CN214377292U - Teaching aid for simulating 1U cube star - Google Patents

Abstract

The application relates to a teaching aid for simulating a 1U cube star, which belongs to the field of satellite teaching aids and comprises six mounting plates, wherein each mounting plate is provided with a mounting position, the six mounting plates are detachably connected to form a cube star shell with a mounting cavity inside, and the side surface of each mounting plate with the mounting position is positioned on one side of the mounting cavity; the functional modules are correspondingly arranged at the mounting positions of the mounting plates and connected through wires, and the contact surface shapes of the functional modules are matched with each other; realize the modularization equipment of cube star casing and inside functional module through above-mentioned scheme, through corresponding each functional module earlier and install on each mounting panel, then directly realize the equipment and the fixed of inside functional module through assembling each mounting panel into cube star casing, once only realize the equipment of cube star casing, but also can realize the equipment and the fixed of inside each functional module.

Description

Teaching aid for simulating 1U cube star

Technical Field

The utility model relates to a satellite teaching aid technical field especially relates to a teaching aid for simulating 1U cube star.

Background

The cube satellite is a small satellite which is widely applied to universities internationally and used for developing aerospace scientific research and education, has the characteristics of low cost, high function density, short development period and orbit entering block, and is realized to monitor oceans, atmospheric environment, ships, aviation aircrafts and the like. The cube is divided by U, with 1U referring to a standard cell (volume 10cm x 10cm, weight around 1 kg) being the main direction of microsatellite development. At present, the internal functional modules of the 1U cube star generally comprise a power supply module, a computer board module, an attitude control module, a communication module and the like, and the functional modules are installed in a cube star shell with an opening on one side, and are manually fixed in the shell one by one, and then the side of the opening is sealed by a sealing plate. This kind of mode of fixing each functional module in the casing one by one not only installs, dismantles troublesome, and along with constantly installing each functional module to the in-process in the casing, the space reduces gradually in the shell, and is perhaps comparatively convenient to the functional module of installing at first, and along with the gradual installation of a plurality of functional modules, operable space reduces gradually in the shell, and it is very inconvenient and child wants to know inner structure and disassembles very inconveniently to the installation of the functional module of follow-up waiting to install.

SUMMERY OF THE UTILITY MODEL

This application is in order to solve current cube star when the equipment, its casing is a side open-ended monolithic structure, make inside function module when the installation, need install to the casing in one by one, along with the continuous installation of each function module, space in the casing reduces gradually, make follow-up function module's installation and dismantlement become very inconvenient, cause the trouble to child's operation in the reality (including dismantling or installing each function module), so that lack child of patience and do not want to spend a large amount of time to dismantle the problem of cube star in order to know its internal structure, this application designs a teaching aid for simulating 1U cube star and can solve above-mentioned problem, the technical scheme of its concrete adoption is for the technical scheme that is for dismantling a large amount of time and remove the cube star in order to know its internal structure

A teaching aid for simulating a 1U cube star, comprising:

the mounting device comprises six mounting plates, wherein each mounting plate is provided with a mounting position, the six mounting plates are detachably connected to form a cubic star shell with a mounting cavity inside, and the side surface of each mounting plate with the mounting position is positioned on one side of the mounting cavity;

the functional modules are correspondingly arranged at the installation positions of the installation plates and connected through wires, and the contact surface shapes of the functional modules are matched with each other.

Preferably, each mounting plate is provided with a clamping protrusion and a clamping groove along the periphery of the edge, the clamping protrusions and the clamping grooves are arranged alternately, and the mounting plates are clamped through the clamping protrusions and the clamping grooves.

Preferably, one of the mounting plates is provided with an observation window.

Preferably, the plurality of functional modules are respectively a control module, a communication module and a power supply module, the control module, the communication module and the power supply module are respectively adhered to the inner surface of each corresponding mounting plate, and the control module and the communication module are respectively electrically connected with the power supply module.

Preferably, the outer wall of the cubic star shell is provided with a lighting lamp corresponding to one of the mounting plates, and the lighting lamp is connected with the power supply module.

Preferably, the method further comprises the following steps:

and the solar panel is arranged on the outer wall of one of the mounting plates and is connected with the power supply module.

Preferably, the method further comprises the following steps:

and the laser penetrates through one of the mounting plates and is arranged on the mounting plate, and the laser is connected with the power supply module.

Preferably, the mounting plate is an acrylic plate.

The utility model adopts the above technical scheme, the gained technological effect is:

through setting up the cube star casing into the mode that six mounting panels can dismantle the connection, realize the modularization equipment of cube star casing and inside function module, through corresponding each function module earlier and install on each mounting panel, then directly realize the equipment and the fixed of inside function module through assembling each mounting panel into the cube star casing, once only realize the equipment of cube star casing, but also can realize the equipment and the fixed of inside each function module. The assembling and disassembling complexity of the cube star is greatly reduced, the cube star can be independently operated by children, the internal structure of the cube star can be known in a short distance, and understanding is facilitated.

