Track mechansim for guiding flexible straps around bundles of objects

TECHNICAL FIELD

This invention relates to apparatus and methods for applying flexible straps around bundles of objects.

BACKGROUND OF THE INVENTION

Many high-speed, automatic strapping machines have been developed, such as those disclosed in U.S. Pat. Nos. 3,735,555; 3,884,139; 4,120,239; 4,312,266; 4,196,663; 4,201,127; 3,447,448; 4,387,631; 4,473,005; 4,724,659, 5,379,576, 5,414,980, 5,613,432, and 5,809,873. As disclosed by the devices in these patents, a conveyor belt typically conveys a bundle at high speed to a strapping station where straps are automatically applied before the conveyor belt moves the strapped bundle away from the device.

Typical strapping machines employ an initial or primary tensioning apparatus that provides an initial tensioning of the strap about the bundle. A secondary tensioning apparatus thereafter provides increased or enhanced tension of the strap. A sealing head then seals the strap, typically through the use of a heated knife mechanism, to complete the bundling operation.

FIG. 1

is a strapping machine

100

in accordance with the prior art, as shown and described in U.S. Pat. No. 5,414,980, issued to Shibazaki et al. The strapping machine

100

includes the following major components, all mounted to a housing or frame

110

: a strap dispenser

112

, an accumulator

114

, a feed and tension unit

116

, a track

118

, a sealing head

122

, and a control system

124

. In addition, some devices also have a secondary tension unit

120

(not shown), such as the type disclosed in U.S. Pat. No. 3,552,305 issued to Dorney et al. The basic operation of the machine involves a feeding cycle and a strapping cycle. In the feeding cycle, strap is pulled from a strap coil mounted on the dispenser

112

by a feed and tension motor and is fed through the accumulator

114

, the feed and tension unit

116

, the sealing head

122

, and the track

118

. After the strap has been fed around the track

118

and back into the sealing head

122

, the strapping cycle begins.

During the strapping cycle, the strapping machine performs several functions. First, the sealing head

122

of the strapping machine grips the free end of the strap, holding it securely. Next, in a primary tensioning sequence, a track guide mechanically opens and the strap is pulled from the track

118

as the strap is drawn around the bundle by a feed and tension motor.

As the primary tensioning sequence is completed, additional strap tension may be applied by the secondary tension unit

120

. As this secondary tensioning process is completed, the sealing head

122

grips the supply side of the strap. The overlapping strap sections are then heated by a heater blade, pressed together by a press platen, and severed from the supply by a strap cutter

140

.

Following the sealing process, the strap path through the sealing head

122

is once again aligned and the feeding sequence can begin. The sealing head

122

continues to rotate allowing the seal to cool while the feeding sequence continues. At the end of the strapping cycle, the sealed strap is released and the strapping machine

100

is ready to repeat the feeding cycle.

Although desirable results are achievable using the prior art strapping machines

100

, some operational drawbacks exist. For example, the prior art feed and tension unit

116

typically includes a complicated series of strap guides. The strap must be fed through the strap guides, undergoing several bends and turns between the dispenser

112

and the sealing head

122

. Existing strapping machines typically turn the strap through a total of

360

degrees or more before reaching the track. The bends and turns in the strap path may induce kinks in the strap that may subsequently lead to feeding difficulties. If the strap becomes jammed in the feed and tension unit

116

, the process of clearing the strap path from the complicated series of strap guides may be time-consuming and may require machine downtime.

Another disadvantage of the prior art strapping machines is that the drive assemblies of the sealing head

122

and the feed and tension unit

120

are typically complicated designs featuring a one or more gear boxes. Often these gear boxes are complicated and must transfer the drive forces through a 90 degree angle. Generally, the cost of fabricating the drive assembly increases with the design complexity, adding to the ultimate cost of the strapping machine.

SUMMARY OF THE INVENTION

The present invention improves upon prior strapping devices, and provides additional benefits, such as by providing variability in the apparatus that can be easily altered to fit various production and package requirements and by employing a control system that monitors operating signals and transmits control signals accordingly.

A feed and tension unit under one aspect of the invention includes three sets of wheels: (1) a feeding set including a feed drive roller and a feed pinch roller, (2) a primary tensioning set including a primary tension drive roller and a primary tension pinch roller, and (3) a secondary tensioning set including a secondary tension drive roller and a secondary tension pinch roller, and wherein at least one of the feed pinch roller, the primary tension pinch roller, or the secondary tension pinch roller is coupled to a solenoid that controllably biases the pinch roller against the respective drive roller based on a pinch signal supplied to the solenoid, the pinch signal having a first pulse width modulated stage that provides a full pinch force and a second pulse width modulated stage that provides a reduced pinch force.

During a primary tensioning operation, a control system monitors position signals from a feed pinch roller position sensor and terminates primary tensioning when a slippage condition is determined. The control system then initiates a secondary tensioning operation. The secondary tensioning operation lasts for a predetermined amount of time, then the control system initiates a joining operation that secures the strap around the bundle.

In another aspect of the invention, the three sets of wheels or rollers of the feed and tension unit are configured to provide a simplified strap path that reduces bending of the strap, thereby reducing friction and consequent feeding difficulties. Alternately, the drive wheels of the feed and tension unit may be positioned on the side of the strap opposite from the bundle to reduce adverse effects of debris from the bundle. In another aspect, the feed and tension unit includes inner and outer guides that form a strap channel through the feed and tension unit. The inner and outer guides are configured to provide easy access to the strap path for clearing the strap path in the event of a jam.

In a further aspect of the invention, a strap material accumulating compartment includes a first sidewall having a plurality of mounting posts projecting therefrom, each mounting post having a plurality of mounting holes disposed therethrough, a second sidewall having a plurality of mounting apertures alignable with and slideably engageable with, the mounting posts, and a plurality of pin holders positioned proximate the mounting apertures, and a plurality of mounting pins removably and adjustably engageable with the mounting holes and the pin holders. The first and second sidewalls approximately form a chamber therebetween wherein the strap may accumulate. The width of the chamber may be adjusted easily and quickly to accommodate varying widths of strap by removal of the retaining pins, repositioning the second sidewall at the desired location, and replacement of the retaining pins within the desired holes.

