U.S. patent number 3,858,990 [Application Number 05/327,880] was granted by the patent office on 1975-01-07 for tube holder and interconnector system.
Invention is credited to Otto Busselmeier.
United States Patent |
3,858,990 |
Busselmeier |
January 7, 1975 |
TUBE HOLDER AND INTERCONNECTOR SYSTEM
Abstract
A tube holder for connecting a tube to an interconnector which
has clamping dogs, and comprising a base one end of which carries
rigid clamping lugs which are adapted to engage the clamping dogs
on said inconnector to clamp said holder and said interconnector
together when said holder and said interconnector are placed
together and relatively rotated, and a resilient intermediate
component which can be expanded to engage the internal wall of said
tube by an expander actuated by a tension screw which has a head
located at the same end of said tube holder as said clamping
lugs.
Inventors: |
Busselmeier; Otto (D-5828
Ennepetal Milspe, DT) |
Family
ID: |
5834568 |
Appl.
No.: |
05/327,880 |
Filed: |
January 29, 1973 |
Foreign Application Priority Data
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Jan 31, 1972 [DT] |
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2204461 |
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Current U.S.
Class: |
403/194; 403/252;
403/349; 403/297 |
Current CPC
Class: |
F16B
7/0446 (20130101); F16B 12/40 (20130101); Y10T
403/557 (20150115); Y10T 403/7007 (20150115); F16B
2200/20 (20180801) |
Current International
Class: |
F16B
7/04 (20060101); F16B 12/40 (20060101); F16B
12/00 (20060101); F16b 012/40 () |
Field of
Search: |
;403/240,252,263,292,295,189,194,297,349 ;52/758C ;211/148,177 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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281,187 |
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Dec 1914 |
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DD |
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106,150 |
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May 1917 |
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GB |
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1,361,398 |
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Apr 1964 |
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FR |
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431,196 |
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Feb 1967 |
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CH |
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Primary Examiner: Schroeder; Werner H.
Claims
What is claimed as invention is:
1. A tube holder and interconnector system for the assembly and
dismantling of frames and structures made up of at least two
profiled tubes comprising:
multi-sided, bridging interconnector means (1) for connecting the
tubes together having an opening (6) therein with dogs (8)
associated therewith in at least two of its sides; and
at least two tube holders (2,2'), each comprising
a base (9, 109, 9', 309, 409, 509), one end of which carries rigid
clamping lugs (15, 115, 315, 415, 515);
a tension screw (18, 118, 18', 318, 418, 518) having a head located
at the same end of said tube holder as said clamping lugs;
an expander (12, 112, 12', 312, 412, 512) actuated by said tension
screw; and
an intermediate component (10, 110, 10', 310, 410, 510) located
between said base and said expander and being expandable to engage
the internal wall of the tube by said expander being actuated by
said screw;
said tube holders being designed to be clamped to said
interconnector means by means of inserting said lugs into said
openings and rotating said lugs with respect to said dogs until
said lugs and said dogs interlock.
2. A tube holder and interconnector system as claimed in claim 1 in
which said clamping lugs are rigidly connected to said base and in
which said screw passes through said base and is seated with said
head against said end carrying said clamping lugs.
3. A tube holder and interconnector system as claimed in claim 2,
in which said tube holder further includes an anchor (11, 111, 311,
411, 511), said clamping lugs being integrally part of said anchor,
and said anchor being rigidly connected to said base; and wherein
the shape of said lugs and said anchor correspond with the profile
of said openings provided in said interconnector.
4. A tube holder and interconnector system as claimed in claim 3 in
which said clamping lugs and said clamping dogs have the same
radial dimensions.
5. A tube holder and interconnector system as claimed in claim 4 in
which said clamping lugs and said dogs are engaged on diagonals of
said interconnector.
6. A tube holder and interconnector system as claimed in claim 2 in
which said screw head is located within the area defined by said
clamping lugs.
