CROSS-REFERENCE TO RELATED APPLICATIONS
BACKGROUND
[0002] A cable tie is a type of fastener, for holding items together, primarily electrical
cables or wires. These cable ties are well known. Typically, they are thin, flexible
polymeric strips that can be wrapped about the cables. Because of their low cost and
ease of use, cable ties find use in a wide range of other applications.
[0003] One common cable tie is made of nylon and has a flexible tape section with teeth
that engage with a pawl in a head to form a ratchet so that as the free end of the
tape section is pulled the cable tie tightens and does not come undone. Some ties
include a tab that can be depressed to release the ratchet so that the tie can be
loosened or removed, and possibly reused.
[0004] Tools for applying cable ties about a bundle of wires or similar articles are also
well known. These tools may be manual, semi-automatic, or automatic. Many of these
tools are complicated multiple operation tools that provide individual cable ties
from a dispenser having a cartridge or reel containing a large number of cable ties
to a conveyance mechanism for provision to the application tool.
[0005] Portable hand tools of this type are possible when the mechanism for separating each
cable tie from the cable tie ribbon is within the tool itself. Thus, individual cable
tie ribbons of a manageable length are positioned in the portable tool which sequentially
separates, advances and applies each cable tie. Prior automatic cable tie installation
tools have utilized various reciprocating mechanisms such as a pushing rod or carriage
as the cable tie advancing mechanism to transport the tie into application position
around the bundle. Tools of this type still have drawbacks due to the requirement
that the reciprocating member needs to be retracted to be in position to transport
the next cable tie. Therefore, the simplification of the cable tie advancing mechanism
will greatly reduce the complexity of the overall tool. Additionally, the elimination
of a reciprocating transport mechanism allows for a shorter length tool and one which
uses fewer moving parts.
[0006] The present invention is provided to solve the problems discussed above and other
problems, and to provide advantages and aspects not provided by prior cable tie tools
devices of this type. A full discussion of the features and advantages of the present
invention is deferred to the following detailed description, which proceeds with reference
to the accompanying drawings.
[0007] US5595220A discloses a portable automatic cable tie installation tool for applying individual
cable ties around bundles of wires.
SUMMARY
[0008] A first aspect of the invention is directed to an automatic cable tie apparatus for
tightening and fastening a cable tie about around a bundle of cables or the like,
as in the appended claim 1. A first motor imparts rotational movement to a first shaft
separately in a first direction and a second direction wherein the first and second
directions are one of a clockwise and a counter-clockwise direction, respectively.
A cable tie delivery mechanism is operably joined to the first motor such that the
cable tie delivery mechanism transfers a cable tie to a cable tie load starting position
as the first shaft rotates in the first direction. A transporter is operably joined
to the first motor such that the transporter transfers the cable tie from the cable
tie load starting position to a cable tie tensioning position as the first shaft rotates
in the second direction.
[0009] The first aspect of the invention may further comprise one or more of the following
features. A first clutch may be located between the first motor and the cable tie
delivery mechanism. The first clutch has an engaged condition wherein rotational movement
by the first shaft in the first direction drives a movement by the cable tie delivery
mechanism and a disengaged condition wherein rotational movement by the first shaft
in the second direction causes the first shaft to freewheel in relation to the cable
tie delivery mechanism wherein such rotational movement by the first shaft in the
second direction does not impart movement to the cable tie delivery mechanism. A second
clutch may be located between the first motor and the transporter. The second clutch
has an engaged condition wherein rotational movement by the first shaft in the second
direction drives a movement by the transporter and a disengaged condition wherein
rotational movement by the first shaft in the first direction causes the first shaft
to freewheel in relation to the transporter wherein such rotational movement by the
first shaft in the first direction does not impart movement to the transporter.
[0010] The cable tie delivery mechanism may comprise a gearing assembly operably joined
to the first motor wherein a first gear in the gearing assembly includes a plurality
of chamfered teeth configured to frictionally engage a cable tie carrier to impart
movement to the cable tie carrier upon rotation of the first shaft in the first direction
to deliver the cable tie in the plurality of cable ties to the cable tie load starting
position.
[0011] The transporter may also comprise a gearing assembly operably joined to the first
motor wherein a first gear imparts movement to the transporter to convey the cable
tie from the cable tie load starting position to the cable tie tensioning position.
[0012] The first aspect of the invention may further comprise a support wall operably joined
to the second motor such that the support wall moves upwardly in response to the second
shaft rotating in the direction corresponding to one of the first direction or the
second direction. The support wall may move upwardly to a position adjacent the transporter
to support the cable tie as the cable tie moves from the cable tie load starting position
to the cable tie tensioning position.
[0013] The first aspect further comprises a second motor imparting rotational movement to
a second shaft separately in the first direction or the second direction. A cable
tie supporter is operably joined to the second motor such that the cable tie supporter
directs a moving cable tie from the cable tie load start position to the cable tie
tensioning position as the second shaft rotates in a direction corresponding to one
of the first direction or the second direction. A cable tie tensioner is operably
joined to the second motor such that the cable tie tensioner decreases a circumferential
length of the annular shape as the second shaft rotates in the other of the first
direction or the second direction.
[0014] The present disclosure is also directed to an automatic cable tie apparatus for tightening
and fastening a cable tie around a bundle of cables or the like. A motor imparts rotational
movement to a shaft separately in a first direction or a second direction, wherein
the first or second directions are one of a clockwise and a counter-clockwise direction,
respectively. A support wall may be operably joined to the motor such that the support
wall moves upwardly in response to the shaft rotating in the first direction. The
support wall may move upwardly to a position adjacent the transporter to support the
cable tie as the cable tie moves from a cable tie load starting position to a cable
tie tensioning position.
[0015] A cable tie supporter is operably joined to the motor such that the cable tie supporter
directs a moving cable tie from the cable tie load start position to the cable tie
tension position as the shaft rotates in the first direction. A cable tie tensioner
is operably joined to the motor such that the cable tie tensioner decreases a circumferential
length of the annular shape as the shaft rotates in the second direction,
[0016] The present disclosure is also directed to an automatic cable tie apparatus for tightening
and fastening a cable tie around a bundle of cables or the like. A plurality of mechanical
functions performed in sequence delivers a cable tie from a plurality of cable ties
to a cable load starting position, forms the cable tie into an annular form, tensions
the cable tie, and shortens a circumferential length of the annular form. A first
motor imparts rotational movement to a first shaft separately in a first direction
and a second direction wherein the first and second directions are one of a clockwise
and a counter-clockwise direction. The first motor separately provides a mechanical
power to a first apparatus function in the plurality of mechanical functions as the
first shaft rotates in the first direction and a second apparatus function in the
plurality of mechanical functions as the first shaft rotates in the second direction.