In yet another aspect of the invention, the track assembly includes a plurality of sections providing modularity of construction. Each section includes a backplate attached to at least one support member, and a slotted cover pivotably attached to the at least one support member proximate the backplate and moveable between an open position spaced apart from the backplate and a closed position proximate the backplate, and a biasing member engaged with the slotted cover that exerts a biasing force on the slotted cover to urge the slotted cover toward the closed position. The biasing force is small enough that a tensioning force in the strap material may overcome the biasing force and thereby actuate the slotted cover toward the open position to allow the strap material to escape from the guide passage during a tension cycle. During a feed cycle, the strap material exerts a closing force on an outer surface of the slotted cover, urging the slotted cover into the closed position. In another aspect, the slotted covers are pivotably mounted on guide pins that are approximately parallel to the path of the strap material within the guide passage.

In another aspect, a cutting assembly for severing strap material includes a press platen and a cutter having a first cutting blade along a first edge thereof and a second cutting blade along a second edge thereof, the cutter being removably and variably engaged to the press platen such that at least one of the first or second cutting blades is engageable with the strap material. In another aspect, at least one of the first and second edges is slanted at a slant angle with respect to an adjacent edge of the cutter.

These and other benefits of the present invention will become apparent to those skilled in the art based on the following detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

is a front elevational view and partial fragmentary view of a strapping machine under the prior art.

FIG. 2

is an isometric view of a strapping machine in accordance with an embodiment of the invention.

FIG. 3

is an isometric view of a sealing head in accordance with an embodiment of the invention.

FIG. 4

is a top elevational view of the sealing head of FIG.

3

.

FIG. 5

is a back elevational view of the sealing head of FIG.

3

.

FIG. 6

is an isometric view of a press platen and a cutter of the sealing head of FIG.

3

.

FIG. 7

is an isometric view of a main drive assembly in accordance with an embodiment of the invention.

FIG. 8

is a top elevational view of the main drive assembly of FIG.

7

.

FIG. 9

is a side elevational view of the main drive the assembly of FIG.

7

.

FIG. 10

is a first isometric view of a feed and tension unit in accordance with an embodiment of the invention.

FIG. 11

is a second isometric view of the feed and tension unit of FIG.

10

.

FIG. 12

is a partial front elevational view of a strap path of the feed and tension unit of FIG.

10

.

FIG. 13

is a partial isometric view of a primary pinch wheel and a proximity switch of the feed and tension unit of FIG.

10

.

FIG. 14

is an exploded isometric view of an accumulator in accordance with an embodiment of the invention.

FIG. 15

is a front elevational view of the accumulator of FIG.

14

.

FIG. 16

is a top elevational view of the accumulator of FIG.

14

.

FIG. 17

is an isometric view of a dispenser in accordance with an embodiment of the invention.

FIG. 18

is a top elevational view of the dispenser of FIG.

17

.

FIG. 19

is an isometric view of a track in accordance with an embodiment of the invention.

FIG. 20

is a partial sectional view of a straight section of the track of

FIG. 19

taken along line

20

—

20

.

FIG. 21

is an isometric view of a corner section of the track of FIG.

19

.

FIG. 22

is an exploded isometric view of the press platen and cutter of FIG.

6

.

FIG. 23

is an enlarged partially-exploded isometric view of a pair of inner and outer strap guides of the feed and tension unit of FIG.

10

.

FIG. 23A

is a cross-sectional view of the inner and outer guides of

FIG. 23

to illustrate the guide slot created by the inner and outer guides.

FIG. 24

is a cross-sectional view of the accumulator of

FIG. 15

taken along line

24

—

24

.

FIG. 25

is a partially exploded isometric view of a straight section of the track of FIG.

19

.

In the drawings, identical reference numbers identify identical or substantially similar elements or steps.

DETAILED DESCRIPTION OF THE INVENTION

The present disclosure is directed toward apparatus and methods for strapping bundles of objects. Specific details of certain embodiments of the invention are set forth in the following description, and in

FIGS. 2-25

, to provide a thorough understanding of such embodiments. A person of ordinary skill in the art, however, will understand that the present invention may have additional embodiments, and that the invention may be practiced without several of the details described in the following description.

FIG. 2

is an isometric view of a strapping machine

200

in accordance with an embodiment of the invention. The strapping machine

200

includes seven major subassemblies: a frame

210

, a control system

220

, a dispenser

250

, an accumulator

300

, a feed and tension unit

350

, a sealing head

400

, a drive assembly

500

, and a track

450

. The subassemblies are of modular construction, which allows them to be used in multiple frame configurations.

Throughout the following discussion and in the accompanying figures, the strap material is shown and referred to as a particular type of material, namely, a flat, two-sided, tape-shaped strip of material. This practice is adopted herein solely for the purpose of simplifying the description of the inventive methods and apparatus. It should be understood, however, that several of the methods and apparatus disclosed herein may be equally applicable to various types of strap material, and not just to the flat, two-sided, tape-shaped material shown in the figures. Thus, as used herein, the terms “strap” and “strap material” should be understood to include all types of materials used to bundle objects.

The overall operation of the strapping machine

200

will first be described with reference to various figures, and thereafter, the individual components will be described in detail. In brief, the operation of the strapping machine

200

involves paying off strap

202

from a strap coil

204

located on the dispenser

250

(FIGS.

17

-

18

), and feeding a free end

206

of the strap

202

through the accumulator

300

(FIGS.

14

-

16

), the feed and tension unit

350

(FIGS.

10

-

13

), the sealing head

400

(FIGS.

3

-

5

), and around the track

450

(FIGS.

19

-

20

). After the strap

202

is fed around the track

450

, the free end

206

is fed back into the sealing head

400

. At this point the strap

202

is in position to start a strapping cycle.

