CN115059846A

CN115059846A - Electronic intelligent road monitoring probe

Info

Publication number: CN115059846A
Application number: CN202210631516.0A
Authority: CN
Inventors: 马宏
Original assignee: China Utone Construction Consulting Co ltd
Current assignee: China Utone Construction Consulting Co ltd
Priority date: 2022-06-06
Filing date: 2022-06-06
Publication date: 2022-09-16
Anticipated expiration: 2042-06-06
Also published as: CN115059846B

Abstract

The invention discloses an electronic intelligent road monitoring probe, which relates to the technical field of monitoring probes and has the advantages of adjusting the height and the angle of the monitoring probe, and the key points of the technical scheme are as follows: including setting up branch subaerial and the monitor probe of setting in the branch upper end, monitor probe installs on the installation piece, the branch upper end is equipped with the driving piece that drives monitor probe simultaneously and changes angle and height.

Description

Electronic intelligent road monitoring probe

Technical Field

The invention relates to the technical field of monitoring probes, in particular to an electronic intelligent road monitoring probe.

Background

The monitoring probe is a semiconductor imaging device and has the advantages of high sensitivity, strong light resistance, small distortion, small volume, long service life, vibration resistance and the like.

At present, in order to guarantee that vehicles on the town road can be orderly and normally pass, the monitoring probe for monitoring and shooting illegal vehicles is installed at some town road positions, and the existing monitoring probe is generally installed on a support rod through screws and then supplies power to the monitoring probe through an external line.

Chinese patent with publication number CN211423796U discloses an intelligent monitor's mounting structure, including the mounting panel, mounting panel upper end four corners has all been opened the mounting hole, mounting panel upper end middle part fixed mounting has adjusting device, adjusting device upper end fixed mounting has the connecting rod, the connecting rod left end is opened has about two slots that link up, connecting rod front end fixed mounting has two screws, the connecting rod alternates through two slots and is connected with fixing device, fixing device lower part joint has the monitoring head, the common fixedly connected with auxiliary device in connecting rod and the fixing device upper end. The utility model provides an intelligent monitor probe's mounting structure, through setting up adjusting device, can make the control head can carry out angle and height adjustment after the installation is accomplished, is convenient for enlarge monitoring range. The application provides another structure of adjusting monitor probe and carrying out height and angle modulation.

Disclosure of Invention

In view of the technical shortcomings, the invention aims to provide an electronic intelligent road monitoring probe which has the advantage of adjusting the height and the angle of the monitoring probe.

In order to solve the technical problems, the invention adopts the following technical scheme:

the invention provides an electronic intelligent road monitoring probe, which comprises a supporting rod arranged on the ground and a monitoring probe arranged at the upper end of the supporting rod, wherein the monitoring probe is arranged on an installation block, and a driving piece which can simultaneously drive the monitoring probe to change the angle and the height is arranged at the upper end of the supporting rod.

By adopting the technical scheme, the driving piece can drive the monitoring probe to change the angle and the height simultaneously, the use requirement of the monitoring probe is met, and the monitoring range of the monitoring probe is enlarged.

Preferably, the driving member includes a placement groove formed at the upper end of the supporting rod, a first motor is arranged at the bottom of the placement groove, a rotating shaft is rotatably connected to the placement groove of the supporting rod, the rotating shaft is driven by the first motor, the upper end of the rotating shaft extends out of the upper end of the supporting rod, an L-shaped driving rod is arranged at the extended end of the rotating shaft, a mounting plate is arranged on the outer wall of the upper end of the supporting rod, a first circular through groove is formed in the mounting plate, a second through groove communicated with the first through groove is formed in the upper end face of the mounting plate, a rotating plate is rotatably connected to the first through groove, a third through groove communicated with and corresponding to the second through groove is formed in the rotating plate, the third through groove is a U-shaped groove, an annular driving ring is connected to one end of the driving rod, which is far away from the rotating shaft, the longitudinal section of the driving ring is circular, and the ring wall of the driving ring enters the third through groove in the rotating plate through the second through groove, the plate surface of the rotating plate is provided with a swing rod, one end of the swing rod is arranged below the third through groove, the other end of the swing rod extends out of the mounting plate, the mounting block is arranged at one end, far away from the rotating plate, of the swing rod, and when the first motor drives the rotating shaft to rotate, so that the driving rod drives the driving ring to rotate, the outer wall of the driving ring is provided with a first power piece which drives the rotating plate to rotate in the first through groove.

