CN216687162U

CN216687162U - Visual tower crane control system

Info

Publication number: CN216687162U
Application number: CN202122147986.3U
Authority: CN
Inventors: 邢铭涵; 王湘江; 黄予; 梁继烨; 王浩源; 黎泽庭; 陆瀚元; 郑军斌; 袁克凯; 曾宪睿
Original assignee: University of South China
Current assignee: University of South China
Priority date: 2021-09-07
Filing date: 2021-09-07
Publication date: 2022-06-07
Anticipated expiration: 2031-09-07

Abstract

The visual tower crane control system comprises a tower crane, a hanging object auxiliary supporting assembly, a safety monitoring assembly, a PC (personal computer) and a single chip microcomputer; the auxiliary supporting component for the hanging object comprises a camera A, a camera B, a camera C and a millimeter wave radar; the safety monitoring assembly comprises a laser ranging module, a flat arm deformation detection module, a tower body inclination detection module and a wind power detection module. The PC is respectively in communication connection with the camera A, the camera B, the camera C and the millimeter wave radar and is used for visually displaying data. According to the utility model, the visual field and the obstacle distribution condition around the tower crane are obtained through the combination of the millimeter wave radar and the multiple cameras, and an operator can accurately grasp the environment information of the operation site based on the image obtained by the cameras and the radar map obtained by the millimeter wave radar, so that the tower crane can be remotely and accurately controlled in the ground control room, and the working intensity of the operator is reduced.

Description

Visual tower crane control system

Technical Field

The utility model relates to the technical field of control of construction machinery, in particular to a visual tower crane control system.

Background

In the process of novel urbanization development, a tower crane is an indispensable hoisting device, the safety problem of the tower crane is not ignored, and in order to take into account the safety problem in development, great attention and attention are paid to the tower crane, because the safety problem of the tower crane not only serves as a large scalar quantity of the urbanization development quality, but also concerns the life safety of tower crane operators, and the severity of the safety problem is not inconstant.

A conventional tower crane structure is shown in fig. 3, and includes a tower base 11, a tower body 12, a flat arm 13, a first driving device (not shown), a trolley 15, a second driving device (not shown), and a crane assembly. The tower footing 11 is fixedly installed on the ground. The tower body 12 is fixedly connected to the upper end of the tower footing 11. The flat arm 13 is rotatably connected to the upper end of the tower body 12 through a first driving device, the flat arm 13 rotates on a horizontal plane under the driving of the first driving device, the flat arm 13 is bounded by a rotation connection point, and a balance arm section 131 and a lifting arm section 132 are respectively arranged at two ends of the flat arm 13. The trolley 15 is movably connected to the jib section 132 of the flat arm 13 through a second driving device, and the trolley 15 is driven by the second driving device to do reciprocating linear motion along the jib section 132 of the flat arm 13. The object hanging component comprises a steel cable 171, a third driving device (not shown in the figure) and a lifting hook 173, the steel cable 171 is arranged at the lower end of the trolley 15 and is connected with the trolley 15 through the third driving device, the lifting hook is connected to the lower end of the steel cable 171, the take-up or pay-off of the steel cable 171 is controlled through the third driving device, and then the lifting hook 173 is controlled to do vertical lifting movement.

On one hand, a tower crane driver needs to control a tower crane in a trolley located in the high altitude, so that certain potential safety hazards exist in the high altitude operation of the driver, the high altitude operation spirit of the driver is in a highly tense state for a long time, and the driver is easy to feel tired; on the other hand, when the object is hung, the object is hung in an auxiliary way by means of visual observation of a driver, experience analysis of the driver, contact of ground personnel with the driver through an interphone and the like, the way is relatively extensive and original, and the efficiency and the success rate of the object hanging depend on the personal ability of the driver to a large extent; on the other hand, when the driver operates the tower crane to perform various actions, certain misoperation probability exists, and if the driver collides with an obstacle or hurts people due to misoperation, the result is unimaginable.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art, and provides a visual tower crane control system which solves the problems that the existing tower crane control mode is relatively extensive and original, the efficiency of hoisting objects is difficult to guarantee, and certain misoperation probability exists.