Upon the start of the strapping cycle, several sealing head cams

402

in the sealing head

400

(

FIGS. 3-5

) begin to rotate, forcing a left-hand gripper

404

to pinch the free end

206

of the strap

202

against an anvil

406

. After gripping the strap

202

in the sealing head

400

, the feed and tension unit

350

(

FIGS. 10-13

) retracts the strap

202

from the track

450

. As the strap

202

is pulled from the track

450

, the strap

202

is tensioned around a bundle of objects (not shown) located in a strapping station

208

(

FIG. 2

) by a feed and tension motor

361

(FIG.

10

). As the strap

202

becomes tight around the bundle, a primary tension pinch wheel

352

(

FIG. 10

) stops rotating. A proximity sensor

354

(

FIG. 11

) detects the lack of rotation of the primary tension pinch wheel

352

(

FIG. 12

) and starts a secondary tension process.

Preferably, the cams

402

operate as cycloidal cams allowing the sealing head

400

to operate smoothly at increased speeds and the cam follower pressure angles are minimized to extend cam life. As used herein, the term cycloidal cam means a cam with cycloidal displacement generated by taking a sinusoidal acceleration function that has a magnitude of zero at its beginning and end, and integrating the function to obtain the velocity and displacement of the follower.

Secondary tension is applied until a drive wheel clutch

356

(

FIGS. 7-8

) slips, at a predetermined set-point, and the sealing head

400

rotates far enough to grip the strap

202

with a right-hand gripper

408

. After the strap

202

is gripped by the right-hand gripper

408

, the tension on the free end

206

of the strap

202

is released and the strap

202

around the bundle is cut free from the coil

204

by a cutter

414

(FIGS.

3

and

6

). The two overlapping ends of the strap

202

are then heated by inserting a heater blade

410

(

FIG. 3

) between them and lightly pressing the straps against the blade

410

with a press platen

412

(FIG.

3

). The press platen

412

then lowers slightly and the heater blade

410

is removed from between the strap ends. Next, the press platen

412

presses both ends against the anvil

406

(

FIG. 3

) for bonding and cooling. As the sealing head cams

402

continue to rotate, the press platen

412

lowers slightly allowing the anvil

406

to open and release the sealed strap. After the strap is released, the anvil

406

is closed and the strapping cycle is completed by feeding strap

202

through the sealing head

400

, around the track

450

, back into the sealing head

400

and finally actuating a feed stop switch

416

(FIG.

3

).

Two modes of operation are available: manual and automatic. The manual mode applies single or multiple straps while an operator actuates a switch. The automatic mode applies a single strap or multiple straps when a switch is actuated by a moving bundle. The automatic mode is used in conveyor lines and in conjunction with other automated machinery.

As shown in

FIG. 2

, the frame

210

consists of a main support

212

, adjustable legs

214

, and cover plates

216

. The frame

210

provides structural support for all of the other sub-assemblies of the strapping machine

200

. In this view, the strap

202

is fed about the track

450

in a strap-feed direction

209

that is generally counter-clockwise.

The strapping machine

200

is controlled by a control system

220

that may include a programmable logic controller

222

(

FIG. 3

) that operates in conjunction with various input and output devices and controls the major subassemblies of the strapping machine

200

. Input devices may include, for example, momentary and maintained push buttons, selector switches, toggle switches, limit switches and inductive proximity sensors. Output devices may include, for example, solid state and general purpose relays, solenoids, and indicator lights. Input devices are scanned by the controller

222

, and their on/off states are updated in a controller program

224

. The controller

222

executes the controller program

224

and updates the status of the output devices accordingly. Other control functions of the controller

222

are described below in further detail.

In one embodiment, the programmable controller

222

and its associated input and output devices may be powered using a 24 VDC power supply. The controller

222

, power supply, relays, and fuses may be contained within a control panel (not shown). The momentary and maintained push buttons, selector switches, and toggle switches may be located on a control pendant or a control panel cover. The limit switches, inductive proximity sensors, and solenoids are typically located within the strapping machine

200

at their point of use. At least one indicator light may be mounted on the top of the track

450

and may light steadily to indicate an out-of-strap condition, and may flash to indicate a strap misfeed condition.

One commercially-available programmable controller

222

suitable for use with the strapping machine

200

is the T100MD1616+PLC manufactured by Triangle Research International Pte Ltd in Singapore. This device includes sixteen NPN-type digital outputs, four of which are NPN Darlington Power Transistor types and twelve of which are N-channel power MOSFET types. Two of the outputs are capable of generating a Pulse Width Modulated (PWM) signal with a frequency and duty cycle determined in the programming software. Also included are four input channels of 10-bit analog-to-digital converters. Two of the input channels are buffered by operational amplifiers with a x5 gain accepting analog signals of 0-1V full scale. The remaining two channels are unbuffered and accept 0-5V full scale analog signals. The unit includes a stable 5V (+/−1% accuracy) regulated DC power supply to be used as a voltage reference for the analog inputs. A single channel 8-bit digital-to-analog output utilizing a 0-20 mA current loop signal, also resides on the PLC.

The T100MD1616+PLC has communication ports, including an RS232C port for program uploads, downloads and monitoring, a two-wire RS485 network port, a 14-pin LCD display port for possible future use as a diagnostic display driver, and a port for expansion. The PLC itself is controlled by a custom CPU that has both EEPROM and RAM memory backup. The controller program

224

used to program the controller

222

may, for example, include Trilogi programming software available from Triangle Research International Pte Ltd, and may include both ladder logic and Basic type code (described more fully at tri.com.sg/index.htm).

FIG. 3

is an isometric view of the sealing head

400

of the strapping machine

200

of FIG.

2

.

FIGS. 4 and 5

are top elevational and back elevational views, respectively, of the sealing head

400

of FIG.

3

.

FIG. 6

is an isometric view of the press platen

412

and the cutter

414

of the sealing head

400

of FIG.

3

. The sealing head

400

comprises a motor-driven main shaft

418

and a series of cams

402

which perform gripping, sealing and cutting functions. These cams

402

drive three sliding members

422

and three rotating arms

424

(FIG.

5

). One slide member

422

is coupled to the right-hand gripper

408

, another slide member

422

is coupled to the left-hand gripper

404

, and the third slide member

422

is coupled to the press platen

412

. The sliding members

422

perform the gripping, sealing and cutting functions, while the pivoting arms

424

move an inner slide

420

, the anvil

406

, and the heater blade

410

into and out of a strap path as required during a strapping cycle.