The second motor imparts rotational movement to a second shaft separately in a third
direction and a fourth direction wherein the third and fourth directions are one of
a clockwise and a counter-clockwise direction. The second motor separately provides
a mechanical power to a third apparatus function in the plurality of mechanical functions
as the second shaft rotates in the third direction and a fourth apparatus function
in the plurality of mechanical functions as the second shaft rotates in the fourth
direction. A cable tie delivery mechanism is operably joined to one of the first and
second motors and performs one of the plurality of mechanical functions wherein the
cable tie delivery mechanism delivers the cable tie to the cable load starting position.
A cable tie supporter is operably joined to one of the first and second motors and
performs one of the plurality of mechanical functions wherein the cable tie supporter
can guide the cable tie into the transport channel, raise the lower jaw, and cut the
tie from the carrier strip. A cable tie transporter is operably joined to one of the
first and second motors and performs one of the plurality of mechanical functions
wherein the cable tie transporter moves the cable tie from the cable tie load starting
position to the cable tie tensioning position and bends the cable tie into an annular
position. A cable tie tensioner is operably joined to one of the first and second
motors and performs one of the plurality of mechanical functions wherein the cable
tie tensioner shortens the circumferential length of the annular form and removes
the excess cable tie.
[0017] Other features and advantages of the invention will be apparent from the following
specification taken in conjunction with the following drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0018] To understand the present invention, it will now be described by way of example,
with reference to the accompanying drawings in which:
FIG. 1 is a perspective view of a handheld cable tie tool of the present invention;
FIG. 2 is a perspective view of the handheld cable tie tool of the present invention
with a housing removed showing a plurality of cable ties loaded therein;
FIG. 3 is a partial perspective view of the handheld cable tie tool loaded with a
plurality of cable ties;
FIG. 4 is a partial perspective view of the handheld cable tie tool loaded with a
plurality of cable ties showing a cable tie being delivered via an auger towards a
cable tie tensioning position;
FIG. 5 is a partial perspective view of the handheld cable tie tool loaded with a
plurality of cable ties;
FIG. 6 is a partial perspective view of the handheld cable tie tool loaded with a
plurality of cable ties with a support wall in an upper position showing a cable tie
in a cable load starting position;
FIG. 7 is a left front perspective view of an upper portion of the cable tie tool
of the present invention with a housing removed;
FIG. 8 is a right front perspective view of an upper portion of the cable tie tool
of the present invention with a housing removed;
FIG. 9 is a right rear perspective view of an upper portion of the cable tie tool
of the present invention with a housing removed;
FIG. 10 is a left side view of an upper portion of the cable tie tool of the present
invention with a housing removed;
FIG. 11 is a right side view of an upper portion of the cable tie tool of the present
invention with a housing removed;
FIG. 12 is a right side view of an upper portion of the cable tie tool of the present
invention with a housing removed showing a drive belt;
FIG. 13 is a front view an upper portion of the cable tie tool of the present invention
with a housing removed;
FIG. 14 is a back view of an upper portion of the cable tie tool of the present invention
with a housing removed;
FIG. 15 is a partial cross-sectional view of the apparatus showing a cable tie bent
into an annular form and the rear jaw in an upper position; and
FIG. 16 is a partial cross-sectional view of the apparatus showing a cable tie bent
into an annular form in a cable tie tensioning position and a circumferential length
of the annular form decreased by a cable tie tensioner.
DETAILED DESCRIPTION
[0019] While this invention is susceptible of embodiments in many different forms, there
is shown in the drawings and will herein be described in detail preferred embodiments
of the invention with the understanding that the present disclosure is to be considered
as an exemplification of the principles of the invention and is not intended to limit
the broad aspect of the invention to the embodiments illustrated.
[0020] Referring generally to the figures, a portable, handheld cable tie apparatus 10 is
illustrated. This cable tie apparatus dispenses a cable tie 14 from a supply of cable
ties 18, wraps the cable tie 14 about a plurality of cables (not shown), and tightens
the cable tie 14 about the cables. The cable tie apparatus is advantageous for many
reasons.
[0021] For example, it is fully self-contained, A supply of cable ties 18, while external
to a housing 22 of the cable tie apparatus 10, is easily transported when loaded into
or onto the cable tie apparatus 10.
[0022] Additionally, the cable tie apparatus 10 may be operated with one hand. Thus, a user
has a hand free to support cables, lift or move cables, and/or feed cables to the
cable tie apparatus 10.
[0023] Further, the cable tie apparatus 10 of the present invention is powered by a power
source or supply 26, preferably a DC power supply such as a rechargeable battery electronically
connected to apparatus drivers. Thus, actuation of the cable tie apparatus 10 by manipulating
an actuator 30, such as a trigger, causes a cable tie 14 to be dispensed and wrapped
about the cables without further manual intervention,
[0024] As shown in FIGS, 2-6, cable ties 18 used with the cable tie apparatus 10 may be
ratchet-type cable ties. One end, typically a head 34, of each cable tie 14 is attached
to a carrier strip 38. An opposite end, a tapered tip end 42, is a free end, not attached
to the carrier strip 38. The cable ties 18 and carrier strip 38 are fed into a left
side of the cable tie apparatus 10. A pair of transfer gears 46 have teeth configured
to bite into the carrier strip 38 and index each cable tie 14 into a proper position
for separating, e.g. by cutting or severing, the cable tie 14 from the carrier strip
38. A pressure bar 50 creates an upward force to ensure the carrier strip 38 is always
loaded up against the transfer gears 46. This is critical for proper operation and
cable tie transfer.
[0025] A first motor 55, e.g. a stepper motor, has a shaft joined to a drive gear 56 which
transfers rotational movement to the transfer gears 46. Accordingly, the shaft imparts
rotational movement separately in a first direction and a second direction wherein
the first and second directions are one of a clockwise and a counter-clockwise direction,
respectively. The transfer gears 46 transfer movement to the plurality of cable ties
18 attached to the carrier strip 38.
[0026] A cable delivery mechanism 52 is operably joined to the motor 55. This mechanism
delivers a cable tie 14 to a load starting position (see, e.g., FIG. 6), The cable
ties 14 are loaded on the left side of the apparatus 10 with the carrier strip 38
being urged or pushed upwardly into a carrier strip guide 54. Once the carrier strip
38 reaches the transfer gears 46, the transfer gears 46 engage and bite into the carrier
strip 38 and rotate to move the cable ties 14 to a load starting position.
