PORTABLE PIPE THREADER

Abstract

A portable pipe threader includes a stand upon which a pipe is supported, a carriage supported by the stand, a spindle mounted to the carriage for clamping the pipe against rotation such that the pipe is stationary, a plurality of pipe threading tools coupled to the carriage and selectively operable to perform work on the pipe, a drive assembly including a plurality of brushless direct current (BLDC) motors. Each of the plurality of BLDC motors is mounted to one of the plurality of pipe threading tools and is operable to provide torque to a corresponding one of the plurality of pipe threading tools to rotate the corresponding one of the plurality of pipe threading tools relative to the pipe. A battery pack is supported by the stand and in selective electrical communication with the plurality of BLDC motors to provide electrical power to the plurality of motors.

Claims

1. A portable pipe threader comprising: a stand upon which a pipe is supported; a carriage supported by the stand; a spindle mounted to the carriage for clamping the pipe against rotation such that the pipe is stationary, a plurality of pipe threading tools coupled to the carriage and selectively operable to perform work on the pipe; a drive assembly including a plurality of brushless direct current (BLDC) motors, each of the plurality of BLDC motors mounted to one of the plurality of pipe threading tools, each of the plurality of BLDC motors being operable to provide torque to a corresponding one of the plurality of pipe threading tools to rotate the corresponding one of the plurality of pipe threading tools relative to the pipe; and a battery pack supported by the stand and in selective electrical communication with the plurality of BLDC motors to provide electrical power to the plurality of motors.

2. The portable pipe threader of claim 1, wherein the drive assembly further includes a plurality of gearboxes, each of the plurality of gearboxes corresponding to one of the plurality of BLDC motors, and wherein each of the plurality of gearboxes is configured to provide torque to the corresponding one of the plurality of pipe threading tools to rotate the corresponding one of the plurality of pipe threading tools relative to the pipe.

3. The portable pipe threader of claim 2, further comprising an electronic speed selection switch configured to selectively activate one of the plurality of BLDC motors and control a relative speed at which the corresponding one of the plurality of pipe threading tools are rotated.

4. The portable pipe threader of claim 3, wherein the electronic speed selection switch is a pedal.

5. The portable pipe threader of claim 1, wherein the plurality of pipe threading tools includes a die holder having a plurality of dies to cut threads on the pipe, a cutter to trim excess pipe, and a reamer to smooth edges of a newly threaded or cut pipe.

6. The portable pipe threader of claim 1, further comprising: a lubricant port mounted on the carriage; and a lubrication system fluidly connected to the lubricant port to provide a lubricant to one of the pipe or one of the plurality of pipe threading tools.

7. A portable pipe threader comprising: a carriage supported by a support surface; a spindle mounted to the carriage for clamping a pipe against rotation such that the pipe is stationary; a first pipe threading tool coupled to the carriage, the first pipe threading tool including a die holder having a plurality of dies configured to cut threads on the pipe; a second pipe threading tool coupled to the carriage, the second pipe threading tool including a cutter or a reamer, the cutter configured to trim excess pipe, the reamer configured to smooth edges of a newly threaded pipe; a drive assembly including a first brushless direct current (BLDC) motor mounted to the first pipe threading tool, the first BLDC motor being operable to provide torque to the first pipe threading tool to rotate the first pipe threading tool relative to the pipe, and a second brushless direct current BLDC motor mounted to the second pipe threading tool, the second BLDC motor being operable to provide torque to the second pipe threading tool to rotate the second pipe threading tool relative to the pipe; and a battery pack in selective electrical communication with the first BLDC motor and the second BLDC motor to provide electrical power to the first BLDC motor and the second BLDC motor.

8. The portable pipe threader of claim 7, wherein the drive assembly further includes a first gearbox corresponding to the first BLDC motor and a second gearbox corresponding to the second BLDC motor, and wherein the first and second gearboxes are configured to provide torque to rotate the respective first and second pipe threading tools relative to the pipe.

9. The portable pipe threader of claim 7, further comprising an electronic speed selection switch configured to selectively activate one of the first or second BLDC motors and control a relative speed at which the selected one of the first or second pipe threading tools are rotated.

10. The portable pipe threader of claim 9, wherein the electronic speed selection switch is a pedal.

11. The portable pipe threader of claim 7, wherein the second pipe cutting tool is a cutter, further comprising a third pipe threading tool coupled to the carriage, the third pipe threading tool including a reamer configured to smooth edges of a newly threaded or cut pipe, and wherein the drive assembly further includes a third brushless direct current BLDC motor mounted to the third pipe threading tool, the third BLDC motor being operable to provide torque to the third pipe threading tool to rotate the third pipe threading tool relative to the pipe, the battery pack in selective electrical communication with the third BLDC motor to provide electrical power to the third BLDC motor.

