Patent Description:
With the continuous and rapid development of the national economy, more and more investment has been made in infrastructure. Under this background, a large number of road and railway tunnels have appeared. In the operation of the tunnel, it is necessary to detect and prevent the leakage, freezing and thawing of the tunnel, lining damage and other diseases, and at the same time clean and maintain the tunnel. In the related art, the tunnel operation robot includes a power supply and a rotating fan, and the power supply provides power to the rotation fan to make the rotation fan work, thereby keeping the tunnel operation robot suspended. As the requirements for tunnel operations become more and more stringent, the operating devices on tunnel operation robots are becoming more and more complex and heavier. In order to ensure the work requirements, the current common practice is to increase the radius of the rotating fan, and increasing the radius of the rotating fan usually increases the size of the tunnel operation robot in different directions. Furthermore, due to the influence of the included angle between the bottom of the tunnel and the ground, and the curvature of the tunnel itself, it is prone to encountering work blind spots due to interference issues in the direction contained within the cross section of the tunnel.

Patent literature <CIT> discloses an automatic wall climbing type radar photoelectric robot system for damages of a bridge and tunnel structure, mainly including a control terminal, a wall climbing robot and a server. The system further includes robot controller, robot chassis provided with protruding cantilever parts on both sides, Mecanum wheel, robot chassis, and rotor system which includes rotating fan as shown in <FIG>. The wall climbing robot generates a reverse thrust by rotor systems, moves flexibly against the surface of a rough bridge and tunnel structure by adopting an omnidirectional wheel technology, and during inspection by the wall climbing robot, bridges and tunnels do not need to be closed, and the traffic is not affected. Bridges and tunnels can divide into different working regions only by arranging a plurality of UWB base stations, charging and data receiving devices on the bridge and tunnel structure by means of UWB localization, laser SLAM and IMU navigation technologies, a plurality of wall climbing robots supported to work at the same time, automatic path planning and automatic obstacle avoidance realized, and unattended regular automatic patrolling can be realized.

Patent literature <CIT> discloses an unmanned quadrotor aerial vehicle for two rotatable ductwork with a fixed wing. An elliptical fuselage is provided with a main ductwork power system in the long axis direction to provide main takeoff and suspension power, and an auxiliary ductwork power system in the short axis direction can be driven by a rotating motor inside the fuselage to realize + <NUM> degrees rotation. When the thrust of the auxiliary power is consistent with the main power, the take-off and suspension of the main power are assisted. When the thrust of the auxiliary power is perpendicular to the main power, it provides the power for the aircraft to fly forward or fly backward at low speed in the air, and the difference in rotational speed between the two ducted fans controlling the auxiliary power plays a yaw role. In addition, the fixed wing with fixed wingspan is installed in the short axis direction of the fuselage, which can provide quantitative lift for the whole fuselage, reduce the power consumption of the main power, save electricity compared with other quadrotors at the same speed, and improve the endurance.

While the above publications may achieve their intended purposes, there is still a need for a new and improved tunnel operation robot.

The disclosure aims to solve at least one of the technical problems in the existing technology. For this reason, the disclosure proposes a tunnel operation robot, which has a relatively large load capacity, and is not prone to encountering work blind spot due to interference issue, and is more convenient to control.

The tunnel operation robot according to the embodiment of the disclosure includes a robot body, a walking module, a fixed wing module and a plurality of rotatable wing modules. Both sides of the robot body are provided with protruding cantilever parts, and the cantilever parts on both sides are collinearly arranged. The walking module is arranged on the robot body, and is configured to drive the robot body to walk and steer on a tunnel wall surface. The fixed wing module includes a fixed fan and is arranged on the robot body, and is configured to provide a pressure for the walking module to be pressed and attached to the tunnel wall surface. The plurality of rotatable wing module are respectively arranged on the cantilever parts on both sides of the robot body, and include a rotatably arranged rotating fan and a wind direction adjustment driver. Each rotating fan has a rotation axis parallel to an extension direction of the cantilever parts and an air outlet direction perpendicular to the extension direction of the cantilever parts, and the wind direction adjustment driver is connected to the rotating fan, and is configured to maintain the air outlet direction of the rotating fan downward to generate a thrust capable of balancing gravity. A pressure detection device is provided between the robot body and the walking module, and the pressure detection device is configured to detect a pressure transmitted from the robot body to the walking module.