7. A tube holder and interconnector system as claimed in claim 1 in
which said expander is conical in shape in its axial plane and has
tapered surfaces, and in which said intermediate component includes
several spreader arms which also have tapered, internal surfaces
which are engaged by the tapered surfaces on the expander when said
expander is actuated by said screw.
8. A tube holder and interconnector system as claimed in claim 7 in
which said expander has a pocket extending at right angles to the
axis of said screw and in which pocket a nut is located which is
threaded on said screw.
9. A tube holder and interconnector system as claimed in claim 7 in
which four spreader arms are provided and wherein said expander in
its radial plane is in the shape of a regular octagonal
pyramid.
10. A tube holder and interconnector system as claimed in claim 1
in which a second intermediate component is provided which can be
expanded in a plane perpendicular to the axis of the tube in which
it is to be used, said plane being spaced apart axially from the
perpendicular plane of expansion of said first intermediate
component.
11. A tube holder and interconnector system as claimed in claim 10
in which said base has chamfered faces, and said second
intermediate component being provided by spreader arms formed on
said expander, said expander spreader arms having chamfered faces
which engage those on the base.
12. A tube holder and interconnector system as claimed in claim 11
in which said expander with spreader arms is made from one piece of
a synthetic plastics material.
13. A tube holder and interconnector system as claimed in claim 11
in which said first intermediate component is provided by several
spreader arms on said base which are arranged at 45.degree. to said
spreader arms on said expander.
14. A tube holder and interconnector system as claimed in claim 13
in which said spreader arems of said base are arranged in gaps
between said spreader arms of said expander.
15. A tube holder and interconnector system as claimed in claim 1
in which said expander comprises a resilient body and there is
included a tensioner plate on said expander, and wherein said
intermediate component comprises several spreader arms which
surrounds said expander, and which, when said tension screw is
actuated, is compressed by said tensioner plate and acts with its
peripheral surface to expand said spreader arms of said
intermediate component which surrounds it.
16. A tube holder and interconnector system as claimed in claim 15
in which said spreader arms are formed by L-shaped cut-outs in said
intermediate component.
17. A tube holder and interconnector system as claimed in claim 15
in which said spreader arms are formed by cut-outs directed axially
towards one another in said surrounding intermediate component.
18. A tube holder and interconnector system as claimed in claim 15
in which there is further included a tension sleeve which carries
said clamping lug and wherein said expander surrounds said tension
sleeve, said tension plate having a guide shoulder which guides
said plate on said tension sleeve.
19. A tube holder and interconnector system as claimed in claim 1
in which said intermediate component has several U-shaped spreader
arms.
20. A tube holder and interconnector system as claimed in claim 1
wherein said interconnector is a cube and has an opening with the
dogs associated therewith on everyone of its six faces.
Description
BACKGROUND OF THE INVENTION
The present invention relates to a tube holder which allows the
assembly and dismantling of frames and structures made up of
profiled tubes, and is particularly but not exclusively applicable
for use with square tubes for racks, furniture, etc. the tube
holder being designed to be clamped to a cuboid interconnector, the
latter having dogs and the tube holder having clamping lugs, which
dogs and lugs, by rotation of the tube assembled on the tube
holder, in either direction, can be clamped together; a resilient
intermediate component of the tube holder being forced against the
internal wall of the tube by means of a tensioner.
One tube holder is known in which the cuboid interconnector and/or
the tube holder itself, has curvilinear tracks and slider pins. The
tube holder is introduced into the tube and its clamping lugs
directed into the interconnector. By rotating the tube which is
then in position upon the tube holder, a resilient intermediate
component inside the tube is compressed with the aid of a tensioner
and thus loaded against the internal wall of the tube. At the same
time, clamping takes place between the tube holder and the cuboid
interconnector, through the agency of the dogs and clamping
lugs.
