CN113309227A - Moon cabin body structure system combining mechanical expansion and inflation expansion and method - Google Patents
Moon cabin body structure system combining mechanical expansion and inflation expansion and method Download PDFInfo
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- CN113309227A CN113309227A CN202110591387.2A CN202110591387A CN113309227A CN 113309227 A CN113309227 A CN 113309227A CN 202110591387 A CN202110591387 A CN 202110591387A CN 113309227 A CN113309227 A CN 113309227A
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- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B1/00—Constructions in general; Structures which are not restricted either to walls, e.g. partitions, or floors or ceilings or roofs
- E04B1/343—Structures characterised by movable, separable, or collapsible parts, e.g. for transport
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- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B1/00—Constructions in general; Structures which are not restricted either to walls, e.g. partitions, or floors or ceilings or roofs
- E04B1/38—Connections for building structures in general
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- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B1/00—Constructions in general; Structures which are not restricted either to walls, e.g. partitions, or floors or ceilings or roofs
- E04B1/62—Insulation or other protection; Elements or use of specified material therefor
- E04B1/74—Heat, sound or noise insulation, absorption, or reflection; Other building methods affording favourable thermal or acoustical conditions, e.g. accumulating of heat within walls
- E04B1/76—Heat, sound or noise insulation, absorption, or reflection; Other building methods affording favourable thermal or acoustical conditions, e.g. accumulating of heat within walls specifically with respect to heat only
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- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
- E04B1/00—Constructions in general; Structures which are not restricted either to walls, e.g. partitions, or floors or ceilings or roofs
- E04B1/62—Insulation or other protection; Elements or use of specified material therefor
- E04B1/92—Protection against other undesired influences or dangers
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- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04H—BUILDINGS OR LIKE STRUCTURES FOR PARTICULAR PURPOSES; SWIMMING OR SPLASH BATHS OR POOLS; MASTS; FENCING; TENTS OR CANOPIES, IN GENERAL
- E04H1/00—Buildings or groups of buildings for dwelling or office purposes; General layout, e.g. modular co-ordination or staggered storeys
- E04H1/12—Small buildings or other erections for limited occupation, erected in the open air or arranged in buildings, e.g. kiosks, waiting shelters for bus stops or for filling stations, roofs for railway platforms, watchmen's huts or dressing cubicles
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- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04H—BUILDINGS OR LIKE STRUCTURES FOR PARTICULAR PURPOSES; SWIMMING OR SPLASH BATHS OR POOLS; MASTS; FENCING; TENTS OR CANOPIES, IN GENERAL
- E04H1/00—Buildings or groups of buildings for dwelling or office purposes; General layout, e.g. modular co-ordination or staggered storeys
- E04H1/12—Small buildings or other erections for limited occupation, erected in the open air or arranged in buildings, e.g. kiosks, waiting shelters for bus stops or for filling stations, roofs for railway platforms, watchmen's huts or dressing cubicles
- E04H1/1205—Small buildings erected in the open air
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- E—FIXED CONSTRUCTIONS
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- E04B—GENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
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Abstract
The invention provides a moon cabin structure system combining mechanical expansion and inflation expansion and a method thereof, wherein the structure system comprises an upper platform, a lower platform, a ball screw connected between the upper platform and the lower platform, an upper sliding ring rod, a middle sliding ring rod, a lower sliding ring rod, a linear bearing optical axis support rod, a ball screw support bearing assembly, a ball screw fixed bearing assembly, an upper movable ring rod, a middle movable ring rod, a lower movable ring rod, a motor, an expandable ground and a skin system; the motor drives the ball screw to rotate, and the ball screw drives the three sliding ring rods to move up and down; when the foldable bicycle is unfolded, the upper sliding ring rod and the middle sliding ring rod both move upwards, and the lower sliding ring rod moves downwards; the moon cabin structure system is in a contracted cylinder shape before being unfolded, is radially expanded in the unfolding process and takes a shuttle shape, and is in a sphere shape after being unfolded. The invention has the advantages of small transmitting volume, high folding efficiency, strong space protection capability, simple engineering implementation and low transmitting cost.
Description
Technical Field
The invention belongs to the field of lunar capsule body structures, and particularly relates to a lunar capsule body structure system combining mechanical expansion and inflation expansion and a method.
