Sealing tool for strap

Abstract

A tool for sealing overlying courses of a strap that includes a gripping unit, a power supply unit detachably affixed to one end of the gripping unit, and a motor in the gripping unit. A cam is coupled to the motor and a notching unit is coupled to the cam by a plurality of linkages.

Description

BACKGROUND

Manual sealers provide positive sealing action with minimal effort. They interlock overlapping courses of a strap into a high strength joint. One type of sealing tool is a manual notch-type sealer that cuts into and seals the outer edges of the strap, turning tabs down (down notch) or up (reverse notch). Crimp-type sealers press the edges of the strap and the seal into wavy crimps especially shaped to produce maximum frictional forces on the strap.

There are two principal types of manual strap sealers, front action sealers and side action sealers. Front-action sealer handles are held perpendicular to the strap, usually in front of the operator who forces the handles together for maximum leverage. These are generally used for light duty strap applications. Side-action sealers have a lower handle that can be rested on the flat surface of the load being strapped. Operators can apply much of their weight, again for maximum leverage, with both hands on the upper handle. These are generally used in heavier strap applications.

The joint is the weakest part of the system, therefore the type of joining method used is very important if strength is an issue. The strength of a joint is defined as the force required to break the strap in uniaxial tension. This is then compared to the uniaxial strength of the strap and recorded as the percent difference (e.g., a sample of strap may have a 5,000 lb (2,300 kg) break strength and the seal may fail at 3,750 lbs. (1,750 kg), so the seal is said to have a 75% strength). Hot knife welds have a minimum break strength of 55%. Friction welds have a minimum break strength of 65%.

SUMMARY

Various embodiments of the present disclosure provide a sealing tool for sealing a strap, comprising a gripping unit, a power supply unit detachably affixed to one end of the gripping unit, and a motor in the gripping unit. The tool can include a cam coupled to the motor, and a notching unit coupled to the cam by a plurality of linkages where the notching unit is configured to create a notch in a strap.

In an embodiment, the power supply unit is a battery. The notching unit can be configured to create a notch in a strap. A gear can be coupled to the motor which drives the cam.

In another embodiment, the notching unit includes a notch plate having a first notch surface at a first depth in the notch plate and a second notch surface surrounding the first notch surface at a second depth in the notch plate. The notch plate can be configured to create a notch in a strap. The tool can include a push button switch coupled to the motor and the power supply unit.

A strap position indicating switch can be included in the notching unit that provides power to the motor when a strap is positioned in the sealing tool. A home position switch can also be provided to sense that the notching unit is at the home or full open position at the end of a sealing cycle.

The notching unit can include a first linkage having a first end coupled to the cam, a second linkage and a third linkage each having a first end coupled to the second end of the first linkage, a first jaw rotatably affixed to a second end of the second linkage, and a second jaw affixed to a second end of the first linkage, such that the first jaw and second jaw are rotatably affixed to the notch plate so that pincers located at ends of each of the jaws face each other.

A method of operating a sealing tool includes the steps of receiving an operation signal from a switch, receiving a signal from a strap sensor indicating that a strap is positioned in a notch plate, providing power from a power supply unit to a motor in a gripping unit, and driving a notching unit via a cam coupled to the power supply unit to create a notch in the strap.

Other objects, features, and advantages of the disclosure will be apparent from the following description, taken in conjunction with the accompanying sheets of drawings, wherein like numerals refer to like parts, elements, components, steps, and processes.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side view of an embodiment of a sealing tool;

FIGS. 2A and 2B illustrate a grip handle on the sealing tool of FIG. 1;

FIG. 3 illustrates a central channel of the sealing tool of FIG. 1;

FIG. 4 depicts the motor positioned in the central channel of FIG. 3;

FIG. 5A is an embodiment of a sealing assembly of the sealing tool of FIG. 1;

FIG. 5B illustrates the jaws of the sealing assembly of FIG. 5A;

FIG. 5C illustrates the notch plates of the sealing tool of FIG. 1;

FIG. 6 illustrates a home position switch for the tool;

FIG. 7 depicts an exemplary sensor in the sealing assembly of FIG. 5A;

FIG. 8 illustrates a control system used to control the sealing tool of FIG. 1; and

FIGS. 9A-9D shows the operation of the sealing tool.