The tunnel operation robot according to the embodiment of the disclosure has at least the following beneficial effects.

In the tunnel operation robot according to the embodiment of the disclosure, by means of the fixed wing module, i.e., by means of the thrust generated by the fixed fan in the fixed wing module, the walking module in the tunnel operation robot can be attached to and contact with the tunnel wall surface with a certain pressure. By arranging the rotatable wing modules, and enabling the rotating fans in the rotatable wing modules to keep the wind outlet direction downward under the drive of the wind direction adjustment driver, so that the rotatable wing modules can generate a thrust for balancing the gravity, and further by means of the walking module, the walking and steering of the tunnel operation robot on the wall surface can be realized. Therefore, the tunnel operation robot according to the embodiment of the disclosure can use the rotatable wing modules, the fixed wing module and the walking module to respectively realize suspension, wall pressing and attaching, and walking, the control process is simpler and easier to operate. Meanwhile, since there are multiple rotatable wing modules for generating an upward thrust, it can generate a more powerful lifting force to balance the gravity, so that the tunnel operation robot can bear greater gravity to carry an operation module with more comprehensive functions and larger weight. Moreover, since the rotatable wing modules are all connected to the cantilever parts collinearly arranged on both sides of the robot body, the plurality of rotatable wing modules arranged to enhance the lifting force are arranged along the same direction, so they only affect the size of the tunnel operation robot in the extension direction of the cantilever part, and it is not prone to encountering work blind spots due to interference issues in the direction contained within the cross section of the tunnel.

In some embodiments of the disclosure, the rotation axis of each rotating fan is located on the same straight line passing through a center of gravity of the tunnel operation robot.

In some embodiments of the disclosure, the rotatable wing modules on the cantilever parts on both sides of the robot body are arranged symmetrically.

In some embodiments of the disclosure, the rotatable wing modules are detachably connected to the cantilever parts.

In some embodiments of the disclosure, the rotatable wing module further includes a connecting frame and a rotating bracket, the rotating fan is arranged on the rotating bracket, and the wind direction adjustment driver is connected to the connecting frame and the rotating bracket, and is capable of driving the rotating bracket to rotate relative to the connecting frame, and the connecting frame is detachably connected to a corresponding one of the cantilever parts.

In some embodiments of the disclosure, the tunnel operation robot further includes a control module, the rotatable wing module further includes a thrust detection device, the thrust detection device is arranged between the rotating bracket and the rotating fan, and configured to detect a magnitude of the thrust transmitted from the rotating fan to the rotating bracket, and both the thrust detection device and the rotating fan are electrically connected to the control module.

In some embodiments of the disclosure, the walking module includes a frame body, a walking assembly and a driving assembly, the walking assembly is arranged on the frame body and configured for walking and steering, the driving assembly is arranged on the frame body and connected to the walking assembly for driving, the frame body is detachably connected to the robot body, and the pressure detection device is arranged between the frame body and the robot body.

In some embodiments of the disclosure, a detection module is arranged inside the robot body, the detection module is configured to detect a tunnel, the frame body is arranged in a framework-model manner, a detection port is formed in a middle of the frame body, the detection module penetrates through the detection port, and a detection end of the detection module protrudes from the frame body.

Additional aspects and advantages of the disclosure will be pointed out in part in the following description, and in part will be apparent from the following description, or may be learned by practice of the disclosure.

The above-mentioned and/or additional aspects and advantages of the disclosure will become apparent and comprehensible from the description of the embodiments in conjunction with the following drawings, wherein:.

Robot body <NUM>; cantilever part <NUM>; detection module <NUM>; walking module <NUM>; second pressure sensor <NUM>; frame body <NUM>; detection port <NUM>; walking assembly <NUM>; driving assembly <NUM>; fixed wing module <NUM>; fixed fan <NUM>; fixing bracket <NUM>; rotatable wing module <NUM>; rotating fan <NUM>; ear plate <NUM>; connecting piece <NUM>; wind direction adjustment driver <NUM>; connecting frame <NUM>; first connection part <NUM>; second connection part <NUM>; first connection through hole <NUM>; rotating bracket <NUM>; abutting part <NUM>; connecting plate <NUM>; second connection through hole <NUM>; thrust detection device <NUM>.