FIG. 22

is an exploded isometric view of the press platen

412

and cutter

414

of FIG.

6

. As shown in this view, the press platen

412

includes a pair of mounting nubs

411

, and the cutter

414

includes mounting recesses

413

. A spring

415

is disposed between the cutter

414

and the press platen

412

, one end of the spring

415

being partially disposed within a seating hole

417

disposed in the press platen

412

. The cutter

414

has cutting edges

419

at both ends, allowing the cutter

414

to be reversibly positioned on the press platen

412

for added operational life. In the embodiment shown in

FIG. 22

, the cutting edges

419

are slanted at an angle α. Although a wide variety of cutting edge angles α may be used, a cutting edge angle in the range of approximately 9 degrees or less is preferred.

During assembly, the spring

415

is compressed between the cutter

414

and the press platen

412

until the two mounting recesses

413

slideably engage two of the mounting nubs

411

. One may note that the cutter

414

has a pair of mounting recesses

413

situated near each end of the cutter

414

which allows the cutter

414

to be reversibly mounted onto the press platen

412

. The cutter

414

and the press platen

412

are then positioned securely between the left and right-hand grippers

404

,

408

with the pressure from these parts maintaining the compression of the spring

415

. The cutter

414

and press platen

412

are then engaged with the third slide member

422

. This arrangement provides the necessary scissors action to sever the strap

202

.

An advantage of the cutter

414

and press platen

412

assembly shown in

FIGS. 6 and 22

is that the cutter

414

is removably and replaceably mounted to the press platen

412

by slideably engaging onto the press platen

412

. This allows the cutter

414

to be more easily removed for replacement or maintenance than in the prior art devices. The reversibility of the cutter

414

also essentially doubles the useful life of the component.

FIG. 7

is an isometric view of a main drive assembly

500

in accordance with an embodiment of the invention.

FIGS. 8 and 9

are top and side elevational views, respectively, of the main drive assembly

500

of FIG.

7

. The main drive assembly

500

includes a main drive motor

502

that drives a sealing head drive belt

508

and a drive wheel belt

510

. The sealing head drive belt

508

and the drive wheel belt

510

are preferably “toothed” belts. The sealing head drive belt

508

is directly coupled to a spring clutch

504

. The drive wheel belt

510

is turned approximately 90 degrees on a pair of drive pulleys

512

and is coupled to the drive wheel clutch

356

. As shown in

FIG. 7

, the main drive motor

502

, the spring clutch

504

, and the drive wheel clutch

356

are operatively coupled to the controller

222

, such as, for example, by electrically conductive leads

223

.

One advantage of the main drive assembly

500

is that the drive wheel clutch

356

is driven by the drive wheel belt

510

, which is turned at an approximately 90 degree angle on the drive pulleys

512

. This arrangement, commonly referred to as a “mule drive,” eliminates a 90-degree gearbox commonly found in drive systems of prior art strapping machines. Thus, the complexity and costs of fabrication of the main drive assembly

500

are reduced, and reliability and maintainability is improved.

In the embodiments shown in the accompanying figures, the spring clutch

504

is a wrap spring clutch and the drive wheel clutch

356

is an electromagnetic clutch. Alternately, other spring clutch

504

and drive wheel clutch

356

embodiments may be used. The spring clutch

504

stops the sealing head cams

402

at the proper degree of rotation during each stage of the cycle and stops the cams

402

in their home position at the end of each cycle. As stated above, the drive wheel clutch

356

slips at a torque that is determined by the voltage supplied to a coil located within the electromagnetic drive wheel clutch

356

. The slip in the drive wheel clutch

356

determines the amount of secondary tension that is applied to the strap

202

.

The main drive motor

502

drives the sealing head

400

by means of the sealing head drive belt

508

and the spring clutch

504

(

FIGS. 7 and 8

) which is mounted over an end of the sealing head main shaft

418

(FIG.

3

). Rotation of the main shaft

418

causes the keyed cams

402

(

FIGS. 3 and 5

) to rotate and perform the necessary gripping, sealing and cutting functions. During a first period of rotation, the main shaft

418

rotates to the first of three stops on the spring clutch

504

, causing a cutter-gripper assembly

426

to grip the strap

202

and the inner slide

420

to move out of the strap path. The main drive motor

502

then tensions the strap about the bundle, as will be described more fully below. When the strap tensioning is complete, the controller

222

pulses the spring clutch

504

allowing the cams

402

to rotate in a second period of rotation.

During the second period of rotation the right-hand gripper

404

grips the tensioned strap just ahead of the feed stop switch

416

and the tension in the strap is then released. After the tension is released, the platen

412

and the cutter

414

(

FIGS. 6 and 22

) rise to cut the strap

202

and press the strap against the heater blade

410

. The cams

402

continue to rotate through a dwell section as the strap

202

melts on the heater blade

410

. After a predetermined time for melting has passed, the press platen

412

and the cutter

414

retract slightly allowing the heater blade

410

to retract.

After the heater blade

410

retracts, the press platen

412

rises again to press the two melted ends of the strap

202

together for cooling and sealing. The sealing head main shaft

418

continues to rotate during a third period of rotation until a clutch trigger

428

disengages the spring clutch

504

. The sealing head

400

maintains this position for a predetermined time until the controller

222

again energizes a spring clutch solenoid

506

(not shown) located within the spring clutch

504

. The continued rotation of the cams

402

releases the press platen

412

and drops the left and right-hand grippers

404

,

408

to their one positions. One of the cams

402

then pivots the anvil

406

out of the strap line past a air of strippers

430

. As the anvil

406

pivots, the strippers

430

push the strap off of the anvil

406

. After the strap

202

is out of the sealing head

400

, the anvil

406

closes, and the cams

402

reach their home positions. At the home position the spring clutch

504

reaches the third and final stop as the feed stop switch

416

(

FIG. 3

) signals the controller

222

to begin another feed sequence.

FIG. 10

is a first isometric view of the feed and tension unit

350

in accordance with an embodiment of the invention.