[0027] A tie sensor 58 is located at the end of the carrier strip guide 54 (see, e.g., FIG.
7). The tie sensor 58 (FIG. 8) senses the presence of a cable tie 14. The tie sensor
58 transmits a signal which causes the first motor 55 to stop rotating the drive gear
56 and the carrier strip 38 with the cable ties 14 which stops advancing when a cable
tie 14 is located just under a transfer auger 62. When a cable tie 14 is in this position,
the apparatus 10 is ready for an operator to begin applying cable ties 14 to a bundle
of cables (not shown).
[0028] The first motor 55 shaft is further joined to cable tie transporter 60. The cable
tie transporter 60 moves the cable tie 14 linearly from the cable tie load starting
position to a cable tie tensioning position. The cable tie transporter 60 includes
a second set of gears 63, 64 which drive the auger 62. The drive gear 63 transfers
movement to an auger gear 64 directly attached to an end of the auger 62.
[0029] The cable tie delivery mechanism 52 and the cable tie transporter 60 each have a
one-way clutch 65. The drive gears 56, 63 are outfitted with the clutches 65. These
clutches 65 are set to engage in one direction and disengage in the other direction.
This enables the first motor 55 to separately enable two different functions with
one prime mover. In this case, when the shaft of the first motor 55 rotates in a first
direction, it drives revolution of a first drive gear 56 which transfers motion to
the transfer gears 46 to index the plurality of cable ties 18. When the shaft of the
first motor 55 rotates in a second direction, it drives revolution of a drive gear
63 which transfers motion to the auger gear 64 which causes the auger 62 to transfer
a cable tie 14 from the plurality of cable ties 18 outwardly along a length of the
auger 62 towards front and rear jaws 68, 70. The cable tie 14 is pushed around the
cable tie supporter 66 of the front and rear jaws 68, 70 into an annular shape around
a bundle of cables (not shown).
[0030] Thus, one clutch 65 is located between the first motor 55 and the cable tie delivery
mechanism 52. This clutch 65 has an engaged condition wherein rotational movement
by the first motor 55 shaft in the first direction drives a movement by the cable
tie delivery mechanism 52 and a disengaged condition wherein rotational movement by
the first motor 55 shaft in the second direction causes the cable tie delivery mechanism
52 to freewheel in relation to the first motor 55 shaft. Such rotational movement
by the first motor 55 shaft in the second direction does not impart movement to the
cable tie delivery mechanism 52.
[0031] A second clutch 65 is located between the first motor 55 and the cable tie transporter
60. This clutch 65 also has an engaged condition wherein rotational movement by the
first motor 55 shaft in the second direction drives a movement by the cable tie transporter
60 and a disengaged condition wherein rotational movement by the first motor 55 shaft
in the first direction causes drive gear 63 to freewheel in relation to the fist motor
55 shaft. Such rotational movement by the first motor 55 shaft in the first direction
does not impart movement to the cable tie transporter 60.
[0032] Further to the transfer gears 46, each gear exhibits a modified end of tooth profile
(see, e.g., FIG. 5). Tips of the transfer gears 46 have two small chamfers on each
side of every tooth. This chamfer profile makes the end of each tooth pointed and
allows the teeth to frictionally engage by biting into the carrier strip 38 and reliably
impart movement to the carrier strip 38 and index the cable ties 18. This profile
also reduces the surface area of each tooth to allow surface penetration of the carrier
strip 38 regardless of whether the cable ties 18 are dry or wet.
[0033] The operator positions front and rear jaws 68, 70 around the bundle of cables and
actuates the apparatus 10 by engaging the actuator 30, e.g. pressing a trigger on
the apparatus.
[0034] A second motor 74 imparts rotational movement to a shaft separately in the clockwise
and counter-clockwise directions. A cable lie supporter 66, is operably joined to
the second motor 74 such that the cable tie supporter 66 directs a cable tie tapered
tip end 42 through the cable tie head 34 as the shaft rotates in one of a clockwise
or counter-clockwise direction (see, e.g., FIG. 15). A cable tie tensioner is also
operably joined to the second motor 74 such that the cable tie tensioner decreases
a circumferential length of the annular shape when the tapered tip end 42 engages
the gripper gear 122 as the shaft rotates in the opposite direction to the direction
which drives the cable tie supporter 66.
[0035] Upon actuation, the second motor 74, such as a brushless motor, causes a drive belt
78 to move. The drive belt 78 is wound about a motor pulley 82 attached to the second
motor 74, an idler 86, cam pulley 90, and a tensioning and cut-off pulley 94. The
second motor 74 drives the motor pulley 82 which drives the drive belt 78 causing
rotation of the cam pulley 90 and the tensioning and cut-off pulley 94.
[0036] A support wall 98 is operably joined to the second motor 74 to support the cable
tie 14 as the cable tie 14 moves from the cable tie load starting position to the
cable tie tensioning position. A support wall 98 moves upwardly to a position adjacent
the cable tie transporter 60 in response to the second motor 74 shaft rotating in
the direction corresponding to one of a clockwise or counter-clockwise direction.
[0037] Rotation, generally 180 degrees, of cam pulley 90 causes a movement in the support
wall 98. The support wall 98 moves upwardly into an upper position (see, e.g. FIG.
4 and 6). The support wall 98 is operably joined to the rear jaw 70 and includes features
that actuate closing of the rear jaw 70 (compare, e.g., FIG. 11 with FIG. 15), cutting
the cable tie 14 from the carrier strip 38, and supporting the cable tie 14 being
transferred by the auger 62 from the load starting position to a tensioning position.
During the supporting wall's 98 upward movement three events occur to locate the cable
tie 14 in a proper or desired position.
[0038] First, the support wall 98 is operably joined to the second motor 74 such that the
support, wall moves upwardly in response to the second shaft rotating in the direction
corresponding to one of the first direction or the second direction. The support wall
98 moves upward with the rear of the support wall 98 moving up first due to a resistance
on a front portion of the support wall 98 created by a rear jaw linkage 99. The support
wall 98 moves upwardly on an angle until a cutter blade 102 attached to a rear portion
of the support wall 98 contacts the cable tie 14. This adds resistance to the rear
of the support wall 98 moving upwardly and causes the front of the support wall 98
to move up angularly until the front of the support wall 98 is totally up and stopped
by one or more pins 103.