DETAILED DESCRIPTION

While the present disclosure is susceptible of embodiment in various forms, there is shown in the drawings and will hereinafter be described one or more embodiments with the understanding that the present disclosure is to be considered illustrative only and is not intended to limit the disclosure to any specific embodiment described or illustrated.

FIG. 1 illustrates an embodiment of a sealing tool 100. The tool 100 includes a power supply unit 102, a grip handle 104 and a notcher assembly 106. In one embodiment, the grip handle 104 and notcher assembly 106 are manufactured from a strong, but lightweight material including, but not limited to, aluminum, magnesium, titanium, or any other light weight material.

The power supply unit 102 can be a lithium-ion or nickel cadmium battery having an operational voltage of about 14.4 to 24 volts inclusive. The power supply 102 is removably affixed to a first end of the grip handle 104 by a holding unit 108. In one embodiment, the holding unit 108 includes a first plate 110 that is affixed to a second plate 112. An upper surface of the second plate 112 is affixed to the first end of the grip handle 104. The first plate 110 and second plate 112 are separated by a distance sufficient to accommodate batteries of varying sizes. A locking unit (not shown), holds the first plate 110 against the second plate 112 such that the power supply unit 102 is prevented from disengaging the grip handle 104. In another embodiment, the power supply unit 102 is removably secured to the grip handle 104 by a locking clip (not shown) on the grip handle 104 which engages an opening on a side of the power supply unit 102.

FIG. 2A illustrates an embodiment of a grip handle 104. The grip handle 104 includes the first end 202 that includes a first extension 204 which is collinear with the central axis of the grip handle 104 and a second extension 206 which is substantially perpendicular to the central axis of the grip handle 104, a central portion 208 and a top portion 210. The first extension 204 and second extension 206 are configured to accommodate the battery holding unit 108. The first extension 204 includes a plurality of openings which each correspond to openings in the first plate 110 and second plate 112 such that the first plate 110 and second plate 112 are affixed to the first extension 204. In one embodiment, the second extension acts 206 as the second plate.

The central portion 208 of the grip handle 104 includes a grip area 212 which includes a plurality of raised areas 214 and corresponding lower areas 216. The lower areas 216 are spaced from the raised areas 214 such that the lower areas 216 can comfortably accommodate a user's finger. Further, the depth of the lower areas 216 in relation to the raised areas 214 are set to a depth which prevents a user's finger from moving parallel with the central axis of the grip handle 104. In one embodiment, the central portion 208 includes an interior channel that is manufactured using a single bore housing. By using a single bore housing, the diameter of the central portion 208 is reduced which allows for a user hand to comfortably engage the grip area 212 and the back surface of the central portion 208. The central portion 208 can be manufactured of two half sections which are sealed together using a sealing unit including, but not limited to, screws, bolts, pins, clasps, rivets or any other mechanism for securing the two halves together.

A push button switch 218 is positioned between the top portion 210 and the grip area 212. The switch 218 is positioned such that an operator can simultaneously engage the grip area 212 and the switch 218. When activated, the switch 218 completes a circuit between the power supply unit 102 and a motor (see, for example 302, FIG. 3) in the top portion 210 as will be described herein. In one embodiment, the front portion of the switch 218 is curved to comfortably accommodate a user's finger.

The top portion 210 of the grip handle 104 includes a first end affixed to the central portion 208. In one embodiment, the first end of the top portion 210 engages an opening in the center portion 206 as shown in FIG. 2B. The opening is sized to engage the first end of the top portion 210. A central channel 300 extends through the top portion 210 along a central axis of the top portion 210.

