Some hinged covers, due to geometry and kinematics, use a pre-tensioned spring to keep the cover in an open and/or closed position. The pre-tensioned spring is deflected to produce mechanical force throughout the motion of the cover and to maintain the position of the hinged cover. However, the use of a pre-tensioned spring can have a number of disadvantages. During assembly, the spring is pre-tensioned by deflecting the spring. The force in the spring is maintained while the spring is connected to the various components of the device. Before it is secured to the device, the spring can be suddenly released from its pre-tensioned state. This sudden release of the spring can result in damage to surrounding components, catapulting of the spring into the air, and injury to technicians. After the cover is assembled, the pre-tensioned spring can complicate maintenance procedures. The cover may need to be removed for repair, replacement, or to access other components. Removing the cover can involve removing the fasteners holding the tensioned spring. This can result in the sudden and uncontrolled release of the spring energy. Further, the reassembly of the cover involves pre-tensioning the spring, which can be a difficult and dangerous task for the technicians.
The accompanying drawings illustrate various examples of the principles described herein and are a part of the specification. The illustrated examples are merely examples and do not limit the scope of the claims.
Throughout the drawings, identical reference numbers designate similar, but not necessarily identical, elements.
Pre-tensioned springs are useful in applying consistent forces within mechanisms. For example, pre-tensioned springs can be used to counteract gravitational forces or to bias moving mechanisms toward desired positions. One application of pre-tensioned springs is in covers. Covers typically have two positions, an open position that exposes the opening or component and a closed position that conceals the opening or component. In many cases it is desirable for the covers to be mechanically stable in both the open and closed positions. For example, having a stable open position allows a user to access the component or opening without concern that the cover will undesirably close. Similarly, having a stable closed position ensures that the cover will remain closed and protect the enclosed part or opening.
However, the handling, assembly, and disassembly of pre-tensioned springs can be both difficult and hazardous. Pre-tensioned springs can store a significant amount of energy. If the mechanical constraints on a pre-tensioned spring are suddenly released, the pre-tension spring can violently revert to its original neutral configuration. This can result in damage or injury to the spring's surroundings.
Some hinged covers, due to the geometry and kinematics, use a pre-tensioned spring to keep the cover in an open and/or closed position. The pre-tensioned spring is deflected to produce force throughout the motion of the cover. The use of a pre-tensioned spring provides mechanical force to maintain the position of the hinged cover. Where the cover is relatively large or heavy, the spring may be very stiff and store a significant amount of energy in its pre-tensioned state.
The use of a pre-tensioned spring in a hinged cover can have a number of disadvantages. During assembly, the spring is pre-tensioned by applying a compressive or tensile force. This compressive or tensile force is maintained while the spring is connected to the various components of the device. Before it is secured to the device, the spring can be suddenly released from its pre-tensioned state. This sudden release of the spring can result in damage to surrounding components, flying of the spring, or injury to technicians. After the cover is assembled, the pre-tensioned spring can complicate maintenance procedures. The cover may need to be removed for repair or replacement or to access other components. When the cover is removed, the pre-tensioned spring can be suddenly released. Further, the reassembly of the cover involves pre-tensioning the spring, which can be a difficult and dangerous task for the service personnel.
In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the present systems and methods. It will be apparent, however, to one skilled in the art that the present apparatus, systems and methods may be practiced without these specific details. Reference in the specification to “an example” or similar language means that a particular feature, structure, or characteristic described in connection with the example is included in at least that one example, but not necessarily in other examples.
As used in the specification and appended claims the term “pre-tensioned” or similar expressions refer to the deflection of a spring prior to installation in a mechanism such that the spring maintains a force throughout the entire range of motion of the mechanism.
The covers (105, 115) in this example are relatively large and are supported at each end. Relatively strong springs are used at both ends of the covers (105, 115) to provide desired mechanical force.
The printer described above is only one illustrative example of a mechanism that may use bistable covers with pre-tensioned springs. A variety of other devices may use pre-tensioned springs to create bistable covers or doors.
The spring (215) is pre-tensioned to provide forces to create two stable positions, one at either end of the cover travel. The bistable hinge mechanism is mirrored at both ends of the long cover (210). The spring (215) remains tensioned for all cover positions. Because the cover mass is relatively high, the pre-tension on the spring (215) is high. The torque provided by the spring force biases the cover (210) toward the mechanical stops (227, 230) at either end of the cover travel.
During assembly of the cover mechanism (200), the spring pre-tension can be manually applied and held while the spring (215) is secured in place. This may have a number of disadvantages, including using two technicians during the assembly process: one to pre-tension and position the spring (215) and another to position and tighten the screws. If the spring (215) slipped during the assembly process, the spring's pre-tension could be violently released, potentially causing injury to the technicians or surrounding components.
Similarly, when service technicians work on a deployed printer and replace the cover or remove it to access other components, the spring can suddenly release its preload when one of the spring ends are loosened. After the maintenance is complete, the service technician then reassembles the mechanism, including tensioning the spring and securing it in place. As discussed above, it can be manually challenging to simultaneously apply a preload to the spring, position the spring with respect to the other components, and position/tighten the fasteners on both ends of the spring.