Embodiments of the present disclosure will be described in detail below. Examples of the embodiments are illustrated in the accompanying drawings, where the same or like reference numerals throughout the figures indicate the same or like elements having the same or like functions. The embodiments described below with reference to the accompanying drawings are exemplary and are intended only to explain the present disclosure instead of being construed as limiting the present disclosure.

In the description of the present disclosure, it should be understood that, descriptions relating to orientation, for example, orientation or positional relationships indicated by "up", "down", "front", "back", "left", "right", etc. are based on the orientation or positional relationships shown in the accompanying drawings, and are to facilitate the description of the present disclosure and simplify the description only, rather than indicating or implying that the device or element referred to must have a specific orientation or be constructed and operated in a specific orientation, and therefore cannot be construed as limiting the present disclosure.

In the description of the present disclosure, if "first" and "second", etc. are referred to, it is only for the purpose of distinguishing technical features, and shall not be understood as indicating or implying relative importance or implying the number of the indicated technical features or implying the sequence of the indicated technical features.

In the description of the present disclosure, unless otherwise explicitly defined, the words such as "set", "install", and "connect" should be understood in a broad sense, and those having ordinary skills in the art can determine the specific meanings of the above words in the present disclosure in a rational way in combination with the specific contents of the technical solutions.

Referring to accompanying drawings <NUM> to <NUM>, the tunnel operation robot according to the embodiment of the disclosure will be described below.

Referring to <FIG>, <FIG> and <FIG>, a tunnel operation robot according to an embodiment of the disclosure includes a robot body <NUM>, a walking module <NUM>, a fixed wing module <NUM> and a plurality of rotatable wing modules <NUM>.

Both sides of the robot body <NUM> are provided with protruding cantilever parts <NUM>, and the cantilever parts <NUM> on both sides are collinearly arranged. The walking module <NUM> is arranged on the robot body <NUM>, and is configured to drive the robot body <NUM> to walk and turn on a tunnel wall surface. The fixed wing module <NUM> is arranged on the robot body <NUM>, and includes a fixed fan <NUM>, and is configured to provide pressure for the walking module <NUM> to be pressed against the tunnel wall surface. The plurality of rotatable wing modules <NUM> are respectively arranged on the cantilever parts <NUM> on both sides of the robot body <NUM>, and each include a rotatably arranged rotating fan <NUM> and a wind direction adjustment driver <NUM>. Each rotating fan <NUM> has a rotation axis parallel to an extension direction of the cantilever part <NUM>, and a wind outlet direction perpendicular to the extension direction of the cantilever part <NUM>. The wind direction adjustment driver <NUM> is connected to the rotating fan <NUM> and is configured to keep the wind outlet direction of the rotary fan <NUM> downward to generate a thrust for balancing the gravity.

It can be understood that, in order to realize the tunnel operation, the tunnel operation robot may further be provided with an operation module. In this embodiment, specifically, the operation module is a detection module <NUM>, and the detection module <NUM> is arranged inside the robot body <NUM>. In order to avoid that the casing of the robot body <NUM> affects the detection operation of the detection module <NUM> on the tunnel, a detection end of the detection module <NUM> is exposed from the robot body <NUM>, and the detection end is located on a side of the robot body <NUM> where the walking module <NUM> is disposed.

It should be understood that, in addition to being the above-mentioned detection module <NUM>, the operation module can also be configured according to different types of operations required, and can also include multiple operation modules for completing various types of operations. For example, when a cleaning operation is required, in other embodiments, a vacuum cleaner, an air duct, and a cleaning roller brush similar to the sweeping robot can also be arranged inside the robot body <NUM>, and the surrounding sides of the cleaning roller brush are exposed from the robot body <NUM>, so as to be able to contact the tunnel wall surface to be cleaned. For example, when the image information of the tunnel needs to be collected, a camera device can also be arranged inside the robot body <NUM>, and the camera of the camera device is exposed from the robot body <NUM>, so as to be able to photograph the tunnel wall surface to be photographed. For example, the detection module <NUM> and the camera device can also be installed inside the robot body <NUM> at the same time.

