CN208867806U - A kind of land, water and air three are dwelt rotor robot - Google Patents
A kind of land, water and air three are dwelt rotor robot Download PDFInfo
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- CN208867806U CN208867806U CN201821351635.6U CN201821351635U CN208867806U CN 208867806 U CN208867806 U CN 208867806U CN 201821351635 U CN201821351635 U CN 201821351635U CN 208867806 U CN208867806 U CN 208867806U
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- bottom plate
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Abstract
It dwells rotor robot the utility model discloses a kind of land, water and air three.It includes: main body bottom plate;Four rotor modules, are symmetricly set on the four corners of main body bottom plate, receive the control of electronic control module, and rotor module includes the driving mechanism of rotor, land row wheel and driving rotor, the work of land row wheel;Four deformation modules correspond with four rotor modules respectively, are symmetricly set on the four corners of main body bottom plate, for driving corresponding rotor module to rotate in vertical direction, receive the control of electronic control module;Electronic control module, be arranged on main body bottom plate, for three dwell rotor robot provide electric energy and control signal.The utility model being capable of the arbitrarily switching, rapid deployment work under the working environment of three kinds of land, water and air.
Description
Technical field
It dwells rotor robot the utility model relates to robotic technology field more particularly to a kind of land, water and air three.
Background technique
With the development of the times, social production life produces higher requirement to robot technology.The conventional machines National People's Congress
More have the ability to work under one of three kinds of working environments of water, land and air working environment, send out in robot technology
Under exhibition pushes, also occur some amphibious robots that can be worked under wherein two kinds of working environments successively.
To meet the needs of operation in complex work environment, robot should have to intersect in three kinds of land, water and air working environment
The ability of operation, and dwell robot there is presently no can work under the working environment of three kinds of land, water and air three.
Summary of the invention
In order to solve the above-mentioned technical problem, the utility model provides a kind of land, water and air three and dwells rotor robot, can
The arbitrarily switching, rapid deployment work under the working environment of three kinds of land, water and air.
To solve the above-mentioned problems, the utility model is achieved using following technical scheme:
It dwells rotor robot a kind of land, water and air three of the utility model, comprising:
Main body bottom plate;
Four rotor modules, are symmetricly set on the four corners of main body bottom plate, receive the control of electronic control module, rotor module packet
Include the driving mechanism of rotor, land row wheel and driving rotor, the work of land row wheel;
Four deformation modules correspond with four rotor modules respectively, are symmetricly set on the four corners of main body bottom plate, use
In driving corresponding rotor module to rotate in vertical direction, receive the control of electronic control module;
Electronic control module, be arranged on main body bottom plate, for three dwell rotor robot provide electric energy and control signal.
In the technical scheme, it is logical to offer several screw threads thereon for the rack that main body bottom plate dwells rotor robot as three
Hole, unthreaded hole, groove type hole etc. are used to be coupled other robot building block and realize the peripheral hardware of corresponding function.
Rotor module for drive three dwell rotor robot in water, land, aerial sports.Three dwell rotor robot in sky
When middle flight, rotor is in horizontality, and high speed rotation provides the power of lift and pose adjustment for fuselage;Three dwell rotor machine
For people when land is run, land row wheel is in a vertical state, and rotation driving three is dwelt rotor robot land row;Three rotor robots of dwelling exist
When moving under water in water, rotor is in a vertical state, and high speed rotation provides the power of thrust and pose adjustment for fuselage.
Deformation module drives corresponding rotor module to rotate in vertical direction, so as to adjust the horizontal of rotor and land row wheel
State, vertical state.
Electronic control module provides electric energy for three rotor robots of dwelling, and can control rotor module, deformation module work.
Preferably, further including undercarriage, it is arranged in main body bottom plate bottom surface, for dwelling rotor robot by flight shape three
State is converted to support three during the row state of land and dwells rotor robot, receives the control of electronic control module.
When three dwell rotor robot land row state is switched to from state of flight when, firstly, undercarriage is fallen, three dwell rotor
Machine lands, and then, all deformation modules drive corresponding rotor module to rotate to vertical state, so that land row wheel and main body bottom
Plate is vertical, completes the switching of land row state.
