projection does not impair the anchoring
of the sleeve surface to the surface of the bore.
The expansion sleeve is securely held on the anchor bolt when the sleeve
does not have a longitudinal slot. Further, it is advantageous if the
expansion sleeve has two diametrically opposite cross-sectional weakened
or reduced thickness sections with a projection extending along each
section. Such an arrangement assures the formation of two axially
extending sleeve sections due to the breakage along the weakened sections,
so that a completely uniform pressure distribution takes place along the
cylindrical surface of the expansion sleeve.
The projection may extend radially outwardly from the sleeve across the
width of the weakened or reduced diameter section, that is, it extends for
the full circumferential dimension of the section. It is advantageous to
form the cross-sectionally weakened sections by forming dies. The edge
transition between the reduced thickness or recessed zones formed in such
an operation relative to the adjacent undeformed section affords a
breaking region.
In one embodiment of the invention, the projection is constructed as a web
with a smaller circumferential width than that of the cross-sectionally
weakened section. Such an arrangement facilitates breakage of the weakened
section. The weakened section, in addition, is advantageously formed so
that its thickness varies in the circumferential direction of the
expansion sleeve. In this manner, the separation along the predetermined
breaking region can be controlled as desired in connection with the
formation and arrangement of the reduced thickness section.
In another embodiment of the invention, the expansion sleeve is divided
into sections by means of axially extending highes formed in the expansion
sleeve and spaced between two adjacent projections. As a result, the
hinges have a swivel axis extending parallel to the sleeve axis. When the
sleeve ruptures along the predetermined breaking regions as the anchor
assembly is being set, the sections formed in the breaking operation are
deformable to a large extent due to the hinges so that practically an
ideal, uniformly circular contact of the outside surface of the expansion
sleeve and the surface of the bore is attained.
The hinges can be produced by providing sleeve parts which hook into one
another. By providing a snap connection between the hinge parts, even
after the separation takes place along the predetermined breaking regions,
a secure hinge engagement is maintained, and this hinge construction
permits a simple assembly of the expanding sleeve during the manufacture
of the expansion anchor assembly.
The various features of novelty which characterize the invention are
pointed out with particularity in the claims annexed to and forming a part
of this disclosure. For a better understanding of the invention, its
operating advantages and specific objects attatined by its use, reference
should be had to the accompanying drawings and descriptive matter in which
there are illustrated and described preferred embodiments of the invention
.
BRIEF DESCRIPTION OF THE DRAWING
In the drawings:
FIG. 1 is an axially extending side view of an expansion anchor assembly
embodying the present invention with the assembly ready to be inserted;
FIG. 2 is an enlarged cross-sectional view through the expansion anchor
assembly taken along II--II in FIG. 1;
FIG. 2a is a sectional view similar to that shown in FIG. 2 taken along the
line II--II of FIG. 1, however, the expansion anchor assembly has been set
in place;
FIG. 3 is a detail of a partial cross-section of an expansion anchor
assembly, similar to that in FIG. 2, with a different construction of the
expansion sleeve;
FIG. 4 is a partial sectional view similar to FIG. 3, showing an expansion
anchor assembly like the one in FIG. 2, but with a different construction
of the expansion sleeve;
FIG. 5 is a partial sectional view similar to the expansion anchor assembly
in FIG. 2, however, with a different construction of the expansion sleeve;
and
FIG. 6 is a side view of the expansion sleeve shown in FIG. 5 taken in the
direction of the arrow VI in FIG. 5.
DETAIL DESCRIPTION OF THE INVENTION
In FIG. 1 an expansion anchor assembly is illustrated made up of an axially
elongated anchor bolt 1 and an expansion sleeve 2 mounted on the bolt. The
main axially extending portion of the anchor bolt is cylindrically shaped
and it has a circular recess 3 adjacent to the frusto-conically shaped
section 4 adjacent the leading end of the bolt. As viewed in FIG. 1, the
right-hand end of the bolt is its leading end, that is the end which is
inserted first into a borehole. The frusto-conical section 4 tapers
outwardly toward the leading end of the bolt. The cylindrically shaped
section of the bolt extending from the recess 3 to the trailing end is
provided with a thread 5 running from the trailing end. A nut, not shown,
can be screwed onto the thread 5.
As shown in FIG. 2, expansion sleeve 2 is made up of two sleeve half
sections 6, 7 secured together at diametrically opposite location by
reduced thickness sections 8, 9 which provides weakened sections extending
along the sleeve. The reduced thickness section 8, 9 are in the form of
recesses or grooves 11, 12 extending outwardly from the inside surface of
the sleeve and the grooves have a generally rectangular cross-section
extending in the axial direction of the sleeve . The reduced thickness
sections 8, 9 formed by the groove 11, 12 define predetermined breaking
regions extending along the axial direction of the sleeve. The depth of
the grooves 11, 12 increases in one circumferential direction so that the
wall of the sleeve 2 has a residual thickness a at one side of the groove
smaller than residual thickness b at the other side of the groove. As
shown in the lower portion of FIG. 2, the thickness a extends along the
groove half section 6 while the other thickness b extends along the sleeve
half section 7. On the outside surface of the sleeve half sections 6 and
7, in the area of the reduced thickness sections 8, 9, projections in the
form of axially extending, rib-shaped webs 13, 14 are provided. Each
sleeve half section 6, 7 is divided in the axial direction equidistantly
spaced from the reduced thickness sections by means of hinges 15, 16.