The technical scheme of the utility model is as follows: the visual tower crane control system comprises a tower crane; the tower crane comprises a tower foundation, a tower body, a flat arm, a first driving device, a trolley, a second driving device and a hanging component; the tower footing is fixedly arranged on the ground; the tower body is fixedly connected to the upper end of the tower foundation; the horizontal arm is rotatably connected to the upper end of the tower body through a first driving device, the horizontal arm is driven by the first driving device to rotate on the horizontal plane, the horizontal arm is bounded by a rotating connection point, and a balance arm section and a lifting arm section are respectively arranged at two ends of the horizontal arm; the trolley is movably connected to the jib section of the flat arm through a second driving device and is driven by the second driving device to do reciprocating linear motion along the jib section of the flat arm; the object hanging component comprises a steel cable, a third driving device and a lifting hook, the steel cable is arranged at the lower end of the trolley and is associated with the trolley through the third driving device, the lifting hook is connected to the lower end of the steel cable, and the third driving device controls the steel cable to take up or pay off so as to control the lifting hook to vertically move;

the system also comprises a hanging auxiliary supporting component, a safety monitoring component, a PC and a singlechip;

the auxiliary hanging supporting component comprises a camera A, a camera B, a camera C and a millimeter wave radar; the camera A is arranged on the tower body and used for acquiring the ground and aerial visual field around the tower body, the camera B is arranged at the lower end of the crane arm section and used for acquiring the visual field of the lower area of the crane arm section, and the camera C is arranged at the lower end of the trolley and used for acquiring the visual field right below the lifting hook and the lifting hook; the millimeter wave radar is installed at the lower end of the crane arm section and used for acquiring the obstacle distribution condition of the lower area of the crane arm section;

the safety monitoring assembly comprises a laser ranging module, a flat arm deformation detection module, a tower body inclination detection module and a wind power detection module; the two laser ranging modules are respectively arranged on two opposite side walls of the flat-arm crane jib section, and the light emitting directions of the two laser ranging modules are parallel to the crane jib section and extend towards the tail end of the crane jib section, and the two laser ranging modules are used for detecting whether barriers exist on the rotation path of the crane jib section; the flat arm deformation detection module is arranged at the lower end of the lifting arm section and is used for detecting the bending deformation degree of the lifting arm section; the tower body inclination detection module is arranged on the tower body and used for detecting the bending deformation degree of the tower body; the wind power detection module is arranged on the tower body and/or the flat arm and is used for detecting the wind power level;

the PC is respectively in communication connection with the camera A, the camera B, the camera C and the millimeter wave radar and is used for visually displaying images acquired by the camera A, the camera B and the camera C and radar data acquired by the millimeter wave radar;

the signal input end of the single chip microcomputer is in communication connection with the laser ranging module, the flat arm deformation detection module, the tower body inclination detection module and the wind power detection module respectively, and the signal output end of the single chip microcomputer is in communication connection with the first driving device, the second driving device, the third driving device and the PC respectively.

The further technical scheme of the utility model is as follows: the PC also comprises a quick frame grabber and an image edge calculation module; the fast frame grabber is respectively in communication connection with the camera A, the camera B and the camera C so as to capture each frame of a video image shot by the camera A, the camera B and the camera C; the image edge calculation module is in communication connection with the fast frame grabber so as to perform object contour tracing processing on the frame pictures extracted by the fast frame grabber.

Compared with the prior art, the utility model has the following advantages:

1. through the combination of millimeter wave radar and a plurality of camera, acquire the peripheral field of vision of tower crane and barrier distribution condition, operating personnel can pinpoint the material and hold operation site environment information based on the image that the camera obtained and the radar map that the millimeter wave radar acquireed, and then just can carry out long-range accurate efficient to the tower crane and control in ground control room, reduced operating personnel's working strength.

2. The operation state information and the external environment information of the tower crane are monitored through the safety monitoring assembly, a whole set of complete risk early warning and disposal flow is established, an operator is helped to know the state information of the tower crane in real time, the safety work of the tower crane is ensured, and the safety of the tower crane operation is greatly improved.

The utility model is further described below with reference to the figures and examples.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic diagram of the communication connections of the various components of the present invention;

fig. 3 is a schematic diagram of the structure of the existing tower crane.

Illustration of the drawings: a tower footing 11; a tower body 12; a flat arm 13; a balance arm segment 131; a boom segment 132; a first drive device 14; a trolley 15; a second drive device 16; a wire rope 171; a third drive 172; a hook 173; camera a 21; a camera B22; camera C23; a millimeter-wave radar 24; a laser ranging module 31; a flat arm deformation detection module 32; a tower inclination detection module 33; a wind detection module 34; a PC machine 4; a fast frame grabber 41; an image edge calculation module 42; and the singlechip 5.

