1. Field of the Invention
The present invention relates to the launching of fireworks in the form of bottle rockets and to devices that assist in the launching of the rockets.
2. Background of the Invention
Fireworks bottle rockets are pyrotechnic devices that have a quantity of flammable powder enclosed in an elongated paper tube that is attached at the head end of a long, thin stick. The tube axial body is aligned parallel to the stick to provide a rocket lifting thrust that is directed parallel to the stick when powder inside the tube is ignited. A flammable thin and flexible fuse that extends out from the base end of the powder tube is used to ignite the powder inside the tube. The bottle rocket stick is typically supported within a beverage bottle that has a tapered shape where the bottle has a small bottle top opening on one end and a larger flat bottom continuous surface on the opposing end. Use of these stick-mounted flammable powder fireworks tubes, which act as rockets, along with bottles that are used as holding and pointing devices originates the name “bottle rockets”. When used as a launcher, the bottle is positioned upright with its flat bottom surface lying flat on the ground and the bottle in a near vertical orientation. A bottle rocket stick base is inserted into the bottle small top mouth opening where the base of the stick contacts the bottle bottom flat surface. Here, the bottle freely confines the stick portion of the bottle rocket, as the stick diameter is very small compared to the bottle-top opening. As the bottle rocket is loosely contained in the upright bottle, the bottle rocket stick axis assumes a near vertical alignment direction. However, the diameter of the base area of the bottle is very large compared to the diameter of the stick, which allows the base of the stick to be randomly positioned on one side or another of the bottle. This random position of the stick base results in a wide variation in the vertical orientation of the bottle rocket stick where the initial incline angle can be inadvertently changed during the launch procedure. It is usually assumed that the bottle rocket flight trajectory will initially start in the direction of the bottle axis as the bottle contains and supports the bottle rocket stick. Because the stick can freely move around within the bottle, the launch angle can also change from that which is intended. It is not possible to have a consistent aimed trajectory of bottle rockets when using a open moth bottle as a launch device. The rocket stick is sufficiently long that when it is inserted into the bottle top opening, the base end of the stick contacts the bottom surface of the bottle and the tubular fireworks rocket portion of the bottle rocket extends upward some distance away from the top surface of the bottle. Here, both the full length of the rocket powder tube and the fuse extend somewhat above the top end of the bottle to allow the fuse to be easily accessed for flame lighting. Upon lighting the end of the flexible fuse, a wall of burning fire travels along the length of the fuse until the fire ignites the leading edge of the flammable powder matrix located in the fuse-end of the powder tube. When the fuse is first lighted, the fuse fire-line slowly progresses up the length of the fuse, which provides a time delay between the time that the fuse is first lit, and the time when the tube-contained powder starts to burn. This time delay allows the operator to light a fuse and then to move away from the bottle rocket for safety reasons before the rocket tube powder burn is initiated. The powder located in the stick base portion of the paper tube is lit first and the gases that are generated by the burning powder are directed out the rear portion of the tube along the axis of the stick. This burning gas provides a propelling force that is also directed along the axial length of the stick. The exhaust gas force accelerates the bottle rocket unit out of the loose-confines of the bottle in a direction that is initially along the axis of the rocket stick as it was held in position by the bottle. Powder burns progressively within the paper tube and continuously thrusts the rocket to a greater speed and a higher elevation. A rocket usually assumes a curved trajectory due to gravity forces acting on the rocket body during flight. The rocket can provide a continuous fireworks display of burning particles and a powder-burn sound as it travels up into the air. At the end of the powder-burning event which occurs at or close to the apex of the rocket flight, a pyrotechnic explosion typically occurs when a cached quantity of powder, located in the forward or head end of the tube, is ignited.