[0039] A rear portion of the support wall 98 includes the cutter blade 102 that separates,
frees, or cuts the cable tie 14 from the carrier strip 38. When the cutter blade 102
contacts a carrier strip connecting gate, the support wall 98 experiences resistance
which causes the front portion of the support wall 98 to start rising. This angular
motion creates a sweeping action that pulls a cable tie 14 in the plurality of cable
ties 18 into a loading channel. This aligns the cable tie 14 for proper tie transfer
by the auger 62.
[0040] Secondly, while the support wall 98 is moving upwardly, it actuates the rear jaw
linkage 99 that causes the rear jaw 70 to close around a cable bundle, or the like
(see, e.g. FIGS. 6 and 15).
[0041] Thirdly, the support wall 98 continues in its upward travel until the cable tie 14
is separated from the carrier strip 38. Once the cable tie 14 is separated, the cam
pulley 90 stops, and the support wall 98 is in its final, fully upward position. The
cam pulley 90 holds the support wall 98 in this position during cable tie transfer.
The support wall 98 acts as a lower guide against which a bottom surface of the cable
tie 14 is supported as it travels outwardly along the length of the auger 62 to the
tensioning position.
[0042] At this point the first motor 55 reverses direction, and the auger 62 begins turning.
This causes the cable tie 14 to transfer forwardly toward the front and rear jaws
68, 70 until it reaches a head stop 110,
[0043] Cable tie 14 movement is achieved by the tie head 34 trapped within a helical channel
114 in the auger 62. Rotation of the auger 62 causes the tie head 34 to move linearly
forwardly within the helical channel 114.
[0044] A one-way clutch 65 is located between the second motor 74 and the cam pulley 90.
This clutch 65 has an engaged condition wherein rotational movement by the second
motor 74 shaft in one direction drives a movement by the cam pulley 90, A disengaged
condition occurs when the shaft rotates in the opposite direction. Here, rotational
movement by the shaft in the opposite direction causes the cam pulley 90 to freewheel
in relation to the second motor 74 shaft. Such rotational movement by the shaft in
the opposite direction does not impart movement to the cam pulley 90.
[0045] Similarly, another one-way clutch 65 is located between the second motor 74 and the
cable tie tensioner. This clutch 65 has an engaged condition where rotational movement
by the second motor shaft in one of the clockwise or counter-clockwise directions
drives a movement by the cable tie tensioner. In a disengaged condition, rotational
movement by the shaft in the opposite direction causes the cable tie tensioner to
freewheel in relation to the second motor 74 shaft. Such rotational movement by the
shaft in the opposite direction does not impart movement to the cable tie tensioner.
[0046] The tensioning and cut-off pulley 94 and the cam pulley 90 include one-way clutches
65 pressed into the tensioning and cut-off pulley and the cam pulley 94, 90, respectively.
The purpose of the one-way clutch 65 is to allow the pulley 94 and cam pulley 90 to
perform a function in one direction and free spin in the other direction. The tensioning
and cut-off pulley 94 and the cam pulley 90 have one-way clutches 65 installed in
opposite directions so the same second motor 74 can perform two different operations
by just reversing direction (see FIGS. 11 and 12).
[0047] The last function is tensioning the cable tie 14 about a bundle of cables, or the
like, and severing the free end 42 at the tie head 34. This is the same function as
performed in the PAT1M 4.0 system marketed and sold by Panduit Corp. and also described
in
U.S. Patent No. 5,595,220, the full disclosure of which is hereby incorporated by reference and for the specific
description of the tensioning on the cable tie 14 about a bundle of cables and the
severing of the cable tie 14 at the tie head 34. In the present apparatus 10, the
second motor 74 reverses direction and the tensioning and cut-off pulley 94 is engaged
such that an intermediate gear 115 is driven by the tensioning and cut-off pulley
94.
[0048] The auger 62 transfers the cable tie 14 from a load position to the head stop 110.
As the cable tie 14 is pushed forward, the free end 42 moves around the front and
rear jaws 68, 70 into an annular shape. The second motor 74 rotates in a clockwise
or counter-clockwise direction and moves the front jaw 68 inwardly to push the free
end 42 into the tie head 34.
[0049] Here, the free end 42 of the cable tie 14 traverses within a groove 118 within the
front and rear jaws 68, 70 which forms a guide within which the cable tie 14 travels
to form a circumferential condition wherein the free end 42 of the cable tie 14 feeds
through the tie head 34.
[0050] The front jaw 68 movement threads the free end 42 through the tie head 34 and delivers
the free end 42 to a gripper gear 122. Once the free end 42 feeds through the tie
head 34, the front jaw 68 pushes an intermediate portion of the cable tie 14 farther
through the tie head 34 where the free end 42 is gripped by a gripper gear 122. The
gripper gear 122 rotates which causes the free end 42 to move and the cable tie 14
to tension or tighten about the cable bundle, This process continues until a predetermined
set tension is reached. The predetermined tension is adjustable by a knob 124. At
this, a second cutter blade 126 is actuated and cuts the intermediate portion of the
cable tie 14 flush to the tie head 34.
[0051] The tensioning and cut-off pulley 94 has a gear 127 (see, e.g., FIGS. 9 and 13) which
drives the intermediate gear 115. The intermediate gear 115 is joined by a shaft to
a gripper drive gear 128. The gripper drive gear 128 drives the gripper gear 122.
[0052] A front jaw cam roller 130 (see, e.g., FIG. 13), which is revolving along with gear
127 pushes the front jaw cam link 134 forward resulting in the front jaw 68 pivoting
about a pivot point 138 to rotate in thereby threading the free end 42 of the cable
tie 14 through the tie head 34 and forcing the intermediate portion of the cable tie
14 into engagement with the gripper gear 122. The front jaw 68 is returned to its
normal position after front jaw cam roller 130 has revolved sufficiently by front
jaw return extension spring 142.
[0053] A tension adjusting assembly is mechanically linked to the gripper gear 122 and applies
a preset force through a tension limiting spring 146 to a tension retainer link 150
which is translated to a detent cam follower 154 such that as the gripper gear 122
pulls on the cable tie 14, increasing the downward force applied to a gripper detent
link 158, a point is reached where the downward force overcomes the force applied
by the tension assembly and gripper gear 122 begins walking down the cable tie. When
the gripper detent link 158 rotates, it pulls on a severance link which causes a second
cutter blade 126 to cut the excess intermediate portion of the cable tie 14 from the
tensioned tie. When the excess portion has been cut, a tension limiting spring 146
forces the gripper detent link 158 back into position and engagement of detent cam
follower 154 with a detent or recess in the tensioning retaining link. The return
of the gripper detent link 158 causes activation of a sensor 170 indicating that the
cable tie 14 has been cut, and the cycle was successfully completed. Continued rotation
of gripper gear 122 drives the severed portion of the cable tie 14 out of the apparatus
10.