Preferably, the first power member includes a driving groove formed on an outer wall of the driving ring and a driving rod disposed on a wall of a third through groove of the rotating plate, one end of the driving rod is connected to the driving groove in a sliding manner, the driving groove includes a first groove for driving the rotating plate to rotate in the first through groove when the driving rod slides in the driving groove, and a second groove for communicating with the first groove and driving the rotating plate to rotate in the first through groove when the driving rod slides in the driving groove, the second groove is spirally distributed along the outer wall of the driving ring and gradually separates from or approaches to the second through groove, the driving groove further includes a third groove for communicating with the second groove and driving the driving rod to move in the driving groove, so that the notch of the third through groove is separated from the second through groove, the first groove is located on the outer wall of the driving ring, and the third groove is located on the inner wall of the driving ring, the two second grooves are respectively positioned at two ends of the first groove, one ends of the two second grooves far away from the first groove are communicated through a third groove, and the position where the driving rod is connected with the driving ring is positioned on the outer wall of the upper end of the driving ring corresponding to the midpoint of the first groove.

Preferably, the driving member comprises a first rotating rod rotatably arranged at the upper end of the supporting rod, the supporting rod extends out of both ends of the first rotating rod, the outer wall of the supporting rod is provided with a second motor which drives the first rotating rod to rotate, one end of the first rotating rod, which is far away from the second motor, is provided with a hemispherical connecting groove, a hemispherical connecting block is rotationally connected in the connecting groove, a second rotating rod is arranged at one end of the connecting block, which is far away from the bottom of the connecting groove, the mounting block is arranged at one end of the second rotating rod far away from the first rotating rod, a connecting piece which drives the second rotating rod to rotate when the first rotating rod rotates is arranged in the connecting groove, the outer wall of the supporting rod is provided with a supporting plate which is positioned below the second rotating rod and is hinged with a first cylinder, a driving block is hinged to a piston rod of the first air cylinder and sleeved on the outer wall of the second rotating rod.

Preferably, the connecting piece is including seting up a plurality of first sliding tray in the connecting block outer wall, be equipped with the second sliding tray that corresponds with first sliding tray on the connecting groove cell wall, first sliding tray and corresponding second sliding tray are embedded to be equipped with the ball, first sliding tray distributes along the length direction of connecting block.

Preferably, the driving piece is including setting up the vertical riser in branch upper end, be equipped with the horizontally extension rod on the riser, be equipped with the cradling piece of U-shaped on the extension rod, the relative both ends of cradling piece are rotated and are connected with the criss-cross swinging arms, the relative both ends of swinging arms rotate with the relative both ends of cradling piece and are connected, and relative both ends are rotated and are connected with the rectangle frame in addition, the size of rectangle frame is greater than the size of cradling piece, the one end that the rectangle frame deviates from the cradling piece is equipped with the dead lever of U-shaped, the installation piece sets up on the dead lever, be equipped with drive rectangle frame on the riser and wind two body of rod direction pivoted second power spare of criss-cross swinging arms.

Preferably, the second power part comprises a second cylinder and a third cylinder, one end of the second cylinder and one end of the third cylinder are hinged to the vertical plate, piston rods of the second cylinder and the third cylinder are hinged to one side edge of the rectangular frame, and hinged positions of the piston rods are respectively located on a long edge and a wide edge of the rectangular frame.

Preferably, the outer wall of the rectangular frame is provided with a U-shaped swing plate at a position hinged with the second cylinder and the third cylinder, piston rods of the second cylinder and the third cylinder are respectively provided with a spherical driving ball, and the swing plate is provided with an embedded groove for embedding the driving ball.

Preferably, be equipped with the taper rod on the drive ball, the less one end of taper rod is connected with the drive ball outer wall, the one end that the drive ball was kept away from to the taper rod is established to the cylinder and with the piston rod threaded connection of second cylinder and third cylinder.

Preferably, a plurality of ventilation holes are formed in the vertical plate, and triangular reinforcing rib plates are arranged at the upper end of the supporting rod and on two sides of the vertical plate.

The invention has the beneficial effects that: the driving piece can drive the monitoring probe to change the angle and the height simultaneously, so that the use requirement of the monitoring probe is met, and the monitoring range of the monitoring probe is enlarged.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of the present embodiment;

fig. 2 is a schematic structural diagram of the present embodiment for embodying the first motor;

fig. 3 is a schematic structural diagram for embodying the second rotating lever of the present embodiment;

FIG. 4 is a schematic structural diagram of a rectangular frame according to the present embodiment;

fig. 5 is a schematic structural diagram of the present embodiment for embodying the driving ball.