There are a number of trajectory guidance and safety issues when this traditional bottle holding system is used to ignite and release an activated bottle rocket into the atmosphere. First, it is desirable for the operator to have a method to control the rocket flight trajectory by hand during launch rather than using the passive bottle orientation guidance system. Second, there are a number of safety issues related to different events that always occur or occasionally occur during the launch procedure. In the instance where the fuse is defective and a slow fuse burn rate the main firing of the rocket thrust powder occurs some longer time after the expected delay has passed. Prior to the actual delayed tube-powder firing event, the unaware operator can mistakenly re-approach or even handle the bottle rocket, at which time it can fully ignite or explode. In another instance, if the glass bottle has been structurally weakened or it is fragile in its original state compared to the rocket explosive power, a defective rocket may explode prior to leaving the confines of the glass, which could fracture the glass. If an operator is directly adjacent to the glass bottle when the glass fracture occurs, flying glass fragments could harm the operator or other observers. Some bottle rockets are quite powerful but they are limited in use because they are also more expensive than more common varieties. These powerful bottle rockets are much more dangerous than the common variety types. In addition, positioning a bottle on an uneven or a non-stable ground surface can result in the bottle tipping over during the launch event which can direct the rocket to be propelled in unwanted directions. At other times, a bottle is not used to support a bottle rocket. Instead, the bottle rocket stick is inserted into sand or is held by rocks. Upon ignition, the sand or rocks may firmly grasp the stick and restrain it against the propelling force of the rocket, which prevents the rocket from rising into the air and traveling to areas that are remote from the operator and observers before the final pyrotechnic explosion. In this case the flare of the burning rocket is directed against the ground and the final rocket explosion event occurs also at the immediate ground level. Undesirable launch events can have a damaging effect on adjacent ground materials, operators or observers. There is not a practical safe method for an operator to hold a beverage bottle launch device by hand to direct the flight of the bottle rocket. If a bottle is held by hand during launch, the exhaust plume from the rocket can easily impact the hand or eyes of the operator. Bottle rockets should not be used by children as they are not sophisticated in knowing the techniques required for safe and interesting launching of bottle rockets. A simple but intuitive launcher device that is strong and safe and which has attributes that trigger awareness of important and desirable launch techniques can make it easier to consistently have enjoyable but safe and successful launches. Protection of both the operator and observers from exhaust flames or explosions during launch is very important.
A number of rocket or propellant launch devices are described in U.S. Pat. No. 29,118 (Woodward), U.S. Pat. No. 1,003,082 (Ziegenfuss), U.S. Pat. No. 1,776,354 (Edmands), U.S. Pat. No. 2,005,826 (Kulp et al.), U.S. Pat. No. 2,306,442 (Holmes), U.S. Pat. No. 2,795,386 (Elsey), U.S. Pat. No. 2,923,240 (Blewer), U.S. Pat. No. 2,993,297 (Bednar et al.), U.S. Pat. No. 3,190,033 (Wood), U.S. Pat. No. 3,739,764 (Allport), U.S. Pat. No. 4,076,006 (Bestow et al.), U.S. Pat. No. 4,148,258 (Powers), U.S. Pat. No. 4,411,249 (Fog arty et al.), U.S. Pat. No. 4,429,611 (Oldham et al.), U.S. Pat. No. 4,724,768 (Robinson et al.), U.S. Pat. No. 4,917,015 (Lowery), U.S. Pat. No. 5,339,741 (Craven et al.), U.S. Pat. No. 5,433,646 (Tamg), U.S. Pat. No. 5,496,025 (Phillips et al.), U.S. Pat. No. 5,538,453 (Johnson), U.S. Pat. No. 5,553,598 (Johnson et al.), U.S. Pat. No. 5,619,980 (Lee et al.), U.S. Pat. No. 5,691,500 (Mancini), U.S. Pat. No. 5,819,717 (Johnson et al.), U.S. Pat. No. 5,826,750 (Johnson), U.S. Pat. No. 5,839,940 (Ensmenger), U.S. Pat. No. 5,881,706 (Carson), U.S. Pat. No. 6,315,629 (Jones), and U.S. Pat. No. 6,347,623 (Kownacki et al.).