Background
The traditional large-scale rigid sealed cabin is heavy in mass, large in size, high in launching cost, difficult to assemble on orbit and limited by the envelope size of a carrier rocket, the design is relatively compact, the effective space in the cabin is narrow, so that a plurality of scientific experiments are difficult to smoothly develop, and the requirements of future deep space exploration and development are more and more difficult to meet. In recent years, with the acceleration of deep space exploration pace, large inflatable deployable structures are becoming the focus of more and more attention. The inflatable and expandable structure is a novel space structure, is made of light flexible composite materials, is in a folded state before launching, is inflated and expanded after being carried to a preset working orbit by a launch vehicle, and therefore a larger effective space or surface area is provided inside or on the surface of the inflatable and expandable structure. Compared with the traditional space rigid deployable structure, the inflatable deployable structure has the advantages of small volume, light weight, low processing and manufacturing cost, easy design and forming, high deployment reliability and the like, and in recent years, due to the development of composite material technology, the deployable flexible protective structure has better protective performance than the traditional rigid shell. The volume of the inflated and expanded working orbit carried by the carrier rocket can reach dozens of times or even dozens of times of the volume of the inflated and expanded working orbit, and the advantage provides an effective solution for constructing a large space structure. Therefore, the development of large-scale inflatable deployable structure research is an ideal way for solving the contradiction between the current lower emission capability and the fast-growing space mission, and has wide application prospect in the future deep space exploration process. Particularly, in future moon base construction and Mars base construction, because the interior of the base needs a large moving space, in order to save construction and launching cost, the inflatable expandable cabin body is an ideal base construction choice.
For technical and material reasons, the following problems still exist with the current inflatable deployable capsule:
(1) for the inflatable structure, the common folding modes are mainly Z-shaped folding and curling folding, but the folding technology applied to the inflatable cabin body in real engineering is Z-shaped folding. Due to the limitation of the folding mode, the cabin body can be unfolded only along the axis and cannot be unfolded along the radial direction. This greatly limits the exertion of the radially deployable advantages of the inflatable structure.
(2) The rigidization of the structure of the inflatable cabin means that the flexible cabin is endowed with certain rigidity in a certain way, so that the flexible cabin can bear self and other additional loads without structural instability. For the inflatable space capsule, the in-plane stress generated on the capsule skin under the action of the internal pressure is enough to enable the capsule to obtain the capacity of resisting the deformation of the external force. In a space environment, however, the airship may encounter a vibrating environment, such as the ignition of an engine. In order to make the whole cabin body stable and not sway relative to other butt-jointed cabin bodies, the cabin body needs to be supplemented with a rigid metal support which can be folded and locked in the cabin body, so that good stability performance is achieved, and the research on the aspect is relatively deficient. The invention innovatively combines the advantages of inflation expansion and mechanical expansion, and is beneficial to the fact that the inflatable building skin system can be lapped on a mechanical expansion structure, so that the stress of the inflatable building skin system is more reasonable.
(3) The inflated deployed tanks are generally designed to be cylindrical or spherical in their deployed shape because the cylindrical or spherical tanks are more uniformly stressed relative to the square or polygonal chambers under the internal pressure of the tank. As mentioned in the point (2), in order to make the whole cabin stable and not sway relative to the other docked cabins, a foldable metal frame is required inside or outside the cabin to ensure the stability and deformation of the whole structure. Therefore, the folding mode of the cabin body depends on the folding mode of the metal frame, and the unfolded shape of the cabin body also depends on the folding mode of the metal frame, and the research or the exploration on the aspect is relatively lacked. The invention provides an achievable folding mode, and the cabin has certain expansibility for the unfolded shape of the cabin.
Disclosure of Invention
In view of the above, the present invention is directed to a moon cabin structure system and method combining mechanical deployment and inflation deployment, which solves the problems of the existing inflatable space cabin that the type of deployment and the shape after deployment are single, and the stability of the cabin is poor. The invention has the advantages of small transmitting volume, high folding efficiency, strong space protection capability, simple engineering implementation, low transmitting cost and the like.
