CN111994308B - Auxiliary recovery system for rocket recovery - Google Patents

Abstract

If the present invention provides an auxiliary recovery system for rocket recovery, comprising: the device comprises a bearing platform, a side wall, a plurality of telescopic devices and a controller, wherein the side wall is arranged on one side of the bearing platform and connected with the bearing platform; the portion of the side walls facing each other is provided with a plurality of pairs of openings corresponding to each other, at least one of the openings corresponding to each pair being provided with the retractable means, the length of extension of which upon activation is greater than the distance between the two corresponding openings. The auxiliary recovery system provided by the embodiment of the invention can guide and limit the movement of the sub-stage to be recovered before the sub-stage to be recovered descends, so that the phenomenon that the sub-stage to be recovered turns over or topples over in the landing process is avoided, the attitude requirement of the rocket to be recovered is reduced, and the recovery success rate is improved.

Description

Auxiliary recovery system for rocket recovery

The application is filed on 19.4.2019 and is named as an auxiliary recovery system for carrier rocket recovery, and is a divisional application of an invention patent with the application number of '201910316445.3'.

Technical Field

The invention relates to the technical field of rocket recovery, in particular to an auxiliary recovery system for rocket recovery.

Background

The rocket recovery technology is a bright pearl in the technical field of aerospace, and is the comprehensive embodiment of the strength of the aerospace technology, so that the rocket recovery technology is also greatly concerned by all aerospace major countries. At present, no liquid rocket recovery scheme which is put into use is available in China. Rocket X, blue origin in the United states, has been used with many successful rocket recoveries. For example, the rocket recovery solution adopted by Space X company in its last few shots is: in the rocket secondary landing process, the main engine is ignited to realize deceleration, and the attitude control engine is used for adjusting the flight attitude of the rocket secondary, so that the rocket is ensured to fall in an approximately vertical attitude. As the falling rocket substage approaches the ground, the support legs, in a collapsed state, open, allowing the rocket to rest stably on a landing surface (e.g., ground or offshore platform).

Specifically, retractable supporting legs are arranged at the bottom of the rocket stage. In the process of rocket flight, the supporting legs can be always in a furled state. After the rocket substages finish working and are separated from the rocket bodies, the main engine is shut down, and the rocket substages fly to a preset landing area or fly back to a launching field. When the rocket approaches the ground, the main engine is ignited again to start, and the rocket is decelerated. Before falling to the ground, the support legs are unfolded and locked under the action of high-pressure gas. The rocket substage is controlled by the main engine to reduce the speed to 0 at the moment of final touchdown, and is stabilized on a recovery site or a recovery ship by the unfolded supporting legs.

The rocket sublevel vertical recovery technology has high requirements on controlling the attitude and the speed of the rocket during landing, and if the attitude or the speed of the rocket sublevel landing is not well controlled, the rocket is likely to topple or explode, so that the rocket recovery is completely failed.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide an auxiliary recovery system for rocket recovery, which can guide and limit the motion of a sublevel to be recovered before landing, so that the phenomenon that the sublevel to be recovered turns over or topples during landing is avoided, the attitude requirement of the rocket to be recovered is reduced, and the recovery success rate is improved.

The invention provides an auxiliary recovery system for rocket recovery, which comprises: the device comprises a bearing platform, a side wall, a plurality of telescopic devices and a controller, wherein the side wall is arranged on one side of the bearing platform and connected with the bearing platform; the part of the side wall facing each other is provided with a plurality of pairs of openings corresponding to each other, at least one of the openings corresponding to each pair is provided with the telescopic device, and the length of the telescopic device after being started is larger than the distance between the two corresponding openings; the controller is used for controlling the corresponding telescopic devices to be started when the to-be-recovered substages of the rocket fall to the inner end part of the outer side wall, so that the telescopic devices extend out from the openings matched with the telescopic devices on the same side to the corresponding openings to enter the corresponding openings, and the telescopic devices circumferentially surround the to-be-recovered rocket substages to guide and limit the to-be-recovered rocket substages in a falling mode.

In one embodiment, the auxiliary recovery system further comprises a detector, the detector is used for detecting a first projection position of the rocket stage to be recovered on the bearing platform along a first direction of the gravity line, and the controller is used for controlling the corresponding telescopic device to extend according to the first projection position.

In one embodiment, the controller is used for controlling the extension of the corresponding telescopic device according to the relation between the second projection position and the first projection position of the perforated connecting line corresponding to each other on the carrying platform along the first direction; the controller controls a plurality of telescopic devices which are arranged around the first projection position and correspond to a second projection position which is closest to the first projection position to be started.