FIGS. 11 and 12

are a second isometric view and a partial front elevational view, respectively, of the feed and tension unit

350

of FIG.

10

. As best seen in

FIG. 12

, there are three sets of wheels in the feed and tension unit

350

: (1) a primary tensioning set including a primary tension drive wheel

360

and a primary tension pinch wheel

352

, (2) a secondary tensioning set including a secondary tension drive wheel

362

and a secondary tension pinch wheel

364

, and (3) a feeding set including a feed drive wheel

366

and a feed pinch wheel

368

.

The feed and tension unit

350

pinches the strap

202

between each of the three sets of drive wheels and pinch wheels. The feed, primary tension, and secondary tension pinch wheels

366

,

360

,

362

are engaged against the strap

202

by a feed pinch solenoid

370

a

, a primary tension pinch solenoid

370

b

, and a secondary tension pinch solenoid

370

c

, respectively. The drive wheel clutch

356

is powered by a drive wheel belt

510

from the main drive motor

502

. The primary tension and feed drive wheels

360

,

366

are powered by a secondary drive belt

372

mounted on a feed and tension motor

361

. The secondary tension drive wheel

362

is powered by the drive wheel clutch

356

that is driven by the drive wheel belt

510

from the main drive motor

502

. As shown in

FIGS. 10 and 11

, the feed and tension motor

361

, and the solenoids

370

a

,

370

b

,

370

c

are operatively coupled to the controller

222

by conductive leads

223

.

Unlike prior art strapping machines which feed the strap around several bends in the feed and tension unit prior to reaching the track, the strapping machine

200

features a simplified strap path (

FIG. 12

) allowing the strap to be fed in a straighter path than previously achievable. The path begins at the supply dispenser

250

that is located on the opposite side of the strapping machine from the feed and tension unit. This position further enables the strap to travel in a less tortuous path. As shown in

FIG. 12

, the drive wheels

360

,

366

, and

362

are positioned in an approximately triangular orientation, with the strap

202

traversing an approximately “V-shaped” strap path having an included angle of in the range of approximately 20 degrees to approximately 40 degrees. Less bending of the strap reduces friction throughout the system, increasing the reliability of strap feeding. Less bending also reduces the tendency of the strap to permanently deform and cause feeding difficulties. Thus, the feed and tension unit

350

of the present invention advantageously reduces or eliminates kinks in the strap which lead to feeding difficulties. While the strapping machines of the prior art typically turned the strap through a total of 360 degrees or more prior to reaching the track, the feed and tension unit

350

greatly reduces the amount of turning of the strap. For example, in the embodiment shown in the accompanying figures, the strap is turned through between approximately 180 and approximately 220 degrees as the strap is initially fed from the dispenser

250

across the strapping machine to the sealing head

400

.

As the strap

202

passes through each set of pinch wheels, a plurality of inner guides

374

and a plurality of outer guides

376

keep the strap

202

in line with the sealing head

400

.

FIG. 23

is an enlarged partially-exploded isometric view of a pair of inner and outer strap guides

374

,

376

of the feed and tension unit

350

of FIG.

10

. As best viewed in

FIG. 23

, each “L-shaped” inner guide

374

has a roughly L-shaped cross-section and is coupled to a matching “L-shaped” outer guide

376

to form a strap channel

380

through which the strap

202

passes.

FIG. 23A

is a cross-sectional view of the inner guide

374

and outer guide

376

and illustrates the guide chamber formed by the inner and outer guides to guide the strap material

202

.

The inner and outer guides

374

,

376

are secured in position on a plurality of guide pins

378

which project from a back plate

382

(

FIG. 10

) of the feed and tension unit

350

by a plurality of retaining knobs

379

, although a variety of other securing devices may be used. In

FIG. 10

, one of the outer guides

376

is removed from the strap path adjacent to the primary tension pinch and drive wheels

352

,

360

to provide a view of one of the “L-shaped” inner guides

374

.

During a feeding sequence, the strap

202

is pinched between the feed drive and pinch wheels

366

,

368

. In one embodiment, a feed force applied by the feed drive and pinch wheels

366

,

368

is regulated by a pulse width modulated solenoid

370

a

in two stages: a first stage that provides a full feed force and a second stage that provides a reduced feed force by altering the pulse width modulation of the feed pinch solenoid

370

a

. Because the pinch force exerted by a solenoid

370

a

on the strap

202

varies with supplied voltage, supplying a pulse width modulated voltage signal to the solenoid

370

a

provides the ability to vary the force exerted by the solenoid

370

a

. As the force exerted by the solenoid

370

a

is decreased, the strap

202

is permitted to slip on the feed drive wheel

366

more easily with a decreased amount of feed drive force. Commercially-available solenoids suitable for this purpose include those solenoids available from Ledex®) Actuation Products of Vandalia, Ohio.

It should be noted that the frequency of the pulses which are fed to the solenoid affects the operation and performance of the solenoid. Generally, as the frequency of the pulses is increased, the adjustability of the pinch force exerted by the solenoid is improved. For example, using the above-referenced solenoids available from Ledex® Actuation Products, a pulse frequency of 8000 Hz has been successfully used.

The feed drive and pinch wheels

366

,

368

feed the strap through the sealing head

400

, around the track

450

, and back into the sealing head

400

. When the free end

206

of the strap

202

reaches the sealing head

400

, the arrival of the free end

206

is detected by feed stop switch

416

, which transmits a feed stop signal to the controller

222

. The controller

222

then sends a feed pinch signal to the feed pinch wheel

368

to disengage the feed pinch wheel

368

from the strap

202

, and the feeding sequence is complete.

During a primary tensioning sequence, the strap

202

is pinched between the primary tension drive wheel

360

and the primary tension pinch wheel

352

. In a first primary tension stage, the primary tension solenoid

370

b

engages the primary tension pinch wheel

352

against the primary tension drive wheel

360

with full pinch force to ensure that the primary tensioning solenoid engages and the strap

202

is pulled free of the track

450

. the pinch force is then reduced during a second primary tension stage by altering the pulse width modulation of the primary tension solenoid

370

b

. As the strap

202

is pulled tightly around the bundle during the primary tensioning sequence, the primary tension pinch wheel

352

stops rotating due to the slippage of the strap on the primary tensioning drive wheel

360

.