It should be understood that, similarly, the detection module <NUM> can also be selected according to the category of items detected on the wall surface of the tunnel, for example, it can be a nuclear magnetic resonance detection device, an electromagnetic wave detection device and an ultrasonic detection device, etc., and the type of the detection module <NUM> is not specifically limited herein.

Specifically, when the wall surface of the tunnel is detected by the tunnel operation robot according to the embodiment of the disclosure, firstly, the side of the tunnel operation robot equipped with the walking module <NUM> is abutted against the wall surface of the tunnel by manually grabbing the tunnel operation robot (at this time, the cantilever part <NUM> of the tunnel operation robot is close to a horizontal state, and the extension direction of the cantilever part <NUM> is roughly close to the extension direction of the tunnel, that is, the length direction of the tunnel). Then the tunnel operation robot is be started to work in the tunnel. After the tunnel operation robot is started, both the fixed-wing module <NUM> and the rotatable wing module <NUM> start to work. At the same time, the attitude detection mechanism such as gyroscope installed inside the robot body <NUM> will automatically detect the attitude state of the tunnel operation robot. According to the detected attitude, the walking module <NUM> works and performs quick adjustments such as walking and steering, so that the cantilever part <NUM> is in a horizontal state, that is, the leveling of the cantilever part <NUM> is completed (since the rotation axis of the rotating fan <NUM> is parallel to the extension direction of the cantilever part <NUM>, when the cantilever part <NUM> is adjusted to a horizontal state, it is convenient to adjust the rotating fan <NUM> to enable the air outlet direction to be vertically downward). Almost at the same time, the rotating fan <NUM> in the rotatable wing module <NUM> is also driven by the wind direction adjustment driver <NUM> to complete adjustment of the wind outlet direction to be vertically downward. Therefore, attachment to the wall and suspension can be realized by means of the fixed wing module <NUM> and the rotatable wing module <NUM>. In the detection process, the walking module <NUM> drives the entire tunnel operation robot to walk on the wall surface of the tunnel, so that the tunnel operation robot can perform scanning detection on the tunnel wall surface. Moreover, in the detection process, considering that the curvature of the tunnel wall surface changes greatly in the direction of its cross section, but has less change in the length direction of the tunnel, so in order to avoid frequent and large angle adjustment of the rotating fan <NUM>, in the detection process, the tunnel operation robot may move from one end of the tunnel to the other end of the tunnel along the extension direction of the tunnel, and then the tunnel operation robot may be controlled to move up or down by a position of the tunnel operation robot position along the contour of the tunnel wall on the cross section, and then continue to move from one end to the other end of the tunnel along the extension direction of the tunnel.

It can be seen from the above detection process that the cantilever part <NUM> is always kept horizontal in the detection process, and is basically parallel to the extension direction of the tunnel. Moreover, the plurality of rotatable wing modules <NUM> arranged to achieve a larger load are installed in a row on the cantilever part <NUM>. Therefore, arrangement of the plurality of rotatable wing modules <NUM> only affects the size of the tunnel operation robot in the tunnel extension direction, and does not affect the size of the tunnel operation robot in the direction contained within the cross section of the tunnel, so it is not prone to encountering work blind spots due to interference issues in the direction contained within the cross section of the tunnel.

To sum up, it can be understood that, in the tunnel operation robot according to the embodiment of the disclosure, by means of the fixed wing module <NUM>, i.e., by means of the thrust generated by the fixed fan <NUM> in the fixed wing module <NUM>, the walking module <NUM> in the tunnel operation robot can be attached to and contact with the tunnel wall surface with a certain pressure. By arranging the rotatable wing modules <NUM>, and enabling the rotating fans <NUM> in the rotatable wing modules <NUM> to keep the wind outlet direction downward under the drive of the wind direction adjustment driver <NUM>, so that the rotatable wing modules <NUM> can generate a thrust for balancing the gravity, and further by means of the walking module <NUM>, the walking and steering of the tunnel operation robot on the wall surface can be realized. Therefore, the tunnel operation robot according to the embodiment of the disclosure can use the rotatable wing modules <NUM>, the fixed wing module <NUM> and the walking module <NUM> to respectively realize suspension, wall pressing and attaching, and walking, the control process is simpler and easier to operate. Meanwhile, since there are multiple rotatable wing modules <NUM> for generating an upward thrust, it can generate a more powerful lifting force to balance the gravity, so that the tunnel operation robot can bear greater gravity to carry a detection module <NUM> with more comprehensive functions and larger weight or other types of operation modules. Moreover, since the rotatable wing modules <NUM> are all connected to the cantilever parts <NUM> collinearly arranged on both sides of the robot body <NUM>, the plurality of rotatable wing modules arranged to enhance the lifting force are arranged along the same direction, so they only affect the size of the tunnel operation robot in the extension direction of the cantilever part <NUM>, and it is not prone to encountering work blind spots due to interference issues in the direction contained within the cross section of the tunnel.