Preferably, the undercarriage includes four frame modules that rise and fall for being symmetricly set on main body bottom plate bottom surface four corners,
The frame module that rises and falls includes line handspike motor, connecting rod, link block, supporting leg and hinged seat, and the line handspike motor is fixed
In main body bottom plate bottom surface, the push rod front end and connecting rod one end of the line handspike motor are hinged, the connecting rod other end with connect
Block is hinged, and the link block is fixedly connected with supporting leg, and the supporting leg top and hinged seat are hinged, and the hinged seat is fixed on main body
Bottom plate bottom surface.
The push rod of all line handspike motors stretches out, and connecting rod drives supporting leg decline, and undercarriage is fallen;All line handspike electricity
The pusher retracted of machine, connecting rod drive supporting leg to rise, gear up.
Preferably, the driving mechanism includes horn, driving motor and freewheel clutch, the driving motor setting exists
Horn front end, the horn rear end are connected with corresponding deformation module, and output shaft end and the rotor of the driving motor are fixed
Connection, the output shaft and freewheel clutch of the driving motor are cooperatively connected, and the land row wheel passes through wheel hub and freewheel clutch
It is fixedly connected.
Rotor and land row wheel are parallel to each other.Freewheel clutch is a kind of transformation tool using driving and driven part direction of rotation
There is the device of voluntarily clutch function.When driving motor is rotated according to the direction of rotation of regulation, freewheel clutch and driving motor
Output shaft separation, driving motor do not drive land row wheel, and land row wheel does not rotate, and driving motor drives rotor wing rotation, due to land row wheel
It does not rotate, alleviates driving motor load and decrease energy consumption;When driving motor is according to the direction opposite with above-mentioned direction of rotation
When rotation, engage freewheel clutch with the output shaft of driving motor, driving motor drives the rotation of land row wheel.
Preferably, the deformation module includes digital rudder controller, driving gear, driven gear and two axle beds, described two
A axle bed is oppositely arranged, the horn pass through two axle beds and with axle bed rotatable engagement, the driven gear is set on horn
And be fixedly connected with horn, the driven gear is stuck between two axle beds, and the driving gear is engaged with driven gear, described
Driving gear is fixedly connected with the output shaft of digital rudder controller.
Axle bed inner ring is embedded with the bearing passed through for horn, to realize the rotatable engagement of horn and axle bed.Driven gear card
To limit to horn between two axle beds, prevent horn from detaching from axle bed.Digital rudder controller drives driving gear rotation
Turn, driving gear drives driven gear rotation, and driven gear drives horn rotation, so that rotor module be driven to revolve in vertical direction
Turn.
Digital rudder controller is different from traditional simulation steering engine, and simulation steering engine, which needs not stop paying out, send pwm signal that can just be maintained at rule
Fixed position, digital rudder controller then only need to send a pwm signal and are just able to maintain in some defined position, so working as rotor mould
Block pose adjustment in place after, the posture that deformation module is able to maintain rotor module is motionless.
Three dwell rotor robot in state of flight, and adjacent rotor direction of rotation is not respectively on the contrary, land row wheel rotates.Three
Rotor robot dwell when being switched to land row state from state of flight, adjacent deformations module drive corresponds to rotor module on main body bottom plate
Direction of rotation on the contrary, make adjacent rotor module one to rotate clockwise, one counterclockwise rotation, guarantee in land row four
The direction of rotation of land row wheel is consistent.Three rotor robots of dwelling are switched in water when moving under water state, two rotors on front side of main body bottom plate
Two rotor modules of module or rear side rotate it is vertical with main body bottom plate to vertical state, and the two rotation to vertical state rotation
The direction of rotation of wing module is opposite (i.e. one rotates clockwise, a rotation counterclockwise), the rotor rotation of the two rotor modules
Turn direction respectively on the contrary, and land row wheel do not rotate, the rotors of the two rotor modules is fuselage as propeller high speed rotation
The power of thrust and pose adjustment is provided.
Preferably, the electronic control module includes controller, wireless communication module and battery, the controller respectively with nothing
Line communication module is connected with battery.Battery be used for three dwell rotor robot power supply;Wireless communication module is distant for transmitting/receiving wireless
Control signal;Controller is single-chip microcontroller, and entire three rotor machine of dwelling of control is manually made.
Preferably, being equipped with electronic control module waterproof case on the outside of the electronic control module, it is equipped with and becomes on the outside of the deformation module
Shape module waterproof case.Electronic control module waterproof case makes electronic control module have waterproof performance, and deformation module waterproof case makes
Deformation module has waterproof performance, prevent three dwell rotor robot when moving under water in water or in rainy weather operation because of water inlet
And lead to failure.