Using pulse width modulation to control the pinch forces exerted by the solenoids

370

a

,

370

b

during feeding and primary tensioning of the strap advantageously allows the operator a larger range of adjustment than is possible with a mechanical, single force adjustment system of the prior art. The two-stage force operation provides improved controllability of the strap

202

movement, including allowing the strap

202

to be quickly accelerated and to be easily stopped as required by the operator.

FIG. 13

is an isometric view of the primary tension pinch wheel

352

and the proximity sensor

354

of the feed and tension unit

350

of FIG.

10

. The proximity sensor

354

is operatively coupled to the controller

222

. The proximity sensor

354

monitors the primary tension pinch wheel

352

during primary tensioning, such as by monitoring the passing of notches in the wheel

352

, to detect the stall of the primary tension pinch wheel

352

. The proximity sensor

354

transmits signals to the controller

222

. As the signals from the proximity sensor

354

indicate that the primary tension pinch wheel

352

is not turning due to the slippage of the strap

202

on the primary tension drive wheel

360

, the controller

222

starts a secondary tensioning sequence.

The secondary tensioning sequence begins by pinching the strap between the secondary tension pinch wheel

364

and the secondary tension drive wheel

362

. Then, the secondary tension drive wheel

362

is driven by the drive wheel clutch

356

until the drive wheel clutch

356

starts to slip. After the strap

202

is tensioned to the point that the drive wheel clutch

356

slips, the controller

222

permits a predetermined amount of time to pass to allow the strap to be cut and sealed as described above. The feeding sequence may then be repeated.

An advantage of the strapping machine

200

is that the pinch wheels

352

,

364

,

368

are actuated by the solenoids

370

a

,

370

b

,

370

c

. Using a two-stage pulse width modulated (PWM) signal, the solenoids are adjustably controllable by the user during strapping machine

200

operation. During the first stage, the solenoid is given a PWM signal at a constant duty cycle. For the second stage, the solenoid is controlled using a PWM signal with a duty cycle that is user-adjustable via, for example, a potentiometer. Since the average voltage seen by the solenoid is determined by the duty cycle, varying the duty cycle will vary the amount of force the solenoid pulls. Thus, the pinch wheels

352

,

364

,

368

may be adjustably controlled during operation of the strapping machine

200

, eliminating the labor-intensive process of mechanical re-adjustment of the pinch wheels

352

,

364

,

368

and the associated downtime of the strapping machine.

FIG. 14

is an exploded isometric view of an accumulator

300

in accordance with an embodiment of the invention.

FIGS. 15 and 16

are front and top elevational views, respectively, of the accumulator

300

of FIG.

14

.

FIG. 24

is a cross-sectional view of the accumulator

300

of

FIG. 15

taken along line

24

—

24

. The accumulator

300

includes a first and second sidewalls

302

,

304

that substantially enclose a chamber

306

that stores strap for rapid feeding, as well as for temporarily storing of the strap

202

that is drawn back in the tensioning process. The second sidewall

304

is incrementally adjustable by placing retaining pins

308

in a series of holes

310

located in shafts

312

that protrude from the first sidewall

302

to accommodate different sizes of strap

202

. Pin holders

309

are attached to the second sidewall

304

which engage the retaining pins

308

and fix the position of the second sidewall

304

on the shafts

312

.

The chamber

306

is substantially enclosed by the first sidewall

302

and the adjustable second sidewall

304

. A pair of endwalls

320

extend vertically between the first and second sidewalls

302

,

304

. A top wall

322

extends horizontally along between the first and second sidewalls

302

,

304

, the top wall

322

having the top entrance

316

where strap

202

is fed into and pulled out of the accumulator unit

300

. An “L” shaped wand

324

extends between the first and second sidewalls

302

,

304

along the bottom of the chamber

306

. The wand

324

is pivotally attached to the first sidewall

302

.

In operation, an accumulator motor

330

(

FIG. 14

) drives an accumulator rive wheel

332

to feed the strap

202

between the accumulator drive wheel

332

and an accumulator pinch wheel

334

. An accumulator feed switch

336

(

FIG. 14

) is positioned proximate the accumulator drive and pinch wheels

332

,

334

to detect the presence of the strap

202

and to transmit a control signal to the accumulator motor

330

. As the chamber

306

fills with strap

202

, the wand

324

is pushed downwardly by the weight of the strap

202

, pivoting the wand

324

into contact with an indicator switch

326

(FIG.

15

). The indicator switch

326

then transmits a signal to the controller

222

to shut off the accumulator motor

330

, as described more fully below.

Alternately, during an automatic feeding mode, a strap diverter

314

covers a top entrance

316

of the chamber

306

. When strap

202

is fed into the strapping machine

200

by the accumulator motor

330

, a diverter solenoid

318

(

FIG. 14

) pulls the strap diverter

314

over the top entrance

316

of the chamber

306

, diverting the strap

202

directly into the feed and tension unit

350

and around the track

450

.

As best seen in

FIG. 24

, the accumulator

300

advantageously allows the width w of the chamber

306

and the top entrance

316

to be adjusted easily and quickly to accommodate varying widths of strap

202

. Unlike prior art apparatus that have accumulator sidewalls that are solidly affixed to form a single chamber size, the accumulator

300

of the present invention includes shafts

312

having a plurality of holes

310

placed at increments to match various commonly used strap sizes. Thus, the position of the second sidewall

304

with respect to the first sidewall

302

may be quickly and easily varied by removal of the retaining pins

308

, repositioning the second sidewall

304

at the desired location, and replacement of the retaining pins

308

within the desired holes

310

. The pin holders

309

then engage against the retaining pins

308

and fix the position of the second sidewall

304

on the shafts

312

. This mounting configuration allows the adjustment of the accumulator without having any additional parts, such as spacers between the first and second sidewalls

302

,

304

.

FIG. 17

is an isometric view of a dispenser

250

in accordance with an embodiment of the invention.

FIG. 18

is a top elevational view of the dispenser

250

of FIG.

