BACKGROUND OF THE INVENTION

To direct an ejection seat out of a vehicle, it is common practice to guide the seat out of the cockpit with a pair of guide rails. Typically, the seat will have two or three rollers on each side, wherein each set of rollers travels along a single channel in the corresponding rail. Each side of the seat usually having a roller at the bottom, one in the middle and one near the top. As the seat travels up the rails, the seat reaches a point where the top and middle rollers have disengaged from the rail but the bottom rollers are still constrained by the rails. During this interval, the windblast will push the top of the seat aft of the vehicle while the rail constrains the bottom of the vehicle, producing a rotational moment on the seat and causing an undesirable aft pitch angle.

In addition, as the seat emerges from the vehicle, the rails bend due to the force of the windblast on the seat. This causes a further deviation in the pitch angle. One possible way to prevent rail bending would be to add structural support to the rails, but this would add weight and possibly create visual and spatial obstruction. Thus what is needed, is an ejection seat rail that simultaneously releases the seat rollers and can compensate for any rail bending, such that the rails direct the ejection seat out of the vehicle at a desirable pitch angle.

SUMMARY OF THE INVENTION

Disclosed herein is a structure that guides an ejection seat out of a vehicle, comprising: at least one first guide attached to the ejection seat; at least one second guide attached to the ejection seat; at least one rail attached to the vehicle, the rail having a single channel and a curvature along the longitudinal axis of the rail, the first and second guides reside in the single channel and are adapted to travel along the single channel and exit from the end of the single channel.

This invention is an ejection seat rail that simultaneously releases the rollers of an ejection seat. Each rail has two separate channels, a first channel guides the top and middle rollers and a second channel directs the bottom roller. The second channel terminates at a distance from the first channel, equal to the distance between the bottom and middle rollers, such that the bottom roller is released from the second channel at the same time that the middle roller exits the first channel. This simultaneous release of the rollers eliminates the introduction of any rotational moment or deviated aft pitch angle on the seat as it exits the cockpit.

The rails may also have a curvature so that when the beam bends during seat ejection, the beam will bend toward a more linear position, reducing or eliminating the amount of aft pitch caused by rail deflection.

Therefore it is an aspect of this invention to provide a rail for an ejection seat that simultaneously releases the seat rollers.

It is also an aspect of this invention to provide a rail that offsets beam deflection that occurs

when the seat travels up the rail and is subjected to aerodynamic drag.

It is an aspect of this invention to provide a guide rail that simultaneously releases seat rollers, that is simple, lightweight and can be easily retrofitted into existing cockpits.

DETAILED DESCRIPTION OF THE DRAWINGS

This invention and its advantages will become more apparent to those skilled in the art after further review of the specification and the drawings, wherein:

Figure 1 is a side view of an ejection seat traveling up a rail constructed from an I-beam, wherein the seat rollers are releasing from the rail;

Figure 2 is a cross-sectional view of Figure 1 taken at line 2-2 showing the rollers within the first and second channels of the I-beam rail;

Figure 3 is a cross-sectional view of Figure 1 taken at line 3-3, showing the rollers of an ejection seat simultaneously releasing from the I-beam rail; Figure 4 is a side view of an ejection seat traveling up a rail constructed from a stepped "C" channel, wherein the seat rollers are releasing from the rail;

Figure 5 is a cross-sectional view of Figure 4 taken at line 5-5 showing the rollers within the first and second channels of the stepped "C" rail;

Figure 6 is a cross-sectional view of Figure 5 taken at line 6-6, showing the rollers of an ejection seat simultaneously releasing from the stepped "C" rail; Figure 7 is a simultaneous release mechanism utilizing a lever that is attached to the ejection seat;

Figure 8 is an alternative embodiment to the

flange guide disclosed in Figure 7;

Figure 9 is an alternative embodiment to the flange guide disclosed in Figure 7;

Figure 10 is the lever release mechanism depicted in Figure 7, wherein the flange guide has disengaged from the rail and the lever is allowed to freely move in the direction indicated by the arrow;

Figure 11 is a side view of an ejection seat at rest in a curved rail; Figure 12 is a side view of an ejection seat releasing from the end of the rail, wherein rail has deflected to a linear position.

DETAILED DESCRIPTION OF THE INVENTION

Referring to the drawings more particularly by reference numbers, Figure 1 shows an ejection seat 2 traveling up a rail 4 which is mounted into the cockpit 6 of an aircraft 8. The ejection seat 2 can be any standard seat used in the aircraft industry such as the rocket catapult seat sold by McDonnell Douglas under the trademark ACES II. Attached to the side of the seat 2 are first 10 and second 12 guides that ride along and are constrained by first 14 and second 16 channels in the rail 4, respectively. To provide further stability a top guide 18 can be attached to the seat 2, the top guide 18 travels along the first channel 14. Another set of guides, channels and rail can be placed on the other side of the seat 2 and if desirable could also be located in the center of the seat 2. The guides should preferably be rollers, but any conventional guide means that can travel along the channels can be used.