Preferably, the main body bottom plate is in X-shaped.
The beneficial effects of the utility model are: deformation module is according to specific job requirements and athletic posture demand real-time change
The posture of rotor module, enable three dwell rotor robot under the working environment of three kinds of land, water and air arbitrarily switching, rapid deployment
Work, at the same three dwell rotor robot with mechanism it is succinct, it is rationally distributed, control efficient advantage.
Detailed description of the invention
Fig. 1 is the three of the utility model to dwell rotor robot state of flight schematic diagram;
Fig. 2 is the three of the utility model to dwell schematic diagram of rotor robot when being switched to land row state by state of flight;
Fig. 3 is the three of the utility model to dwell rotor robot land row status diagram;
Fig. 4 is that the three of the utility model rotor robot of dwelling moves under water status diagram;
Fig. 5 is the three of the utility model main body floor diagram for dwelling rotor robot;
Fig. 6 is the three of the utility model scheme of installation of the deformation module on main body bottom plate for dwelling rotor robot;
Fig. 7 is the three of the utility model scheme of installation of the undercarriage on main body bottom plate for dwelling rotor robot;
Fig. 8 be the three of the utility model dwell rotor robot rotor module and deformation module cooperation schematic diagram;
Fig. 9 be the three of the utility model dwell rotor robot rotor module schematic diagram;
Figure 10 be the three of the utility model dwell rotor robot rotor module partial structure diagram;
Figure 11 be the three of the utility model dwell rotor robot rotor module land row wheel schematic diagram;
Figure 12 is the three of the utility model undercarriage module diagram for dwelling rotor robot;
Figure 13 is the stabilizer blade schematic diagram of the frame module that rises and falls of the utility model;
Figure 14 is the link block schematic diagram of the frame module that rises and falls of the utility model;
Figure 15 is the connecting rod schematic diagram of the frame module that rises and falls of the utility model.
In figure: 1, main body bottom plate, 2, rotor module, 21, horn, 22, driving motor, 23, freewheel clutch, 24, rotor,
25, wheel hub, 26, land row wheel, 3, deformation module, 31, axle bed, 32, digital rudder controller, 33, driven gear, 34, driving gear, 4, rise
Fall frame module, 41, line handspike motor, 42, supporting leg, 43, connecting rod, 44, link block, 45, hinged seat, 5, electronic control module, 51, control
Device processed, 52, wireless communication module, 53, actuator driving plate, 54, battery, 61, control module waterproof case, 62, deformation module it is anti-
Water shell, 63, battery waterproof shell.
Specific embodiment
Below with reference to the embodiments and with reference to the accompanying drawing the technical solutions of the present invention will be further described.
Embodiment: a kind of land, water and air three of the present embodiment are dwelt rotor robot, as shown in Figure 1, Figure 2, shown in Fig. 5, Fig. 6, comprising:
Main body bottom plate 1;
Four rotor modules 2, are symmetricly set on the four corners of main body bottom plate 1, receive the control of electronic control module 5, pass through rotation
The driving of wing module 2, three rotor robots of dwelling may be implemented to move under the working environment of three kinds of land, water and air;
Four deformation modules 3 correspond with four rotor modules 2 respectively, are symmetricly set on the quadrangle of main body bottom plate 1
Place, for driving corresponding rotor module 2 to rotate in vertical direction, receives the control of electronic control module 5;
Undercarriage, setting is in 1 bottom surface of main body bottom plate, for by state of flight being converted to Lu Hangzhuan in three rotor robots of dwelling
Support three is dwelt rotor robot during state, receives the control of electronic control module 5;
Electronic control module 5, be arranged on main body bottom plate 1, for three dwell rotor robot provide electric energy and control signal.
As shown in figure 5, main body bottom plate 1 is in X-shaped, it is made of light-high-strength material.Main body bottom plate is dwelt gyroplane as three
The rack of device people offers several tapped through holes, unthreaded hole, groove type hole etc. for being coupled other robot building block thereon
With the peripheral hardware for realizing corresponding function.