FIG. 3 shows an embodiment of a central channel 300 in the grip handle 104. The central channel 300 includes a rear portion 306 which is sized to accommodate the motor 302 and worm gear 304 and a front portion 308 which is sized to accommodate the top end of the worm gear 304. In one embodiment, the front portion 308 includes a bearing 310 that engages the top end of the worm gear 304 such that the worm gear 304 freely rotates around its central axis. A rear end 312 of the worm gear 304 is rotatably coupled to the motor 302 such that the motor 302 rotates the worm gear 304 about the worm gear's 304 central axis. A central gear 314 is positioned below the worm gear 304 in a side cavity 316 of the top portion. The central gear 314 includes a plurality of teeth which are sized to engage the worm gear 304. An inner portion of the central gear 314 is affixed to a cam 318 which is affixed to the notcher assembly 106.

FIG. 4 illustrates an embodiment of the motor 302. The motor 302 is affixed to a plate 402 on the rear portion 306 of the central channel 300 of the top portion 210. The plate 402 includes an opening 404 that is sized to accommodate a plurality of connectors coupled to the power supply unit 102 and the switch 218. The axle 406 of the motor 302 includes a plurality of teeth that engage and drive a planetary gear set 408. In one embodiment, the motor 302 includes three planetary gears 408 with each gear having four idler gears. The planetary gears 408 drive the worm gear 304 such that the worm gear 304 rotates around its central axis to drive the central gear 314.

FIG. 5A shows an embodiment of the notcher assembly 106. The notcher assembly 106 includes a back plate 502 affixed to one side of the top portion 210. The back plate 502 includes two openings 504, 506 positioned along a side of the back plate 502 which engage two openings in two extensions 508, 510 which extend from the surface of the top portion 210. The back plate 502 is on the top portion 210 such that the side cavity 316 is in front of the back plate 512 with the back plate 512 connecting to the two extensions 508, 510 which are positioned on a back surface of the top portion 210. A first end of a central linkage 514 is rotatably coupled to the cam 318 by a pin 320 such that the central linkage 514 rotates around the central axis of the cam 318 along a path defined by the periphery of the cam 318. A second end of the central linkage 514, distal from the first end of the central linkage 514, is rotatably coupled to a first end of a first positioning linkage 516 and a first end of a second positioning linkage 518 by a second pin 520. A second end of the first positioning linkage 516 is connected to a first end of a first jaw 522 and a second end of the second linkage 518 is connected to a first end of a second jaw 524. The back plate 502 includes a central slot 512 the width of which is sized to accommodate the second pin 520. The length of the central slot 512 is determined by the travel of the second pin 520. The pin 520 is slidably affixed to the slot 512 such that the second pin 520 travels along the slot 512 as the linkages are driven by the cam 318.

FIG. 5B illustrates an embodiment of jaws 522 and 524. The jaws 522 and 524 include first openings 526 and 528, second openings 530 and 532 and pincers 534 and 536. The first openings 526 and 528 are each rotatably coupled to the second end of the first and second linkages 516 and 518 such that the jaws 522 and 524 rotate around the first opening 526 in each jaw 522 and 524. The second openings 530 and 532 are affixed to a front notch plate 538 and a back notch plate 540. The pincers 534 and 536 are arranged on the jaws 522 and 524 such that the pincer 534 on the first jaw 522 faces the pincer 536 on the second jaw 524. The pincers 534 and 536 are configured to rotate toward the strap to create a fold in a strap. In one embodiment, the pincers 534 and 536 press the sides of a strap toward a center portion of the notch plates 538 and 540 which creates a notch in the strap. Those skilled in the art will recognize that reference to “a notch” includes that configuration in which a notch is formed in opposing sides of the strap (i.e., two opposing notches are formed in the strap).