17

. The dispenser

250

includes a mounting shaft

252

extending outwardly from the frame

210

between an inner hub

254

and an outer hub

256

. A spring brake

258

is operatively coupled to the mounting shaft

252

and to the frame

210

. When actuated, the brake

258

allows the rotation of the mounting shaft

252

. A mandrel

260

is rotatably mounted on the mounting shaft

252

and supports the inner hub

254

and the outer hub

256

. Strap

202

is routed from the strap coil

204

around a first pulley

262

and a second pulley

264

and over a strap exhaust switch

266

.

As strap

202

is required in the accumulator

300

, the accumulator motor

330

is energized and the dispenser brake

258

released, allowing the strap coil

204

to spin freely and strap

202

to feed into the chamber

306

. In this embodiment, the brake

258

releases the strap coil

204

to spin only when power is supplied to the brake

258

. When the strap coil

204

is depleted, the strap exhaust switch

266

is no longer actuated which stops the strapping machine

200

until the strap coil

204

is replenished. A braking circuit is used to prevent the accumulator motor

330

from drawing the free end

206

of the strap into the accumulator

300

. The remaining loose tail of strap can then be pulled out of the accumulator

300

before a new strap coil is installed. The empty strap coil

204

is replaced by removing an outer hub securing nut

268

and the outer hub

256

, and then removing the strap coil core (not shown) from the mandrel

260

. Next, a fresh strap coil

204

is placed on the mandrel

260

with the strap

202

wound in a clockwise direction. Finally, the outer hub

256

and the outer hub securing nut

268

are replaced and the nut tightened securely.

To begin feeding the strap

202

, the free end

206

is removed from the strap coil

204

, threaded around the first pulley

262

, through the strap exhaust switch

266

, around the second pulley

264

and between the accumulator drive wheel

332

and the accumulator pinch wheel

334

. As the strap

202

is placed between the accumulator wheels

332

,

334

, the accumulator feed switch

336

is actuated causing the accumulator feed solenoid to actuate, thus feeding the strap over the accumulator and into the track.

When enough force is applied to the wand

324

by the weight of the strap

202

accumulating in the chamber

306

, the wand

324

moves downwardly to actuate the indicator switch

326

, indicating that the accumulator unit

300

is full. In response to this signal, the controller

222

de-energizes the accumulator motor

328

and the dispenser brake

330

to halt the accumulator filling sequence. A time delay occurs between when the dispenser brake

330

is de-energized and when the accumulator motor

328

is de-energized to take up any slack in the strap coil

204

.

FIG. 19

is an isometric view of a track

450

in accordance with an embodiment of the invention.

FIG. 20

is a partial sectional view of a straight section

452

of the track

450

of

FIG. 19

taken along line

20

-

20

.

FIG. 21

is an isometric view of a corner section

454

of the track

450

of FIG.

19

.

FIG. 25

is a partially exploded isometric view of a straight section

452

of the track

450

of FIG.

19

. During feeding, after the strap

202

exits from the sealing head

400

, it is pushed completely around the track

450

and then back into the sealing head

400

. The track

450

directs the strap

202

around the strapping station

208

.

The track

450

includes a plurality of straight sections

452

and a plurality of corner sections

454

. As shown in

FIGS. 19 and 20

, each straight section

454

includes a guide support

455

at each end of the straight section

454

. A straight slotted cover

456

and a straight backplate

457

are coupled to the straight supports

455

to form a portion of a guide passage

462

that retains the strap

202

during feeding. Each straight slotted cover

456

includes a straight inner surface

472

on the inner circumference of the guide passage

462

, and a straight outer surface

474

on the outer circumference of the guide passage

462

.

As best seen in

FIGS. 20 and 21

, the straight supports

455

and the corner supports

454

are keyed to fit on a raised “T” section

459

of an outer arch

458

. The outer arch

458

forms a frame for the other components of the track

450

. As the strap

200

is tensioned around the bundle, the straight and corner slotted covers

456

,

463

open, allowing the strap

202

to pull clear of the guide passage

462

.

FIG. 20

illustrates the open position of the slotted cover

456

in phantom to assist in a more complete understanding of the invention. As the strap

202

clears the guide passage

462

, each of the straight and corner slotted covers

456

,

463

is closed by the springs

461

and becomes ready for the strap

202

to be fed again. The V-shape of the guide passage

462

in the corner section

454

helps assure that the strap removal begins in the corner sections

454

rather than in the straight sections

452

of the track

450

. When the strap

202

(see

FIG. 20

) is removed from the track

450

, the V-shape of the guide passage

462

in the corner section

454

causes the track cover

463

to begin opening in the corner section

454

. As the strap

202

begins to separate from the track

450

in the corner sections

454

, the V-shaped guide passage

462

imparts a slight twist to the strap to start opening the straight slotted

456

(see

FIG. 20

) in the straight sections

452

of the track

450

.

As shown in

FIG. 21

, each corner section

454

includes a corner slotted cover

463

and a corner backplate

465

coupled to a plurality of guide supports

455

. The corner slotted cover

463

and corner backplate

465

form a portion of the guide passage

462

therebetween. Each corner slotted cover

453

includes a corner inner surface

476

on the inner circumference of the guide passage

462

, and a corner outer surface

478

on the outer circumference of the guide passage

462

. In this embodiment, the corner slotted cover

463

and the corner backplate

465

are coupled to the guide supports

455

using a four-bar linkage assembly

469

that permits the corner slotted cover

463

to pivotably open to release the strap

202

from the guide passage

462

. Although alternate embodiments for pivotably mounting the corner slotted covers

463

may be conceived, in the embodiment shown in

FIG. 21

, the inner bars

468

(one shown) of the four-bar linkage assembly

469

have an enlarged opening

470

to permit the corner slotted cover

463

to pivotably open about an axis of rotation that is oriented approximately 45 degrees from the horizontal.