The bottle rocket launcher described herein comprises a hollow barrel having a breech valve or side load breach mounted on one end of the barrel. The breech valve through-hole opening is aligned with the inside diameter of the launcher barrel by rotating a valve lever. A bottle rocket is partially inserted into the launcher through an open breech valve, the rocket fuse is lit, the rocket is quickly thrust fully into the barrel, the valve is closed and the rocket is then launched out of the barrel upon ignition of the rocket flammable powder. With a side breech load, the side panel is opened, the lit rocket dropped in, and the side panel closed (and preferably locked).
All of the individual rocket launcher components can be constructed of inexpensive, non-corrosive but strong materials including structural PVC (poly vinyl chloride), plated steel, copper, or other materials, or combinations of these materials.
A bottle rocket launcher apparatus is described that provides the following sequence of events during a rocket launch. First, a bottle rocket is partially inserted into a launcher valve opening, the exposed rocket fuse is lighted by a flame, the fuse-lit rocket is fully inserted into the launcher barrel chamber, the valve is closed to seal-off the launcher barrel chamber after which the burning fuse ignites the rocket flammable powder which propels the rocket along the length of the launcher barrel to cause it to exit the barrel in a direction along the axis of the barrel. The burning exhaust powered rocket is accelerated to greater heights until the thrust powder is consumed. Then a reservoir of powder is ignited which results in a load explosion that occurs at the apex of the rocket trajectory. The launch apparatus can be used as a hand held device but it also has features that allow it to be used in a preferred stationary mount configuration.
In one embodiment, the launcher is mounted in a stationary position where the launcher barrel is aligned at an approximate 60 degree incline angle with the ground. Here, the bottle rocket powder-tube front end of the bottle rocket is partially inserted into the breech valve body opening. The breech valve may have a smooth surfaced cylindrical shaped valve opening where the opening diameter is approximately equal to the inside diameter of the launcher barrel. Both the breech valve opening and the barrel bore are in axial alignment to provide a near-continuous, smooth cylindrical bore that extends from the entrance of the breech valve up into the launcher barrel. Even though smooth, the launcher may require at least some modest static coefficient of friction on the internal surface to have any rocket resist backsliding within the chamber after insertion, especially when a lit rocket is inserted into the end breech loading structure described herein. This continuous smooth surface allows unimpeded insertion of the bottle rocket into the depths of the barrel chamber. The launcher barrel with the end load breech system may have controlled friction properties at at least the lower end of the chamber to assure that an inserted rocket will not quickly slide back to the breech opening when thrust inside. The front portion of the bottle rocket may be positioned so that the rocket fuse is partially or fully exposed from the confines of the interior of the valve body. A slot for the fuse may be provided, and although this would reduce some of the expelling forces, the power loss would not be so significant as to prevent launch of the rocket. In this manner, an unlit rocket could be inserted into the launcher with a fuse exposed, and then the fuse could be lit, without having to close a breach or other opening after a fuse has been lit. Because of this partial insertion of the bottle rocket into the launcher body, a large portion of the rocket stick extends outside of the valve body. Immediately after lighting the bottle rocket fuse, the operator grasps the bottle rocket stick and inserts the forward portion of the bottle rocket into the valve opening and upward into the barrel chamber. Then the operator hits the end of the rocket stick with one hand in a direction along the axis of the stick to dynamically propel the complete bottle rocket into the launcher barrel chamber far enough to assure that the trailing base end of the stick arrives at a location within the barrel that is past the valve shut-off component. The bottle rocket tends to cling to the inside surface of the barrel due to gravity acting on the rocket to frictionally secure the rocket from sliding back down the barrel after the rocket stops its dynamic insertion travel. The valve is then quickly closed using the operator's same hand that was used in the rocket insertion event as this hand is already positioned close to the valve lever. Closing the valve seals off the breech end of the launcher barrel. The bottle rocket having a burning fuse is now positioned within the confines of the launcher barrel chamber. This rocket insertion action takes place immediately after lighting the rocket fuse to assure that the rocket is inserted and the valve is closed before the rocket tube powder is first ignited. The muzzle end of the launcher barrel remains open at all times. When the bottle rocket