It can be understood that, in some embodiments, in order to better balance the gravity and prevent the tunnel operation robot from overturning due to the overturning torque generated by the gravity and the lifting force provided by the rotatable wing modules <NUM>, the rotation axes of the rotating fans <NUM> are all located on the same straight line passing through the center of gravity of the tunnel operation robot, so that the tunnel operation robot can be more stable when working.

It can be understood that, in some embodiments, the rotatable wing modules <NUM> on the cantilever parts <NUM> on both sides of the robot body <NUM> are arranged symmetrically. In case that the rotating fans <NUM> have the same specification, the lifting force generated by each rotating fan <NUM> when rotating at the same speed is basically the same. By symmetrically arranging the rotating wing modules <NUM> on both sides of the robot body <NUM>, it is easier to keep the tunnel operation robot in balance and avoid overturning when each rotating fan <NUM> rotates at the same speed. Therefore, it is convenient to uniformly control the rotating speed of each rotating fan <NUM> when the tunnel operation robot works, so as to further improve the control convenience of the tunnel operation robot.

It can be understood that, in an embodiment, the rotatable wing modules <NUM> are detachably connected to the cantilever part <NUM>. By detachably connecting the rotatable wing modules <NUM> to the cantilever part <NUM>, it is convenient for the tunnel operation robot to increase or decrease the number of the rotatable wing modules <NUM> according to the weight of the detection module <NUM> carried. When the weight is relatively heavy, the rotatable wing module <NUM> may be added on the cantilever part <NUM>, and when the weight is relatively light, the rotatable wing module <NUM> may be removed.

It can be understood that, in an embodiment, in order to facilitate the detachable connection of the rotatable wing module <NUM>, and also to facilitate the rotatable setting of the rotating fan <NUM>, referring to <FIG> and <FIG>, specifically, the rotatable wing module <NUM> further includes a connecting frame <NUM> and a rotating bracket <NUM>, wherein the rotating fan <NUM> is arranged on the rotating bracket <NUM>, the wind direction adjustment driver <NUM> is connected with the connecting frame <NUM> and the rotating bracket <NUM>, and can drive the rotating bracket <NUM> to rotate relative to the connecting frame <NUM>, and the connecting frame <NUM> is detachably connected with the cantilever part <NUM>.

It can be understood that, in order to realize the detachable connection between the connecting frame <NUM> and the cantilever part <NUM>, in an embodiment, the connecting frame <NUM> includes a first connecting part <NUM> and a second connecting part <NUM> arranged side by side, the first connecting part <NUM> and the second connecting part <NUM> are each provided with first connecting through holes <NUM>. Specifically, the rotatable wing module <NUM> further includes a connecting plate <NUM>, and the connecting plate <NUM> is provided with second connecting holes <NUM> corresponding to the first connecting through holes <NUM>. A first threaded connector passes through the first connecting through hole <NUM> and is screwed into the second connecting through hole <NUM>. The cantilever part <NUM> passes through a first clamping area formed by the first connecting part <NUM>, the second connecting part <NUM> and the connecting plate <NUM>. Referring to <FIG>, specifically, the cantilever part <NUM> may extend along the left and right directions, the connecting plate <NUM> may be located at an upper end of the cantilever part <NUM>, and the connecting plate <NUM> may be respectively provided with two second connecting through holes <NUM> at a front end and a rear end. Correspondingly, the first connecting part <NUM> may be provided with two first connecting through holes <NUM>, the second connecting part <NUM> may be provided with two first connecting through holes <NUM>, and the first connecting part <NUM> may be located at a front side of the second connecting part <NUM>. The first threaded connector may be provided in four. The first threaded connector may be a screw, and correspondingly, the second connecting through hole <NUM> is a threaded hole, the first connecting through hole <NUM> is a through hole. The first connecting through holes <NUM> in the connecting part <NUM> may correspond to the second connecting through holes <NUM> at the front end of the connecting plate <NUM>. Two screws may be connected to the first connecting through holes <NUM> in the first connecting part <NUM> and the second connection through holes <NUM> at the front end of the connecting plate <NUM>, so that the first connecting part <NUM> is connected to the front end of the connecting plate <NUM>. The first connecting through holes <NUM> in the second connecting part <NUM> may correspond to the second connecting through holes <NUM> at the rear end of the connecting plate <NUM>, and the other two screws may be connected to the first connecting through holes <NUM> in the second connecting part <NUM> and the second connecting through holes <NUM> at the rear end of the connecting plate <NUM>, so that the second connecting part <NUM> is connected to the rear end of the connecting plate <NUM>. Meanwhile, a first clamping area is formed by the first connecting part <NUM>, the second connecting part <NUM> and the connecting plate <NUM>, and the cantilever part <NUM> may pass through the first clamping area, so that the rotatable wing module <NUM> is fixed on the cantilever part <NUM>.