[0054] The tensioning and cut-off pulley 94 also includes a timing control cutout 178 (see,
e.g., FIG. 9) and is timed so that it completes one revolution per tool cycle, The
revolution of the tensioning and cut-off pulley 94 is timed so that when a sensor
170 first senses the timing control cutout 178, the motor 74 slows down. When sensor
170 senses an end of timing control cutout 178, indicating that the front jaw 68 has
returned to the original position, the motor 74 stops.
[0055] Thus, when the cable tie 14 reaches the predetermined tension of the tensioning limiting
spring 146, the tension retainer 150 releases. This causes the gripper detent link
158 to move around a main pivot shaft which causes the second cutter blade 126 to
cut the tensioned cable tie 14.
[0056] The support wall 98 then lowers to a down position (see, e.g., FIG. 10) aided by
a spring force provide by a spring 174. The next cable tie 14 in the plurality of
cable ties 18 indexes to the load position. This completes one cycle of the cable
tie apparatus 10.
[0057] The support wall 98 is lowered by rotating the cam pulley 90 another 180 degrees.
A sensor 170 senses a position of the support wall 98 to ensure it is in a fully down
position.
[0058] When the support wall 98 is down, and the sensor 170 confirms its position, the next
cable tie 14 in the plurality of cable ties 18 is indexed into the load position.
[0059] As described above, according to an embodiment of the invention, the cable tie apparatus
10 performs a plurality of mechanical functions in sequence. These functions are driven
or powered by the first and second motors 55, 74, which are actuated or controlled
by a plurality of sensors 170, generally proximity sensors or optical sensors. The
functions deliver a cable tie 14 from a plurality of cable ties 18 to a cable load
starting position, transport the cable tie 14 from that position to a cable tie tensioning
position, forms the cable tie 14 into an annular ring, and shortens a circumferential
length of the annular form about a bundle of cables.
[0060] The first motor 55 imparts rotational movement to a shaft separately in a first direction
and a second direction. The first and second directions are one of a clockwise and
a counter-clockwise direction. The first motor 55 separately provides a mechanical
power to a first apparatus function in the plurality of mechanical functions as the
shaft rotates in the first direction. The first motor 55 separately provides a mechanical
power to a second apparatus function in the plurality of mechanical functions as the
shaft rotates in the second direction,
[0061] The second motor 74 imparts rotational movement to a shaft separately in a third
direction and a fourth direction wherein the third and fourth directions are one of
a clockwise and a counter-clockwise direction, The second motor 74 separately provides
a mechanical power to a third apparatus function in the plurality of mechanical functions
as its shaft rotates in the third direction. The second motor 74 separately provides
a mechanical power to a fourth apparatus function in the plurality of mechanical functions
as its shaft rotates in the fourth direction.
[0062] The cable tie delivery mechanism is operably joined to one of the first and second
motors 55, 74 and performs one of the plurality of mechanical functions wherein the
cable tie delivery mechanism delivers the cable tie 14 to a cable load starting position.
[0063] The cable tie transporter is operably joined to one of the first and second motors
55, 74 and performs one of the plurality of mechanical functions wherein the cable
tie transporter moves the cable tie 14 from the cable tie load starting position to
the cable tie tensioning position.
[0064] The cable tie tensioner is operably joined to one of the first and second motors
55, 74 and performs one of the plurality of mechanical functions wherein the cable
tie tensioner shortens the circumferential length of the annular form.
1. An automatic cable tie apparatus (10) for tightening and fastening a cable tie (14)
around a bundle of cables, comprising:
a first motor (55) imparting rotational movement to a first shaft separately in a
first direction and a second direction wherein the first and second directions are
one of a clockwise and counter-clockwise direction, respectively;
a cable tie delivery mechanism (52) operably joined to the first motor such that the
cable tie delivery mechanism transfers a cable tie to a cable tie load starting position
as the first shaft rotates in the first direction; and
a transporter (60) operably joined to the first motor such that the transporter transfers
the cable tie from the cable tie load starting position to a cable tie tensioning
position as the first shaft rotates in the second direction; characterized by
a second motor (74) imparting rotational movement to a second shaft separately in
the first direction and the second direction;
a cable tie guide (66) operably joined to the second motor such that the cable tie
guide directs the moving cable tie as the second shaft rotates in a direction corresponding
to one of the first direction or the second direction; and
a cable tie tensioner operably joined to the second motor such that the cable tie
tensioner decreases a circumferential length of the cable tie as the second shaft
rotates in an opposite direction to said
direction corresponding to one of the first direction or the second direction.
2. The automatic cable tie apparatus (10) of Claim 1 further comprising:
a first clutch (65) located between the first motor (55) and the cable tie delivery
mechanism (52), the first clutch having an engaged condition wherein rotational movement
by the first shaft in the first direction drives a movement by the cable tie delivery
mechanism (52) and a disengaged condition wherein rotational movement by the first
shaft in the second direction causes the first shaft to freewheel in relation to the
cable tie delivery mechanism (52) wherein such rotational movement by the first shaft
in the second direction does not impart movement to the cable tie delivery mechanism.
3. The automatic cable tie apparatus (10) of Claim 2 further comprising:
a second clutch (65) located between the first motor (55) and the transporter (60),
the second clutch having an engaged condition wherein rotational movement by the first
shaft in the second direction drives a movement by the transporter (60) and a disengaged
condition wherein rotational movement by the first shaft in the first direction causes
the first shaft to freewheel in relation to the transporter (60) wherein such rotational
movement by the first shaft in the first direction does not impart movement to the
transporter.
4. The automatic cable tie apparatus (10) of Claim 3 wherein the cable tie delivery mechanism
(52) comprises a gearing assembly operably joined to the first motor wherein a first
gear in the gearing assembly includes a plurality of chamfered teeth configured to
frictionally engage a cable tie carrier to impart movement to the cable tie carrier
upon rotation of the first shaft in the first direction to deliver the cable tie to
the cable tie load starting position.