In order to achieve the purpose, the technical scheme of the invention is realized as follows:
a moon cabin structure system combining mechanical expansion and inflation expansion comprises an upper platform, a lower platform, a ball screw, an upper sliding ring rod, a middle sliding ring rod, a lower sliding ring rod, a linear bearing optical axis support rod, a ball screw support bearing assembly, a ball screw fixed bearing assembly, an upper movable ring rod, a middle movable ring rod, a lower movable ring rod, a motor, an expandable ground and a skin system, wherein the ball screw, the upper sliding ring rod, the middle sliding ring rod, the lower sliding ring rod, the linear bearing optical axis support rod, the ball screw support bearing assembly, the ball screw fixed bearing assembly, the upper movable ring rod, the middle movable ring rod, the lower movable ring rod, the motor, the expandable ground and the skin system are connected between the upper platform and the lower platform;
the upper platform and the lower platform are connected through a plurality of linear bearing optical axis support rods, the ball screw is connected with the motor, the ball screw is connected with a ball screw fixing bearing assembly, and the fixing bearing assembly is connected with the ball screw supporting bearing assembly, the upper sliding ring rod, the middle sliding ring rod and the lower sliding ring rod; the expandable ground is fixed at the lower end of the ball screw fixed bearing assembly;
the upper sliding loop bar is connected with the upper movable loop bar through a plurality of upper unfolding short bars, the upper movable loop bar is connected with the middle movable loop bar through a plurality of connecting long bars, each connecting long bar is connected with the middle sliding loop bar through an unfolding long bar, and the lower movable loop bar is connected with the lower movable loop bar through a plurality of lower unfolding short bars; all the movable ring rods are telescopic components;
the skin system is respectively connected and fixed with the upper platform and the lower platform, and is inflated and unfolded through the inflation mechanism;
the motor drives the ball screw to rotate, and the ball screw drives the three sliding ring rods to move up and down; when the three movable loop bars are unfolded, the upper sliding loop bar and the middle sliding loop bar move upwards, the lower sliding loop bar moves downwards, and the sliding loop bars drive the corresponding upper unfolding short bars, lower unfolding short bars, unfolding long bars and connecting long bars to move so as to realize the unfolding of the three movable loop bars;
the moon cabin structure system is in a contracted cylinder shape before being unfolded, is radially expanded in the unfolding process and is in a shuttle shape, and is in a sphere shape after being unfolded.
Further, the expandable surface is actuated by a shape memory alloy.
Further, the expandable ground is expanded according to a lightning folding mode.
Furthermore, the upper unfolding short rod is connected with the upper movable ring rod and the upper sliding ring rod through a rotating connecting component, and two ends of the long connecting rod are connected with the upper movable ring rod and the middle movable ring rod through a rotating connecting component respectively.
Further, the rotating connecting component is a rotating hinge.
Furthermore, the unfolding short rods are connected with the corresponding sliding ring rods through sliding connection members, one ends of the unfolding long rods are hinged with the middle upper portions of the corresponding connecting long rods, and the other ends of the unfolding long rods are connected with the middle sliding ring rods through the sliding connection members.
Furthermore, the sliding connecting piece is a sleeve sleeved on the sliding ring rod, the shape of the sleeve is matched with that of the sliding ring rod, a through hole is formed in the sleeve, and the linear bearing optical axis support rod penetrates through the through hole in the sleeve and the through hole in the sliding ring rod.
Furthermore, the upper movable ring rod, the middle movable ring rod and the lower movable ring rod are identical in structure and comprise a plurality of rod sections and a plurality of springs, the two adjacent rod sections are connected through one spring, and the plurality of rod sections and the plurality of springs are enclosed to form a circular ring structure.
Furthermore, the upper unfolding short rod, the unfolding long rod, the connecting long rod and the lower unfolding short rod are connected with the rod section parts of the corresponding ring rods.