In one example, a solution to improve the serviceability of the roll cover was implemented. This solution called for the technician to carefully release and discard the existing spring. After the maintenance was complete, a new spring that is secured in its pre-tensioned state by a preload bracket is installed by securing one end of the spring to the base and the other end to the cover. The roll cover is then rotated so that the new spring is compressed enough to release the preload bracket. The preload bracket is then discarded. This procedure calls for replacement of a perfectly operational spring with a new spring, only because of the pre-tension.
The illustrative bistable cover assembly (200) shown in
The intermediate part (320) includes a body portion (324), a moving post (322) and a pivot post (321). The pivot post (321) is pivotally connected to the hole (307) in the roll support (305) by a fastener (325-1). The moving post (322) on the opposite end of the intermediate part (320) passes through the arc shaped aperture (330) and is connected to a first end (316) of a torsion spring (315) by a second fastener (325-2). The body portion (324) of the intermediate part (320) interfaces with the cover (310) and has a center hole that receives a fastener to hold it in place. The interface between the body portion (324) and the cover (310) is illustrated in more detail in
The torsion spring (315) has a coiled portion (318), first end (316) and a second end (317). As discussed above, the second end (317) of the torsion spring (315) is attached to the moving end of the intermediate part (322) by a fastener (325-2). The first end (316) is attached to an anchor point on the base (305) by fastener (325-3). The fasteners (325) may be any of a variety of fastener types that are suitable to secure the components together, including screws, pins or rods.
In one implementation, the base (305), spring (315), and intermediate part (320) can be pre-assembled in a manufacturing setting to form a hinge assembly. The cover (310) can then be attached on both ends to hinge assemblies. This pre-assembly of the base (305), spring (315) and intermediate part (320) includes pre-tensioning the torsion spring (315), and fastening the three screws (325-1, 325-2, 325-3) into the intermediate part (320) and the base (305) to hold the components together. As discussed above, there are two of these bistable hinge mechanisms, one at either end of the cover (310). In some examples, a door can cover the opening of the interior cavity (340) of the base (305). This entirely encloses the spring (315) and increases the safety and aesthetics of the cover mechanism.
On the main production line, the cover (310) is slipped over the intermediate parts (320) so that an interface feature (312) captures the body (324) of the intermediate part (320). The intermediate parts (320) are secured to the cover using a fastener (325-4). This simplifies the process of attaching the cover to the device. In this example, two fasteners are used, one on either end of the cover (310). The interface feature (312) of the cover (310) allows torque generated by the torsion spring (315) to be transmitted to the cover (310).
The removal of the cover (310) for maintenance or replacement is also simplified. The cover (310) is opened to provide access to the fasteners (325-4) that hold the intermediate part (320) into the interface feature (312). The fasteners (325-4) are removed and cover (310) is slid away from the base (305). Installation of the cover (310) after the maintenance is complete is done by sliding the cover (310) over the intermediate parts (320) so that the body of the intermediate parts engage the interface feature (312) and reinstalling the fasteners (325-4).
The illustrative bistable cover assembly (300) has a number of advantages. First, the spring (315) is located in an enclosed space that is not normally accessible to the user during the operation of the printer. This prevents the user from accidentally becoming entangled with the spring (315) or releasing the spring (315). Second, if the spring (315) is accidentally released, it is at least partially contained within the cavity (340) of the base (305). These advantages increase the user's safety and the aesthetics of the printer.
This illustrative bistable cover mechanism (300) provides a number of assembly advantages. The hinge assembly (305, 315, 320, 325-1, 325-2, 325-3) can be separately assembled on a sub-assembly line that has specific tools and fixtures for safely and efficiently pre-tensioning and mounting the spring (315) and intermediate part (320) to the base (305). In this example, the assembly process is only performed once because the cover (310) can be attached or removed without disassembly of the hinge assembly. On the main production line or during maintenance, the cover (310) can be easily removed and reattached from the hinge assemblies. Attaching or removing the cover (310) does not involve releasing the tension from the spring or handling a pre-tensioned spring.
The systems and assemblies described above are only illustrative examples. A variety of alternative implementations could be used. For example, the hinge assembly (305, 315, 320, 325-1, 325-2, 325-3) could be used in either a bistable cover application or in a cover that is always preloaded in one direction. Hinge assemblies that always preload a cover in one direction can be used to hold a cover in a closed position.
The method described above is only one illustrative example and is not intended to be limiting. The blocks could be reordered, combined, eliminated or additional blocks could be added. For example, instead of pre-tensioning the spring, the spring may be tensioned when the second end of the spring is attached to the intermediate part. In some implementations the interfacing portion of the cover may include a compliant locking mechanism that eliminates the need for securing the cover to the intermediate part with fastener.
In conclusion, the illustrative bistable cover resolves long standing issues related to pre-tensioned springs. The bistable cover assembly contains a pre-tensioned spring within a base and uses an intermediate part between the spring and the cover. The intermediate part acts as an interface between the spring and the cover and allows the cover to be removed without removing the preload from the spring or detaching the spring from the base. This increases the ease of assembly, printer aesthetics, and ease of maintenance.
The preceding description has been presented only to illustrate and describe examples of the principles described herein. This description is not intended to be exhaustive or to limit these principles to any precise form disclosed. Many modifications and variations are possible in light of the above teaching.
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Number | Date | Country | |
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20120305583 A1 | Dec 2012 | US |