As shown in Fig. 8, Fig. 9, Figure 10, Figure 11, rotor module 2 includes rotor 24, land row wheel 26 and driving rotor 24, land
The driving mechanism of 26 work of row wheel, driving mechanism includes horn 21, driving motor 22 and freewheel clutch 23, and driving motor 22 is set
It sets in 21 front end of horn, 21 rear end of horn is connected with corresponding deformation module 3, the output shaft end and rotor 24 of driving motor 22
Be fixedly connected, the output shaft of driving motor 22 and freewheel clutch 23 are cooperatively connected, land row wheel 26 by wheel hub 25 and surmount from
Clutch 23 is fixedly connected.
Rotor and land row wheel are parallel to each other.Freewheel clutch is a kind of transformation tool using driving and driven part direction of rotation
There is the device of voluntarily clutch function.When driving motor is rotated according to the direction of rotation of regulation, freewheel clutch and driving motor
Output shaft separation, driving motor do not drive land row wheel, and land row wheel does not rotate, and driving motor drives rotor wing rotation, due to land row wheel
It does not rotate, alleviates driving motor load and decrease energy consumption;When driving motor is according to the direction opposite with above-mentioned direction of rotation
When rotation, engage freewheel clutch with the output shaft of driving motor, driving motor drives the rotation of land row wheel.
As shown in Fig. 6, Fig. 8, deformation module 3 includes digital rudder controller 32, driving gear 34, driven gear 33 and two axle beds
31, two axle beds 31 are oppositely arranged, horn 21 pass through two axle beds 31 and with 31 rotatable engagement of axle bed, driven gear 33 is set in
It is fixedly connected on horn 21 and with horn 21, driven gear 33 is stuck between two axle beds 31, driving gear 34 and driven gear
33 engagements, driving gear 34 are fixedly connected with the output shaft of digital rudder controller 32.
Axle bed inner ring is embedded with the bearing passed through for horn, to realize the rotatable engagement of horn and axle bed.Driven gear card
To limit to horn between two axle beds, prevent horn from detaching from axle bed.Digital rudder controller drives driving gear rotation
Turn, driving gear drives driven gear rotation, and driven gear drives horn rotation, so that rotor module be driven to revolve in vertical direction
Turn.
Digital rudder controller is different from traditional simulation steering engine, and simulation steering engine, which needs not stop paying out, send pwm signal that can just be maintained at rule
Fixed position, digital rudder controller then only need to send a pwm signal and are just able to maintain in some defined position, so working as rotor mould
Block pose adjustment in place after, the posture that deformation module is able to maintain rotor module is motionless.
As shown in Figure 1, three dwell rotor robot in state of flight, all rotors are in horizontality, adjacent rotor rotation
Turn direction respectively on the contrary, land row wheel does not rotate.
As shown in figure 3, three dwell rotor robot when being switched to land row state from state of flight, all deformation modules drivings pair
Rotor module is answered to rotate to vertical state, adjacent deformations module drive corresponds to the direction of rotation of rotor module on the contrary, making adjacent
Rotor module one rotate clockwise, one counterclockwise rotation, guarantee that the direction of rotation of four land row wheels in land row is consistent.
As shown in figure 4, three rotor robots of dwelling are switched in water when moving under water state, two rotor modules on front side of main body bottom plate
Or two rotor modules of rear side rotate it is vertical with main body bottom plate to vertical state, and the two rotation to vertical state rotor mould
The direction of rotation of block is opposite (i.e. one rotates clockwise, a rotation counterclockwise), the rotor wing rotation side of the two rotor modules
To respectively on the contrary, and land row wheel do not rotate, the rotor of the two rotor modules is provided as propeller high speed rotation for fuselage
The power of thrust and pose adjustment.
As shown in Fig. 7, Figure 12, Figure 13, Figure 14, Figure 15, undercarriage includes four and is symmetricly set on 1 bottom surface four of main body bottom plate
The frame module 4 that rises and falls at angle, the frame module 4 that rises and falls include line handspike motor 41, connecting rod 43, link block 44, supporting leg 42 and hinged
Seat 45, line handspike motor 41 are fixed on 1 bottom surface of main body bottom plate, and the push rod front end and 43 one end of connecting rod of line handspike motor 41 are cut with scissors
It connects, 43 other end of connecting rod and link block 44 are hinged, and link block 44 is fixedly connected with supporting leg 42, and 42 top of supporting leg and hinged seat 45 are cut with scissors
It connects, hinged seat 45 is fixed on 1 bottom surface of main body bottom plate.