In one embodiment, the detector is further configured to detect a depth of entry of the lower end of the rocket stage to be recovered into the side wall, and the controller controls the retractable device to actuate when the depth is greater than a distance from the aperture to the outer end of the side wall.

In one embodiment, the detector comprises a plurality of cameras and range finders disposed at different positions on the side wall.

In one embodiment, the telescopic device is a multi-stage cylinder; the multistage cylinder comprises a master cylinder barrel and a plurality of slave cylinder barrels which are sleeved with each other, the master cylinder barrel forms a fixed part of the multistage cylinder, the slave cylinder barrels form a telescopic part of the multistage cylinder, and a fuel gas generator is arranged in the master cylinder barrel; and the gas generator pushes the multiple sub-cylinder barrels in the multi-stage cylinder to extend after being started, and the sub-cylinder barrels are arranged in two openings corresponding to the multi-stage cylinder in a spanning mode.

In one embodiment, the detector comprises a plurality of cameras and range finders arranged at different positions on the side wall, the detector is used for detecting the displacement distance from the lower end face of the rocket stage to be recovered to the surface of the outer end part of the side wall, and the controller controls the ignition of the gas generator through an electric signal when the displacement distance is larger than the distance from the opening to the outer end part of the side wall.

In one embodiment, the sidewalls include a first sidewall and a third sidewall facing each other, and a second sidewall and a fourth sidewall facing each other; the two ends of the first side wall are respectively connected with one ends of the second side wall and the fourth side wall, and the two ends of the third side wall are respectively connected with the other ends of the second side wall and the fourth side wall; the first side wall and the third side wall are provided with a first group of open holes at positions close to the outer end portions, the second side wall and the fourth side wall are provided with a second group of open holes at positions close to the outer end portions, and the shortest distance between the first group of open holes and the bearing platform is larger than the largest distance between the second group of open holes and the bearing platform.

In one embodiment, the side walls further comprise openings uniformly disposed therealong proximate to the load-bearing platform, wherein the minimum distance from the openings of the first and third side walls to the load-bearing platform is greater than the maximum distance from the openings of the second and fourth side walls to the load-bearing platform.

In one embodiment, a limiting structure is arranged in the opening corresponding to the opening provided with the multi-stage cylinder, and a sub-cylinder barrel far away from the main cylinder barrel is provided with a matching structure matched with the limiting structure and a guide structure for the movement of the limiting structure; after the multistage cylinder is started, the limiting structure moves along the guide structure and enters the matching structure for limiting.

In one embodiment, the guide structure is a sliding groove arranged on a sub-cylinder barrel far away from the main cylinder barrel, the limit structure is a protrusion arranged on an opening corresponding to the multi-stage cylinder, the matching structure is a recess matched with the protrusion in shape, and the recess is arranged at the limit position of the sliding groove for the protrusion to slide; in the process of extending the multi-stage cylinder, the protrusion enters the sliding groove and slides along the sliding groove, when the multi-stage cylinder extends to the limit position, the protrusion enters the recess and is limited by the recess, and the extended multi-stage cylinder is prevented from being separated from the corresponding opening under the pressure of the rocket stage to be recovered.

According to the embodiment of the invention, by adopting the auxiliary recovery system, the attitude requirement on the rocket during landing can be obviously reduced, the rocket is prevented from overturning at the moment of landing, and the success rate of rocket recovery is improved.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate exemplary embodiments of the invention and together with the description, serve to explain the principles of the invention.

Fig. 1 is a schematic structural diagram of an auxiliary recovery system according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of a controller controlling a plurality of retractable devices according to an embodiment of the present invention.

Fig. 3a and 3b are schematic diagrams illustrating the supporting device, the retractable device and the opening structure of the auxiliary recycling system according to an embodiment of the present invention.

Fig. 4 is a schematic diagram of a connection structure of a controller, a detector and a retractable device according to an embodiment of the present invention.

FIG. 5 is a schematic top view of a rocket stage according to an embodiment of the present invention, after retraction, mated with a retractable device in an extended state.

Fig. 6 is a schematic structural view of a multistage cylinder according to an embodiment of the present invention.

FIG. 7 is a schematic diagram of an embodiment of an auxiliary recycling system with different heights of corresponding sidewall openings.

FIG. 8 is a schematic structural diagram of an auxiliary recycling system including a plurality of supporting stages according to an embodiment of the present invention.

Fig. 9 is a schematic view of a position of a limiting and guiding structure in a retractable device in an auxiliary recovery system according to an embodiment of the present invention.

Detailed Description

Reference will now be made in detail to various exemplary embodiments of the invention, the detailed description should not be construed as limiting the invention but as a more detailed description of certain aspects, features and embodiments of the invention.

