The foregoing aspects and other features of the invention are explained in the following description, taken in connection with the accompanying drawings, wherein:
Referring to
The tool 10 is a hand-held hydraulically operated, battery powered tool. However, features of the invention could be used in a non-battery operated tool. The tool 10 is a crimping tool for crimping an electrical connector onto a conductor, such as an electrical cable for example. However, features of the invention could be used in any suitable type of hydraulically operated tool, such as a cutting tool for example.
Referring also to
Referring also to
The frame 36 forms hydraulic conduits from a piston channel 42 to the rear end of the ram at the ram cylinder 38. Various check valves and a release and/or relief valve are also preferably located in the hydraulic conduits. An exterior side of the frame 36 also forms part of the reservoir 20. A bladder 44 is attached at an annular recess 46 of the frame 36 to form the reservoir 20. However, in an alternate embodiment any suitable type of hydraulic fluid reservoir or hydraulic fluid supply could be provided.
The pump 12 comprises a piston pump member 48 located in the piston channel 42. The piston pump member 48 extends out of the rear end of the frame 36 and is biased outward by a spring 50. The piston member 48 is arranged in the piston channel 42 for reciprocating forward and backward movement. As the piston member 48 moves rearward it draws hydraulic fluid into the piston chamber 42 from the reservoir 20 through the conduit 70 and past check valve 72. As the piston member 48 moves forward, it pushes that hydraulic fluid towards the ram cylinder 38 through conduit 74 and past check valve 76.
The rear end of the frame 36 comprises a pivot member hole 52 and at least one spring hole 54. A pivot member 56 is pivotably located in the hole 52. In this embodiment the pivot member 56 is a ball. However, in alternate embodiments any suitable pivotable connection of the wobble plate 60 to the rear end of the frame 36 could be provided. A spring 58, such as a coil spring, is located in each of the holes 54. In this embodiment only one coil spring 58 is provided. However, in alternate embodiments two to five or more coil springs could be provided. The spring 58 is located on an opposite side of the rear end of the frame 36 from the piston member 48 with the pivot member 56 therebetween.
The transmission 16 generally comprises the wobble plate 60, a transmission case 62, a bevel disk 64 and a gearbox 66. The gearbox 66 is connected to an output shaft of the motor 14. The bevel disk 64 is connected to an output shaft 68 of the gearbox 66. The front end of the bevel disk 64 has an angled front face. The face is angled relative to the center axis. The front end also comprises a counter balance pocket.
The user interface or control 25 includes an activation lever 94 pivotably connected to the frame 36. The lever 94 is preferably biased by a spring in an outward position. However, in alternate embodiments, any suitable type of user activation control could be provided. When the lever 94 is depressed by a user, the motor 14 is activated.
As seen in
The tool 10 also includes a hydraulic fluid relief system 96. The relief system 96 generally comprises a relief valve 98 connected to the conduit system of the frame 36 between the ram cylinder 38 and the reservoir 20. In this embodiment the relief valve 98 is mounted in the conduit 90 proximate the conduit 92. Referring also to
When hydraulic pressure in the ram cylinder 38 reaches a predetermined value, the front of the valve cone 102 is unseated from the valve seat 112 (due to hydraulic pressure at the inlet port 106) and hydraulic fluid is allowed to flow from the ram cylinder 38, through the inlet port 106, out the outlet port 108 and back to the reservoir 20 through conduit 92. If the predetermined pressure is not reached, the relief valve 98 remains closed. The relief valve 98 may be adapted to generate an audible sound, such as a “pop” when it is opened. The relief valve 98 could also be adapted to stay open until a predetermined lower hydraulic pressure is reached.
In addition to the audible signaling system noted above, the tool 10 includes a second signaling system comprising a tactile feedback system. In this embodiment the tactile feedback system comprises the lever 84, the drain pin 80 and the spring of the lever 84. The tactile feedback system is coupled to the conduit system and is adapted to signal a user of an occurrence of a predetermined event. For example, the predetermined event could be the relief valve 98 being actuated or a predetermined hydraulic pressure being reached.
The tactile feedback system provides tactile feedback to a hand of a user because the hand of the user will be contacting the lever 84 while the user is actuating the lever 94. More specifically, when the valve 98 opens, some of the hydraulic fluid from the ram cylinder 38 will be pushed into the conduit 88 and push the drain pin 80 outward. The lever 84 will move outward with the spring of the lever 84 being deflected. When the valve 98 closes again, the spring of the lever 84 will move the lever back to its home position; back inward. Because of the reciprocating motion of the piston pump member 48, the valve 98 will repeatedly open and close until the user stops actuating the lever 94. Thus, the tactile feedback system, in this embodiment, will result in the lever 84 moving up and down in a type of vibratory effect on the user's hand; because the valve 98 will repeatedly open and close. However, in an alternate embodiment the tactile feedback might not be vibratory.
In the embodiment described above, the tool has a signaling system for signaling a user of an occurrence of a predetermined event and, more specifically, the signaling system is adapted to generate at least two different signals to the user. In the embodiment described, the two signals include an auditory signal and a tactile signal. However, in alternate embodiments, more than two types of signals could be provided, and the signals could include signals other than auditory and/or tactile, such as visual for example. In another type of alternate embodiment, only a tactile signaling system might be provided.
The invention can relate to a battery powered hydraulic crimp tool. The invention can provide tactile feedback to the operator which indicates that a crimp is complete. Tactile feedback can be generated once the tool's predetermined relief valve set pressure has been achieved.
