Strapping tools or strappers come in a wide variety of types, from fully manual hand tools to automatic, table-top machines. Strapping tools can be designed and intended for use with different types of strap or strapping materials, such as metal strapping or plastic/polymeric strapping. Strappers for metal strapping materials can be automatic table-top or hand-held devices that are configured to seal the strap onto itself. The sealing function can be performed using a sealless configuration by forming interlocking keys in overlapping courses of the strap, or by applying a seal that is positioned over and crimped onto the overlapping strap courses.
There are two types of known hand-held devices for steel strap: manual tools that require an operator to exert one or more forces to tension the strap and form the seal; and pneumatically operated tools that perform the tension and sealing functions by actuation of one or more pneumatic motors. The manual tools can be fatiguing to operate for long periods of time and may be difficult to maneuver and manipulate in certain instances, for example when the seal is formed on the side of a package or load. Moreover, manual sealing typically requires multiple tools to tension the strap, form the seal and cut the sealed strap from its source.
Pneumatic tools, such as that disclosed in Crittenden, U.S. Pat. No. 6,079,457, commonly assigned with the present application and incorporated herein in its entirety by reference, function well; however, they require a source of compressed gas, such as air, and thus necessitate the use of hoses, compressed gas fittings and the like for operation. As such, the use of pneumatic tools may be limited in certain applications where, for example, the strapping operations are carried out at different locations throughout a manufacturing facility. Moreover, pneumatic tools employ pneumatic motors which can be costly, and pneumatic circuits which can be complex and require casting and machining operations in the manufacture of pneumatic circuit modules.
Accordingly, there is a need for a powered strapping tool that functions to tension strap around a load, form a seal in the overlapping courses of strap material and cut the sealed strap from its source. Desirably, such a tool is self-contained, is electrically and/or battery powered, and is thus portable and can be used throughout a facility at any location. More desirably still, such a tool can be used in a variety of operating modes.
Various embodiments of the present disclosure provide a strapping tool for tensioning and forming a sealless joint in overlapping sections of steel strap around a load that includes a body having a foot, a tensioning assembly operably mounted to the body and a sealing assembly operably mounted to the body. The tensioning and sealing assemblies have electrically powered motors.
A tensioning wheel is operably connected to the tensioner motor and a sealer is operably connected to the sealer motor. The tool includes a control system for controlling operation of the tensioning assembly and the sealing assembly. The control system is configured to operate the strapping tool in an automatic mode in which the tensioning assembly and the sealing assembly are sequentially actuated by, for example, a single action of the control system by an operator, and in a manual mode in which the tensioning assembly and the sealing assembly are sequentially actuated by multiple actions of the control system by the operator.
In an embodiment, the sealing assembly includes a die and punch cooperating with one another to cut keys in the overlapping sections of strap. The tensioner motor is operated in a reverse direction following a sealing cycle to interlock the keys cut in the overlapping sections of strap. The control system, in the automatic mode, is configured to operate in the reverse direction following the sealing assembly actuation by action of the control system to interlock the keys. In an embodiment the action can be carried out by a single action of the control system.
In an embodiment, the tensioner motor assembly is pivotally mounted to the body and is biased to move the tension wheel toward the foot.
In an embodiment, a cam shaft is operably connected to the die and includes a position switch for sensing a position of the cam shaft. The position switch is operably connected to the control system. An embodiment of the tool includes a dynamic brake to stop rotation of the sealer motor assembly at an end of the sealing cycle. The dynamic brake can be controlled by the control system.
The tool includes an actuation switch for controlling the tool. The actuation switch is operably connected to the control system which is operably connected to the tensioner motor assembly and the sealer motor assembly. The control system can include a strap tension adjusting device for varying a tension in the overlapping sections of steel strap. The control system can be configure to stop movement of the tensioning wheel based upon a setting of the strap tension adjusting device.