FIG. 5C shows an embodiment of the notch plates 538 and 540. The notch plates 538 and 540 each have a first opening and second opening on opposite ends which align with the second openings 530 and 532 in the jaws 522 and 524, such that the jaws 522 and 524 are separated by a predefined distance. The center of each notch plates 538 and 540 include a first notch surface 542 and at least two second notch surfaces 544. The first notch surface 542 is positioned at a first depth from the surface of the notch plate 538 or 540 with the second notch surfaces 544 being positioned at opposite ends of the first notch surface 542 and at a second depth. In an embodiment, the first notch surface 542 is positioned at a depth greater than the second notch surfaces 544. Alternately, the notch surfaces 542 and 544 are configured to create a notch in a strap. The notch levels 542 and 544 can be configured to create a single notch in a strap. In an embodiment, the strap has a width of at least 1.25 inches and a thickness of at least 0.025 inches.

FIG. 6 illustrates an embodiment of a home position switch 546 included in the notcher assembly 106. The home position switch 546 is positioned on the back plate 512 and provides a signal to a control system (see, for example 800, FIG. 8) that the cam 318 has returned to a predetermined starting position. The home position switch 546 includes a base portion 600 with a sensor portion 602 attached to one side of the base portion 600. The sensor portion 602 is made from a material having memory and conductive characteristics such as, but not including, steel, copper or any other metal capable of bending and conducting electricity. The home position switch 546 is positioned on the back plate 512 such that one of the linkages 514, 516 and 518 contacts the sensor portion 602 when the linkages 514, 516 and 518 are in a predetermine position.

FIG. 7 illustrates an embodiment of a strap sensor 700. The sensor 700 is secured to the notch plates 538 and 540 such that the sensing portion 702 of the sensor 700 is in contact with a strap when a strap is positioned on the notch plates 538 and 540 for notching. When the sensor 700 is in contact with the strap, a current is inducted through the strap sensor 700 and back to a control system (see, for example 800, FIG. 8) indicating that a strap is in position on the notch plates 538 and 540. If the circuit is not complete, the sealing tool 100 is prevented from operating. In an embodiment, the sensor is an inductive sensor. Alternately, the sensor is a switch. The sensor 700 can be directly coupled to the power supply unit 102, to prevents the power supply unit 102 from powering the motor 302 without a strap present.

FIG. 8 depicts an exemplary control system 800 used to control the tool 100. The control system 800 includes a control panel 802 that includes a central processing unit (“CPU”) 804, a memory 806 and an input and output (“I/O”) unit 808. A plurality of sensors are electrically coupled to the I/O unit 808. Software operating in the CPU 804 monitors each of the plurality of sensors and controls the power from the power supply unit 102 to the motor 302 based on the inputs received from the sensors.

The switch 218, sensor 700 and home position switch 546 are connected as inputs to the control panel. Software operating in the CPU monitors the switch 218 to determine if the strap sealing tool 100 is in use. When the switch 218 is pressed, the software confirms the cam 318 has returned to the home position based on the home position switch 546. If the cam 318 has not returned to the home position, an output on the I/O unit 808 of the control panel 802 provides power to the motor 302 to move the cam 318 to the home position. Once the home position switch 546 confirms the cam 318 is in the home position, the software confirms a strap is positioned for notching by the sensor 700. If a strap is not in position for notching, no power is provided to the motor 302. If a strap is in position for notching, the output on the I/O unit 808 provides power to the motor 302 to drive the jaws 522 and 524.