powder is ignited by the burning fuse the burning exhaust gases thrusts the bottle rocket along the length of the barrel past the muzzle and into the sky in the trajectory direction that the launcher barrel is pointed. The exhaust gasses are all restricted to the valve-sealed interior confirms of the launch barrel tube, which protects the operator from the gases as the rocket travels up the length of the barrel. Exhaust gasses that initially are propelled from the rocket powder tube toward the breech valve body are turned in reverse direction at the sealed breech end of the barrel. These turned gasses then travel in the direction of motion of the rocket as it moves up and along the barrel toward the muzzle. Exhaust gases expelled by the rocket are effective in both providing direct rocket thrust and also in providing an extra drag-force boosts that accelerates the rocket to even greater speeds and greater heights. These extra rocket boost drag forces are generated by moving-gas passing by the rocket body as the gasses move toward the barrel muzzle. Here, the barrel-contained exhaust gases travel in the small annular space that is directly adjacent to the rocket body as the gasses move toward the barrel muzzle to escape the confines of the interior of the launcher barrel. The inside diameter of the bottle rocket is selected to be sufficiently larger than the equivalent diameter of the bottle rocket device to allow unrestrained insertion of the bottle rocket into the launcher barrel. A close fit between the bottle rocket body and the barrel interior wall increases the velocity of the valve-trapped burning powder gasses that travel in the small annular gap between the launcher barrel inside wall and the rocket body. These gasses drag the rocket body to a faster speed as they move past the rocket body when wall-gap spaces are smaller. A typical bottle rocket is approximately 0.5 inches in diameter at the rocket tube end and has a overall length of approximately 11 inches. A rocket launcher barrel would typically have a 0.75 inch inside diameter and a barrel length of 24 inches. Larger diameter and longer barrel length launchers can be used with larger sized bottle rockets. Tubular barrel lengths can be easily changed by the use of threaded couplings to screw-on another section of threaded pipe to the end of a threaded barrel.
In another, but less desirable embodiment, the launch tube may be used as a hand-held rocket launching device rather than the launcher being supported as a stationary device on the surface of the ground. If the launch tube is held by hand during launch, it is necessary that the tube axis be held away from the operators body to prevent the rocket or hot rocket exhaust gases and burning powder debris from being directed at the operator's body, particularly at the operator's eyes. The burning rocket exhaust typically only travels a short distance backward from the moving rocket so there is a minimal problem with rockets that have cleared the end of a launcher having a long barrel. However, even with a long barrel that confines the exhaust products during the first and most dangerous stage of the launch there is yet a possibility of rearward traveling debris moving from the muzzle back along the exterior surface of the barrel and contacting an operator after the moving rocket clears the end of the launcher barrel muzzle.
Adjustable legs can be used to support the rocket launcher. It is preferred to us two adjacent legs on the muzzle and a single leg on the breech to create a very stable three-point launcher support system. The legs can position the breech valve end of the launcher some minimum distance above the ground to assure sufficient room is present for the easy loading of a long stick-type bottle rocket into the breech valve without disturbing the orientation or stability of the launcher apparatus. The height of the breech end of the launcher can be adjusted by positioning the breech leg so that the base of the bottle rocket stick rests on the ground when the powder tube end of the rocket is partially inserted into the breech valve in a manner that the rocket fuse is exposed to the operator. Here, it is not necessary for the operator to hold the rocket stick in position relative to the breech valve at the same time that he or she is lighting the fuse. Legs attached to the muzzle end of the barrel support the axis of the barrel at an incline with the ground. The incline angle can range from a shallow angle of 30 degrees up to a vertical 90 degrees. Initially, the launcher incline angle can be set in position by adjusting the launcher support leg positions. Then the legs can be readjusted to change the trajectory of the launched rockets for subsequent launches. These legs allow the launcher to be set up at the desired angle even on a ground surface that is quite irregular and non-level due to rocks or other factors. When the launcher is not in use it can be prepared for travel or storage by pivoting the legs parallel to the launcher barrel. Likewise the breech valve lever can be positioned parallel to the launcher barrel with the end of the lever pointing toward or away from the muzzle. The folded-up launcher is very lightweight, durable and has a very slim profile.