In this embodiment, stringent requirements are imposed upon the
material and the accuracy of manufacture, and if tube internal
tolerances differ widely, it cannot be ensured that an adequately
solid connection will be produced. The present invention separates
the function of fixing the tube holder inside the tube, from that
of clamping the tube holder to the cuboid interconnector.
According to the present invention a tube holder for connecting a
tube to an interconnector which has clamping dogs comprises a base
one end of which carries rigid clamping lugs which are adapted to
engage the clamping dogs on said interconnector to clamp said
holder and said interconnector together when said holder and said
interconnector are placed together and relatively rotated, and a
resilient intermediate component which can be expanded to engage
the internal wall of said tube by an expander actuated by a tension
screw which has a head located at the same end of said tube holder
as said clamping lugs.
The tube is fixed to the tube holder by the expansion of spreader
arms on the resilient intermediate component, using a wedge-like
expander, operated by the tension screw, the operation taking place
in a region or plane perpendicular to the tube axis. The tube
holder with the spreader arms in the relaxed retracted state, has a
greater or lesser degree of clearance in the tube, because of the
latter's internal dimensional tolerances, and this clearance,
outside the region or plane where the expansion of the spreader
arms takes place within the tube, is still present to a partial
extent, even after fixing has taken place. Consequently, the fixed
tube holder, although it is attached to the cuboid interconnector
in a fixed backlash-free fashion, can tilt a certain amount in the
tube, under bending loads, and this has the disadvantage of giving
the joint a certain resilience. If frequent alternating bending
loads are applied, it may happen that the fixed tube holder will
shift some distance out of the tube.
A further example avoids this drawback however by virtue of the
fact that the tube holder is provided with a second resilient
intermediate component which can be expanded in a plane
perpendicular to the axis of said tube in which it is to be used,
said plane being spaced apart axially from the perpendicular plane
of expansion of said first resilient intermediate component.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention may be performed in various ways and a number of
embodiments will now be described by way of example and with
reference to the accompanying drawings in which:-
Fig. 1 is a section through a cuboid interconnector and with a
first tube holder illustrated partially in section and partially in
elevation, and a plan view of part of a second tube holder inserted
in the interconnector at right angles to the first,
Fig. 2 is a plan view of one of the tube holders shown in FIG.
1,
Fig. 3 is an elevation of the cuboid interconnector shown in FIG.
1,
Fig. 4 is a section on the line IV--IV of FIG. 1,
Fig. 5 is a plan view of the expander used in the tube holder shown
in FIG. 1,
Fig. 6 is a section through the expander,
Fig. 7 shows a second embodiment of the tube holder partially in
section and partially in elevation,
Fig. 8 shows the two resilient intermediate components used in the
construction shown in FIG. 7, partially in section,
Fig. 9 is a plan view in the direction of the arrow IX on one of
the intermediate components,
Fig. 10 shows a third embodiment partially in elevation and
partially in section,
Fig. 11 shows a fourth embodiment in section and side
elevation,
Fig. 12 shows a further variant embodiment in section and side
elevation, and,
Fig. 13 shows a sixth embodiment partially in section and partially
in side elevation and plan, considered in the direction of the
arrow X.
BRIEF DESCRIPTION OF THE PREFERRED EMBODIMENT
The cuboid interconnector 1 shown in FIG. 1 consists of two
identical parts 3 and 3' which have prongs 4 and corresponding
recesses 5 which interlock with one another when the two parts are
assembled so that they are accurately located in the correct
position for a brazing operation which holds the parts together,
and the cube thus made is then hardened. All six sides of the cube
have identical openings 6 each of which has four recesses 7.
Between these recesses, pointing towards the interior are four
curvilinear projections or cams 8 which have been punched inwards,
in the manner shown in FIG. 4. The recesses 7 are directed towards
the side of the cube, whilst the cams 8 are directed towards the
corners and are thus each located upon a diagonal.