Detailed Description

Example 1:

as shown in fig. 1-2, the visual tower crane control system comprises a tower crane, a hanging object auxiliary supporting assembly, a safety monitoring assembly, a PC and a single chip microcomputer.

The tower crane comprises a tower foundation 11, a tower body 12, a flat arm 13, a first driving device 14, a trolley 15, a second driving device 16 and a hanging object assembly. The tower footing 11 is fixedly installed on the ground. The tower body 12 is fixedly connected to the upper end of the tower footing 11. The flat arm 13 is rotatably connected to the upper end of the tower 12 through a first driving device 14, the flat arm 13 is driven by the first driving device 14 to rotate in a horizontal plane, the flat arm 13 is bounded by a rotation connection point, and two ends of the flat arm 13 are a balance arm section 131 and a lifting arm section 132 respectively. The trolley 15 is movably connected to the jib section 132 of the flat arm 13 through the second driving device 16, and the trolley 15 is driven by the second driving device 16 to make reciprocating linear motion along the jib section 132 of the flat arm 13. The object hanging component comprises a steel cable 171, a third driving device 172 and a lifting hook 173, the steel cable 171 is arranged at the lower end of the trolley 15 and is associated with the trolley 15 through the third driving device 172, the lifting hook 173 is connected to the lower end of the steel cable 171, the wire taking-up or paying-off of the steel cable 171 is controlled through the third driving device 172, and then the lifting hook 173 is controlled to move vertically.

The auxiliary supporting component for the hanging object comprises a camera A21, a camera B22, a camera C23 and a millimeter wave radar 24. A camera a21 is mounted on the tower 12 for capturing ground and air views around the tower 12, a camera B22 is mounted at the lower end of the boom section 132 for capturing a view of the lower region of the boom section 132, and a camera C23 is mounted at the lower end of the trolley 15 for capturing a view directly below the hook 173 and the hook 173. The millimeter wave radar 24 is installed at the lower end of the boom segment 132, and is used for acquiring the obstacle distribution condition of the lower area of the boom segment 132.

The safety monitoring assembly comprises a laser ranging module 31, a flat arm deformation detection module 32, a tower body inclination detection module 33 and a wind power detection module 34. The two laser ranging modules 31 are respectively installed on two opposite side walls of the jib section 132 of the flat arm 13, and light emitting directions of the two laser ranging modules 31 are both parallel to the jib section 132 and extend towards the tail end of the jib section 132, and the two laser ranging modules are used for detecting whether an obstacle exists on a rotation path of the jib section 132. The flat arm deformation detection module 32 is mounted at the lower end of the jib portion 132 and is used for detecting the bending deformation degree of the jib portion 132. The tower inclination detection module 33 is mounted on the tower 12, and detects the degree of bending deformation of the tower 12. A wind detection module 34 is mounted on the flat arm 13 for detecting the wind power level.

The PC 4 is in communication connection with the camera a21, the camera B22, the camera C23 and the millimeter wave radar 24 respectively, and is used for visually displaying images acquired by the camera a21, the camera B22 and the camera C23 and radar data acquired by the millimeter wave radar 24.

The signal input end of the single chip microcomputer 5 is respectively in communication connection with the laser ranging module 31, the flat arm deformation detection module 32, the tower inclination detection module 33 and the wind power detection module 34, and the signal output end of the single chip microcomputer 5 is respectively in communication connection with the first driving device 14, the second driving device 16, the third driving device 172 and the PC 4. The single chip microcomputer 5 is in communication connection with the first driving device 14, the second driving device 16 and the third driving device 172 and is used for controlling the running state of the tower crane, and the single chip microcomputer 5 is in communication connection with the PC 4 and is used for visually displaying monitoring data acquired by the safety monitoring assembly on the PC 4.

Preferably, the camera a21, the camera B22 and the camera C23 are all network cameras with built-in 4G modules.

Preferably, the PC 4 comprises a fast frame grabber 41 and an image edge calculation module 42, and the PC 4 is in communication connection with the cameras a21, B22 and C23 through the fast frame grabber 41 respectively to capture each frame of the video images captured by the cameras a21, B22 and C23. The image edge calculation module 42 is in communication connection with the fast frame grabber 41 to perform object contour delineation processing on the frame picture extracted by the fast frame grabber 41.

Preferably, the fast frame grabber 41 is of the type IMPERX _ VCE-CLEX01, and the image edge calculation module 42 is of the type NVIDIA JETSON TX 2.