As shown in Figure 2, the rail 4 can be constructed from a I-beam, wherein a first 20 set of

flanges form the first channel 14 and a second 22 set of flanges form the second channel 16. The second flange set 22 is cut, such that the second channel 16 terminates at a distance x from the end of the first channel 14, the distance x approximately equaling the distance between the first guide 10 and the second guide 12, see Figure 3. By terminating the channels at a distance equal to the space between the guides, the guides will disengage from the rail 4 at a the same time. This simultaneous release of the guides allows the seat 2 to exit the cockpit 6 without any rail 4 induced aft pitch angle and seat rotation.

Figures 4, 5 and 6 show an alternative embodiment to the structure depicted in Figures 1-3. Instead of making the rail 4 out of an I-beam a stepped "C" channel is used. The C channel rail 24 has a set of flanges 26 that differ in width as they extend from the base 28 of the rail 24. The C rail 24 is constructed such that the flanges 26 are thicker near the base 28 of the rail 24. The lower part 30 of the flanges form a first channel 14' and the upper part 32 of the flanges form a second channel 16'. A first guide 10* or roller is attached to the seat 2 by a first pin 34. The first guide 10' travels along the first channel 14 ' . A second guide 12* is attached to the seat 2 by a second pin 36 and travels along the second channel 16' . The second channel 16' terminates at a distance X from the end of the first channel 14' , approximately equal to the distance between the bottom of the first guide 10' and the bottom of the second guide 12' , such that the guides exit the channels simultaneously, see Figure 6.

Another rail/guide embodiment is shown in Figure 7. The rail 37 has one single channel 38. A first guide 10" is attached to the seat 2 and travels

along the single channel 38. A lever 40 is pivotally mounted to the seat 2 by attachment means such as a third pin 42. Extending from or attached to the lever 40 is a second guide 12", which could be a pair of guide flanges 44 as depicted in Figure 7, or a roller 46 as shown in Figure 8, or a pair of rollers 48 as shown in Figure 9. A third guide 50 is pivotally attached to the lever 40 by attachment means such as a fourth pin 52. Both the second 12" and third 50 guides travel along the single channel 38. The second guide 12" is in close proximity to the first guide 10", so that the first 10" and second 12" guides exit the single channel 38 at approximately the same time.

When the first and second guides are released, the lever 40 and the attached seat 2 are allowed to move in the direction as indicated in Figure 10. Because the seat is attached to the lever 40 and the lever 40 is allowed to rotate about the third guide 50, the seat 2 is allowed to move freely without being restrained by the third guide 50. The first 12" and third 50 guides functionally release simultaneously, similar to the releasing mechanism shown in Figures 1-6. To prevent the seat 4 from being restrained between the time the second 12" and third 50 guides release, it is desirable to prevent contact between the lever 40 and the rail 37. To insure this, the geometric relationship between the lever 40, second guide 12", third guide 50 and channel 38, must be established to prevent the lever 40 from making contact with the rail 37, when the seat 2 is subjected to a predetermined windblast. For example, when the seat is to be subjected to a maximum windblast of 700 knots equivalent air speed (KEAS) , and the width of the channel 38 is 4.445 cm., it has been calculated that the lever 40 will avoid channel contact, by using a lever no wider

than 2.2 cm, and placing the third pin 42 approximately .95 cm from the center of the channel 38 at a distance of 20.32 cm from the edge of the second guide 12" and 3.49 cm from the center of the third guide 50. By obtaining a simultaneous guide release with a single channel 38, this embodiment can be retrofitted into existing channel rails that are found in most aircraft 8.

As the seat 2 nears the top of the rail 4, the windblast exerts a load on the seat 2, which is transmitted to the rail 4, causing the rail 4 to deflect. This causes the seat 2 to have a more aft pitch. To compensate for this rail deflection, the rail 4 ¹ can be curved toward the fore position as shown in Figure 11. Thus when the rail 4' is deflected the rail 4' will bend toward a linear position, which allows the seat 2 to exit from the cockpit 6 without rotational velocity, see Figure 12. It has been calculated that for a maximum windblast of 700 KEAS, the rail 4 should have a radius of approximately 5° degrees. The curved rail concept can be used with or without any of the three simultaneous guide release mechanisms previously disclosed.

While certain exemplary embodiments of this invention have been described above and shown in the accompanying drawings, it is to be understood that such embodiments are merely illustrative of, and not restrictive on the broad invention. The invention is not to be limited by the specific constructions or arrangements shown and described, since various other modifications may occur to persons having ordinary skill in the art.