The breech valve can be opened after a miss-fire launch attempt to clear out the defective rocket by simply shaking or impacting the barrel to cause the rocket to drop out of the launcher. A small-diameter cleaning rod can also be inserted into the breech valve end or into the muzzle end of the barrel to dislodge the defective rocket from the barrel. If a defective rocket does experience an undesirable firing event during the rod clearing or impact dislodging process, the rocket will simply be held in place by the rod, or, the rocket will leave the exit end of the barrel. In either case, the operator would not be endangered by the miss-fire if care were exercised in the rocket-clearing process.
In another launcher embodiment, rockets can be inserted into the launcher barrel at a barrel side-door that is located at the side of the barrel just above the valve. The barrel end breech valve would be retained on this launcher configuration to provide a safe defective rocket clean-out capability.
In yet another launcher embodiment, a stationary launcher having a near vertical position can be loaded with a bottle rocket from the muzzle end of the launcher barrel muzzle. A bottle rocket can be positioned with the bottle rocket stick inserted into the launcher barrel tube where the bottle rocket powder tube rests on the edge of the barrel muzzle to prevent the rocket from sliding down into the depths of the barrel before the fuse is lighted. The flexible rocket fuse that originates at the base of the rocket powder tube can be routed over the lip of the muzzle to a position where the free end of the fuse is exposed for access by the operator. At launch, the operator can light the fuse and simply nudge the exposed rocket body to dislodge it from the muzzle support whereby the rocket will immediately fall into the depths of the barrel. After the rocket reaches the bottom of the barrel the burning fuse will light the rocket powder and the rocket will be propelled out of the rocket launch tube. A group of small diameter multiple rockets can be partially inserted into the muzzle end of a large diameter launcher barrel, the fuses lit and the rockets then dropped into the depths of the barrel where they will fire as a group or in the sequence that they were lit. Twisting them together before lighting can mutually join multiple fuses into a single master fuse when using multiple muzzle-loaded rockets at the same time. By having a single lighting event for all the rockets provide assurance assure that sufficient time is allocated to the lighting procedure before the rockets are dropped into the barrel.
The rocket launcher article principal components are a barrel and a breech valve. The breech valve allows a fuse-lit bottle rocket to be quickly inserted into a launcher barrel and the valve closed before the rocket is ignited. The launcher has a launcher breech end and a barrel muzzle end where the bottle rocket is inserted into the breech end and the rocket is propelled out of the muzzle end. The barrel is a lightweight and rigid tube, preferably fabricated from a polymer material to resist corrosion and for ease of cleaning. Plated or corrosion resistant metal materials may also be used for the barrel tube. The barrel has a barrel chamber, a barrel length, a barrel inside diameter, a barrel outside diameter and a barrel inside diameter surface where the surface has a cylindrical shape where the barrel inside diameter is at least 60% of the barrel outside diameter. Also, the barrel has a barrel axis that extends from the launcher breech end to the barrel muzzle end where the barrel axis is concentric with the barrel inside diameter. The breech valve is structurally attached to the barrel at the launcher beech end of the barrel and the breech valve has a valve body that has an exterior surface. In addition, the breech valve has a rotary member, which can be rotated over angles that vary from 0 to at least 90 degrees. The rotary valve member has a smoothbore circular through-hole that is machined or otherwise formed through the diameter of the rotary member. Breech valves may have different types of rotary members including cylindrical or spherical type ball members. Breech valves may also include gate, shuttle or slide valves that have either pivoting or slide actions. It is preferred that there are low friction forces present in rotating the valve rotary member to provide ease of opening or closing a valve. Also, the rotary member has an attached rotary member lever that has a lever axis that extends along the length of the lever. The lever allows the rotary member to be manually rotated over the full allowed rotary member angle