It will be apparent to those skilled in the art that various modifications and variations can be made in the specific embodiments of the present disclosure without departing from the scope or spirit of the disclosure. Other embodiments will be apparent to those skilled in the art from consideration of the specification. The specification and examples are exemplary only.

The existing liquid rocket recovery technology needs to add 4 telescopic supporting legs on the rocket substage and is provided with a set of high-pressure gas actuating mechanism. Among them, the high-pressure gas actuation mechanism is used to deploy the support legs when the rocket substage to be recovered approaches the landing surface, increasing undoubtedly the complexity and structural weight of the rocket system.

In the takeoff stage of the rocket, the additional mechanisms are dead weights which are useless for the rocket to fly, and the carrying capacity of the rocket is reduced. In addition, with the existing rocket recovery technology, the speed and the attitude of the rocket substage must be accurately controlled during the rocket substage landing process, and the speed of the rocket substage is reduced to 0 at the moment of touchdown, and the attitude is kept vertical. Similarly, when a rocket is recovered at sea, the above-mentioned requirements for recovering a rocket on the ground and the requirements for sea conditions are also high. For example, a hull for rocket recovery cannot swing to a large extent when a substage rocket lands.

An auxiliary recovery system for rocket recovery is provided. Referring to fig. 1 and 2, the auxiliary recovery system includes: the device comprises a bearing platform 1, a side wall 2 which is arranged on one side of the bearing platform 1 and is connected with the bearing platform 1, a plurality of telescopic devices 3 which are arranged on the outer side of the side wall 2, and a controller 4 for controlling the starting of the telescopic devices. The portions of the side walls 2 facing each other are provided with pairs of mutually corresponding openings 21, at least one of each pair of mutually corresponding openings being provided with a telescopic means 3, the length of extension of the telescopic means 3 after activation being greater than the distance between the two corresponding openings. The controller 4 is used for controlling the corresponding telescopic devices 3 to be started when the substages to be recovered of the rocket fall to the inner end part of the side wall 2, so that the telescopic devices 3 extend out from the openings matched with the telescopic devices 3 at the same side to the corresponding openings (namely, two openings connected by a dotted line in the figure) to enter the corresponding openings, and the telescopic devices 3 are matched with each other to surround the substages to be recovered along the outer peripheral direction of the substages to be recovered so as to guide and limit the descent of the substages to be recovered.

According to the auxiliary recovery system, the controller controls the telescopic device to extend and span the corresponding opening of the side wall before the sub-stage to be recovered descends, so that the sub-stage to be recovered can be guided and limited in descending, the phenomenon that the sub-stage is turned over or overturned due to unstable landing is avoided, the requirement on the recovery posture of the sub-stage to be recovered is lowered, and the recovery success rate is improved.

In the present application, the carrying platform 1 may be a fixed platform or a movable platform. When the bearing platform 1 is a fixed platform, the substage to be recovered moves to the upper part of the bearing platform 1 through a side-pushing engine, and moves to the bearing platform 1 in a roughly vertical state through adjusting the posture. When the bearing platform 1 is a movable platform, it may be equipped with a signal receiving system (for receiving the position signal returned by the substage to be recovered in real time) and an autonomous navigation motion system, so as to obtain the motion information of the substage to be recovered in real time through communication with the substage to be recovered, and autonomously move towards the substage of the rocket to be recovered, thereby reducing the requirement on the lateral maneuvering capability of the substage to be recovered.

Additionally, a secondary recovery system may be provided within the recovery farm. And preferably the auxiliary recovery system is movable autonomously within the recovery farm. For example, a wheel structure and a motor driving the wheel structure to rotate are arranged on the side (i.e. the lower side of the orientation shown in fig. 1) of the carrying platform 1 far away from the side wall 2, and the auxiliary recovery system is provided with an autonomous navigation motion control system, so that the motor is controlled by the autonomous navigation motion control system to drive the auxiliary recovery system to move in the recovery field. In addition, the auxiliary recovery system can also be controlled in a manual remote control mode.

Referring to fig. 3a, for example, the side wall 2 is located on the side of the load-bearing platform 1 remote from the recovery site floor or offshore platform (the lower side is shown where the floor or offshore platform is located). For example, as shown in fig. 3a, the side wall 2 is disposed at a position near the outer edge of the carrying platform 1, and a plurality of supporting devices 5 are disposed at the outer edge of the side wall 2, and a plurality of retractable devices 3 may be respectively supported by the plurality of supporting devices 5. For example, one end of the retractable device 3 is fixedly connected to the supporting device 5 far away from the loading platform, the other end of the retractable device can be overlapped in the opening 21 on one side of the sidewall 2, and the extending direction of the retractable device 3 is substantially the same as the connecting line direction of the corresponding opening 21 on the opposite sidewall 2, so as to ensure that the retractable device can accurately enter the opening corresponding to the opening when extending.