The push rod of all line handspike motors stretches out, and connecting rod drives supporting leg decline, and undercarriage is fallen;All line handspike electricity
The pusher retracted of machine, connecting rod drive supporting leg to rise, gear up.As shown in Fig. 2, when three dwell rotor robot will be from flight shape
When state is switched to land row state, firstly, undercarriage is fallen, three dwell the landing of rotor machine, and then, all deformation modules drivings correspond to
Rotor module rotate to vertical state so that land row wheel is vertical with main body bottom plate, complete the switching of land row state.
As shown in Figure 6, Figure 7, electronic control module 5 includes controller 51, wireless communication module 52, actuator driving plate 53 and battery
54, controller 51 is connect with wireless communication module 52, driving motor 22, line handspike motor 41 and battery 54 respectively, controller
51 are also connect by actuator driving plate 53 with digital rudder controller 32.Battery be used for three dwell rotor robot power supply;Radio communication mold
Block is used for transmitting/receiving wireless remote signal;Controller is single-chip microcontroller, and entire three rotor machine of dwelling of control is manually made.
As shown in Figure 1 and Figure 2, it is equipped with electronic control module waterproof case on the outside of electronic control module 5, is equipped with deformation on the outside of deformation module 3
Module waterproof case 62, electronic control module waterproof case include being located at controller 51, wireless communication module 52, actuator driving plate 53
The control module waterproof case 61 in outside and the battery waterproof shell for being located at 54 outside of battery.
Electronic control module waterproof case makes electronic control module have waterproof performance, and deformation module waterproof case makes deformation module
Have waterproof performance, prevent three dwell rotor robot cause when moving under water in water or in rainy weather operation because of water inlet therefore
Barrier.
In the present solution, rotor module for drive three dwell rotor robot in water, land, aerial sports.Distorted pattern
Block drives corresponding rotor module to rotate in vertical direction, so as to adjust horizontality, the vertical state of rotor and land row wheel.It is automatically controlled
Module provides electric energy for three rotor robots of dwelling, and transmitting/receiving wireless signal controls rotor module, deformation module, frame module work of rising and falling
Make.
When three dwell rotor robot to be switched to state of flight when, all deformation modules drive corresponding rotor module rotation
Parallel with main body bottom plate to horizontality, the output shaft of the driving motor of rotor module is rotated according to the direction of rotation of setting, is made
Freewheel clutch is separated with the output shaft of driving motor, and land row wheel does not rotate, and driving motor drives rotor wing rotation, and rotor high speed is revolved
Switch to fuselage and the power of lift and pose adjustment is provided, the rotor wing rotation of adjacent rotor module is contrary on main body bottom plate;
When three dwell rotor robot land row state is switched to from state of flight when, firstly, undercarriage is fallen, three dwell rotor
Machine lands, and then, all deformation modules drive corresponding rotor module to rotate, main body vertical with main body bottom plate to vertical state
On bottom plate adjacent rotor module direction of rotation on the contrary, the driving motor of rotor module output shaft according to setting direction of rotation
Rotation, engages freewheel clutch with the output shaft of driving motor, and driving motor drives the rotation of land row wheel, the rotation so that driving three is dwelt
Wing robot land row;
When three dwell rotor robot to be switched in water move under water state when, two deformation modules or rear side on front side of main body bottom plate
It is vertical with main body bottom plate to vertical state that two deformation modules drive corresponding rotor module to rotate, and the two are rotated to vertical
The direction of rotation of the rotor module of state on the contrary, rotation to vertical state rotor module driving motor output shaft according to setting
Fixed direction of rotation rotation, separates freewheel clutch with the output shaft of driving motor, and land row wheel does not rotate, driving motor driving
Rotor wing rotation, rotor high speed rotation provide the power of thrust and pose adjustment for fuselage, rotate to the rotor module of vertical state
Rotor wing rotation it is contrary.
Above embodiments are only to illustrate the technical solution of the utility model, rather than its limitations;Although referring to aforementioned reality
Example is applied the utility model is described in detail, those skilled in the art should understand that: it still can be to preceding
Technical solution documented by embodiment is stated to modify or equivalent replacement of some of the technical features;And these are repaired
Change or replaces, the spirit and scope for the utility model embodiment technical solution that it does not separate the essence of the corresponding technical solution.
