A guided projectile has a deployment system for deploying a deployable structure, such as a fin, another type of control surface, or an antenna. The deployment system includes a single-piece body that has a hub body and a resilient tab. The resilient tab presses against a stepped surface of a guided
A guided projectile has a deployment system for deploying a deployable structure, such as a fin, another type of control surface, or an antenna. The deployment system includes a single-piece body that has a hub body and a resilient tab. The resilient tab presses against a stepped surface of a guided projectile body. As the deployable structure is extended, the deployable structure body rotates about a shaft in a central hole or aperture in the hub body. The resilient tab presses against the stepped surface on one side of an edge of the stepped surface during a first (relatively stowed) part of this deployment. At a certain point, as the contact between the tab and the stepped surfaces reaches the edge (the step of the stepped surface), the resilient tab changes position. The change in position of the resilient tab keeps the deployable structure from retracting again.
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What is claimed is: 1. A deployment system for deploying a deployable structure on a guided projectile comprising: a body of the deployable structure, wherein the body includes: a hub body portion; and a resilient tab that is attached to the hub body portion at one end; and a guided projectile bod
What is claimed is: 1. A deployment system for deploying a deployable structure on a guided projectile comprising: a body of the deployable structure, wherein the body includes: a hub body portion; and a resilient tab that is attached to the hub body portion at one end; and a guided projectile body having a stepped surface that includes a step with an edge; wherein the resilient tab presses against the stepped surface during deployment of the deployable structure, and shifts position when going over the step; wherein the resilient tab is an elongate member having a length in a direction away from where an attached end of the resilient tab attaches to the hub body portion, that is greater than a width or a height of the resilient tab, wherein the width is measured in a plane of the hub body portion; and wherein the elongate member has a protuberance at a free end of the resilient tab that is wider than other parts of the elongate member. 2. The system of claim 1, wherein the body is a single-piece body that includes both the hub body portion and the resilient tab as parts of the single-piece body. 3. The system of claim 1, wherein the hub body portion and the resilient tab are separate pieces. 4. The system of claim 3, wherein the hub body portion and the resilient tab are made of different materials. 5. The system of claim 3, wherein a bent end of the resilient tab fits in a tab-receiving slot in the hub body portion. 6. The system of claim 1, wherein the elongate member includes a straight portion and a curved portion; wherein the straight portion is a proximal straight portion that includes the attached end; and wherein the curved portion is a distal curved portion that is farther from the attached end than the straight portion. 7. The system of claim 1, wherein a slot between the elongate member and part of the hub body portion has a substantially constant width. 8. The system of claim 1, wherein the resilient tab has a side surface that presses against the stepped surface on a first side of the edge; and wherein the resilient tab side surface does not press against the stepped surface on a second side of the edge. 9. The system of claim 1, wherein the resilient tab has a side surface that presses against the stepped surface on a first side of the edge, when the deployable structure is in a relatively stowed configuration; and wherein the resilient tab has an end surface at the free end configured to engage the stepped surface on a second side of the edge when the deployable structure is in a relatively deployed configuration. 10. The system of claim 8, wherein the side surface and the end surface are on the protuberance. 11. The system of claim 1, wherein the guided projectile body includes a shaft about which the body of the deployable structure rotates. 12. The system of claim 1, wherein the body is at least part of a control surface. 13. The system of claim 1, wherein the protuberance has a side surface that presses against the stepped surface on a first side of the edge, when the deployable structure is in a relatively stowed configuration; wherein the protuberance has an end surface at the free end configured to engage the stepped surface on a second side of the edge when the deployable structure is in a relatively deployed configuration; and wherein the stepped surface includes a notch on the second side of the edge that secures a portion of the protuberance therein, wherein the portion of the protuberance includes the side surface. 14. The system of claim 13, wherein the protuberance has a squared-off shape that corresponds to the shape of the notch. 15. The system of claim 1, wherein the step is a substantially right angle step. 16. The system of claim 1, wherein the stepped surface has multiple steps that prevents reversal of motion of the deployable structure at multiple locations along its deployment. 17. The system of claim 16, wherein the multiple steps are right angle steps. 18. A deployment system for deploying a deployable structure on a guided projectile comprising: a single-piece body of the deployable structure, wherein the body includes: a hub body portion; and a resilient tab that is attached to the hub body portion at one end; and a guided projectile body having a stepped surface having a step with an edge; wherein the resilient tab presses against the stepped surface during deployment of the deployable structure, and shifts position when going over the step; wherein the resilient tab is an elongate member having a length in a direction away from where an attached end of the resilient tab attaches to the hub body portion, that is greater than a width or a height of the resilient tab, wherein the width is measured in a plane of the hub body portion; wherein the elongate member includes a straight portion and a curved portion; wherein the straight portion is a proximal straight portion that includes the attached end; wherein the curved portion is a distal curved portion that is farther from the attached end than the straight portion; wherein the distal curved portion includes a free end of the resilient tab; wherein a slot between the elongate member and part of the hub body portion has a substantially constant width; wherein the resilient tab has a side surface that presses against the stepped surface on a first side of the edge, when the deployable structure is in a relatively stowed configuration; wherein the resilient tab has an end surface at a free end configured to engage the stepped surface on a second side of the edge when the deployable structure is in a relatively deployed configuration; wherein the resilient tab includes a protuberance at the free end; wherein the side surface and the end surface are on the protuberance; and wherein the protuberance is wider than other parts of the elongate member.
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이 특허에 인용된 특허 (2)
Meston Spencer D. (Bristol GBX) Phillips John W. (Bristol GBX), Fin erecting mechanisms.
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