Specifically, as shown in fig. 3b, the outermost side of the sidewall comprises a boss 20 protruding beyond the sidewall 2, and the support means 5 is provided on an upper end surface 201 of the boss. The height of the upper end surface 201 of the boss 20 is smaller than the inner height of the side wall 2, so that a certain height difference is formed between the upper end surface 201 of the boss and the inner side of the side wall 2, and the opening 21 on the inner side of the side wall 2 is located above the upper end surface 201 of the boss, so that the telescopic device 3 of the supporting device 5 arranged on the upper end surface 201 of the boss is just matched with the opening 21 on the inner side of the side wall 2.

For example, the supporting device 5 is connected with the upper end surface 201 of the boss 2 of the side wall through a bolt, and the structure of the other end is matched with the telescopic device 3, so that the telescopic device 3 is prevented from shaking up and down and left and right, and the telescopic device is ensured to enter the opening of the corresponding side wall along the extension direction in the extension process.

The opening 21 of the side wall 2 may be located away from the load-bearing platform 1. For example, the plurality of apertures 21 may be evenly distributed along the side wall 2. These openings 21 correspond to each other in order to provide a load bearing for the two ends of the telescopic device 3 after the telescopic device 3 is extended, so that the middle part of the telescopic device 3 can limit and guide the rocket stages to be recovered. Preferably, the cross section of the sidewall 2 in the vertical direction may be a square, rectangle or other quadrilateral structure, thereby simplifying the structure of the auxiliary recovery system and reducing the production cost.

The controller 4 is mainly used for controlling the retractable device 3 to be opened so as to form surrounding of the rocket recovery substage on the inner side of the side wall 2 and avoid the rocket substage from turning over or overturning. When the telescopic device 3 is a multi-stage cylinder structure described below, the controller 4 can be electrically connected to an ignition switch of the gas generator, so that after the ignition switch is turned on, the gas generator can rapidly open the sub-cylinder barrels of the multi-stage cylinder and straddle the sub-cylinder barrels in the corresponding openings in the side walls. After the rocket substages are recovered, the multistage cylinder barrel can be reset to a contraction state, and the gas generator is replaced for the next recovery.

Referring to fig. 4, the secondary recovery system further includes a detector 6. The detector 6 is used for detecting a first projection position of the rocket substage to be recovered on the bearing platform 1 along a first direction where the gravity line is located, and the controller 4 is used for controlling the corresponding telescopic device 3 to extend according to the first projection position. For example, the detector 6 is used to detect the position of the rocket substage above the loading platform 1 in real time and transmit the detection signal to the controller 4. The controller 4 controls the corresponding retractable device 3 to be opened after the rocket stages fall to a certain depth in the side wall according to the detection signal of the detector 6.

In general, the telescopic means 3 are activated when the rocket stages are lowered below the apertures 21 in the side walls 2, so as to avoid the telescopic means 3 in the extended state from obstructing the descent of the rocket stages. Furthermore, the extension of the telescopic means 3 cannot interfere with the descent of the rocket stages. In the embodiment of the present application, the controller 4 may control the actuation of the plurality of retractable devices 3 closest to the rocket substage after the actuation of the extension through the first projection position information sent by the detector 6. After the rocket substages are recovered, the projection view in the vertical direction can be in the state as shown in fig. 5, so that the descending rocket substages can enter the limit areas formed by the telescopic devices 3, and the movement of the rocket substages in the radial direction is limited by the limit areas.

In this embodiment, two of the telescopic devices 3 may restrict the motion of the rocket substage from two sides of the rocket substage, and two other telescopic devices 3 may restrict the motion of the rocket substage from two other sides of the rocket substage, for example, so that four telescopic devices engaged in pairs may restrict the motion of the rocket substage back and forth and side to side, as shown in fig. 5. For example, when the cross section of the side wall 2 in the vertical direction is rectangular or square, the two sets of retractable means 3 are respectively the retractable means 3 provided on one of the first set of opposite side walls 2 and the retractable means 3 provided on one of the second set of opposite side walls 2. After the telescopic means 3 are extended, the rocket stages are surrounded by two sets of telescopic means 3 just from the outside in the radial direction of the rocket stages when viewed in the vertical direction as shown in fig. 5 (for example, the region surrounded by two sets of telescopic means is rectangular or square, wherein the side length of the short side or square of the rectangle is larger than the diameter of the cross section of the rocket stage). For example, in the vertical direction, one set of the retractable devices 3 is staggered from the other set of the retractable devices 3 when the retractable devices start to extend (i.e. they are not staggered from each other in the vertical direction), so that the retractable devices do not interfere with each other or collide with each other when the retractable devices start to extend.