A control system controls a strapping tool of the type for tensioning and forming a sealless joint in overlapping sections of steel strap around a load. The control system includes control circuitry operably connected to the tensioner motor assembly and the sealer motor assembly. In an embodiment, a position switch is operably connected to the sealer to determine a position of the seal. The control system includes an actuation switch. The control system is configured to operate the strapping tool in an automatic mode in which the tensioner motor assembly and the sealer motor assembly are sequentially actuated by a single action of the actuation switch. In an embodiment, the control system is operably connected to a dynamic brake to stop movement of the sealer motor assembly when the sealer reaches a predetermined position.
In an embodiment, following a sealing cycle, the control system actuates the tensioner motor assembly in a reverse direction to secure the sealless joint.
In a manual mode the tensioner motor assembly and the sealer motor assembly are sequentially actuated by multiple actions of the actuation switch.
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.
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.
Referring now to the figures, an embodiment of the electrically powered combination strapping tool 10 is shown. The tool 10 is configured to tension steel strap S or strapping material around an object or load L, seal overlapping portions of the strap S to itself at a seal or joint J to form a tensioned loop around the load L and to cut the tensioned loop from the strap supply P. Generally, the strap S includes a feed or supply end P and a free end F that is fed around the load L and reinserted into the tool 10 to overlap the supply end P.
For purposes of the present disclosure, the term “sealless” refers to the configuration or type of seal or joint that is made in the overlapping portions of the strap. Although a “seal” is made in the strap courses, the sealless joint is made by cutting or punching interlocking keys K or sections of the courses, as illustrated in
The tool 10 includes a body 12, a tensioning section 14 and a sealing section 16. The tensioning section 14 includes a housing 18 and a first or tensioner motor assembly 20 operably mounted to the body 12. The sealing section 16 includes a sealer 21, housing 22 and a second or sealer motor assembly 24 operably mounted to the body 12. The body 12 includes a foot 26, a housing 28 and one or more handles 30 and 32 to facilitate handling and using the tool 10. One handle can be a tool opening handle 30 above the tensioner motor assembly 20 and the other an operating handle 32 mounted above the body 12. A receiver 34 is formed as part of or mounted to the body 12 for receiving a battery 36 or other power source. A temporary hold-down finger 38 can be positioned on the foot 12, opposite the tensioner motor assembly 20. The hold-down finger can be biased toward the foot 26.
The tensioning section 14 includes the tensioner motor assembly 20, which has a motor 40, such as a DC motor, and a gear housing 42 including a gear set 44 to convert the motor 40 output drive to a usable speed. The gear 44 set can include a planetary gear set (not shown) to reduce the output speed and to increase the output power or torque from the motor 40. The gear set 44 includes a final drive (not shown) that meshes with a gear (not shown) on a tension wheel 46. The tension wheel 46 is mounted normal to the final drive. The gear set 44 and final drive are housed in the gear housing 18 mounted to the tool body 12. A gripping pad 48 can be positioned in the foot 26, opposite the tension wheel 46.
The tensioner motor assembly 20, gear housing 42 and tension wheel 46 are movably mounted to the body 12 to move the tension wheel 46 toward and away from the foot 26. This permits the tool 10 to be opened to position the strap S between the foot 26 and the tension wheel 46. In an embodiment, the tensioner motor assembly 20, gear housing 42 and tension wheel 46 are pivotably mounted to the body 12 to pivot the tension wheel 46 toward and away from the foot 26. The tensioner motor assembly 20, gear housing 42 and tension wheel 46 can be biasedly mounted to the body 12, such as by a spring (not shown), to bias the tension wheel 46 toward the foot 26 and into contact with the strap S in the closed position.
The sealing section 16 includes the sealer motor assembly 24 which has a motor 50, such as a DC motor and a drive 52. In an embodiment, the drive 52 is a gear set 54 that includes a planetary gear set (not shown) that drives a cam shaft 56 through a final drive gear (not shown). The planetary gear set reduces the output speed and increases the output power or torque from the motor 50. Other drives can be used to transfer power from the motor 50 to the cam shaft 56, such as belts, chains or the like.