As best shown in

FIG. 25

, the straight slotted cover

456

and the straight backplate

457

are spring-loaded by a plurality of springs

461

. The straight slotted covers

456

and the straight backplates

457

are hingeably engaged on pivot pins

467

that are approximately parallel to the path of the strap

202

in the guide passage

462

. The pivot pins

467

are inserted through corresponding apertures

467

a

and

467

b

in the straight slotted cover

456

and straight backplate

457

, respectively, and rotate about an axis defined by the longitudinal axis of the pivot pins

467

. The pivot pins

467

are retained in position by snap-on retainers or any other convenient retainer element.

The springs

461

are inserted through a corresponding aperture

461

a

in the straight backplate

457

and are coupled to the straight slotted cover

456

by a spring retaining pin

466

. In an exemplary embodiment, the spring retaining pins

466

are identical to the pivot pins

467

and are retained within corresponding apertures

466

a

in the straight slotted cover

456

by the snap-on retainers. The springs

461

are thus coupled on a proximal end to the straight slotted cover

456

by the spring retaining pins

466

and are retained within the aperture

461

a

by an enlarged distal end, sometimes referred to as a circle cotter. This arrangement allows the straight slotted cover

456

to pivot open and release the strap

200

(see

FIG. 20

) and automatically close due to the spring force exerted on the straight slotted cover by the springs

461

. Although various sizes of straight slotted covers

456

may be employed, in the embodiment shown in

FIGS. 20 and 25

, the guide passage

462

is sized to receive strap sizes varying from approximately 5 mm to approximately 15 mm.

One advantage of the track

450

of the present invention is the modular construction of the straight and corner sections

452

,

454

which allows the track

450

to be incrementally extended in length and height. Because the straight and corner sections

452

,

454

are keyed to fit a raised section

459

of the outer arch

458

, these components form an easily assembled slide-together arch system, enabling the size of the track

450

to be easily modified for various combinations of length and height. Thus, the size of the strapping station

208

may be quickly and efficiently modified for a variety of bundle sizes.

Another advantage of the track

450

is that by pivoting the straight slotted covers

456

parallel to the strap path, and by pivoting the corner slotted covers

463

on the four-bar linkage assemblies

469

, each individual straight and corner section

452

,

454

may open using only the forces exerted by the strap

202

as it is tightened during tensioning. During the tension cycle, the strap

202

is drawn against the straight inner surfaces

472

and the corner inner surfaces

476

, forcing the straight slotted covers

456

and corner slotted covers

463

to pivotably open in the manner described above. Thus, the track

450

does not require complex hydraulic or pneumatic actuation systems to open the track to release the strap during tensioning. This reduces costs and simplifies maintenance of the track and strapping machine.

A further advantage of the track

450

is that, in the embodiment shown in

FIGS. 19 through 22

, the forces exerted by the strap on the straight slotted covers

456

and corner slotted covers

463

during the feed cycle assist in keeping the track closed during feeding. During the feed cycle, the strap

202

pushes outwardly on the straight outer surfaces

474

and the corner outer surfaces

478

to create a moment (i.e., a force vector) that forces the straight slotted covers

456

and the corner slotted covers

463

toward the closed position. This aspect of the invention reduces misfeeds of the strap, and eliminates the need for complex hydraulic or pneumatic actuation systems to close the track and keep it closed during the feed cycle.

The detailed descriptions of the above embodiments are not exhaustive descriptions of all embodiments contemplated by the inventors to be within the scope of the invention. Indeed, persons skilled in the art will recognize that certain elements of the above-described embodiments may variously be combined or eliminated to create further embodiments, and such further embodiments fall within the scope and teachings of the invention. It will also be apparent to those of ordinary skill in the art that the above-described embodiments may be combined in whole or in part with prior art methods to create additional embodiments within the scope and teachings of the invention.

Thus, although specific embodiments of, and examples for, the invention are described herein for illustrative purposes, various equivalent modifications are possible within the scope of the invention, as those skilled in the relevant art will recognize. The teachings provided herein of the invention can be applied to other methods and apparatus for strapping bundles of objects, and not just to the methods and apparatus for strapping bundles of objects described above and shown in the figures. In general, in the following claims, the terms used should not be construed to limit the invention to the specific embodiments disclosed in the specification. Accordingly, the invention is not limited by the foregoing disclosure, but instead its scope is to be determined by the following claims.

Number	Name	Date	Kind
3118368	Lems	Jan 1964	A
3179037	Cranston, Jr. et al.	Apr 1965	A
3447448	Pasic	Jun 1969	A
3768396	Coleman	Oct 1973	A
3884139	Pasic	May 1975	A
4011808	Aoki et al.	Mar 1977	A
4120239	Pasic et al.	Oct 1978	A
4155799	Matsushita et al.	May 1979	A
4244773	Siebeck et al.	Jan 1981	A
4278014	Knieps	Jul 1981	A
4387631	Pasic	Jun 1983	A
4516488	Bartzick et al.	May 1985	A
4520720	Urban et al.	Jun 1985	A
4569186	Mori et al.	Feb 1986	A
4625635	Lewis	Dec 1986	A
4697510	Cranston, III et al.	Oct 1987	A
4712357	Crawford et al.	Dec 1987	A
4724659	Mori et al.	Feb 1988	A
4781110	Sakaki et al.	Nov 1988	A
4867053	Kawai et al.	Sep 1989	A
4955180	Sakaki et al.	Sep 1990	A
5146847	Lyon et al.	Sep 1992	A
5187656	Kurakake	Feb 1993	A
5251544	Abrams	Oct 1993	A
5287802	Pearson	Feb 1994	A
5379576	Koyama	Jan 1995	A
5414980	Shibazaki et al.	May 1995	A
5560187	Nagashima et al.	Oct 1996	A
5613432	Hoshino	Mar 1997	A
5778772	Schwede	Jul 1998	A
5809873	Chak et al.	Sep 1998	A

Number	Date	Country
38 41 884	Jun 1990	DE
287 152	Feb 1991	DE
44 21 661	Jan 1996	DE
0 695 687	Feb 1996	EP
2 615 480	Nov 1988	FR
2 226 427	Jun 1990	GB
8011816	Jan 1996	JP
WO 9510452	Apr 1995	WO
WO 9822348	May 1998	WO

Track mechansim for guiding flexible straps around bundles of objects

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

US Referenced Citations (31)

Foreign Referenced Citations (9)