For example, after the controller 4 receives the projection signal detected by the detector 6, the controller 4 may control the extension of the corresponding retractable device 3 according to the relationship between the first projection position and the second projection position (which may be pre-stored in the controller) of the supporting platform 2 along the first direction of the gravity line by the connection line of the corresponding openings 21. The controller 4 controls the plurality of retractable devices 3 corresponding to a second projection position around the first projection position and closest to the first projection position to be started. The extension of the telescopic device 3 is to prevent the rocket substages from moving back and forth and left and right, so as to prevent the falling rocket substages from turning on one side, obviously, the extension action of the telescopic device 3 can not interfere the falling of the rocket substages. Therefore, when the line of the corresponding opening 21 with which the telescopic device 3 is fitted does not coincide with the projection of the rocket substage in the vertical direction, the telescopic device 3 does not interfere with the descent motion of the rocket substage during the starting process. In addition, the distance between the telescopic device 3 and the rocket sublevel can be reduced by selecting the telescopic device 3 corresponding to the second projection closest to the descending rocket sublevel projection, so that the landing rocket is effectively limited, the rocket sublevel is prevented from overturning, and the recovery success rate is improved.

For example, the detector 6 is also used to detect the depth of entry of the lower end of the rocket stage to be recovered into the side wall, the controller 4 controlling the actuation of the telescopic means 3 when this depth is greater than the distance from the aperture 21 to the outer end of the side wall 2. According to the controller provided by the embodiment of the invention, the corresponding telescopic device is started when the lower end part of the rocket sublevel passes through the height position of the opening, so that the extension movement of the telescopic device is prevented from interfering the falling movement of the rocket sublevel, and the recovery success rate is improved.

For example, the detector 6 may comprise a plurality of cameras and range finders arranged at different positions of the side wall 2. The falling position of the rocket can be better detected by adopting a plurality of cameras arranged at different positions of the side wall 2 and the range finder to observe the descending rocket sublevels at multiple angles, so that the controller can more accurately and punctually start the corresponding telescopic device.

In one embodiment, as shown in fig. 6, the telescopic device 3 is a multi-stage cylinder. The multistage cylinder comprises a main cylinder barrel 30 and a plurality of sub cylinder barrels 31 which are sleeved with each other, the main cylinder barrel 30 forms a fixed part of the multistage cylinder, and the plurality of sub cylinder barrels 31 form a telescopic part of the multistage cylinder. A gas generator 32 is disposed within the parent cylinder barrel 30. The gas generator 32 pushes the plurality of sub-cylinders 31 in the multi-stage cylinder to be elongated after starting and to straddle the two openings 21 corresponding to the multi-stage cylinder. On one hand, the multi-stage cylinder and the fuel gas generator are adopted in the embodiment of the invention, on the other hand, the controller can be electrically connected through the ignition switch, the control on the fuel gas generator is simply realized, the structure is simple, and the reliability is high; on the other hand, the mode that the gas generator pushes the sub-cylinder barrel can quickly realize the starting of the multi-stage cylinder and the extension to the motion limit of the multi-stage cylinder, and even when the descending speed of the rocket is high, the guidance and the limitation of the rocket sub-stage can still be realized.

As mentioned above, the detector 6 comprises a plurality of cameras and rangefinders arranged at different positions of the side wall 2, the detector 6 being adapted to detect the depth of the lower end face of the rocket stage to be recovered into the side wall (for example, by detecting the depth by means of the cameras and rangefinders), and the controller 4 being adapted to control the ignition of the gas generator by means of an electrical signal when the depth is greater than the distance from the aperture 21 to the outer end of the side wall 2. As mentioned above, this method makes it possible to avoid the actuation of the telescopic device 3 interfering with the descent motion of the rocket stage.

As described above, when the telescopic device 3 has a structure including a plurality of cylinders, the gas generator is a gas generator. The controller 4 controls the starting of the gas generator through an electromagnetic switch. Specifically, when the controller 4 performs the starting of the multi-stage cylinder, a power-on signal may be sent to the electromagnetic switch, so that the electromagnetic switch generates a magnetic force to connect the power supply connected to the gas generator, so that the gas generator is ignited after receiving the current signal to generate a large amount of gas to push the multi-stage cylinder to be opened.