FIGS. 9A-9D illustrate the operation of the sealing tool 100. FIG. 9A depicts the sealing tool 100 in the full open position with the jaws 524 and 522 separated from each other by a maximum distance. When power is provided to the motor 302, the cam 318 rotates in a clockwise motion pushing the central linkage 514 down towards the notch plates 538 and 540. As the central linkage 514 moves downward, the first and second linkages 516 and 518 are pushed away from the central linkage 514 moving the jaws 522 and 524 towards the notch plates 538 and 540 as shown in FIG. 9B. When the cam 180 has rotated approximately 180 degrees from the starting position, the jaws 522 and 524 are in the full closed position which compresses the strap positioned against the notch plates 538 and 540, as shown in FIG. 9C. As the cam 318 moves beyond the 180 degree position and back towards the home position, the central linkage 514 is moved away from the notch plates 538 and 540 and the first and second linkages 516 and 518 are pulled towards the central linkage 514, which pushes the jaws 522 and 524 away from one another as shown in FIG. 9D.

It should be understood that various changes and modifications to the presently preferred embodiments disclosed herein will be apparent to those skilled in the art. Such changes and modifications can be made without departing from the spirit and scope of the present disclosure and without diminishing its intended advantages. It is therefore intended that such changes and modifications be covered by the appended claims.

Claims

1. A method for forming notches in overlapping portions of a strap to attach the overlapping portions of the strap to one another, the method comprising: while the overlapping portions of the strap are positioned in a strap path defined between first and second jaws of a handheld sealing tool, receiving an actuation of a switch of the sealing tool; andresponsive to receiving the actuation of the switch, actuating a motor of the sealing tool that is operably coupled to a drive element of the sealing tool to: rotate the drive element about a drive element rotational axis ina first rotational direction to cause the first and second jaws to rotate from respective rest positions to respective notch-forming positions to form the notches in the overlapping portions of the strap, wherein the drive element rotational axis is spaced-apart from and extends parallel to the strap path; andafter the notches are formed in the overlapping portions of the strap, continue to rotate the drive element about the drive element rotational axis in the first rotational direction to cause the first and second jaws to rotate back to their respective rest positions.

2. The method of claim 1, wherein the sealing tool comprises a plate to which the first and second jaws are connected via first and second connectors, respectively, so the first and second jaws rotate relative to the plate between their respective rest positions and their respective notch-forming positions.

3. The method of claim 2, wherein the motor comprises a drive shaft operably connected to the drive element, wherein the drive shaft is rotatable about a drive shaft rotational axis, wherein actuating the motor comprises powering the motor to cause the drive shaft to rotate about the drive shaft rotational axis, wherein the sealing tool comprises a first positioning linkage connected to the first jaw, a second positioning linkage connected to the second jaw, and a positioning linkage connector connected to the first and second positioning linkages, wherein the drive element is operably connected to the first and second jaws via the first and second positioning linkages and the positioning linkage connector such that the positioning linkage connector moves away from the drive element rotational axis and toward the strap path in a direction transverse to the drive element rotational axis as the first and second jaws rotate from their respective rest positions to their respective notch-forming positions and such that the positioning linkage connector moves toward the drive element rotational axis and away from the strap path as the first and second jaws rotate back to their respective rest positions.

4. The method of claim 3, further comprising powering the motor via a battery removably received in a housing of the sealing tool.

5. The method of claim 3, wherein the drive element is operably connected to the first and second jaws via the first and second positioning linkages and the positioning linkage connector such that the positioning linkage connector moves toward the one or more plates as the first and second jaws rotate from their respective rest positions to their respective notch-forming positions and such that the positioning linkage connector moves away from the one or more plates as the first and second jaws rotate back to their respective rest positions.

6. The method of claim 1, further comprising actuating the motor to rotate the drive element no more than about 360 degrees from a starting position in the first rotational direction to cause the first and second jaws to rotate from their respective rest positions to their respective notch-forming positions and, afterwards, back to their respective rest positions.

7. The method of claim 6, further comprising actuating the motor to rotate the drive element no less than about 180 degrees and no more than about 360 degrees from the starting position in the first rotational direction to cause the first and second jaws to rotate from their respective rest positions to their respective notch-forming positions and, afterwards, back to their respective rest positions.