It should be understood that, in some other embodiments, the second connection through hole <NUM> may also be directly provided on the cantilever part <NUM>, and the screw passing through the first connection through hole <NUM> and the second connection through hole <NUM> may be directly used to connect the connecting frame <NUM> to the cantilever part <NUM>.

It can be understood that, in order to facilitate the forming and installation of the cantilever part <NUM> on the robot body <NUM>, and also to improve the load-bearing capacity of the cantilever part <NUM>, in an embodiment, the tunnel operation robot further includes a mounting rod, and a middle part of the mounting rod is penetrated through the robot body <NUM>, and both ends of the mounting rod protrude from the robot body <NUM> to form the cantilever parts <NUM>. Specifically, a shell of the robot body <NUM> is provided with a perforation that allows the mounting rod to pass through. The middle part of the mounting rod is located inside the shell of the robot body <NUM>, and the mounting rod pass through the above perforation. Moreover, in order to make sure that the lengths of the cantilever parts <NUM> at left and right sides of the robot body <NUM> can be the same, left and right ends of the mounting rod exposed from the robot body <NUM> have the same length.

It should be understood that, in some other embodiments, it is also possible to select two rods and connect the two rods to the left and right sides of the robot body <NUM> through a fastener to form two cantilever parts <NUM> respectively.

It can be understood that, in another embodiment of the disclosure, the tunnel operation robot further includes a control module (not shown in the drawings). Referring to <FIG>, the rotatable wing module <NUM> further includes a thrust detection device <NUM> arranged between the rotating bracket <NUM> and the rotating fan <NUM> and configured to detect a thrust transmitted from the rotating fan <NUM> to the rotating bracket <NUM>. Both the thrust detection device <NUM> and the rotating fan <NUM> are electrically connected to the control module. During operating of the tunnel operation robot, the control module will obtain a theoretical thrust value required to be generated by each rotating fan <NUM> according to the gravity or acceleration of the tunnel operation robot, and control the rotating speed of the rotating fan <NUM> according to the theoretical thrust value. The thrust detection device <NUM> is configured to detect an actual thrust value transmitted to the rotating bracket <NUM> when the rotating fan <NUM> is working, so as to adjust the speed of each rotating fan <NUM> according to the deviation between the actual thrust value and the theoretical thrust value. For example, when the actual thrust value is smaller than the theoretical thrust value, the actual thrust value is increased by increasing the rotating speed of the rotating fan <NUM>, and when the actual thrust value is greater than the theoretical thrust value, the actual thrust value is reduced by reducing the rotating speed of the rotating fan <NUM>, thereby further improving the control accuracy through a closed-loop control.