5. The automatic cable tie apparatus (10) of Claim 4 wherein the transporter (60) comprises
a gearing assembly operably joined to the first motor wherein a first gear imparts
movement to the transporter (60) to convey the cable tie from the cable tie load starting
position to the cable tie tensioning position.
6. The automatic cable tie apparatus (10) of Claim 1 wherein the transporter (60) comprises
an auger (62) having a helical channel in which a cable tie head (34) is held to impart
a linear movement of the cable tie (14) from the cable tie load starting position
to the cable tie tensioning position.
7. The automatic cable tie apparatus (10) of Claim 6, wherein the auger (62) pushes the
cable tie forward around a cable tie supporter (66) of front and rear jaws (68, 70)
into an annular shape around the bundle of cables.
8. The automatic cable tie apparatus (10) of Claim 1 further comprising:
a third clutch located between the second motor (74) and the cable tie guide (66),
the third clutch having an engaged condition wherein rotational movement by the second
shaft in the direction corresponding to one of the first direction or the second direction
drives a movement by the cable tie guide (66) and a disengaged condition wherein rotational
movement by the second shaft in the opposite direction to the direction corresponding
to one of the first direction or the second direction causes the second shaft to freewheel
in relation to the cable tie guide (66) wherein such rotational movement by the second
shaft in the opposite direction to the direction corresponding to one of the first
direction or the second direction does not impart movement to the cable tie guide
(66).
9. The automatic cable tie apparatus (10) of Claim 8 further comprising:
a fourth clutch located between the second motor (74) and the cable tie tensioner,
the fourth clutch having an engaged condition wherein rotational movement by the second
shaft in the opposite direction to the direction corresponding to one of the first
direction or the second direction drives a movement by the cable tie tensioner and
a disengaged condition wherein rotational movement by the second shaft in the direction
corresponding to one of the first direction or the second direction causes the second
shaft to freewheel in relation to the cable tie tensioner wherein such rotational
movement by the second shaft in the direction corresponding to one of the first direction
or the second direction does not impart movement to the cable tie tensioner.
10. The automatic cable tie apparatus (10) of Claim 9 wherein the cable tie guide (66)
comprising a support wall (98) operably joined to the second motor (74) such that
the support wall moves upwardly in response to the second shaft rotating in the direction
corresponding to one of the first direction or the second direction.
11. The automatic cable tie apparatus (10) of Claim 10 wherein the support wall (98) moves
upwardly to a position adjacent the transporter (60) to support the cable tie (14)
as the cable tie (14) moves from the cable tie load starting position to the cable
tie tensioning position.
12. The automatic cable tie apparatus (10) of Claim 10 wherein upward movement of the
support wall (98) actuates rear jaw (70) closing the rear jaw (70) around the cable
bundle.
13. The automatic cable tie apparatus (10) of Claim 10 wherein upward movement of the
support wall (98) cuts the cable tie (14) from a carrier strip and pulls the cable
tie (14) into the cable tie load starting position.
1. Automatische Kabelbindervorrichtung (10) zum Spannen und Befestigen eines Kabelbinders
(14) um ein Kabelbündel, umfassend:
einen ersten Motor (55), der eine Drehbewegung auf eine erste Welle separat in einer
ersten Richtung und einer zweiten Richtung aufbringt, wobei die erste und die zweite
Richtung eine einer Richtung im Uhrzeigersinn bzw. gegen den Uhrzeigersinn ist;
einen Kabelbinderzuführmechanismus (52), der mit dem ersten Motor derart wirkverbunden
ist, dass der Kabelbinderzuführmechanismus einen Kabelbinder zu einer Kabelbinderladestartposition
überführt, während sich die erste Welle in der ersten Richtung dreht; und
eine Transportvorrichtung (60), die mit dem ersten Motor derart wirkverbunden ist,
dass die Transportvorrichtung den Kabelbinder von der Kabelbinderladestartposition
zu einer Kabelbinderspannposition überführt, während sich die erste Welle in der zweiten
Richtung dreht;
gekennzeichnet durch
einen zweiten Motor (74), der eine Drehbewegung auf eine zweite Welle separat in der
ersten Richtung und der zweiten Richtung aufbringt;
eine Kabelbinderführung (66), die mit dem zweiten Motor derart wirkverbunden ist,
dass die Kabelbinderführung den sich bewegenden Kabelbinder lenkt, während sich die
zweite Welle in einer Richtung dreht, die einer der ersten Richtung oder der zweiten
Richtung entspricht; und eine Kabelbinderspannvorrichtung, die mit dem zweiten Motor
derart wirkverbunden ist, dass die Kabelbinderspannvorrichtung eine Umfangslänge des
Kabelbinders verringert, während sich die zweite Welle in einer entgegengesetzten
Richtung zu der Richtung dreht, die einer der ersten Richtung oder der zweiten Richtung
entspricht.
2. Automatische Kabelbindervorrichtung (10) nach Anspruch 1, ferner umfassend:
eine erste Kupplung (65), die sich zwischen dem ersten Motor (55) und dem Kabelbinderzuführmechanismus
(52) befindet, wobei die erste Kupplung einen eingerückten Zustand, in dem eine Drehbewegung
durch die erste Welle in der ersten Richtung eine Bewegung durch den Kabelbinderzuführmechanismus
(52) antreibt, und einen ausgerückten Zustand, in dem eine Drehbewegung durch die
erste Welle in der zweiten Richtung bewirkt, dass die erste Welle in Relation zu dem
Kabelbinderzuführmechanismus (52) freiläuft, wobei eine solche Drehbewegung durch
die erste Welle in der zweiten Richtung keine Bewegung auf den Kabelbinderzuführmechanismus
aufbringt, aufweist.
3. Automatische Kabelbindervorrichtung (10) nach Anspruch 2, ferner umfassend:
eine zweite Kupplung (65), die sich zwischen dem ersten Motor (55) und der Transportvorrichtung
(60) befindet, wobei die zweite Kupplung einen eingerückten Zustand, in dem eine Drehbewegung
durch die erste Welle in der zweiten Richtung eine Bewegung durch die Transportvorrichtung
(60) antreibt, und einen ausgerückten Zustand, in dem eine Drehbewegung durch die
erste Welle in der ersten Richtung bewirkt, dass die erste Welle in Relation zu der
Transportvorrichtung (60) freiläuft, wobei eine solche Drehbewegung durch die erste
Welle in der ersten Richtung keine Bewegung auf die Transportvorrichtung aufbringt,
aufweist.