Meanwhile, in order to facilitate the controller 4 to select the corresponding retractable device 3 to be opened, the retractable device, the corresponding opening and the projection of the corresponding opening on the bearing platform 1 in the vertical direction can be numbered in the controller 4 in sequence. When the detector 6 sends detection information (e.g., information about the relationship between the corresponding opening projection and the rocket stage projection) including the detection result to the controller 4, the controller 4 may directly select the retractable device 3 to be activated according to the detection information. Specifically, when the detector 6 is a camera, the camera can detect all the corresponding opening lines and the projection information of the rocket substages on the carrying platform 1, so that the controller 4 can select the retractable device corresponding to the opening line closest to the rocket substage projection to be started.

Referring to fig. 7, for example, in one embodiment, the side walls 2 include a first side wall and a third side wall facing each other (i.e., the side walls facing each other as shown in the drawing), and a second side wall and a fourth side wall facing each other (i.e., the side walls facing each other as shown in the drawing). Wherein the both ends of first lateral wall are connected the second lateral wall respectively with the one end of fourth lateral wall, the both ends of third lateral wall are connected the other end of second lateral wall and fourth lateral wall respectively. The first group of holes M1 are arranged at the positions of the first side wall and the third side wall close to the outer end, the second group of holes M2 are arranged at the positions of the second side wall and the fourth side wall close to the outer end, wherein the shortest distance between the first group of holes M1 and the bearing platform 1 is larger than the largest distance between the second group of holes M2 and the bearing platform. The shortest distance from the first set of correspondingly disposed openings to the supporting platform 1 is the distance from the lower end of the opening (the end close to the supporting platform 1) to the supporting platform 1, and similarly, the largest distance from the second set of openings M2 to the supporting platform 1 is the distance from the upper end (the end far from the supporting platform) of the second set of openings M2 to the supporting platform 1. In this embodiment of the present invention, by adjusting the vertical position relationship between the first set of openings M1 and the second set of openings M2, the telescopic devices corresponding to the two sets of openings can be prevented from interfering or colliding during the extending process.

It should be noted that, the openings of the first set of openings M1 disposed on the first side wall and the openings disposed on the third side wall may have the same or different heights from the supporting platform 1. Under the condition that the telescopic device 3 is a multi-stage cylinder, considering that the sub-cylinder barrel can slightly bend towards the direction of the bearing platform 1 in the extension process (especially, when the distance between the first side wall and the third side wall is larger), the opening height of the first side wall can be slightly higher than the opening height of the opposite third side wall (the multi-stage cylinder is arranged on the outer side of the first side wall), so that the multi-stage cylinder can be better ensured to enter the corresponding opening of the third side wall after being extended. In addition, the height and the shape of the openings on the same side wall can be the same or different, and the simple deformation based on the scheme of the application is within the protection scope of the scheme.

In one embodiment, the sidewall 2 further comprises two sets of openings corresponding to each other uniformly disposed along the position thereof close to the loading platform 1, wherein the minimum distance from the openings corresponding to the first sidewall and the third sidewall to the loading platform 1 is greater than the maximum distance from the openings of the second sidewall and the fourth sidewall to the loading platform 1. As mentioned above, the positions of the minimum distances from the first side wall and the third side wall to the load-bearing platform 1 are at the lower end of the opening, and the positions of the maximum distances from the second side wall and the fourth side wall to the load-bearing platform 1 are at the upper end of the opening, and by further arranging the opening at the position where the side walls are close to the load-bearing platform 1, the retractable device 3 matched with the opening can further limit the to-be-recovered rocket stage, so that the to-be-recovered rocket stage can more stably fall on the load-bearing platform 1. In addition, as mentioned above, by defining the distance between the corresponding openings of the opposite sidewalls, the telescopic devices in different directions can be prevented from being interfered or impacted during the extension process, thereby further improving the reliability of the auxiliary recovery system.

Further, in order to further improve the stability after the substage to be recovered falls, multilayer openings (wherein, each layer of openings is provided with a group of telescopic devices, and two adjacent layers of openings can be spaced by 3-5 meters) can be arranged at intervals outside the side wall along the vertical direction, so that continuous guiding and multiple limiting of the substage to be recovered of the descending rocket are realized through continuous starting of the telescopic devices 3 arranged at the groups of openings with different heights. In the case of a sidewall 2 having multiple layers of openings (i.e. different openings having different heights in the vertical direction), for example, in any layer of openings located along the sidewall 2 at different heights, the retractable device 3 may be extended in only one direction of the sidewall 2, thereby avoiding interference of the extendable retractable device in that direction with the sidewall in the other direction.