Preferably, the model of the singlechip 5 is stm32f103zet 6.

A tower crane control method is applied to the visual tower crane control system and comprises a risk disposal method and a visual control method.

The visual control method comprises the following steps:

a. the ground and air visual fields around the hung object are acquired through the camera A21 and the camera B22, the visual fields right below the hook 173 and the hook 173 are acquired through the camera C23, and the radar map of the obstacle distribution around the hung object is acquired through the millimeter wave radar.

b. The detection ranges of the camera A21, the camera B22, the camera C23 and the millimeter wave radar 24 are all conical, the vertex of each conical is the position of the camera A21, the camera B22, the camera C23 and the millimeter wave radar 24, and the included angle formed by the central line of each conical and the horizontal plane is a detection angle; then, the detection angle of the camera a21 is larger than that of the camera B22, the detection angle of the camera C23 is 90 °, and the detection angle of the millimeter wave radar 24 is the same as that of the camera a 21.

c. The images captured by the camera a21, the camera B22, the camera C23, and the radar chart acquired by the millimeter wave radar 24 are displayed in real time in different areas of one display connected to the PC 4, or are displayed separately on a plurality of displays connected to the PC 4.

The risk management method is as follows:

a. the wind power level of the periphery of the tower crane is detected in real time through a wind power detection module 34, and the detection result is transmitted to a PC (personal computer) 4 through a singlechip 5; when the wind power is higher than 6 levels, the PC 4 gives out early warning to prompt an operator to stop the tower crane operation; when the wind power is greater than 8 grades, the first driving device 14, the second driving device 16 and the third driving device 172 of the tower crane are directly controlled by the single chip microcomputer 5 to stop running, so that the tower crane stops running.

b. Detecting the inclination angle of the tower body 12 in real time through the tower body inclination detection module 33, defining the inclination angle as an included angle formed by the tower body 12 and a vertical plane, and setting the inclination angle as r, wherein the r is 0 degree under the condition that the tower crane is unloaded (namely, objects are not hoisted on the lifting hook 173); when the range of r is more than minus 0.2 degrees and less than 0.2 degrees, the inclination angle of the tower body 12 is in the range of safety value; when r is more than or equal to 1 degree or less than or equal to minus 1 degree, the singlechip 5 directly controls the first driving device 14, the second driving device 16 and the third driving device 172 of the tower crane to stop running, so that the tower crane stops running; when r is more than 1 degree and less than or equal to 0.2 degree or more than or equal to 0.2 degree and less than 1 degree, the PC machine 4 sends out early warning (alarm information is displayed on a display connected with the PC machine) to prompt an operator to stop the tower crane operation.

c. The bending deformation degree of the crane arm section 132 is detected in real time through the flat arm deformation detection module 32, the flat arm deformation detection module 32 is a pressure sensor, the pressure sensor is installed at the lower end of the middle part of the crane arm section 132, the distance from the tail end of the crane arm section 132 is 1/3 of the total length of the crane arm section 132, an alarm threshold value and a shutdown threshold value are set through the single chip microcomputer 5, and the alarm threshold value is smaller than the shutdown threshold value; when the tower crane is unloaded, the crane arm section 132 only generates downward bending deformation under the self weight, when the tower crane lifts an object, the bending deformation degree of the crane arm section 132 under the combined action of the lifted object and the self weight is increased, the pressure applied to the pressure sensor is correspondingly increased, and the detection numerical value of the pressure sensor is correspondingly increased;

setting the detection value of the pressure sensor as F, when F is more than 0 and less than a, the bending deformation degree of the lifting arm section is in a safety range, when a is more than or equal to F and less than b, sending out an early warning by a PC (personal computer) to remind an operator to stop the tower crane operation, and when F is more than or equal to b, simultaneously executing the following control by a singlechip: 1. controlling the first driving device 14 to stop running so as to stop the rotation of the flat arm 13; 2. controlling the second driving device 16 to move the trolley 15 to an extreme position far away from the end of the jib section 132 so as to reduce the bending deformation degree of the jib section 132; 3. controlling the third driving device 172 to move so that the hook 173 is lowered, and the hung object is placed back on the ground;

when the tower crane lifts the object with the maximum weight allowed to be lifted, the pressure applied to the pressure sensor is the stop threshold value; when the tower crane lifts the object which is 80% of the maximum weight allowed to be lifted, the pressure applied to the pressure sensor is the alarm threshold value.