A first tube holder 2 shown half in section and half in elevation
is shown engaged in the lower opening 6 of the cube. At right
angles thereto a second tube holder 2' engages in the cube, the
visible top section of which has only been partially illustrated,
in order not to overburden the drawing. The tube holder 2 consists
of the base 9 with four spreader arms 10, a tensioner 11 with
clamping lugs 15, a tension screw 18 and an expander 12. The base 9
has a shoulder 13 which prevents the tube holder 2 from slipping
into the tube 20 which it is holding. The hardened tensioner 11 has
four laterally projecting clamping lugs 15 and is embedded in the
base 9 which is made of synthetic material so that the clamping
lugs 15 point diagonally towards the corners. The expander 12, has
a pocket 16 containing a square-headed nut 17 which is engaged by
the screw 18. The expander 12 is in the form of a regular octagonal
pyramid so that it can be assembled in arbitrary positions in
co-operation with taper surfaces 14 on the rear internal surfaces
of the spreader arms 10. The screw head 22 is located in the region
inside the tensioner 11 with its clamping lugs 15.
In order to establish the connection between square-section tubes
20, an assembly of a frame tube holder is first inserted into the
tube up to the shoulder 13, and secured there by tightening up the
screw 18. Rotation of the screw 18, causes the expander 12 to move
in the direction of the taper surfaces 14 on the spreader arms 10,
until the taper surfaces 19 contact them. As the screw 18 is
rotated further, the spreader arms are forced outwards and are thus
loaded firmly into contact with the corner surfaces of the tube 20
so that the latter is securely connected to the tube holder 2.
Instead of a nut 17, the bore 21 in the expander 12 can be
internally threaded to co-operate with the screw 18.
The tensioner 11, with its clamping lugs 15 is now introduced into
an opening 6 in the cube 1, the square profile of tube and cube
being arranged at an angle of 45.degree. to one another. By
forceful rotation through 45.degree. in one direction or the other,
using suitable spanners, the clamping lugs 15 of the tube holders 2
can be engaged behind the cams or dogs 8 formed in the opening 6 of
the cube 1, the relevant sideplate of the hardened cube being
resiliently distorted by a small amount. In this fashion a very
secure connection between cube and tube holder is obtained. In the
same fashion, if required, tubes can be connected to all the other
sides of the cube, through the medium of tube holders, for example,
as shown by tube holder 2'. The detachment of the connection is
just as simple and is achieved by rotating the tube 2 in relation
to the cube 1. Unwanted connections of the cube can be covered over
by cheap caps, for example, of synthetic plastics material, to
improve the appearance.
By application of the features of the invention, a whole series of
other constructions can be achieved. For example, the expander 12
can be in the form of a deep-drawn metal component with a threaded
bore and the spreader arms can likewise consist of sheet steel.
If a frame or rack is to be dismantled and re-erected at another
point, for example a requirement which occurs in the case of
measuring equipment, then the tube holders remain attached to the
tube sections so that the assembly time for re-erection is
shortened and additional attachments to the frame can be produced
without the need to change any of the connectors.
In the second embodiment to be described and as shown in FIGS. 7, 8
and 9, the tube holder, made primarily of synthetic plastics
material is intended for use with square-section tubes and consists
of a base 109 in which tensioner 111, with its clamping lugs 115,
is embedded, and an expander 112 and a tensioner screw 118 with the
nut 117 are provided. The base 109 has four spreader arms 110
provided with chamfered surfaces 114 at their inner ends. Also, the
base 109 has four chamfered surfaces 123, supplementary to those
shown in the first example. The expander 112 additionally possesses
four spreader arms 124 with chamfered surfaces 125 and also has
four chamfered surfaces 119, corresponding with the tapered
surfaces 19 of the first example.