4. Automatische Kabelbindervorrichtung (10) nach Anspruch 3, wobei der Kabelbinderzuführmechanismus
(52) eine Zahnradanordnung umfasst, die mit dem ersten Motor wirkverbunden ist, wobei
ein erstes Zahnrad in der Zahnradanordnung eine Mehrzahl von abgeschrägten Zähnen
aufweist, die dazu ausgelegt sind, einen Kabelbinderträger reibschlüssig in Eingriff
zu nehmen, um eine Bewegung auf den Kabelbinderträger bei Drehung der ersten Welle
in der ersten Richtung aufzubringen, um den Kabelbinder zu der Kabelbinderladestartposition
zu liefern.
5. Automatische Kabelbindervorrichtung (10) nach Anspruch 4, wobei die Transportvorrichtung
(60) eine Zahnradanordnung umfasst, die mit dem ersten Motor wirkverbunden ist, wobei
ein erstes Zahnrad eine Bewegung auf die Transportvorrichtung (60) aufbringt, um den
Kabelbinder von der Kabelbinderladestartposition zu der Kabelbinderspannposition zu
befördern.
6. Automatische Kabelbindervorrichtung (10) nach Anspruch 1, wobei die Transportvorrichtung
(60) eine Schnecke (62) umfasst, die einen spiralförmigen Kanal aufweist, in dem ein
Kabelbinderkopf (34) gehalten ist, um eine lineare Bewegung des Kabelbinders (14)
von der Kabelbinderladestartposition zu der Kabelbinderspannposition aufzubringen.
7. Automatische Kabelbindervorrichtung (10) nach Anspruch 6, wobei die Schnecke (62)
den Kabelbinder nach vorn um eine Kabelbinderstützvorrichtung (66) aus vorderen und
hinteren Backen (68, 70) in eine ringförmige Form um das Kabelbündel drückt.
8. Automatische Kabelbindervorrichtung (10) nach Anspruch 1, ferner umfassend:
eine dritte Kupplung, die sich zwischen dem zweiten Motor (74) und der Kabelbinderführung
(66) befindet, wobei die dritte Kupplung einen eingerückten Zustand, in dem eine Drehbewegung
durch die zweite Welle in der Richtung, die einer der ersten Richtung oder der zweiten
Richtung entspricht, eine Bewegung durch die Kabelbinderführung (66) antreibt, und
einen ausgerückten Zustand, in dem eine Drehbewegung durch die zweite Welle in der
entgegengesetzten Richtung zu der Richtung, die einer der ersten Richtung oder der
zweiten Richtung entspricht, bewirkt, dass die zweite Welle in Relation zu der Kabelbinderführung
(66) freiläuft, wobei eine solche Drehbewegung durch die zweite Welle in der entgegengesetzten
Richtung zu der Richtung, die einer der ersten Richtung oder der zweiten Richtung
entspricht, keine Bewegung auf die Kabelbinderführung (66) aufbringt, aufweist.
9. Automatische Kabelbindervorrichtung (10) nach Anspruch 8, ferner umfassend:
eine vierte Kupplung, die sich zwischen dem zweiten Motor (74) und der Kabelbinderspannvorrichtung
befindet, wobei die vierte Kupplung einen eingerückten Zustand, in dem eine Drehbewegung
durch die zweite Welle in der entgegengesetzten Richtung zu der Richtung, die einer
der ersten Richtung oder der zweiten Richtung entspricht, eine Bewegung durch die
Kabelbinderspannvorrichtung antreibt, und einen ausgerückten Zustand, in dem eine
Drehbewegung durch die zweite Welle in der Richtung, die einer der ersten Richtung
oder der zweiten Richtung entspricht, bewirkt, dass die zweite Welle in Relation zu
der Kabelbinderspannvorrichtung freiläuft, wobei eine solche Drehbewegung durch die
zweite Welle in der Richtung, die einer der ersten Richtung oder der zweiten Richtung
entspricht, keine Bewegung auf die Kabelbinderspannvorrichtung aufbringt, aufweist.
10. Automatische Kabelbindervorrichtung (10) nach Anspruch 9, wobei die Kabelbinderführung
(66) eine Stützwand (98) umfasst, die mit dem zweiten Motor (74) derart wirkverbunden
ist, dass die Stützwand sich in Reaktion darauf nach oben bewegt, dass sich die zweite
Welle in der Richtung dreht, die einer der ersten Richtung oder der zweiten Richtung
entspricht.
11. Automatische Kabelbindervorrichtung (10) nach Anspruch 10, wobei sich die Stützwand
(98) aufwärts zu einer Position bewegt, die an die Transportvorrichtung (60) angrenzt,
um den Kabelbinder (14) zu stützen, während sich der Kabelbinder (14) von der Kabelbinderladestartposition
zu der Kabelbinderspannposition bewegt.
12. Automatische Kabelbindervorrichtung (10) nach Anspruch 10, wobei die Aufwärtsbewegung
der Stützwand (98) die hintere Backe (70) betätigt, sodass sich die hintere Backe
(70) um das Kabelbündel schließt.
13. Automatische Kabelbindervorrichtung (10) nach Anspruch 10, wobei die Aufwärtsbewegung
der Stützwand (98) den Kabelbinder (14) von einem Trägerstreifen abschneidet und den
Kabelbinder (14) in die Kabelbinderladestartposition zieht.
1. Appareil d'attache de câble automatique (10) pour serrer et attacher une attache de
câble (14) autour d'un faisceau de câbles, comprenant :
un premier moteur (55) transmettant un mouvement de rotation à un premier arbre séparément
dans une première direction et une seconde direction dans lequel les première et seconde
directions sont l'une d'une direction horaire et antihoraire, respectivement ;
un mécanisme de libération d'attache de câble (52) joint de manière opérationnelle
au premier moteur de telle sorte que le mécanisme de libération d'attache de câble
transfère une attache de câble à une position de démarrage de chargement d'attache
de câble lorsque le premier arbre tourne dans la première direction ; et
un dispositif de transport (60) joint de manière opérationnelle au premier moteur
de telle sorte que le dispositif de transport transfère l'attache de câble de la position
de démarrage de chargement d'attache de câble vers une position de mise sous tension
d'attache de câble lorsque le premier arbre tourne dans la seconde direction ; caractérisé par
un second moteur (74) transmettant un mouvement de rotation à un second arbre séparément
dans la première direction et la seconde direction ;
un guide d'attache de câble (66) joint de manière opérationnelle au second moteur
de telle sorte que le guide d'attache de câble dirige l'attache de câble en mouvement
lorsque le second arbre tourne dans une direction correspondant à l'une de la première
direction ou de la seconde direction ; et
un tendeur d'attache de câble joint de manière opérationnelle au second moteur de
telle sorte que le tendeur d'attache de câble diminue une longueur circonférentielle
de l'attache de câble lorsque le second arbre tourne dans une direction opposée à
ladite direction correspondant à l'une de la première direction ou de la seconde direction.