where the rotary member angle position of the lever, as seen visually relative to the valve body exterior surface, indicates the angle at which the rotary member is positioned relative to the barrel axis. It is easy to see or verify that the valve is fully open or fully closed by simply observing the position of the extended valve lever, the same method that is used to visually determine if a home furnace natural gas valve is open or closed. A cylindrical shape is preferred, in which case the axis of the through-hole is perpendicular to the axis of the axis of the cylinder. The rotary member has two fixed rotational stop positions, which are separated by 90 degrees. At one extreme position, the valve is full open and the lever is aligned with the barrel axis to indicate this open position. At the second extreme position the valve is full closed where the rotary member lever axis is positioned perpendicular to the barrel axis to indicate the full closed position. In the full open position, the valve member through-hole axis is aligned congruent with the barrel axis to provide a continuous cylindrical-shape opening that extends from the external surface of the breech valve through the full length of the inside diameter of the barrel. When in the full closed position, the rotary member seals the barrel breech valve to prevent direct in-line communication between the exterior of breech valve and the barrel chamber. The valve member through-hole diameter is at least 50% of the barrel inside diameter. The smooth cylindrical shape of the valve through hole and also the cylindrical shape of the barrel allows a bottle rocket to be fully inserted up into the barrel chamber with little force when the valve is full open. In the event that the trailing end of the bottle rocket stick is not fully inserted to a position within the barrel chamber that is past the valve member after the fuse is lit, there is a possibility that the valve member clamps onto the end of the stick when the valve lever is rotated toward the closed position, which would prevent the valve from being successfully rotated into a valve full closed position. In this case there would be a small gap opening between the barrel chamber and the exterior surface of the valve body which would allow some of the burning rocket powder gases to escape from the breech end of the rocket launcher apparatus when the rocket contained within the barrel chamber becomes ignited by the burning fuse. Because the leakage gap is small, only a fraction of the total quantity of the gases generated by the rocket would escape and these gases would be directed at the ground in a harmless fashion. The rocket would not be propelled from the barrel muzzle, as the rotating valve member would trap the rocket inside the barrel chamber. After the rocket had harmlessly fully burned it's powder and exploded within the barrel chamber, the rocket explosion would indicate to the operator that the rocket is in a harmless state. The force generated by the rocket explosion inside the launcher barrel would not damage the rocket barrel or breech valve as both the barrel and valve would selected to have sufficient strength to resist these forces. The valve could be opened and the expended bottle rocket carcass removed from the rocket launcher. If there is a question about the safety of the launcher that contains an unfired rocket or a rocket of unknown nature, water could be poured down the barrel prior to opening the valve to saturate the rocket body and snuff out or prevent any powder burning action before the rocket is removed from the barrel. Water could be easily cleared from the interior surface of the smoothbore launcher barrel and valve member through-hole prior to launching another bottle rocket. A sturdy mirror can be used to check the condition of the launcher or to verify that a rocket is not lodged in the barrel before it is used to launch a new rocket. When a mirror is used, it is easy to see through the full interior length of a launcher when the valve is open. With a mirror it is not necessary for the operator to look directly down the bore of the barrel, which could expose the operator's eye to potential damage from an undesirable rocket firing or explosive event.
The valve construction (both in materials and shape) optionally provides sufficient hardness and sharpness as to be able to cut through or at least snap off (by crushing or shearing) a bottle rocket end stick, if it should happen to engage the valve through improper insertion. The lever should be long enough and strong enough to enable application of sufficient forces to accomplish this removal of any entrapped stick portion.