As shown in fig. 8, in order to ensure that a plurality of sets of openings are provided along the outside of the side wall 2, the outside wall 2 is provided with corresponding support stands 22, 23, 24 and corresponding support means 5 (not shown) are provided at the support stands. I.e. the outer wall support platforms 22, 23, 24 may be arranged at vertical intervals, so that the support platforms of each layer may be provided with the telescopic device 3 and the openings corresponding to the layer, respectively.

In this embodiment, further, in the case that the side wall 2 has the first side wall, the third side wall, and the second side wall and the fourth side wall, as described above, the controller 4 may control the retractable device corresponding to the opening of the first side wall and the third side wall opposite to each other in one of the adjacent layers to be activated, and control the retractable device corresponding to the opening of the second side wall and the fourth side wall opposite to each other in the opening of the other layer to be activated, so that the controller improves the supporting stability of the retractable device to the recycling sub-stage by controlling the direction of the retractable device of the adjacent layers to be different.

Referring to fig. 9, for example, in one embodiment, a limiting structure is arranged in the opening corresponding to the opening provided with the multi-stage cylinder, and the outermost sub-cylinder 33 far away from the main cylinder 30 is provided with a matching structure matching with the limiting structure and a guiding structure for the movement of the limiting structure. After the multistage cylinder is started, the limiting structure moves along the guide structure and enters the matching structure for limiting. According to the embodiment of the invention, the limiting structure is arranged on the opening, the matching structure and the guide structure are arranged at the corresponding position of the sub-cylinder barrel entering the opening after the multi-stage cylinder extends, and the limiting structure is in contact with the matching structure under the guidance of the guide structure, so that the front end and the side wall of the extended multi-stage cylinder are fixed.

In this embodiment, if the side wall is thinner, the guiding structure (e.g., a groove) may be disposed on the sub-cylinder 33 of the multi-stage cylinder, and the limiting structure in the opening moves along the guiding structure and enters the matching structure of the sub-cylinder 33, so as to limit the sub-cylinder 33 and reduce the cost.

Specifically, the guide structure is a sliding groove arranged on the sub-cylinder barrel 33 far away from the main cylinder barrel 30, the limiting structure is a protrusion arranged on an opening corresponding to the multi-stage cylinder, and the matching structure is a recess with a shape matched with the protrusion. After the multi-stage cylinder is expanded in an extending mode, the sliding groove faces the protrusion arranged on the opening (for example, when the multi-stage cylinder is expanded, the sliding groove faces downwards, the protrusion is arranged on the lower side of the opening, and when the multi-stage cylinder is expanded, the sliding groove faces upwards, the protrusion is arranged on the upper side of the opening, so that the protrusion can move in the sliding groove in the expanding process of the multi-stage cylinder). The recess for engaging the projection may be provided at an extreme position of the slide groove for sliding the projection, which may be a sliding extreme position of the sub-cylinder 33 at the slide groove thereof away from the outer end portion of the sub-cylinder 33.

At the in-process that multistage cylinder extension and contact correspond the trompil, the arch on the trompil gets into the spout and slides along the spout, when multistage cylinder extension to extreme position, the arch gets into the sunken of setting on the sub-cylinder section just to multistage cylinder is spacing fixed, deviates from the trompil under the lateral pressure that receives to wait to retrieve rocket sublevel in order to avoid the multistage cylinder of extension. According to the auxiliary recovery system provided by the embodiment of the invention, the bulges are arranged on the side wall openings, the sliding grooves are arranged on the sub-cylinder barrels, and the concave parts matched with the bulges are arranged, so that the multi-stage air cylinder can be quickly positioned and limited after being extended, and the working stability of the auxiliary recovery system is improved.

According to the embodiment of the invention, by adopting the auxiliary recovery system, the attitude requirement on the rocket during landing can be obviously reduced, the rocket is prevented from overturning at the moment of landing, and the success rate of rocket recovery is improved.

The rocket recovery device and the rocket recovery system can be matched with the existing rocket adopting a supporting leg supporting mode, but the starting time of the part for rocket substage recovery landing and the telescopic device arranged outside the side wall of the bearing platform needs to be correspondingly matched with the opening action of the supporting leg, namely the action process of the auxiliary recovery system (namely, the corresponding telescopic device is started only when the part provided with the supporting leg of the rocket recovery substage is positioned below the hole at the upper end of the side wall, and the rocket recovery substage is not landed at the moment) and the space of each structure do not influence the opening of the supporting leg, thereby further improving the success rate of rocket substage recovery.

The foregoing is merely an illustrative embodiment of the present invention, and any equivalent changes and modifications made by those skilled in the art without departing from the spirit and principle of the present invention should fall within the protection scope of the present invention.