With the embodiment described above, the battery powered hydraulic crimp tool can be powered by a DC battery coupled to a DC motor which has an output shaft coupled to a gearbox which also has an output shaft. As the shaft rotates, the bevel disk rotates which rotates on the thrust bearing and transfers rotary motion into linear motion of the wobble plate. This activity causes the pump and pump spring to reciprocate. This reciprocating motion pumps hydraulic fluid from the reservoir to the rearward section of the piston ram. As the pump moves in a direction toward the rear of the tool fluid is drawn from the reservoir through the inlet check valve. As the pump moves in a direction towards the front of the tool, fluid is pushed through the outlet check valve and behind the piston ram into the cylinder. As fluid fills the cylinder, the piston ram advances towards the front of the tool forcing the carrier and rollers onto the cam surface of the jaws. As this happens the jaws close and the crimp groove or dies (not shown) crimp the work piece.
Pressure in the cylinder will rise to a predetermined relief valve set pressure. As pressure rises in the cylinder port, the relief valve is subjected to the same pressure as the cylinder. When the pressure is at the predetermined valve set pressure, the valve cone lifts off of the valve seat and the cone shuttles away from port 106 and allows fluid to pass through ports 108 back to the reservoir. As this happens some fluid is permitted to pass over the valve body at a small diameter annular passageway created by reduced outer diameter section 111 and into the conduit holding the drain pin 80.
The resulting hydraulic pressure in the conduit holding the drain pin 80 is much lower than the hydraulic pressure in the cylinder 38 because the majority of escaping fluid is channeled to the reservoir. However, there is still ample pressure to push on the drain pin. The pressure that is applied to the drain pin happens over a very small period of time and causes the drain pin to shuttle in a direction opposite to the drain valve. The drain valve spring is sized to be relatively stiff and the pressure pulse into conduit holding the drain pin 80 cannot provide enough force to move this spring; so the drain valve remains closed. As the drain pin shuttles in a direction opposite to the drain valve, it bumps the retract trigger which provides the tactile feedback to the operator that the predetermined relief valve pressure setting is achieved and, therefore, the crimp is complete.
In addition it should also be noted that an operator can abort the crimp cycle at any point in time by simply activating the retract lever and depress the drain pin; thus actuating the drain valve. When this occurs fluid is allowed to drain from the cylinder through conduits, through the drain valve, and through the annular passageway at the valve 98 back to the reservoir. This activity will cause the crimp jaws to open.
In one type of alternate embodiment the pump could be provided outside of the tool. In another type of alternate embodiment, the tool could be a pneumatic tool rather than a hydraulic tool. Preferably the tool is portably hand held, but in an alternate embodiment only a portion of the tool might be held by a hand of the user.
Referring now also to
The drain trigger, or drain trigger section, 118 is stationarily mounted on the first end 124 of the rocker mechanism 120 to form the retract lever 84. The activation trigger, or activation trigger section, 116 is pivotably mounted on the center section 122 and/or the pivotal mount 114.
As seen with reference to
As seen with reference to
One concept is the three beams all sharing a common pivot point or pivot axis (axis of the mount 114). Further, the drain trigger portion 118 of the rocker switch is longer than the activation trigger portion 116, so it is more likely to snag or contact another object. Once the drain trigger 118 contacts another object and is depressed, it is virtually impossible for the activation trigger portion 116 of the rocker switch to depress and activate the tool 10. In addition, a basic rocker switch is split into two sections instead of one solid piece of plastic. This allows for independent movement of at least one of the rocker switch arms.
The invention ensures the drain trigger 118 on a hydraulic crimping tool 10 will not press the drain button 80 while the activation trigger 116 is engaged. If both are depressed at the same time the tool's 10 hydraulic fluid will cycle through the tool 10 without the pump 12 building pressure. Lying under the drain and activation triggers 118, 116 is the rocker mechanism 120. All three components 116, 118, 120 share a common pivot point. There is some space (about a few of degrees) between the activation trigger 116 and the rocker 120. When the activation trigger 116 is engaged it will first rotate through this open space before it contacts the rocker 120. When the activation trigger 116 comes in contact with the rocker 120, the rocker 120 will then raise on the opposite side, therefore, moving the drain button contact surface 128 away from the drain button 80. About a fraction of a degree later (or about a few degrees later), the activation trigger 116 will contact the electrical switch and activate the motor 14.
The drain button contact surface 128 could be located either on the rocker mechanism 120 or on the drain trigger itself 118. If the drain button contact surface 128 is located on the rocker 120 as it is shown, it can also act as a support rib for the drain trigger 118.
When the drain trigger 118 is depressed, the rocker mechanism 120 will rotate up to the activation trigger 116 but will not cause the activation trigger 116 to rotate. If the drain and activation triggers 118, 116 were one solid piece, they would act as a rocker mechanism, but when one is depressed it would always cause the other to rise by a ratio of their links, which is not desirable to the end user. By designing the triggers 116, 118 such that the drain trigger 118 is tallest (farthest away from the axis of the mount 114) if the tool 10 is laid on a flat surface, it is more likely that the drain trigger 118 would depress first and rotate the rocker mechanism 120 so that its opposite side 126 rises and restricts the activation trigger 116 from contacting the electrical switch. This forms a type of lockout mechanism. This type of control could be used with or without the vibration indicator.
It should be understood that the foregoing description is only illustrative of the invention. Various alternatives and modifications can be devised by those skilled in the art without departing from the invention. Accordingly, the invention is intended to embrace all such alternatives, modifications and variances which fall within the scope of the appended claims.
This application claims priority under 35 U.S.C. §119(e) to U.S. provisional patent application No. 60/851,525 filed Oct. 12, 2006 which is hereby incorporated by reference in its entirety.
Number | Date | Country | |
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60851525 | Oct 2006 | US |