Certain, narrow embodiments of the disclosed bottle rocket launcher can be summarized by the following:
A bottle rocket launcher apparatus comprises a barrel and a breech valve, the launcher having a launcher breech end and a barrel muzzle end where the barrel is a hollow tube having an inside surface, a barrel chamber that extends the full inside surface of the barrel, and the barrel has a barrel length and a barrel axis that extends parallel to the length of the barrel. The breech valve is structurally attached to the barrel at the launcher beech end of the barrel where the breech valve has a valve body that has a exterior surface. The breech valve has a internal rotary member which has a cylindrical or spherical shape, the shape has a cylindrical or spherical diameter, and the rotary member is capable of being rotated over a angle that ranges at least from 0 to 90 degrees. The rotary member has a through-hole which extends through the diameter of the rotary member and the through-hole has a through-hole axis that is located at the center of the cross section area of the through-hole and extends along the length of the through hole. The rotary member provides line-of-sight communication from the exterior surface of the breech valve to the barrel chamber when the valve is in the valve full-open position that occurs when the through-hole axis is rotationally aligned parallel with the barrel axis. When the valve is at the full-open position, a continuous passageway opening extends from the external surface of the breech valve through the full length of the barrel chamber is provided. The rotary member provides that line-of-sight communication from the exterior surface of the breech valve to the barrel chamber is blocked when the valve is in the full-closed position where the through-hole axis is rotationally aligned perpendicular to the barrel axis. The rotary member has an attached rotary member lever, and the lever has a lever axis that extends along the length of the lever and the lever is manually rotated to open or close the valve. Rotation of the lever rotates the rotary member where the rotary member angle position of the lever, as viewed relative to the valve body exterior surface, indicates the angle that the rotary member is positioned relative to the barrel axis.
In addition, the rocket launcher can have a cylindrical shaped barrel, a barrel cylindrical inside surface shape, a barrel inside diameter and a barrel outside diameter where the barrel inside diameter is at least 60% of the barrel outside diameter. Further, the rocket launcher can have three support legs where the launcher breech end of the launcher is supported with a single breech leg and the launcher barrel end of the launcher is supported by two individual barrel legs where the three legs form a three-point launcher support that aligns the barrel axis at a launcher incline angle that ranges from 30 to 90 degrees, where the angle is measured from the ground surface at the launcher location and where, one end of each of the three legs is attached to the rocket launcher and the opposite end of each leg is capable of being manually moved in space relative to the rocket launcher apparatus. Also, all three of the rocket launcher support legs can be positioned with sufficient distance between each leg, where the distance is measured at the location where each leg contacts the ground, to provide stable structural support of the launcher. Additionally, the breech leg is attached to the launcher apparatus with a mounting fastener that allows the breech leg to be rotated or otherwise moved, manually into positions that allow the elevation of the breech end of the launcher to be adjusted relative to the ground surface at the launcher location. Further, the barrel legs can be attached to the launcher apparatus with mounting fasteners and barrel clamps that allow the legs to be moved manually into positions that allow the elevation of the muzzle end of the launcher to be adjusted relative to the ground surface at the launcher location to provide a desired launcher incline angle. In addition, the three support legs attached to the launcher apparatus can be attached to the launcher apparatus with the use of fasteners and clamps that allow all three legs to be rotated and moved into launcher storage positions wherein all three legs lay directly adjacent to and parallel to the launcher barrel. The rocket launcher can have a rotary member lever that has a return spring that allows the rotary member to be manually rotated to a desired rotary member angle where the valve passageway to the barrel chamber is opened but where the spring automatically returns the rotary member to a valve-closed position when manual force is removed from the lever. Also, the rotary member lever return spring can be an over-center spring that provides two extreme lever positions to the breech valve manually operated valve lever where at one extreme lever position the breech valve is at a full-open position and at the second extreme lever position the breech valve is at a full-closed position.