Cams 58 on the cam shaft 56 contact and moves a set of dies 60 in the sealing section 16. The dies 60 reciprocate toward and away from a punch 62 located on the foot 26 to bring the dies 60 into and out of contact with the overlapping course of strap S positioned between the dies 60 and the punch 62. When the dies 60 engage the strap S (in a sealing portion of the cycle), the dies 60 and punch 62 form keys K in the strap S that, when shifted longitudinally, lock into one another. An example of a sealer section 16 is illustrated in
The tool 10 is configured to permit operation in fully automatic and manual modes. To this end, the tool 10 includes a control system, shown generally at 66, to control operation of the tool 10. In an embodiment the tool 10 includes an actuation 68 switch and one or more circuits 70, 72 to control the tensioner motor 40 and the sealing motor 50. In an embodiment, the tensioner motor and sealing motor circuits 70, 72 are provided on separate boards within the tool 10. It will be appreciated that the tensioner and sealer motor boards 70, 72 can be combined on a single board.
The control system 66 can further include a cam position switch or sensor 74 to sense the position of the cam shaft 56 in the sealing section 16, a strap size/tension adjustment device 76, an anti jam device 78 and a dynamic brake 80. The cam position switch 74 is positioned to determine the position of the cam shaft 56 and thus the position of the cam lobes 58 (or cams), and consequently the dies 60 and cutter 64. The strap size/tension adjustment device 76 can be, for example, a knob-type dial adjustment provided on the tool body 12. Control of the anti jam device 78 can be incorporated within the tension/strap size adjustment dial 76. The dynamic brake 80 is associated with the sealing motor 50 to brake or stop the motor 50 when the cam shaft 56 is at a home position and to bleed power from the motor 50 at the completion of the sealing cycle. The tool 10 can further include one or more indicators, such as LEDs, to provide indication of certain functions and states of the tool. An LED indicator 82 can be positioned within or around the actuation switch 68.
Referring to
To commence a strapping cycle, the tool 10 is opened by urging or pulling the tensioner motor assembly 20 toward the tensioner handle 30 to open a gap between the tension wheel 46 and the foot 26. A lead or free end F of the strap S is positioned around the load and a supply end P of the strap S (from a strap dispenser) is positioned overlapping the free end F. The overlapping courses of strap S are positioned in the tool 10 between the tension wheel 46 and the foot 26 and between the dies 60 and punch 62 with the supply end P entering from the rear end (the tension wheel 46 end) of the tool 10 as illustrated in
In one scenario of an automatic mode, depressing and releasing the actuation switch 68 commences the operating cycle. With overlapping strap S courses positioned between the tension wheel 46 and the foot 26 and between the dies 60 and punch 62, the tension cycle starts, as at step 108, in which the tensioner motor 40 operates to drive the tension wheel 46 to draw tension in the strap S. As the tensioner motor 40 operates, the actuation switch LED 84 is illuminated. When a predetermined amount of tension is drawn (as set by using the strap size/tension adjustment knob 76), the tensioner motor 40 stops and the LED indicator 84 goes out.
The sealing cycle then starts, as at step 110, in which the sealing motor 50 operates to rotate the cam shaft 56 and the cams 58 move into contact with and move the dies 60 downward to contact the strap S. When the sealing motor 50 starts, the actuation switch LED 84 illuminates to indicate tool 10 operation. The interlocking keys K are cut by the force of the cams 58 on the dies 60 forcing the dies 60 into the strap S and forcing the strap S against the punch 62. The strap supply P end is cut to separate the looped strap S from the strap supply P.