A method for unfolding a moon cabin structural system by combining mechanical unfolding and inflation unfolding specifically comprises the following steps:
the method comprises the following steps that firstly, a motor is started to drive a ball screw to rotate, the ball screw drives an upper sliding loop bar and a middle sliding loop bar to move upwards and drives a lower sliding loop bar to move downwards, an upper unfolding short bar and an unfolding long bar are driven to move along with the upward movement of the upper sliding loop bar and the middle sliding loop bar, an upper movable loop bar connected with the upper unfolding short bar is unfolded, and the middle movable loop bar is unfolded under the combined action of the unfolding long bar and the unfolding short bar while the upper movable loop bar is unfolded; meanwhile, the lower unfolding short rod is driven to drive the lower movable loop bar to unfold along with the downward movement of the lower sliding loop bar, so that the mechanical unfolding is completed;
step two, at the same time, unfolding the expandable ground;
and step three, inflating and unfolding the skin system through an inflating mechanism while mechanically unfolding and unfolding the skin system on the ground.
Compared with the prior art, the moon cabin structure system and the method combining mechanical expansion and inflation expansion have the following advantages:
1. the moon building is launched by a rocket in a folded state, then is fixed on the surface of the moon, and is unfolded in a mechanical combined inflatable manner.
2. The method combines the related technology of mechanical unfolding, and can effectively enhance the integrity and stability of the whole structure of the building.
3. The inflatable building skin system can be connected to the mechanical unfolding structure in a lap joint mode, and stress of the inflatable building skin system is more reasonable.
4. The building form has certain expansibility, and the building form can be changed by changing the unfolding mode of the mechanical unfolding structure and the folding mode of the skin system.
Drawings
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate an embodiment of the invention and, together with the description, serve to explain the invention and not to limit the invention. In the drawings:
FIG. 1 is a pre-deployment state view of a lunar chamber structure combining mechanical deployment and inflation deployment according to an embodiment of the present invention;
FIG. 2 is a semi-deployed view of a lunar chamber structure combining mechanical deployment and inflation deployment according to an embodiment of the present invention;
FIG. 3 is a cross-sectional view of a semi-deployed state of a moon pool structure combining mechanical deployment and inflation deployment;
FIG. 4 is a deployed state view of a lunar chamber structure combining mechanical deployment and inflation deployment;
FIG. 5 is a diagram of the deployed effect of a lunar chamber structure combining mechanical deployment and inflation deployment;
FIG. 6 is a schematic view of a mechanical deployment process of a moon pool body combining mechanical deployment and inflation deployment;
FIG. 7 is a schematic illustration of a deployment process of a deployable ground surface of a moon pool that combines mechanical deployment with inflatable deployment;
FIG. 8 is a schematic view of a ball screw coupled to a sliding ring rod;
FIG. 9 is a schematic connection diagram of the upper and middle movable ring rods with the upper and middle unfolding short rods, the long connecting rods and the unfolding long rods;
FIG. 10 is a schematic view showing the connection of the middle sliding ring rod with the linear bearing optical axis stay rod and the unfolding long rod;
fig. 11 is a schematic structural view of the movable ring rod.
Description of reference numerals:
1-ball screw, 2-ball screw fixed bearing assembly, 3-linear bearing optical axis brace, 4-upper sliding ring bar, 5-deployable ground, 6-upper movable ring bar, 7-upper deployed short bar, 8-deployed long bar, 9-connecting long bar, 10-middle movable ring bar, 11-upper platform, 12-lower platform, 13-ball screw support bearing assembly, 14-motor, 15-rotating connecting member, 16-sliding connecting member, 17-skin system, 18-middle sliding ring bar, 19-lower sliding ring bar, 20-lower movable ring bar, 21-lower deployed short bar.
Detailed Description
It should be noted that the embodiments and features of the embodiments may be combined with each other without conflict.
The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.