In an embodiment, specifically, a connecting piece <NUM> is provided on an outer side surface of the rotating fan <NUM>, an abutting part <NUM> is provided on the rotating bracket <NUM>. The abutting part <NUM> and the connecting piece <NUM> are arranged along a direction parallel to the axis of the rotating fan <NUM>, and the abutting part <NUM> is located at a side of the connecting piece <NUM> close to an air suction port of the rotating fan <NUM>. The thrust detection device <NUM> is a first pressure sensor, and the first pressure sensor is arranged between the connecting piece <NUM> and the abutting part <NUM>, so that when the rotating fan <NUM> is working, it can move towards the abutting part <NUM> under its own thrust, to press against the first pressure sensor through the connecting piece <NUM>, thereby detecting the magnitude of the thrust transmitted from the rotating fan <NUM> to the rotating bracket <NUM>.

Specifically, the rotating fan <NUM> adopts a ducted fan, and the ducted fan includes a ducted cylinder, and fan blades and a motor arranged in the ducted cylinder. Both sides of the ducted cylinder are provided with an ear plate <NUM>, and there are two connecting pieces <NUM> which are respectively connected to the two ear plates <NUM>. Similarly, there are also two abutting parts <NUM>, which are arranged corresponding to the two connecting pieces <NUM> respectively. The first pressure sensor is arranged between each of the abutting parts <NUM> and a respective one of the connecting pieces <NUM>.

It can be understood that, in an embodiment of the disclosure, referring to <FIG>, similarly, the fixed fan <NUM> also adopts a ducted fan, and the fixed wing module <NUM> further includes a fixing bracket <NUM>. The ducted fan in the fixed wing module <NUM> is fixedly connected to the fixing bracket <NUM>, and the fixing bracket <NUM> is fixedly connected to the robot body <NUM>. Specifically, there are two fixed wing modules <NUM>, which are respectively arranged on a front side and a rear side of the robot body <NUM>, so as to avoid the installation positions of the rotatable wing modules <NUM>.

Referring to <FIG>, it can be understood that, according to the invention, a pressure detection device is provided between the robot body <NUM> and the walking module <NUM>, and the pressure detection device is configured to detect a pressure transmitted from the robot body <NUM> to the walking module <NUM>. Specifically, the pressure detection device includes a second pressure sensor <NUM>, and the second pressure sensor <NUM> is disposed on the walking module <NUM> and abuts against the robot body <NUM>.

It should be understood that, in some other embodiments, the second pressure sensor <NUM> may also be disposed on the robot body <NUM> and abut against the walking module <NUM>.

In an embodiment, similarly, the control module is also electrically connected to the fixed fan <NUM>, and can control the pressure exerted by the robot body <NUM> to the walking module <NUM> by controlling the speed of the fixed fan <NUM>. When the second pressure sensor <NUM> detects that the pressure on the walking module <NUM> is greater than a set value, a pressure signal is sent to the control module, and the control module controls the fixed fan <NUM> to reduce the speed, so as to reduce the pressure exerted by the robot body <NUM> to the walking module <NUM>. When the second pressure sensor <NUM> detects that the pressure on the walking module <NUM> is less than the set value, a pressure signal is sent to the control module, and the control module controls the fixed fan <NUM> to increase the speed, so as to increase the pressure exerted by the robot body <NUM> to the walking module <NUM>.

It can be understood that, in an embodiment, the walking module <NUM> includes a frame body <NUM>, a walking assembly <NUM> and a driving assembly <NUM>. The walking assembly <NUM> is arranged on the frame body <NUM> and configure for walking and steering. The driving assembly <NUM> is arranged on frame body <NUM> and connected with the walking assembly <NUM> for driving the walking assembly <NUM>. The frame body <NUM> is detachably connected with the robot body <NUM>. Specifically, the pressure detection device is disposed between the frame body <NUM> and the robot body <NUM>.

It can be understood that, in an embodiment, specifically, the frame body <NUM> is detachably connected to the robot body <NUM> through a threaded fastener. It should be understood that, in some other embodiments, the frame body <NUM> may also be detachably connected to the robot body <NUM> in a snap-fit or clamping manner.

It can be understood that, referring to <FIG>, in an embodiment, the driving assembly <NUM> includes a motor and a coupling, the motor is arranged on the frame body <NUM>, one end of the coupling is connected to an output shaft of the motor, and the other end is connected with the walking assembly <NUM>. Specifically, in this embodiment, the motors drive the corresponding walking assemblies <NUM> through the couplings, and through the differential speed control among the multiple motors, the multiple walking assemblies <NUM> can realize forward and backward walking and steering actions.