d. Whether an obstacle exists on the rotation path of the jib section 132 is detected through the laser ranging module 31, the inherent distance from the laser ranging module 31 to the tail end of the jib section 132 is set to be s, the ranging value of the laser ranging module 31 is set to be h, when h is larger than s, the obstacle does not exist on the rotation path of the jib section 132, and when h is smaller than or equal to s, the obstacle exists on the rotation path of the jib section 132;

the two laser ranging modules 31 start ranging at the same time, and the laser ranging module 31 with a relatively small ranging value at the same time point is used as a judgment reference; when h > s + p, it means that the boom segment 132 does not hit an obstacle during rotation; when h is less than or equal to s + p, the crane arm section 132 is indicated to have the risk of colliding with an obstacle in the rotating process, the singlechip 5 controls the first driving device 14 to stop running, and the flat arm 13 stops rotating; and p is a safe distance and has a value range of 0.1-0.5 m.

Preferably, after the fast frame grabber 41 grabs the frame pictures in the images shot by the camera a21, the camera B22 and the camera C23, the image edge calculation module 42 performs object contour edge tracing on the frame pictures, and finally the picture after the object contour edge tracing is presented on the display of the PC; the object outline tracing process takes the shape of an object in a picture or the color threshold change in the picture as a constraint condition.

Claims

1. The visual tower crane control system comprises a tower crane; the tower crane comprises a tower foundation, a tower body, a flat arm, a first driving device, a trolley, a second driving device and a hanging component; the tower footing is fixedly arranged on the ground; the tower body is fixedly connected to the upper end of the tower footing; the horizontal arm is rotatably connected to the upper end of the tower body through a first driving device, the horizontal arm is driven by the first driving device to rotate on the horizontal plane, the horizontal arm is bounded by a rotating connection point, and a balance arm section and a lifting arm section are respectively arranged at two ends of the horizontal arm; the trolley is movably connected to the jib section of the flat arm through a second driving device and is driven by the second driving device to do reciprocating linear motion along the jib section of the flat arm; the object hanging component comprises a steel cable, a third driving device and a lifting hook, the steel cable is arranged at the lower end of the trolley and is associated with the trolley through the third driving device, the lifting hook is connected to the lower end of the steel cable, and the third driving device controls the steel cable to take up or pay off so as to control the lifting hook to vertically move;

the system is characterized by also comprising a hanging auxiliary supporting component, a safety monitoring component, a PC and a singlechip;

the auxiliary supporting component for the hanging object comprises a camera A, a camera B, a camera C and a millimeter wave radar; the camera A is arranged on the tower body and used for acquiring the ground and aerial visual field around the tower body, the camera B is arranged at the lower end of the crane arm section and used for acquiring the visual field of the lower area of the crane arm section, and the camera C is arranged at the lower end of the trolley and used for acquiring the visual field right below the lifting hook and the lifting hook; the millimeter wave radar is installed at the lower end of the crane arm section and used for acquiring the obstacle distribution condition of the lower area of the crane arm section;

the safety monitoring assembly comprises a laser ranging module, a flat arm deformation detection module, a tower body inclination detection module and a wind power detection module; the two laser ranging modules are respectively arranged on two opposite side walls of the flat-arm crane jib section, and the light emitting directions of the two laser ranging modules are parallel to the crane jib section and extend towards the tail end of the crane jib section, and the two laser ranging modules are used for detecting whether barriers exist on the rotation path of the crane jib section; the flat arm deformation detection module is arranged at the lower end of the crane arm section and is used for detecting the bending deformation degree of the crane arm section; the tower body inclination detection module is arranged on the tower body and used for detecting the bending deformation degree of the tower body; the wind power detection module is arranged on the flat arm and used for detecting the wind power level;

the signal input end of the single chip microcomputer is respectively in communication connection with the laser ranging module, the flat arm deformation detection module, the tower body inclination detection module and the wind power detection module, and the signal output end of the single chip microcomputer is respectively in communication connection with the first driving device, the second driving device, the third driving device and the PC.

2. The visual tower crane control system of claim 1, characterized in that: the PC also comprises a quick frame grabber and an image edge calculation module; the fast frame grabber is respectively in communication connection with the camera A, the camera B and the camera C so as to capture each frame of a video image shot by the camera A, the camera B and the camera C; the image edge calculation module is in communication connection with the fast frame grabber so as to perform object contour tracing processing on the frame pictures extracted by the fast frame grabber.