As shown in fig. 1-11, a moon cabin structural system combining mechanical deployment and inflation deployment comprises an upper platform 11, a lower platform 12, a ball screw 1 connected between the upper platform 11 and the lower platform 12, an upper sliding ring rod 4, a middle sliding ring rod 18, a lower sliding ring rod 19, a linear bearing optical axis brace 3, a ball screw supporting bearing assembly 13, a ball screw fixed bearing assembly 2, an upper movable ring rod 6, a middle movable ring rod 10, a lower movable ring rod 20, a motor 14, a deployable ground 5 and a skin system 17; the ball screw supporting bearing assembly 13 plays a role in supporting the ball screw, and the ball screw fixing bearing assembly 2 mainly starts and positions the ball screw and other structural parts;
the upper platform 11 and the lower platform 12 are connected through a plurality of linear bearing optical axis support rods 3 and are a main structural system of a core cabin part of a moon cabin body, the ball screw 1 is connected with a motor 14, the ball screw 1 is connected with a ball screw fixed bearing assembly 2, and the fixed bearing assembly 2 is connected with a ball screw supporting bearing assembly 13, an upper sliding ring rod 4, a middle sliding ring rod 18 and a lower sliding ring rod 19; the expandable ground 5 is fixed at the lower end of the ball screw fixed bearing assembly 2;
the upper sliding ring rod 4 is connected with an upper movable ring rod 6 through a plurality of upper unfolding short rods 7, the upper movable ring rod 6 is connected with a middle movable ring rod 10 through a plurality of long connecting rods 9, each long connecting rod 9 is connected with a middle sliding ring rod 18 through an unfolding long rod 8, and the lower movable ring rod 20 is connected with a lower movable ring rod 19 through a plurality of lower unfolding short rods 21; all the movable ring rods are telescopic components; the part is a main unfolding structure of the moon cabin body and is also used as a supporting structure of the skin system 17;
the skin system 17 is respectively connected and fixed with the upper platform 11 and the lower platform 12, and the skin system 17 is inflated and unfolded through an inflation mechanism;
the motor drives the ball screw 1 to rotate, and the ball screw 1 drives the three sliding ring rods to move up and down; when the folding loop is unfolded, the upper sliding loop 4 and the middle sliding loop 18 both move upwards, and the lower sliding loop 19 moves downwards;
the moon cabin structure system is in a contracted cylinder shape before being unfolded, is radially expanded in the unfolding process and is in a shuttle shape, and is in a sphere shape after being unfolded.
The expandable ground 5 is driven by a shape memory alloy. The expandable floor 5 is expanded in a lightning folding manner. The expandable ground is expanded according to a lightning (Flasher) folding mode. The power for the deployment of the structure is derived from temperature changes that change the shape of the structure. The expandable ground involved in the present invention is a mechanical structure constructed using a shape memory polymer that changes shape depending on temperature. This structure uses a circular frame instead of a spherical frame, which contains disk-shaped lamellae. The folding principle of the sheet is the same as that of "flasher" paper, where parallel folds enable the sheet to fold into a compact spiral somewhat like a rose petal pattern. The lightning folding is that the diagonal folding and the rectangle folding have been mixed, can be quadrangle, pentagon or even polygon folding, through the preferred hexagon scheme of folding and unfolding of comparison, is a current folding model, no longer gives details here.
The upper unfolding short rod 7 is connected with the upper movable ring rod 6 and the upper sliding ring rod 4 through a rotating connecting component 15, and two ends of the long connecting rod 9 are respectively connected with the upper movable ring rod 6 and the middle movable ring rod 10 through a rotating connecting component 15. The rotating connecting member 15 is a rotating hinge.
The unfolding short rods are connected with the corresponding sliding ring rods through sliding connecting components 16, one end of each unfolding long rod 8 is hinged with the middle upper portion of the corresponding connecting long rod, and the other end of each unfolding long rod is connected with the middle sliding ring rod through the sliding connecting components. The sliding connecting piece 16 is a sleeve sleeved on the sliding ring rod, the shape of the sleeve is matched with that of the sliding ring rod, a through hole is formed in the sleeve, and the linear bearing optical axis support rod 3 penetrates through the through hole in the sleeve and the through hole in the sliding ring rod.
The upper movable ring rod 6, the middle movable ring rod 10 and the lower movable ring rod 20 are identical in structure and comprise a plurality of rod sections and a plurality of springs, the two adjacent rod sections are connected through one spring, and the rod sections and the springs are enclosed to form a circular ring structure. The upper unfolding short rod 7, the unfolding long rod 8, the connecting long rod 9 and the lower unfolding short rod 21 are connected with the rod section parts of the corresponding loop rods.
The inflation mechanism is a chemical reactor device which can rapidly generate gas, the skin system is unfolded by the gas rapidly generated by the chemical reactor device, and the generated gas can be blown into the inner skin system 17 more rapidly by a blower.