8. The method of claim 1, wherein the sealing tool comprises a plate to which the first and second jaws are connected via first and second connectors, respectively, so the first and second jaws rotate relative to the plate between their respective rest positions and their respective notch-forming positions, wherein movement of the first and second jaws from their respective rest positions to their respective notch-forming positions causes the jaws to force the overlapping portions of strap against the plate and then form the notches in the overlapping portions of strap.

9. The method of claim 8, wherein the first jaw comprises a first pincer and the second jaw comprises a second pincer, wherein the first and second pincers are not in the strap path when the first and second jaws are in their respective rest positions and are in the strap path when the first and second jaws are in their respective notch-forming positions.

10. The method of claim 1, wherein the drive element comprises a cam.

11. The method of claim 10, wherein the first and second jaws are in an open configuration when in their respective first and second jaw rest positions and in a closed configuration when in their respective first and second jaw notch-forming positions, wherein the first jaw comprises a first pincer and the second jaw comprises a second pincer, wherein the first and second pincers are not in the strap path when the first and second jaws are in the open configuration and are in the strap path when the first and second jaws are in the closed configuration.

12. The method of claim 10, further comprising actuating the motor to rotate the drive element no more than about 360 degrees from a starting position in the first rotational direction to cause the first and second jaws to rotate from the open configuration to the closed configuration and, afterwards, back to the closed configuration.

13. The method of claim 12, further comprising actuating the motor to rotate the drive element no less than about 180 degrees and no more than about 360 degrees from the starting position in the first rotational direction to cause the first and second jaws to rotate from the open configuration to the closed configuration and, afterwards, back to the closed configuration.

14. The method of claim 13, wherein the motor comprises a drive shaft operably connected to the drive element, wherein the drive shaft is rotatable about a drive shaft rotational axis, wherein actuating the motor comprises powering the motor to cause the drive shaft to rotate about the drive shaft rotational axis, wherein the sealing tool comprises a first positioning linkage connected to the first jaw, a second positioning linkage connected to the second jaw, and a positioning linkage connector connected to the first and second positioning linkages, wherein the drive element is operably connected to the first and second jaws via the first and second positioning linkages and the positioning linkage connector such that the positioning linkage connector moves away from the drive element rotational axis and toward the strap path in a direction transverse to the drive element rotational axis as the first and second jaws rotate from the open configuration to the closed configuration and such that the positioning linkage connector moves toward the drive element rotational axis and away from the strap path as the first and second jaws rotate back to the open configuration.

15. The method of claim 14, further comprising powering the motor via a battery removably received in a housing of the sealing tool.

16. The method of claim 14, wherein the drive element is operably connected to the first and second jaws via the first and second positioning linkages and the positioning linkage connector such that the positioning linkage connector moves toward the one or more plates as the first and second jaws rotate from the open configuration to the closed configuration and such that the positioning linkage connector moves away from the one or more plates as the first and second jaws rotate back to the open configuration.

17. The method of claim 10, wherein the sealing tool comprises a plate to which the first and second jaws are connected via first and second connectors, respectively, so the first and second jaws rotate relative to the plate between the open and closed configurations, wherein movement of the first and second jaws from the open configuration to the closed configuration causes the jaws to force the overlapping portions of strap against the plate and then form the notches in the overlapping portions of strap.

18. The method of claim 17, wherein the first jaw comprises a first pincer and the second jaw comprises a second pincer, wherein the first and second pincers are not in the strap path when the first and second jaws are in the open configuration positions and are in the strap path when the first and second jaws are in the closed configuration.

19. The method of claim 3, wherein drive shaft rotational axis is transverse to the drive element rotational axis.

20. The method of claim 3, wherein the plate comprises a first plate, wherein the first and second jaws are connected via the first and second connectors, respectively, to a second plate so the first and second jaws rotate relative to the second plate between their respective rest positions and their respective notch-forming positions, wherein the first and second jaws are positioned between the first and second plates.