2. Appareil d'attache de câble automatique (10) selon la revendication 1 comprenant en
outre :
un premier embrayage (65) situé entre le premier moteur (55) et le mécanisme de libération
d'attache de câble (52), le premier embrayage ayant un état de mise en prise dans
lequel un mouvement de rotation par le premier arbre dans la première direction entraîne
un mouvement par le mécanisme de libération d'attache de câble (52) et un état de
désaccouplement dans lequel un mouvement de rotation par le premier arbre dans la
seconde direction amène le premier arbre à être en roue libre par rapport au mécanisme
de libération d'attache de câble (52) dans lequel un tel mouvement de rotation par
le premier arbre dans la seconde direction ne transmet pas de mouvement au mécanisme
de libération d'attache de câble.
3. Appareil d'attache de câble automatique (10) selon la revendication 2 comprenant en
outre :
un second embrayage (65) situé entre le premier moteur (55) et le dispositif de transport
(60), le second embrayage ayant un état de mise en prise dans lequel un mouvement
de rotation par le premier arbre dans la seconde direction entraîne un mouvement par
le dispositif de transport (60) et un état de désaccouplement dans lequel un mouvement
de rotation par le premier arbre dans la première direction amène le premier arbre
à être en roue libre par rapport au dispositif de transport (60) dans lequel un tel
mouvement de rotation par le premier arbre dans la première direction ne transmet
pas de mouvement au dispositif de transport.
4. Appareil d'attache de câble automatique (10) selon la revendication 3 dans lequel
le mécanisme de libération d'attache de câble (52) comprend un ensemble d'engrenages
joint de manière opérationnelle au premier moteur dans lequel un premier engrenage
dans l'ensemble d'engrenages inclut une pluralité de dents chanfreinées configurées
pour mettre en prise par friction un support d'attache de câble pour transmettre un
mouvement au support d'attache de câble lors de la rotation du premier arbre dans
la première direction pour libérer l'attache de câble dans la position de démarrage
de chargement d'attache de câble.
5. Appareil d'attache de câble automatique (10) selon la revendication 4 dans lequel
le dispositif de transport (60) comprend un ensemble d'engrenages joint de manière
opérationnelle au premier moteur dans lequel un premier engrenage transmet un mouvement
au dispositif de transport (60) pour transporter l'attache de câble de la position
de démarrage de chargement d'attache de câble à la position de mise sous tension d'attache
de câble.
6. Appareil d'attache de câble automatique (10) selon la revendication 1 dans lequel
le dispositif de transport (60) comprend une vis sans fin (62) ayant un canal hélicoïdal
dans lequel une tête d'attache de câble (34) est maintenue pour transmettre un mouvement
linéaire de l'attache de câble (14) de la position de démarrage de chargement d'attache
de câble à la position de mise sous tension d'attache de câble.
7. Appareil d'attache de câble automatique (10) selon la revendication 6, dans lequel
la vis sans fin (62) pousse l'attache de câble vers l'avant autour d'un dispositif
de support d'attache de câble (66) de mâchoires avant et arrière (68, 70) dans une
forme annulaire autour du faisceau de câbles.
8. Appareil d'attache de câble automatique (10) selon la revendication 1 comprenant en
outre :
un troisième embrayage situé entre le second moteur (74) et le guide d'attache de
câble (66), le troisième embrayage ayant un état de mise en prise dans lequel un mouvement
de rotation par le second arbre dans la direction correspondant à l'une de la première
direction ou de la seconde direction entraîne un mouvement par le guide d'attache
de câble (66) et un état de désaccouplement dans lequel un mouvement de rotation par
le second arbre dans la direction opposée à la direction correspondant à l'une de
la première direction ou de la seconde direction amène le second arbre à être en roue
libre par rapport au guide d'attache de câble (66) dans lequel un tel mouvement de
rotation par le second arbre dans la direction opposée à la direction correspondant
à l'une de la première direction ou de la seconde direction ne transmet pas de mouvement
au guide d'attache de câble (66).
9. Appareil d'attache de câble automatique (10) selon la revendication 8 comprenant en
outre :
un quatrième embrayage situé entre le second moteur (74) et le tendeur d'attache de
câble, le quatrième embrayage ayant un état de mise en prise dans lequel un mouvement
de rotation par le second arbre dans la direction opposée à la direction correspondant
à l'une de la première direction ou de la seconde direction entraîne un mouvement
par le tendeur d'attache de câble et un état de désaccouplement dans lequel un mouvement
de rotation par le second arbre dans la direction correspondant à l'une de la première
direction ou de la seconde direction amène le second arbre à être en roue libre par
rapport au tendeur d'attache de câble dans lequel un tel mouvement de rotation par
le second arbre dans la direction correspondant à l'une de la première direction ou
de la seconde direction ne transmet pas de mouvement au tendeur d'attache de câble.
10. Appareil d'attache de câble automatique (10) selon la revendication 9 dans lequel
le guide d'attache de câble (66) comprend une paroi de support (98) jointe de manière
opérationnelle au second moteur (74) de telle sorte que la paroi de support se déplace
vers le haut en réponse à la rotation du second arbre dans la direction correspondant
à l'une de la première direction ou de la seconde direction.
11. Appareil d'attache de câble automatique (10) selon la revendication 10 dans lequel
la paroi de support (98) se déplace vers le haut vers une position adjacente au dispositif
de transport (60) pour supporter l'attache de câble (14) lorsque l'attache de câble
(14) se déplace de la position de démarrage de chargement d'attache de câble vers
la position de mise sous tension d'attache de câble.
12. Appareil d'attache de câble automatique (10) selon la revendication 10 dans lequel
un mouvement vers le haut de la paroi de support (98) actionne la mâchoire arrière
(70) en fermant la mâchoire arrière (70) autour du faisceau de câbles.
13. Appareil d'attache de câble automatique (10) selon la revendication 10 dans lequel
un mouvement vers le haut de la paroi de support (98) découpe l'attache de câble (14)
d'une bande de support et tire l'attache de câble (14) dans la position de démarrage
de chargement d'attache de câble.