The present invention is directed to a device for rotating a die, such as but not limited to, a trim die.
It is well known that dies of various design are used in a number of different stamping, forming, and/or trimming processes. These processes may involve, without limitation, the creation and/or alteration of sheet metal parts or cast parts.
It would be understood by one of skill in the art that there may be various occasions within such a process wherein an associated die needs to be at least partially rotated (i.e., rolled-over to an inverted or partially inverted orientation). One such example involves a trimming die used in a cast part trimming operation, where gates, runners, flash, etc., are trimmed/removed from a cast part. During such an operation, it is common for the trimmed part to be removed from the die and for the die to subsequently traverse to a position where it is at least partially rotated so that the trimmed gates, runners, flash, etc., are dumped into a pit or other collection receptacle for transfer to a furnace for remelting.
It would also be understood by one of skill in the art that such dies are typically very heavy and, therefore, the transfer and particularly rotation thereof may be difficult to accomplish smoothly. For example, when rotating a die, it is generally difficult to smoothly terminate the inverting rotational motion or the return (reverting) rotational motion of the die due to the inertia and momentum associated therewith. Rather, the use of known systems and methods for accomplishing die rotation typically results in an abrupt and jarring termination of an inverting or reverting operation, typically from the die or a component to which it is coupled impacting a hard stop. This may lead to damage to the die being rotated and/or to the device used to rotate the die.
Therefore, it would be desirable to provide a system and method for rotating a die that avoids the aforementioned jarring movement. Ideally such a system would also be robust, reliable, easy to service and troubleshoot, and inexpensive to maintain. A die rotation system of the present invention is such a system.
A die rotation system of the present invention is capable of smoothly rotating (i.e., rolling over) a die to an inverted (meaning wholly or partially inverted) position in a controlled manner and without the undesirable jarring or impact effects described above. A system of the present invention may be associated with or completely separate from other devices or systems that are used to transfer the die between various positions, such as trimming, unloading, and inverted positions.
A system of the present invention generally includes a roll-over unit that is coupled to a pivotable die support structure (e.g., roll frame) to which a die is temporarily and releasably secured. Embodiments of the roll-over unit are powered by a motor coupled to a drive mechanism. In one exemplary embodiment, the drive motor is a hydraulic motor, which turns a drive sprocket to which is connected a drive chain. The drive chain is used to rotate an inversion sprocket that is coupled, such as by a shaft, to the roll frame. Consequently, operation of the drive motor causes a corresponding rotation of the inversion sprocket and a rotation (flipping) of the roll frame and associated die.
The degree of die rotation may be controlled by use of a limit switch, proximity switch, or some other sensor adapted to detect die rotation and cause a reversal thereof once the die reaches some predetermined inversion point. For example, upon reaching a desired inversion point, a limit switch may be tripped, which causes a reversal in the direction of drive motor rotation (e.g., by reversing the direction of flow of hydraulic fluid) and a corresponding return (reversion) of the die to its upright position.
Embodiments of the present invention also include a deceleration assembly that acts to smoothly terminate the inversion and reversion rotational motion of the die. That is, the deceleration assembly functions to smoothly decelerate and halt die inversion/reversion so that the aforementioned jarring and impact effects of known systems are avoided.
To this end, embodiments of the present invention may be equipped with deceleration valves that, when actuated, meter (restrict) the flow of hydraulic fluid to slow the rotational movement of the die and reduce or eliminate impact forces associated with the end point of die inversion/reversion.
In one embodiment, a pair of deceleration valves may be located near the inversion sprocket. The deceleration valves may be equipped with plungers or similar actuators. A rack gear may be positioned near the deceleration valves such that movement of the rack gear by some amount in one direction will actuate one of the deceleration valves. Movement of the rack gear in an opposite direction will have the same effect on the other deceleration valve. The rack gear may be linearly driven by rotation of a corresponding pinion coupled to the inversion sprocket. The deceleration assembly may also be associated with position sensors (e.g., limit switches, proximity switches) and appropriate actuating elements that interact to reverse movement of the die. Alternatively, these position sensors may be located elsewhere.
In addition to the features mentioned above, other aspects of the present invention will be readily apparent from the following descriptions of the drawings and exemplary embodiments, wherein like reference numerals across the several views refer to identical or equivalent features, and wherein:
As stated above, a system and method of the present invention may be used to rotate a variety of die types. As an example, a trim die 5 for removing gates, runners, flash, etc., from a cast part is shown in
As shown in
When the lower die half 10 reaches the position shown in
An exemplary roll-over unit 25 is illustrated in more detail in
As shown in
The relationship of the roll-over unit 25 to the roll frame 20, and use thereof to rotate the lower die half 10 is most clearly depicted in
During a rotation operation, the lower die half 10 may be temporarily secured to the roll frame 20 in various ways. In this particular example, the lower die half 10 is equipped with guide blocks (not shown) that ride on and capture substantially T-shaped guide rails (not visible in
Referring now to
As part of the deceleration assembly 100, a rack gear 135 is mounted to a frame or similar element (not shown) located rearward of the inversion gear 45. An associated pinion (e.g., spur gear) 140 is coupled to a rear of the inversion gear 45 or to a shaft portion thereof and positioned to be engaged with the rack gear 135.
In operation, hydraulic fluid supplied to the drive motor 35 from a pressurized source (not shown) either passes through the deceleration valves 105, 110 or can be otherwise metered by the deceleration valves 105, 110. With the roll frame 20 engaged with the roll-frame engagement and rotation element 50 of the roll-over unit 25, pressurized hydraulic fluid is supplied to the drive motor 35, causing the powered rotation thereof. This produces a corresponding rotation of the drive gear 40 and the inversion gear 45, which causes a rotation of the roll frame 20 and lower die half 10 secured thereto (see
As the inversion gear 45 rotates, the pinion 140 also rotates, thereby causing a linear translation of the rack gear 135 toward one deceleration valve 105 or the other 110 (depending on the direction of rotation of the inversion gear 45). For example, referring to
The same slow and controlled stopping of rotational die movement occurs when the die is thereafter rotated (reverted) to its normal upright position. That is, as the inversion gear 45 is rotated clockwise to revert the lower die half 10 in this particular example, the pinion 140 causes the rack gear 135 to move linearly toward the reversion deceleration valve 110. When the lower die half 10 reaches some selected point prior to its normal operating position, the rack gear 135 will contact and depress the plunger 130 of the reversion deceleration valve 110 (see
As should be apparent from the drawing figures, the spacing between the deceleration valves 105, 110, the length of the rack gear 135, the pitch of the rack gear 135 and pinion 140, and/or other parameters of the deceleration assembly 100 and/or roll-over unit 25 may be adjusted to ensure that the appropriate deceleration valve 105, 100 is activated by the rack gear 135 at the proper time.
The overall degree of rotation of the roll frame 20 and associated lower die half 10, may be controlled through the use of sensors. In this particular exemplary embodiment, those sensors are in the form of limit switches 150, 155. In other embodiments, the sensors may be proximity switches, photo eyes, etc. The sensors may be located in various places so as to be properly activated.
Referring to
While certain embodiments of the present invention are described in detail above, the scope of the invention is not to be considered limited by such disclosure, and modifications are possible without departing from the spirit of the invention as evidenced by the following claims:
This application claims the benefit of U.S. Provisional Application No. 61/500,968, which was filed on Jun. 24, 2011 and is incorporated by reference herein.
Number | Date | Country | |
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61500968 | Jun 2011 | US |