The sealing motor 50 continues to operate, and when the cam shaft 56 completes one full (360 degree) revolution, the cam switch or sensor 74 is triggered and the sealing motor 50 turns off. The dynamic brake 80 stops the cam shaft 56 at the home position by absorbing excess energy from the sealing motor 50. The hold-down finger 38 at the foot 26 holds the strap S temporarily in place in the tool 10. Once sealing is complete, the tensioner motor 40 operates in reverse for a short period (less than about 1 second) to allow the tension in the strap S to “pull” the keys K into an interlocking arrangement (see,
Once the sealing cycle is completed, as at step 112, with the dies 60 returned to the home position and the sealing motor 50 stopped, the LED indicator 84 goes out. The tool 10 is then in the ready/sleep state.
In automatic mode, depressing and releasing the actuation switch 68 at any time during the tension and/or sealing cycles (see, steps 108 and 110), can, for example, stop the tool 10, and depressing and holding the actuation switch 68, as at step 114, can operate the tensioner motor 40 in reverse. This functions as an emergency stop of the tool 10.
The tool 10 can also be operated in manual mode in which, for example, a first depression of the actuation switch 68 commences the tension cycle, and the tensioner motor 40 stops when a predetermined tension is reached. In this example of manual operation, a second depression of the actuation switch 68 may then be required to commence the sealing cycle. The auto-stop functions (for example, depressing and/or depressing and holding the actuation switch) can again serve to stop the tool 10 and/or reverse the tensioner motor 10 in manual mode.
With reference to the trigger functions and events referenced in
(*) Automatic mode—after tensioning tool automatically seals. Manual mode—after tensioning tool waits for a second trigger event to activate sealer motor. (**) Tension knob—selects strap width, mode and option to only activate sealer motor.
As noted above, the tool 10 can include an anti jam feature 78 actuation of which can be incorporated into the strap size/tension adjusting device 76. When the anti-78 jam function is selected and the actuation switch 68 is depressed, the tensioner motor 40 operates in reverse to clear any material that may be jammed in the tool 10, between the tension wheel 46 and the foot 26. The sealing motor 50 will cycle once, also to clear any material that may be jammed in the tool 10.
The tool 10 as disclosed and described is an electrically powered tool that uses a battery 36; it will however be appreciated that the tool 10 can be configured to operate with a voltage converter (not shown) for example, for use at line voltages (e.g., 120V-240V). In addition, although the tool 10 is described as including a tensioner motor 40 and a sealing motor 50, it is contemplated that a single motor can be used to carry out both the tension and sealing functions with appropriate drives in place.
It will also be appreciated by those skilled in the art that various other automatic and manual operating scenarios are and can be contemplated in connection with the disclosed electrically powered combination hand-held strapping tool 10, and that such other operating scenarios are within the scope and spirit of the present disclosure.
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.
This application claims the benefit of and priority to U.S. Provisional U.S. Patent Application Ser. No. 62/026,865, filed Jul. 21, 2014, the disclosure of which is incorporated herein in its entirety.
Number | Name | Date | Kind |
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5694984 | Cheung | Dec 1997 | A |
6079457 | Crittenden | Jun 2000 | A |
6338375 | Harada | Jan 2002 | B1 |
6966255 | Crittenden | Nov 2005 | B1 |
7556129 | Nix | Jul 2009 | B2 |
8281711 | Haberstroh | Oct 2012 | B2 |
Number | Date | Country |
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1134903 | Jan 2004 | CN |
101678903 | Mar 2010 | CN |
2711301 | Mar 2014 | EP |
2016014167 | Jan 2016 | WO |
Entry |
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International Preliminary Report on Patentability issued by the ISA/EPO in connection with PCT/US2015/035477 dated Feb. 2, 2017. |
International Search Report and Written Opinion of the International Searching Authority dated Jan. 5, 2016, in PCT/US2015/035477. |
Number | Date | Country | |
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20160016682 A1 | Jan 2016 | US |
Number | Date | Country | |
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62026865 | Jul 2014 | US |