12. The portable pipe threader of claim 11, wherein the drive assembly further includes a third gearbox corresponding to the third BLDC motor, and wherein the third gearbox is configured to provide torque to the third pipe threading tool to rotate the third pipe threading tool relative to the pipe.

13. The portable pipe threader of claim 12, further comprising an electronic speed selection switch configured to selectively activate one of the first, second, or third BLDC motors and control a relative speed at which the selected one of the first, second, or third pipe threading tools are rotated.

14. The portable pipe threader of claim 13, wherein the electronic speed selection switch is a pedal.

15. The portable pipe threader of claim 7, further comprising: a lubricant port mounted on the carriage; and a lubrication system fluidly connected to the lubricant port to provide a lubricant to one of the pipe or one of the first or second pipe threading tools.

16. A portable pipe threader comprising: a carriage supported by a support surface; a spindle mounted to the carriage for clamping a pipe against rotation such that the pipe is stationary; a plurality of pipe threading tools coupled to the carriage and selectively operable to perform work on the pipe; a drive assembly including a plurality of brushless direct current (BLDC) motors, each of the plurality of BLDC motors mounted to a corresponding one of the plurality of pipe threading tools, each of the plurality of BLDC motors being operable to provide torque to the corresponding one of the plurality of pipe threading tools to rotate the corresponding one of the plurality of pipe threading tools relative to the pipe; a battery pack in selective electrical communication with the plurality of BLDC motors to provide electrical power to the plurality of BLDC motors; and an electronic speed selection switch configured to selectively activate one of the plurality of BLDC motors and control a relative speed at which the corresponding one of the plurality of pipe threading tools is rotated.

17. The portable pipe threader of claim 16, wherein the drive assembly further includes a plurality of gearboxes, each of the plurality of gearboxes corresponding to one of the plurality of BLDC motors, and wherein each of the plurality of gearboxes is configured to provide torque to the corresponding one of the plurality of pipe threading tools to rotate the corresponding one of the plurality of pipe threading tools relative to the pipe.

18. The portable pipe threader of claim 16, wherein the electronic speed selection switch is a pedal.

19. The portable pipe threader of claim 16, wherein the plurality of pipe threading tools includes a die holder having a plurality of dies to cut threads on the pipe, a cutter to trim excess pipe, and a reamer to smooth edges of a newly threaded or cut pipe.

20. The portable pipe threader of claim 16, further comprising: a lubricant port mounted on the carriage; and a lubrication system fluidly connected to the lubricant port to provide a lubricant to one of the pipe or one of the plurality of pipe threading tools.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0010] FIG. 1 is a top view of a portable pipe threader in accordance with an embodiment of the invention.

[0011] FIG. 2 is a top view of a portable pipe threader in accordance with another embodiment of the invention.

[0012] FIG. 3 is a top view of a portable pipe threader in accordance with yet another embodiment of the invention.

[0013] FIG. 4 is a schematic view of a lubrication system for use with any of the portable pipe threaders of FIGS. 1-3.

[0014] FIG. 5 is a perspective view of one of the pipe threaders of FIGS. 1-3 including a male quick-connect coupling to which a corresponding female quick-connect coupling of the lubrication system of FIG. 4 may be connected.

[0015] FIG. 6 is a perspective view of the pipe threader of FIG. 1.

[0016] Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting.

DETAILED DESCRIPTION

[0017] With reference to FIG. 1, a portable pipe threader 10 includes a stand 68 (FIG. 5) and a carriage 42 supported by the stand 68 having a plurality of pipe threading tools 46, 50, 54 supported by the carriage 42. The pipe threader 10 further includes a drive assembly 18 mounted to the stand 68 having a motor 22 (e.g. a brushless direct current motor), a gear box 26 coupled to the motor 22 having an output gear (not shown), and an electronic speed selection switch, such as a pedal 30, that selectively controls the drive assembly 18. The drive assembly 18 is powered by a battery pack 38 supported by the stand 68 in selective electrical communication with the motor 22 to provide electrical power to the motor 22. In some constructions, the battery pack 38 and the motor 22 can be configured as an 18 Volt high power battery pack and motor, such as the 18 Volt high power system disclosed in U.S. patent application Ser. No. 16/045,513 filed on Jul. 25, 2018 (now U.S. Patent Application Publication No. 2019/0044110), the entirety of which is incorporated herein by reference. In other constructions, the battery pack 38 and the motor 22 can be configured as an 80 Volt high power battery pack and motor, such as the 80 Volt battery pack and motor disclosed in U.S. patent application Ser. No. 16/025,491 filed on Jul. 2, 2018 (now U.S. Patent Application Publication No. 2019/0006980), the entirety of which is incorporated herein by reference. In such a battery pack 38, the battery cells within the battery pack 38 have a nominal voltage of up to about 80 V. In some embodiments, the battery pack 38 has a weight of up to about 6 lb. In some embodiments, each of the battery cells has a diameter of up to 21 mm and a length of up to about 71 mm. In some embodiments, the battery pack 38 includes up to twenty battery cells. In some embodiments, the battery cells are connected in series. In some embodiments, the battery cells are operable to output a sustained operating discharge current of between about 40 A and about 60 A. In some embodiments, each of the battery cells has a capacity of between about 3.0 Ah and about 5.0 Ah. And, in some embodiments of the motor 22 when used with the 80 Volt battery pack 38, the motor 22 has a power output of at least about 2760 W and a nominal outer diameter (measured at the stator) of up to about 80 mm.