Drawings

Fig. 1 is a perspective view of the present invention;

fig. 2 is a rear view of the present invention.

In the figure, the device comprises a mounting plate 1, a mounting plate 101, a clamping groove 102, a clamping protrusion 2, a laser 3, a communication module 4, a control module 5, a power supply module 6, a solar panel 7, a lighting lamp 8 and an observation window.

Detailed Description

In order to clearly illustrate the technical features of the present invention, the present invention is explained in detail by the following embodiments with reference to the accompanying drawings.

In addition, in the description of the present invention, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", etc., indicate orientations and positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

Wherein the face of the cube-star housing is seen as the front, viewed in the direction of the arrows in fig. 1, and the remaining directions are defined on the basis of this direction.

As shown in fig. 1-2, the present application is a teaching aid for simulating a 1U cube star, which comprises six mounting plates 1 and a plurality of functional modules.

The six mounting plates 1 are detachably connected to form a cubic star shell with a mounting cavity inside. For convenience of description in this application, six mounting panels 1 are respectively a lower mounting panel, an upper mounting panel, a left mounting panel, a right mounting panel, a front mounting panel and a rear mounting panel, each mounting panel 1 is provided with a mounting position, and the mounting position can be represented as a corresponding mounting groove arranged on each mounting panel 1, or can be represented as a mounting clamping strip arranged on each mounting panel 1, and after the six mounting panels 1 are connected into a cubic star shell, the surface of each mounting panel 1 provided with the mounting position is located on the side of a mounting cavity.

The functional modules are correspondingly arranged at the installation positions of the installation plates 1 and are connected through electric wires, and the contact surface shapes of the functional modules are matched with each other, namely the contact surfaces of the functional modules are matched with each other, so that when the installation plates 1 are connected into a cubic star shell after the functional modules are fixed at the installation positions of the installation plates 1, the functional modules in the shell cannot interfere with each other; or when the functional modules are fixed on the corresponding mounting plates 1, the functional modules are staggered, so that after the mounting plates 1 are connected to form a cubic star shell, the internal functional modules are not in contact with each other, and thus, the interference phenomenon cannot occur between the internal functional modules.

It should be noted that after the functional modules are correspondingly fixed on the mounting plates 1, cables required to be connected between the functional modules are connected before the mounting plates 1 are connected to form the cubic star shell, after the mounting plates 1 are connected to form the cubic star shell, the cables connected between the functional modules may have redundancy, and the redundant cables are curled in a mounting cavity inside the cubic star shell, which does not affect the connection and assembly of the mounting plates 1.

Through setting up above-mentioned cube star casing into the mode of six mounting panel 1 equipment to and fix each functional module blocking of inside at the mounted position of each mounting panel 1, through directly connect into each mounting panel 1 and assemble, fix each functional module in the lump in the installation cavity of cube star casing when becoming the cube star casing, it is very convenient that make each functional unit fix and assemble together, no longer because of current cube star fix one by one, the equipment leads to the narrow and small degree of difficulty that increases fixed or equipment in inside operating space. Meanwhile, the difficulty in disassembling, assembling and fixing each internal functional module for children to learn the internal structure of the cube star is avoided, the children can disassemble independently and quickly, the fixing or disassembling time is shortened, and the children cannot lose interest in further learning the internal structure of the cube star due to long-time disassembly or assembly and fixation.

Further, for the detachable connection among the six mounting plates 1, specifically, each mounting plate 1 is provided with the locking projections 102 and the locking grooves 101 along a circumference of the edge thereof, the locking projections 102 and the locking grooves 101 are arranged alternately, and when the six mounting plates 1 need to be connected, the locking groove 101 on one of the two adjacent mounting plates 1 only needs to be locked into the locking groove 101 on the other mounting plate 1, so as to realize the locking between the mounting plates 1. By connecting the six mounting plates 1 in the mode, the quick connection before the mounting plates 1 can be realized, children can quickly disassemble the cubic star shell when further learning the internal structure of the cubic star, and can also quickly assemble the cubic star shell after the cubic star is used, so that the operation time of the children is shortened.

Further, when the cube housing and the internal functional units are in the assembled state, children can observe the layout and the position of the internal functional units conveniently, the observation window 8 is arranged on the rear mounting plate, and the observation window 8 can be in a five-pointed star shape, or a rectangle, a square and the like for the sake of attractiveness.