The covering system 17 is made of flexible composite materials (such as film or fabric) and mainly comprises an airtight layer (or a gas barrier layer), a reinforcing layer (or a structural layer or a limiting layer), a microfluid star/track fragment protection layer, a radiation protection layer and a multilayer thermal insulation layer, wherein the airtight layer is made of polyurethane, polyethylene, ethylene-vinyl alcohol copolymer, polyamide or aluminum foil; the material of the enhancement layer is: a Kevlar fabric or Vectran fabric; the material of the micro-fluidic star/track fragment protective layer is polyester foam or polyethylene; the radiation-proof layer is made of insulating fabric or film material.
A method for unfolding a moon cabin structural system by combining mechanical unfolding and inflation unfolding specifically comprises the following steps:
step one, because the ball screw 1 is connected with the ball screw fixed bearing assembly 2, the fixed bearing assembly 2 is connected with the ball screw supporting bearing assembly 13 and three sliding ring rods, therefore, the motor 14 is started to drive the ball screw 1 to rotate, the ball screw 1 drives the upper sliding ring rod 4 and the middle sliding ring rod 18 to move upwards, drives the lower sliding ring rod 19 to move downwards, since the long deployment rod, the upper deployment short rod and the lower deployment short rod are respectively connected with the sliding connection member 16 through a rotating connection member 15, therefore, along with the upward movement of the upper sliding ring rod 4 and the middle sliding ring rod 18, the connecting component 15 can make the unfolding short rod flexibly rotate, the sliding connecting component on the sliding ring rod drives the upper unfolding short rod 7 and the unfolding long rod 8 to move, the upper movable ring rod 6 connected with the upper unfolding short rod 7 is unfolded, and the middle movable ring rod 10 is unfolded under the combined action of the unfolding long rod 8 and the unfolding time of the upper movable ring rod 6; meanwhile, along with the downward movement of the lower sliding ring rod 19, the lower unfolding short rod 21 is driven to drive the lower movable ring rod 20 to unfold, and because the lengths of the upper unfolding short rod 7, the lower unfolding short rod 21 and the long connecting rod 9 are different, the unfolding sizes of the upper movable ring rod 6, the middle movable ring rod 10 and the lower movable ring rod 20 are different, the middle movable ring rod 10 is unfolded maximally, and the upper movable ring rod 10 is unfolded minimally and takes the shape of a shuttle, so that the mechanical unfolding is completed; the motor 14 of the whole unfolding process is controlled by a control device to start and stop;
step two, at the same time, unfolding the expandable ground 5; the expandable ground 5 adopts a mechanical structure constructed by shape memory polymer, the shape can be changed according to the temperature, and the expandable ground 5 is expanded according to a lightning (Flasher) folding mode;
and step three, in the mechanical unfolding and ground unfolding processes, the skin system 13 is inflated and unfolded through an inflation mechanism, so that the moon cabin structure system is unfolded.
The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.
Claims (10)
1. A moon cabin structure system combining mechanical expansion and inflation expansion is characterized in that: the device comprises an upper platform (11), a lower platform (12), a ball screw (1) connected between the upper platform (11) and the lower platform (12), an upper sliding ring rod (4), a middle sliding ring rod (18), a lower sliding ring rod (19), a linear bearing optical axis support rod (3), a ball screw supporting bearing assembly (13), a ball screw fixed bearing assembly (2), an upper movable ring rod (6), a middle movable ring rod (10), a lower movable ring rod (20), a motor (14), an expandable ground (5) and a skin system (17);
the upper platform (11) is connected with the lower platform (12) through a plurality of linear bearing optical axis support rods (3), the ball screw (1) is connected with a motor (14), the ball screw (1) is connected with a ball screw fixed bearing assembly (2), and the fixed bearing assembly (2) is connected with a ball screw support bearing assembly (13), an upper sliding coil rod (4), a middle sliding coil rod (18) and a lower sliding coil rod (19); the expandable ground (5) is fixed at the lower end of the ball screw fixed bearing assembly (2);
the upper sliding ring rod (4) is connected with an upper movable ring rod (6) through a plurality of upper unfolding short rods (7), the upper movable ring rod (6) is connected with a middle movable ring rod (10) through a plurality of connecting long rods (9), each connecting long rod (9) is connected with a middle sliding ring rod (18) through an unfolding long rod (8), and the lower movable ring rod (20) is connected with a lower movable ring rod (19) through a plurality of lower unfolding short rods (21); all the movable ring rods are telescopic components;
the skin system (17) is respectively connected and fixed with the upper platform (11) and the lower platform (12), and the skin system (17) is inflated and unfolded through an inflation mechanism;
the motor drives the ball screw (1) to rotate, and the ball screw (1) drives the three sliding ring rods to move up and down; when the folding ring is unfolded, the upper sliding ring rod (4) and the middle sliding ring rod (18) both move upwards, and the lower sliding ring rod (19) moves downwards;
the moon cabin structure system is in a contracted cylinder shape before being unfolded, is radially expanded in the unfolding process and is in a shuttle shape, and is in a sphere shape after being unfolded.