Claims (7)
- The rotor robot 1. a kind of land, water and air three are dwelt characterized by comprisingMain body bottom plate (1);Four rotor modules (2), are symmetricly set on the four corners of main body bottom plate (1), receive the control of electronic control module (5), rotor Module (2) includes the driving mechanism of rotor (24), land row wheel (26) and driving rotor (24), land row wheel (26) work;Four deformation modules (3) correspond with four rotor modules (2) respectively, are symmetricly set on the quadrangle of main body bottom plate (1) Place, for driving corresponding rotor module (2) to rotate in vertical direction, receives the control of electronic control module (5);Electronic control module (5), be arranged on main body bottom plate (1), for three dwell rotor robot provide electric energy and control signal.
- The rotor robot 2. a kind of land, water and air three according to claim 1 are dwelt, which is characterized in that it further include undercarriage, if It sets in main body bottom plate (1) bottom surface, is supported for dwelling during rotor robot is converted to land row state by state of flight three Three dwell rotor robot, receive the control of electronic control module (5).
- The rotor robot 3. a kind of land, water and air three according to claim 2 are dwelt, which is characterized in that the undercarriage includes four A frame module that rises and falls (4) for being symmetricly set on main body bottom plate (1) bottom surface four corners, the frame module that rises and falls (4) includes that straight line pushes away Bar motor (41), connecting rod (43), link block (44), supporting leg (42) and hinged seat (45), the line handspike motor (41) are fixed In main body bottom plate (1) bottom surface, the push rod front end and connecting rod (43) one end of the line handspike motor (41) are hinged, the connecting rod (43) hingedly, the link block (44) is fixedly connected with supporting leg (42), supporting leg (42) top for the other end and link block (44) Hingedly with hinged seat (45), the hinged seat (45) is fixed on main body bottom plate (1) bottom surface.
- The rotor robot 4. a kind of land, water and air three according to claim 1 are dwelt, which is characterized in that the driving mechanism includes Horn (21), driving motor (22) and freewheel clutch (23), the driving motor (22) setting are described in horn (21) front end Horn (21) rear end is connected with corresponding deformation module (3), and the output shaft end of the driving motor (22) and rotor (24) are solid Fixed connection, the output shaft of the driving motor (22) and freewheel clutch (23) are cooperatively connected, and the land row wheel (26) passes through wheel Hub (25) is fixedly connected with freewheel clutch (23).
- The rotor robot 5. a kind of land, water and air three according to claim 4 are dwelt, which is characterized in that the deformation module (3) Including digital rudder controller (32), driving gear (34), driven gear (33) and two axle beds (31), described two axle beds (31) are opposite Setting, the horn (21) pass through two axle beds (31) and with axle bed (31) rotatable engagement, the driven gear (33) is set in It is fixedly connected on horn (21) and with horn (21), the driven gear (33) is stuck between two axle beds (31), the active Gear (34) is engaged with driven gear (33), and the driving gear (34) is fixedly connected with the output shaft of digital rudder controller (32).
- The rotor robot 6. a kind of land, water and air three according to claim 1 are dwelt, which is characterized in that the electronic control module (5) Including controller (51), wireless communication module (52) and battery (54), the controller (51) respectively with wireless communication module (52) it is connected with battery (54).
- The rotor robot 7. a kind of land, water and air three according to claim 1 are dwelt, which is characterized in that the main body bottom plate (1) In X-shaped.
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110861454A (en) * | 2019-11-29 | 2020-03-06 | 吉林大学 | Reconfigurable air-submersible amphibious robot |
CN112009647A (en) * | 2020-09-10 | 2020-12-01 | 张愉 | Fire-fighting robot |
CN114132499A (en) * | 2022-01-04 | 2022-03-04 | 中国海洋大学 | Sea, land and air underwater four-purpose aircraft |
CN114633823A (en) * | 2022-03-07 | 2022-06-17 | 清华大学 | Triphibian robot |
-
2018
- 2018-08-21 CN CN201821351635.6U patent/CN208867806U/en not_active Expired - Fee Related
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110861454A (en) * | 2019-11-29 | 2020-03-06 | 吉林大学 | Reconfigurable air-submersible amphibious robot |
CN112009647A (en) * | 2020-09-10 | 2020-12-01 | 张愉 | Fire-fighting robot |
CN114132499A (en) * | 2022-01-04 | 2022-03-04 | 中国海洋大学 | Sea, land and air underwater four-purpose aircraft |
CN114633823A (en) * | 2022-03-07 | 2022-06-17 | 清华大学 | Triphibian robot |
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