It can be understood that, referring to <FIG>, in an embodiment, the walking assembly <NUM> is configured as a wheeled-model walking structure, the walking assembly <NUM> includes a driving wheel, and the driving wheel is connected to the coupling, and is driven by a motor to rotate. In an embodiment, the driving wheel adopts Mecanum wheel to realize walking and steering, so that the walking and steering of the walking module <NUM> are more flexible. In addition, in some other embodiments, the driving wheel may also use rubber wheel to realize walking and steering.

It should be understood that, in some other embodiments, the walking assembly <NUM> may also be configured as a crawler-model walking structure. Furthermore, in some other embodiments, the walking assembly <NUM> may also adopt a walk-model walking structure. Moreover, in some other embodiments, there are multiple walking modules <NUM>, and the walking modules <NUM> adopt different walking assemblies <NUM>, such as respectively adopting a wheeled-model walking structure, a crawler-model walking structure or a walk-model walking structure, so that the tunnel operation robot can adapt to the walking requirements of different environments by selecting and replacing the walking module <NUM> with a walking assembly <NUM> of a different form.

It should be understood that, in an embodiment, the walking module <NUM> is an independent module formed by combination of the frame body <NUM>, the driving assembly <NUM> and the walking assembly <NUM>, and the walking module <NUM> and the robot body <NUM> may be detachably connected, which makes the disassembly and assembly between the walking module <NUM> and the robot body <NUM> more convenient, and when the walking module <NUM> fails, the walking module <NUM> can be quickly removed from the robot body <NUM> for replacement or repairment, thereby ensuring the efficiency for operation of the tunnel operation robot.

It can be understood that, referring to <FIG>, in an embodiment, the frame body <NUM> is configured in a framework-mode, and a detection port <NUM> is formed in the middle thereof, so that when the walking module <NUM> is assembled with the robot body <NUM>, the detection module <NUM> can be installed in the frame body <NUM>, and the detection end of the detection module <NUM> can extend out of the frame body <NUM>. Specifically, after the walking module <NUM> is assembled with the robot body <NUM>, the frame body <NUM> is placed around the detection module <NUM> to reduce the space occupied by the walking module <NUM> during installation and make the overall structure of the tunnel operation robot more compact. In order to ensure a better detection effect, the distance between the detection end surface of the detection module <NUM> and the tunnel wall surface to be detected is controlled between <NUM>-<NUM>, that is, the distance between the point which is farthest from the robot body in the driving wheel and the plane where the detection end surface of the detection module <NUM> is located is between <NUM>-<NUM>, and in an embodiment, is specifically <NUM>, so as to achieve the best detection effect.

Claim 1:
A tunnel operation robot, comprising:
a robot body (<NUM>), provided with protruding cantilever parts (<NUM>) on both sides, wherein the cantilever parts (<NUM>) on both sides are collinearly arranged;
a walking module (<NUM>), arranged on the robot body (<NUM>) and configured to drive the robot body (<NUM>) to walk and steer on a tunnel wall surface;
a fixed wing module (<NUM>), comprising a fixed fan (<NUM>), fixedly arranged on the robot body (<NUM>), and configured to provide a pressure for the walking module (<NUM>) to be pressed against the tunnel wall surface; and
a plurality of rotatable wing modules (<NUM>), respectively arranged on the cantilever parts (<NUM>) on both sides of the robot body (<NUM>), and comprising a rotatable rotating fan (<NUM>) and a wind direction adjustment driver (<NUM>), wherein each rotating fan (<NUM>) has a rotation axis parallel to an extension direction of the cantilever parts (<NUM>) and an air outlet direction perpendicular to the extension direction of the cantilever parts (<NUM>), and the wind direction adjustment driver (<NUM>) is connected to the rotating fan (<NUM>), and configured to maintain the air outlet direction of the rotating fan (<NUM>) downward to generate a thrust capable of balancing gravity; the rotatable wing modules (<NUM>) are detachably connected to the cantilever parts (<NUM>),
wherein a pressure detection device is provided between the robot body (<NUM>) and the walking module (<NUM>), and the pressure detection device is configured to detect a pressure transmitted from the robot body (<NUM>) to the walking module (<NUM>).