An alternative description of launchers taught herein might comprise a bottle rocket launcher apparatus comprising a barrel and a breech valve, the launcher having a launcher breech end and a barrel muzzle end. The barrel comprises a hollow tube having an inside surface, the barrel having a barrel chamber that compromises all of the inside surface of the barrel, the barrel having a barrel length and the barrel having a barrel axis that extends parallel to the length of the barrel. The breech valve may be structurally attached to the barrel at the launcher beech end of the barrel wherein the breech valve has a valve body with an exterior surface. The breech valve may have an internal rotary member, the rotary member having a cylindrical or spherical shape, the rotary member shape having a cylindrical or spherical diameter, and wherein the rotary member is capable of being rotated over an angle that ranges at least between at least 0 to 90 degrees. The rotary member may have a through-hole, the through-hole extending through the diameter of the rotary member, the through-hole having a through-hole axis that is located at the center of the cross section area of the through-hole and extends along the length of the through hole. The rotary member provides line-of-sight communication from the exterior surface of the breech valve to the barrel chamber such that when the breech valve is in the valve full open position and when the through-hole axis is rotationally aligned parallel with the barrel axis and when at the valve full open position, a continuous passageway opening extending from the external surface of the breech valve through the full length of the barrel chamber is provided. The rotary member may provide blocked line-of-sight communication from the exterior surface of the breech valve to the barrel chamber when the valve is in the full closed position when the through-hole axis is rotationally aligned perpendicular to the barrel axis; and the rotary member may have an attached rotary member that may be manually rotated to open or close the valve. The apparatus may have the rotary member comprises a lever outside of the chamber such that rotation of the lever rotates the rotary member and the angular position of the lever with respect to the barrel chamber indicates the angle at which the rotary member is positioned relative to the barrel axis.
Another alternative description for the apparatus for the launching of bottle rockets comprises: a hollow barrel chamber, a port allowing insertion of a bottle rocket into the chamber, a port closure system that closes with sufficient security that propulsive forces from launch of a bottle rocket will not open the port closure system, a support system for the apparatus that allows at least three-point contact of the support with the ground, and the support system comprising at least three arms, and at least one of the arms being rotatable and/or telescopic to enable angling of the hollow barrel chamber relative to the ground. The apparatus may have the port comprises a side breech opening with locking features to secure the port upon closure. The apparatus may have the port with dimensions parallel to the hollow barrel chamber that allows insertion of a rocket without any flexing of the rocket. The apparatus may have the port with a length that is at least 25 cm in length when open. The apparatus may have the port comprise an end breech system. With an end breech system, with the rocket thrust into the chamber, it is desirable to have the system resist backsliding of the rocket (lit usually with a back breech system) towards the breech opening. To accomplish this, at least a portion of internal surface on the hollow chamber closest to the end breech system has a coefficient of friction with regard to soft wood that prevents a cylindrical 0.5 mm per side square soft wood stick lying on the surface at an angle of 37° from accelerating towards the breech end at greater than 0.2 ft/sec2, which is about 0.1 times normal gravity acceleration on Earth.
Number | Name | Date | Kind |
---|---|---|---|
29118 | Woodward | Jul 1860 | A |
1003082 | Ziegenfuss | Sep 1911 | A |
1776354 | Edmunds | Sep 1930 | A |
2005826 | Kulp et al. | Jun 1935 | A |
2306442 | Holmes | Dec 1942 | A |
2380024 | Chandler | Jul 1945 | A |
2795386 | Elsey | Jun 1957 | A |
2923240 | Blewer | Feb 1960 | A |
2993297 | Bednar et al. | Jul 1961 | A |
3190033 | Wood | Jun 1965 | A |
3739764 | Allport | Jun 1973 | A |
4076006 | Breslow et al. | Feb 1978 | A |
4128039 | Skliris | Dec 1978 | A |
4148258 | Powers | Apr 1979 | A |
4198897 | Lipp et al. | Apr 1980 | A |
4411249 | Fogarty et al. | Oct 1983 | A |
4429611 | Oldham et al. | Feb 1984 | A |
4724768 | Robinson et al. | Feb 1988 | A |
4917015 | Lowery | Apr 1990 | A |
5339741 | Craven et al. | Aug 1994 | A |
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