Further, the functional modules are respectively embodied as a control module 4, a communication module 3 and a power module 5. The control module 4 is bonded on the lower mounting plate, the control module 4 generally comprises a computer module and an attitude control module 4, the computer module and the attitude control module 4 adopt the existing functional module of the cubic star, the structure and the control mode of the computer module and the attitude control module 4 are mature technologies, detailed description is omitted here, the control module 4 is bonded on the lower mounting plate, the fixing is simple and easy to operate, the control module 4 is bonded on the lower mounting plate only by smearing adhesive on the lower mounting plate before the mounting plates 1 are connected into the cubic star shell, and after the control module is bonded and fixed, the mounting plates 1 are connected into the cubic star shell. And communication module 3 and power module 5 also bond on mounting panel 1, and is specific, and communication module 3 bonds on left mounting panel, and power module 5 bonds on right mounting panel, and the fixed equipment speed is fast through the connected mode that bonds, and is simple, easy operation. The communication module 3 generally includes an antenna system module and a wireless transceiver board module, and the like, and it adopts the existing functional module of a cube star, and the structure and the control mode thereof are mature technologies, and will not be described in detail. In addition, the control module 4 and the communication module 3 are respectively electrically connected with the power module 5, and the power module 5 provides electric energy for the whole cube star, so that the normal operation of each functional module of the cube star is ensured.

Furthermore, in order to enable children to still operate the cube star under dim light and clearly see the internal structure, the outer wall of the cube star shell is provided with two illuminating lamps 7 corresponding to the rear mounting plate, the two illuminating lamps 7 are positioned at two sides of the observation window 8, and the illuminating lamps 7 are connected with the power supply module 5; in addition, the illuminating lamp 7 can also realize the self-illumination of the cube star and is used for identifying the position of the cube star in a dark environment.

Further, in an embodiment, in addition to the power module 5, the solar panel 6 is further included, the solar panel 6 can convert solar energy into electric energy, the solar panel 6 is disposed on an outer wall of the upper mounting plate and connected to the power module 5, the electric energy converted by the solar panel 6 is stored in the power module 5 and released when needed, and the solar panel 6 can provide electric energy for the power module 5 without a power supply, so that normal operation of each internal functional module is ensured.

Further, in one embodiment, the method further comprises:

laser instrument 2, laser instrument 2 pass the front mounting panel setting on the front mounting panel, and this laser instrument 2 is fixed on the front mounting panel, and this laser instrument 2 links to each other with power module 5 simultaneously, and laser instrument 2 can detect the distance of outside barrier, especially can acquire the distance of space rubbish to in order to handle the space rubbish.

Further, in one embodiment, the mounting plate 1 is an acrylic plate, which is light in weight, good in light transmittance, and attractive in appearance, and requires a small light intensity in a dark environment, so that electric energy is saved.

The above-mentioned specific embodiments can not be regarded as the restriction to the scope of protection of the utility model, to technical personnel in this technical field, it is right the utility model discloses any replacement improvement or transform that embodiment made all fall within the scope of protection of the utility model.

The parts of the present invention not described in detail are the known techniques of those skilled in the art.

Claims (8)

1. A teaching aid for simulating a 1U cube star, comprising:

the mounting device comprises six mounting plates, wherein each mounting plate is provided with a mounting position, the six mounting plates are detachably connected to form a cubic star shell with a mounting cavity inside, and the side surface of each mounting plate, which is provided with the mounting position, is positioned on one side of the mounting cavity;

the functional modules are correspondingly arranged at the installation positions of the installation plates, the functional modules are connected through wires, and the contact surface shapes of the functional modules are matched with each other.

2. A teaching aid for simulating a 1U cube star according to claim 1 wherein each mounting plate is provided with a locking projection and a locking groove along a circumference of the edge, the locking projections and the locking grooves are alternately arranged, and each mounting plate is locked with each other by the locking projections and the locking grooves.

3. A teaching aid as claimed in claim 1, wherein one of the mounting plates is provided with a viewing window.

4. A teaching aid as claimed in claim 1, wherein the plurality of functional modules are a control module, a communication module and a power module, the control module, the communication module and the power module are respectively adhered to the inner surface of each of the mounting plates, and the control module and the communication module are respectively electrically connected to the power module.

5. A teaching aid for simulating a 1U cube star according to claim 4 is characterized in that an illuminating lamp is arranged on one of the mounting plates corresponding to the outer wall of the cube star shell, and the illuminating lamp is connected with the power supply module.

6. A teaching aid for simulating a 1U cube star in accordance with claim 5, further comprising:

and the solar panel is arranged on one of the outer walls of the mounting plates and is connected with the power supply module.

7. A teaching aid for simulating a 1U cube star in accordance with claim 4, further comprising:

the laser device penetrates through one of the mounting plates and is arranged on the mounting plate, and the laser device is connected with the power supply module.

8. A teaching aid as claimed in claim 1, wherein the mounting plate is an acrylic plate.

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