Accordingly, each sleeve half section is made up of two parts secured
together by the hinges 15, 16. The hinges are formed by projections 15a,
15b, 16a, 16b which interlock with one another.
To set the expansion anchor assembly, it is inserted into a previously
prepared bore 17, note FIG. 2a, in a receiving material 18 and the
diameter of the bore is not sigificantly larger than the diameter of the
anchor bolt. The webs 13, 14 on the expansion sleeve 2 project slightly
outwardly beyond the outside surface of the sleeve and, as can be seen in
FIG. 1, also beyond the outside surface of the section of the anchor bolt
extending to the trailing end. The outside surface of the sleeve 2 has
approximately the same diameter as the adjacent axially extending
cylindrically shaped surface of the anchor bolt 1. As the expansion anchor
assembly is inserted into the bore 17, the webs 13, 14 dig into the
surface of the bore and provide a preliminary or temporary holding action
within the receiving material 18.
To facilitate the insertion of the expansion sleeve 2 into the opening into
the bore 17, the leading ends 19 of the webs are beveled.
With the anchor bolt 1 of the expansion anchor assembly inserted into the
bore a sufficient distance so that the sleeve 3 is located interiorly of
the opening into the bore, the nut is run onto the thread 5 until it bears
against the surface of the receiving material 18. As the nut is tightened
onto the thread 5 while it contacts the surface of the receiving material
18, the frusto-conical section 4 is drawn in the direction out of the bore
so that it moves into the expansion sleeve 2 which is held within the bore
by the webs 13, 14. As the frusto-conical section 4 moves into the sleeve,
the sleeve begins to expand radially outwardly. The radially projecting
webs 13, 14 forced against the surface of the bore 17 provide increasing
compressive stress on the predetermined breaking regions formed by the
reduced thickness sections 8, 9 until the smaller residual thickness a is
unable to withstand the stress after a small amount of expansion has taken
place, with the result that the sleeve ruptures along the edges of the
grooves 11, 12 defined by the smaller thickness a. The rupture of the
reduced thickness sections 8, 9 is shown in FIG. 2a. When the rupture
takes place, the web 13, 14 and the wall portions of the expansion sleeve
outwardly of the grooves 11, 12 deflect inwardly into the space left by
the grooves, note FIG. 2a.
As the anchor bolt 1 continues to move rearwardly into the sleeve 2 the
breaking apart of the sleeve half sections 6, 7, continues and the outside
surfaces of the sleeve half sections are displaced radially outwardly
against the surface of the bore 17 in the receiving material 18. The hinge
15, 16 permit the hinged parts of the sleeve half sections 6, 7 to swivel
outwardly and adapt their diameter to the diameter of the anchor bolt
which widens as the frusto-conical section continues to move rearwardly
within the bore through the sleeve. As a consequence, the outside surface
of the sleeve half sections rest for their full circular extent against
the inside surface of the bore 17 and thus afford the uniform application
of force which assures a high anchoring value.
The further embodiments of the expansion anchor assembly, shown in detail
in FIGS. 3 to 6, differ with regard to the assembly shown in FIG. 1, only
with regard to the expansion sleeve. Accordingly, only the expansion
sleeve is provided with new reference numerals.
In FIG. 3 the inside surface of the expansion sleeve 21 is seated along its
axial length within the cylindrical recess 3 in the anchor bolt 1. A
two-sided cross-sectional groove forms a reduced thickness section 22
which is formed by means of dies with a radially outwardly directed
projection 23 extending for the full circumferential width of the
two-sided groove forming the reduced thickness section 22.
In the embodiment in FIG. 4, a reduced thickness section 25 provides a
weakened section in the expansion sleeve 24 defining a saw-toothed like
zone. The shaped configuration of the reduced thickness section 25 is
provided by forming dies. As a result, radially outwardly from the reduced
thickness section 25 there is a projection 26 so that when expansion takes
place a rupture of the sleeve occurs along the reduced thickness section
25 in the wall of the sleeve.
The embodiment in FIG. 5 is similar to the one shown in FIG. 4. In this
embodiment, an expansion sleeve 27 has a saw-tooth like projection 28
produced by forming dies. The projection 28 is connected by means of two
cross-sectionally weakened sections 29 at each end of the expansion sleeve
27. In FIG. 6 only one of the weakened sections 29 is shown.
Preferably, each of the expansion sleeves illustrated in FIGS. 3 to 6 has,
similar to the embodiment shown in FIG. 1 to 2a, two diametrically
oppostie projections. The comment on the function of the sleeve provided
above with regard to the embodiment of FIGS. 1 to 2a also apply with
respect to the other embodiments.
While specific embodiments of the invention have been shown and described
in detail to illustrate the application of the inventive principles, it
will be understood that the invention may be embodied otherwise without
departing from such principles.
* * * * *
|
|
|
|
|
|
|
Description |
|