When assembled together, as shown in FIG. 7, the tube holder is
introduced into a tube 20 and there fixed by tightening up the
screw 118. In so doing, by the action of the surfaces 123 on the
surfaces 125, the spreader arms 124 of the expander 112 are clamped
in the tube 20 in the neighbourhood of the plane A--A, whilst at
the same time the surfaces 119 act upon the surfaces 114 so that
the spreader arms 110 of the base 109 are secured in the tube in
the neighbourhood of the plane B--B. The spreader arms 110 of the
base 109 are pressed, as in the case of the first example, into the
internal corners of the tube whilst the spreader arms 124 of the
expander 112 are loaded against the flat internal walls of the
tube. The axial interval between the planes A--A and B--B means
that the system of securing the tube holder inside the tube is
particularly resistant to bending and buckling stresses, even under
conditions of frequent load alternation.
In addition to the embodiment described, tube holders with the
features of the present invention, could also be designed for other
materials and for other tube profiles.
In the embodiment shown in FIG. 10, all the components are made of
metal. The expander 12' is a dish-like sheet metal component with a
threaded central bore in which a tension screw 18 engages. The base
9" is rigidly attached to the end 9' of a cupped sheet metal
component whose walls consist of spreader arms 10' and a tensioner
11' with clamping lugs 15' is rigidly connected to the base 9".
In the case of the tube holder shown in FIG. 11, a tensioner 311,
with clamping lugs 315, is rigidly attached to a base 309. Rigidly
connected to the base 309 is an intermediate component 310 and
arranged within the intermediate component, and between tensioner
plates 312' and 312", is an expander 312 which consists of an
resilient material, for example, rubber. The front tensioner plate
312", like the expander 312, is provided with a bore, whilst the
rear tensioner plate 312' has a threaded bore in which a screw 318
engages. When the screw 318 is rotated, the expander 312 is clamped
between the tensioner plates 312' and 312" so that the spreader
arms 310' of the intermediate component 310 are forced outwards. As
shown in the righthand illustration of FIG. 11, the spreader arms
310' are formed by L-shaped cut-outs 310" in the intermediate
component 310. By using this shape of cut-outs the spreader arms
310' bear against the internal wall of the tube which is to be
clamped, over virtually their entire length.
In the embodiment of FIG. 12, a tubular tensioner 411 with clamping
lugs 415, is rigidly attached to a base 409. Inside the tubular
tensioner 411, there is a rigid shoulder 427 against which the head
of a tension screw 418 can seat. Rigidly connected to the base 409
is an intermediate component 410, preferentially in two mutually
opposite locations 428. The tension screw 418 engages in a threaded
bore in the tensioner plate 412' and within the intermediate
component 410, once again there is an expander 412 of resilient
material, surrounding a tubular tensioner 411. The tensioner plate
412' is provided with a shoulder 426 which serves to centralise the
tensioner plate 412' of the sleeve-like tensioner 411.
In the example of FIG. 12, the intermediate component is provided
with several cut-outs 410", extending in the longitudinal
direction, so that several spreader arms 410' are formed. The
fixing of the tube holder in the tube, is thus effective over
virtually the full length of the tube holder.
In a final embodiment, shown in FIG. 13, a base 509 is once again
rigidly connected to a tubular tensioner 511 which has clamping
lugs 515. Within the tubular tensioner a shoulder 527 is provided
against which the head of a tension screw 518 seats, the end of the
screw 518 engaging in a threaded bore in an expander 512. This
capshaped expander 512 enshrouds the rear end of a part 526 of an
intermediate component 510. Said part 526 is guided on the outside
of the tensioner 511 and also at the centre, over the section 529.
The intermediate component 510 has several spreader arms 510',
U-shaped and articulated at their ends, which arms, when the
expander 512 is tightened up by the screw 518, expand towards the
tube which is to be fixed. The bottom part of FIG. 13 shows the
position of the spreader arms 510' relatively to a tube 20 to which
the holder is to be secured.
Because many varying and different embodiments may be made within
the scope of the inventive concept herein taught, and because many
modifications may be made in the embodiments herein detailed in
accordance with the descriptive requirements of the law, it is to
be understood that the details herein are to be interpreted as
illustrative and not in a limiting sense.
* * * * *