Claims (10)

1. An auxiliary recovery system for rocket recovery, comprising: the device comprises a bearing platform, a side wall, a plurality of telescopic devices and a controller, wherein the side wall is arranged on one side of the bearing platform and connected with the bearing platform;

the part of the side wall facing each other is provided with a plurality of pairs of openings corresponding to each other, at least one of the openings corresponding to each pair is provided with the telescopic device, and the length of the telescopic device after being started is larger than the distance between the two corresponding openings;

the controller is used for controlling the corresponding telescopic devices to be started when the rocket substages to be recovered land to the inner end part of the outer side wall, so that the telescopic devices extend out from the openings matched with the telescopic devices on the same side to the corresponding openings to enter the corresponding openings, and the plurality of telescopic devices circumferentially surround the rocket substages to be recovered so as to guide and limit the rocket substages to be recovered;

the side wall is arranged at a position, close to the outer edge, of the bearing platform, a plurality of supporting devices are arranged at the outer edge of the side wall, and the plurality of telescopic devices are respectively supported by the plurality of supporting devices.

2. An auxiliary recovery system for rocket recovery as recited in claim 1, wherein the outermost side of said sidewalls includes a boss projecting outwardly of said sidewalls, said support means being provided on an upper end surface of said boss.

3. An auxiliary recovery system for rocket recovery according to claim 2 wherein the height of the upper surface of said boss is less than the height of the inner side of said side wall to form a height difference between said upper surface of said boss and the inner side of said side wall, and the opening of the inner side of said side wall is located above said upper surface, so that the retractable means supported by the supporting means provided on said upper surface is matched with the opening of the inner side of said side wall.

4. An auxiliary recovery system for rocket recovery according to claim 1 further comprising a detector for detecting a first projected position of a rocket substage to be recovered on said load-bearing platform along a first direction of gravity, said controller for controlling the elongation of the respective telescopic device according to said first projected position.

5. An auxiliary recovery system for rocket recovery according to claim 4 wherein said controller is configured to control the elongation of the corresponding retractable device according to the relationship between the line of apertures corresponding to each other at the second projected position of said load-bearing platform in said first direction and said first projected position;

the controller controls a plurality of telescopic devices which are arranged around the first projection position and correspond to a second projection position which is closest to the first projection position to be started.

6. An auxiliary recovery system for rocket recovery as recited in claim 4, wherein said detector is further adapted to detect a displacement distance from a lower end of a rocket stage to be recovered to a surface on which said outer end of said side wall is located, said controller controlling said retractable device to actuate when said displacement distance is greater than a distance from said aperture to said outer end of said side wall.

7. An auxiliary recovery system for rocket recovery as recited in claim 6, wherein said detector comprises a plurality of cameras and range finders disposed at different locations on said side wall, said detector is adapted to detect said displacement distance from the lower end surface of the rocket stage to be recovered to the surface of said outer end portion of said side wall, and said controller is adapted to control the ignition of said gas generator by an electrical signal when said displacement distance is greater than the distance from said aperture to said outer end portion of said side wall.

8. An auxiliary recovery system for rocket recovery as recited in claim 1, wherein said retractable means is a multi-stage cylinder; the multistage cylinder comprises a master cylinder barrel and a plurality of slave cylinder barrels which are sleeved with each other, the master cylinder barrel forms a fixed part of the multistage cylinder, the slave cylinder barrels form a telescopic part of the multistage cylinder, and a fuel gas generator is arranged in the master cylinder barrel;

and the gas generator pushes the multiple sub-cylinder barrels in the multi-stage cylinder to extend after being started, and the sub-cylinder barrels are arranged in two openings corresponding to the multi-stage cylinder in a spanning mode.

9. An auxiliary recovery system for rocket recovery as recited in claim 1, wherein said sidewalls include first and third sidewalls facing each other, and second and fourth sidewalls facing each other; the two ends of the first side wall are respectively connected with one ends of the second side wall and the fourth side wall, and the two ends of the third side wall are respectively connected with the other ends of the second side wall and the fourth side wall;

the first side wall and the third side wall are provided with a first group of open holes at positions close to the outer end portions, the second side wall and the fourth side wall are provided with a second group of open holes at positions close to the outer end portions, and the shortest distance between the first group of open holes and the bearing platform is larger than the largest distance between the second group of open holes and the bearing platform.

10. An auxiliary recovery system for rocket recovery as recited in claim 9, wherein said sidewalls further comprise apertures uniformly disposed along the sidewalls at locations adjacent to said load-bearing platform, wherein the minimum distance from the apertures of said first and third sidewalls to said load-bearing platform is greater than the maximum distance from the apertures of said second and fourth sidewalls to said load-bearing platform.

Images