2. The lunar pod structural system combining mechanical deployment and inflatable deployment of claim 1, wherein: the expandable ground (5) is driven by a shape memory alloy.
3. The moon cabin structural system combining mechanical deployment and inflatable deployment according to claim 2, wherein: the expandable floor (5) is expanded in a lightning folding manner.
4. The lunar pod structural system combining mechanical deployment and inflatable deployment of claim 1, wherein: the upper unfolding short rod (7) is connected with the upper movable ring rod (6) and the upper sliding ring rod (4) through a rotary connecting component (15), and two ends of the long connecting rod (9) are respectively connected with the upper movable ring rod (6) and the middle movable ring rod (10) through a rotary connecting component (15).
5. The moon cabin structural system combining mechanical deployment and inflation deployment according to claim 4, wherein: the rotating connecting component (15) is a rotating hinge.
6. The lunar pod structural system combining mechanical deployment and inflatable deployment of claim 1, wherein: the unfolding short rods are connected with the corresponding sliding ring rods through sliding connecting components (16), one end of each unfolding long rod (8) is hinged with the middle upper portion of the corresponding connecting long rod, and the other end of each unfolding long rod is connected with the middle sliding ring rod through the sliding connecting components.
7. The lunar pod structural system combining mechanical deployment and inflatable deployment of claim 6, wherein: the sliding connecting piece (16) is a sleeve sleeved on the sliding ring rod, the shape of the sleeve is matched with that of the sliding ring rod, a through hole is formed in the sleeve, and the linear bearing optical axis support rod (3) penetrates through the through hole in the sleeve and the through hole in the sliding ring rod.
8. A moon cabin structural system combining mechanical deployment and inflatable deployment according to any one of claims 1 to 7, wherein: the structure of the upper movable ring rod (6), the middle movable ring rod (10) and the lower movable ring rod (20) is the same and comprises a plurality of rod sections and a plurality of springs, the two adjacent rod sections are connected through one spring, and the plurality of rod sections and the plurality of springs are enclosed to form a circular ring structure.
9. The lunar pod structural system combining mechanical deployment and inflatable deployment of claim 8, wherein: the upper unfolding short rod (7), the unfolding long rod (8), the connecting long rod (9) and the lower unfolding short rod (21) are connected with the rod section parts of the corresponding ring rods.
10. A method of deploying a moon pool structural system combining mechanical deployment and inflatable deployment according to any one of claims 1-7, wherein: the method specifically comprises the following steps:
step one, a motor (14) is started to drive a ball screw (1) to rotate, the ball screw (1) drives an upper sliding ring rod (4) and a middle sliding ring rod (18) to move upwards and drives a lower sliding ring rod (19) to move downwards, an upper unfolding short rod (7) and an unfolding long rod (8) are driven to move along with the upward movement of the upper sliding ring rod (4) and the middle sliding ring rod (18), an upper movable ring rod (6) connected with the upper unfolding short rod (7) is unfolded, and the middle movable ring rod (10) is unfolded under the combined action of the unfolding long rod (8) and the unfolding short rod (7) when the upper movable ring rod (6) is unfolded; meanwhile, along with the downward movement of the lower sliding ring rod (19), the lower unfolding short rod (21) is driven to drive the lower movable ring rod (20) to unfold, and the mechanical unfolding is completed;
step two, at the same time, unfolding the expandable ground (5);
and step three, the skin system (13) is inflated and unfolded through an inflation mechanism at the same time of the mechanical unfolding and ground unfolding processes.
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