[0018] With reference to FIG. 1, the drive assembly 18 further includes a drive element 34 (e.g., a belt) coupled to the gear box 26 and powered by the motor 22. The motor 22 is configured to supply torque to the output gear of the gear box 26, rotatably driving the drive element 34 to rotate a pipe 14 or a selected one of the plurality of pipe threading tools. The pedal 30 is operable to activate the motor 22 and control a relative speed at which the pipe 14 rotates. In other embodiments, the relative speed at which the pipe 14 rotates can be selected using an electronic speed selection switch other than the pedal 30 (e.g., dial, key pad, button, etc.; not shown).

[0019] With reference to FIGS. 1 and 5, the portable pipe threader 10 further includes a spindle 60 in which the pipe 14 is clamped. The drive element 34 interconnects the spindle 60 and the output gear of the gear box 26. Thus, torque from the motor 22 is transferred to the spindle 60, causing it and the pipe 14 to rotate, via the gear box 26 and the drive element 34. With reference to FIG. 1, the plurality of pipe threading tools 46, 50, 54 includes a die holder 46 having a plurality of dies (not shown) to cut threads on the pipe 14, a cutter 50 to trim excess pipe 14, and a reamer 54 to smooth edges of the threaded or cut pipe 14. The plurality of pipe threading tools 46, 50, 54 remain stationary on the carriage 42 while the pipe 14 is rotated by the spindle 60. The portable pipe threader 10 also includes a lubricant port 64 (e.g., a male quick-connect coupling) configured to fluidly connect to a lubrication system 300 (FIG. 4) to provide lubricant during a threading, cutting, or reaming operation using, respectively, the die holder 46, the cutter 50, or the reamer 54.

[0020] FIG. 2 illustrates a portable pipe threader 110 according to an alternative embodiment. Like components and features as the pipe threader 10 of FIG. 1 will be used plus 100. The portable pipe threader 110 includes a stand 68 (FIG. 5) and a carriage 142 supported by the stand 68. The pipe threader 110 includes a spindle 160 to which a pipe 114 is clamped and a plurality of pipe threading tools 146, 150, 154 supported by the carriage 142. However, rather than the spindle 160 being rotated, the pipe threader 110 includes a drive assembly 118 mounted to the carriage 142 with the pipe threading tools 146, 150, 154 for rotating the individual tools 146, 150, 154.

[0021] More specifically, the drive assembly 118 includes a plurality of motors 122, each having a corresponding gear box 126, to directly provide torque to each of the plurality of pipe threading tools 146, 150, 154 to rotate the tools 146, 150, 154 relative to the stationary pipe. The pipe threader 110 further includes a pedal 130 to selectively control the drive assembly 118. In particular, the pedal 130 is operable to activate any of the motors 122 and control a relative speed at which the pipe 114 and the selected one of the pipe threading tools 146, 150, 154 are rotated. The pipe threader also includes a battery pack 138 supported by the stand 68 (FIG. 5) in selective electrical communication with each of the motors 122 to provide electrical power thereto.

[0022] FIG. 3 illustrates a portable pipe threader 210 according to an alternative embodiment. Like components and features as the pipe threader 10 of FIG. 1 will be used plus 200. The portable pipe threader 210 includes a stand 68 (FIG. 5) and a carriage 242 supported by the stand 68. The pipe threader 210 includes a spindle 260 to which a pipe 214 is clamped and a plurality of pipe threading tools 246, 250, 256 supported by the carriage 242. However, rather than the spindle 260 being rotated, the pipe threader 210 includes a drive assembly 218 mounted to the stand 68 for selectively rotating one of the pipe threading tools 246, 250, 256.

[0023] More specifically, the drive assembly 218 includes a motor 222, a gear box 226 coupled to the motor having an output gear (not shown), a pedal 230 that selectively controls the drive assembly 218, and a battery pack 238 supported by the stand 68 in selective electrical communication with the motor 222 to provide electrical power to the motor 222. The drive assembly 218 further includes a common driveline 234 interconnecting the motor 222 and the plurality of pipe threading tools 246, 250, 254 for selectively providing torque from the motor 222 to one of the pipe threading tools 246, 250, 254. The pedal 230 is operable to activate the motor 222 and control a relative speed at which the pipe 214 and the selected one of the pipe threading tools 246, 250, 254 are rotated.

[0024] With reference to FIGS. 1 and 4, the lubricant ports 64, 164, 264 of any of the pipe threaders 10, 110, 210 shown in FIGS. 1-3 are configured to fluidly connect to a lubrication system 300 to receive lubricant therefrom. In some embodiments, the lubrication system 300 is separate and detachable from the threader 10. And, in other embodiments, the lubrication system 300 is integrated with the threader 10. As shown in FIG. 4, the lubrication system 300 includes a pump 330 (e.g. self-priming positive displacement) that draws lubricant from a tank 315 through a plurality of tubes 335. A battery pack 325, which is separate from any of the battery packs 38, 138, 238, provides electrical power to the pump 330. In other embodiments of the lubrication system 300, the pump 330 may receive electrical power from the same battery packs 38, 138, 238 powering the electric motors 22, 122, 222, respectively. The lubrication system 300 also includes a connector 310 (e.g., a female quick-disconnect coupling) downstream of the pump 330 to receive pressurized lubricant therefrom and a regulator valve 320 having an inlet in fluid communication with the tube 335 interconnecting the pump 330 and the connector 310, and an outlet in fluid communication with the tube 335 interconnecting the tank 315 and the pump 330. As such, during operation of the pump 330, the regulator valve 320 limits the flow of pressurized lubricant sent to the connector 310 by recirculating some of the pressurized lubricant to the inlet of the pump 330. As explained in further detail below, the connector 310 can fluidly connect the lubrication system 300 to either a hand-held lubrication system 400 (FIG. 4) or any of the lubricant ports 64, 164, 264 on the respective pipe threaders 10, 110, 210.

[0025] With continued reference to FIGS. 1 and 4, the hand-held lubrication system 400 includes a hand-operated pump 410 configured to apply lubricant to the pipe 14 (FIG. 1) as it is threaded, cut, or reamed, and a connector 420 (e.g., a male quick-connect coupling) capable of fluidly connecting to the corresponding connector 310 of the lubrication system 300 (FIG. 4). In this manner, the hand-operated pump 410 can be used to draw lubricant from the tank 315 while bypassing the pump 330. The hand-operated pump 410 can be used, for example, by an operator of the pipe threader 10 desiring manual control over when and where lubricant is provided to the pipe during a threading, cutting, or reaming operation. Alternatively, if the operator desires lubricant to be automatically applied to the pipe, the connector 310 of the lubrication system 300 can be attached to any of the lubricant ports 64, 164, 264 of the respective pipe threaders 10, 110, 210, in which case the pump 330 is operated to provide pressurized lubricant to the pipe threaders 10, 110, 210 for discharge to the pipe through internal passageways in the pipe threaders 10, 110, 210. In other embodiments, the pump 330 may be used to provide a pressurized flow of lubricant to the pump 410, which could be used as a hand-held dispenser by the operator of the threader 10 to start and stop the flow of the lubricant, to manually direct the lubricant discharged from the pump 330 to the pipe.

[0026] With reference to FIG. 6, the pipe threader 10 includes a housing 51 in which the drive assembly 18 is located, a first set of guide rails 44 extending from a first end of the housing 51 in a first direction, and a second set of guide rails 45 extending from an opposite, second end of the housing 51 in a second direction. The first set of guide rails 44 is configured to support the carriage 42, which is slidable along the rails 44 to position the pipe threading tools 46, 50, 54 relative to the pipe 14. The housing 51 further includes a battery receptacle 53 recessed within the housing 51 and located on a side 57 of the housing 51 that is oriented parallel with the first and second set of guide rails 44, 45. The recessed battery receptacle 53 coincides with a gap 55 defined by the housing 51 between the first and second sets of guide rails 44, 45. The battery receptacle 53 defines a battery insertion axis 56 transverse to the first and second sets of guide rails 44, 45 along which the battery pack 38 is slidably received to electrically power the motor 22. When the battery pack 38 is connected to the battery receptacle 53, the battery pack 38 is partially recessed within the housing 51 and located within the gap 55 between the first and second sets of guide rails 44, 45.

[0027] In some embodiments of the pipe threader 10, the carriage 42 can alternatively be supported on the second set of guide rails 45 and slidable in the second direction.

[0028] Various features of the invention are set forth in the following claims.