Description of reference numerals:

in the figure: 1. a strut; 11. monitoring the probe; 12. mounting blocks; 13. a placement groove; 131. a first motor; 132. a rotating shaft; 133. a drive rod; 134. mounting a plate; 135. a first through groove; 1351. rotating the plate; 1352. a third through groove; 136. a second through groove; 137. a drive ring; 138. a swing rod; 139. a drive slot; 1391. a first groove; 1392. a second groove; 1393. a third groove; 14. a first rotating lever; 141. a second motor; 142. connecting grooves; 143. connecting blocks; 144. a second rotating rod; 145. a support plate; 146. a first cylinder; 147. driving the block; 148. a first sliding groove; 149. a second sliding groove; 1491. a ball bearing; 15. a vertical plate; 151. an extension rod; 152. a support rod; 153. a swing lever; 154. a rectangular frame; 155. fixing the rod; 156. a second cylinder; 157. a third cylinder; 158. a swinging plate; 1581. a drive ball; 1582. a tapered rod; 1583. a ventilation hole; 1584. and a reinforcing plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

An electronic intelligent road monitoring probe is shown in figures 1 and 2 and comprises a supporting rod 1 arranged on the ground and a monitoring probe 11 arranged at the upper end of the supporting rod 1, wherein the monitoring probe 11 is arranged on an installation block 12, and a driving piece which simultaneously drives the monitoring probe 11 to change the angle and the height is arranged at the upper end of the supporting rod 1.

As shown in fig. 1 and fig. 2, the driving member drives the monitoring probe 11 to change the angle and the height simultaneously, so as to meet the use requirement of the monitoring probe 11 and expand the monitoring range of the monitoring probe 11.

As shown in fig. 1 and fig. 2, the driving member includes a placing groove 13 disposed at the upper end of the supporting rod 1, a notch of the placing groove 13 is disposed upward, a first motor 131 is disposed at the bottom of the placing groove 13, a rotating shaft 132 is rotatably connected to the placing groove 13 of the supporting rod 1, the rotating shaft 132 is driven by the first motor 131, an L-shaped driving rod 133 is disposed at one end of the rotating shaft 132, which extends out of the upper end of the supporting rod 1, a mounting plate 134 is disposed at the outer wall of the upper end of the supporting rod 1, the mounting plate 134 is vertically disposed, a circular first through groove 135 is disposed on the mounting plate 134, two vertical side faces of the mounting plate 134 extend out of two ends of the first through groove 135, a second through groove 136 communicated with the first through groove 135 is disposed on the upper end face of the mounting plate 134, a rotating plate 1351 is rotatably connected to the first through groove 135, a third through groove 1352 communicated with and corresponding to the second through groove 136 is disposed on the rotating plate 1351, the third through groove 1352 is a U-shaped groove, one end of the driving rod 133, which is far away from the rotating shaft 132, and is connected to a circular driving ring 137, at this time, the driving ring 137 is fixed on the driving rod 133, the central axis of the driving ring 137 is coaxial with the central axis of the rotating shaft 132, the longitudinal section of the driving ring 137 is circular, the annular wall of the driving ring 137 enters the third through groove 1352 in the rotating plate 1351 through the second through groove 136, the plate surface of the rotating plate 1351 is provided with the swing link 138, one end of the swing link 138 is disposed below the third through groove 1352, and the other end of the swing link 138 extends out of the mounting plate 134, the mounting block 12 is disposed at an end of the swing link 138 away from the rotating plate 1351, when the driving rod 133 drives the rotating shaft 132 to rotate, so that the driving ring 137 is driven by the driving rod 133 to rotate, the outer wall of the driving ring 137 is provided with a first power member which drives the rotating plate 1351 to rotate in the first through groove 135.

As shown in fig. 1 and fig. 2, when the rotating plate 1351 is driven by the first power member to rotate in the first through slot 135, the swing link 138 on the rotating plate 1351 also rotates with the rotating plate 1351, and at this time, the height of the monitoring probe 11 on the swing link 138 gradually changes during the rotation process of the rotating plate 1351, and the angle of the monitoring probe 11 also changes due to the rotation of the swing link 138.

As shown in fig. 1 and 2, the first power member includes a driving groove 139 opened on an outer wall of the driving ring 137 and a driven rod provided on a wall of a third through-groove 1352 of the rotating plate 1351, one end of the driven rod is slidably connected to the driving groove 139, the driving groove 139 includes a first groove 1391 for allowing the notch of the third through-groove 1352 to be opposite to the second through-groove 136 when the driven rod is slidably moved in the driving groove 139, and a second groove 1392 for allowing the driven rod to rotate in the first through-groove 135 when the driven rod is slidably moved in the driving groove 139, the second groove 1392 is spirally distributed along the outer wall of the driving ring 137 and allowing the notch of the third through-groove 1352 to be gradually separated from or close to the second through-groove 136, the driving groove 139 further includes a third groove 1393 for communicating with the second groove 1392 and allowing the driven rod to be moved in the driving groove 139 so that the notch of the third through-groove 1352 is separated from the second through-groove 136, the first groove 1391 is located on the outer wall of the driving ring 137, the third grooves 1393 are formed in the inner wall of the drive ring 137, the second grooves 1392 are formed in two pieces and are formed at both ends of the first grooves 1391, one ends of the two second grooves 1392, which are away from the first grooves 1391, communicate through the third grooves 1393, and the position where the drive rod 133 is connected to the drive ring 137 is formed in the outer wall of the upper end of the drive ring 137 corresponding to the midpoint of the first grooves 1391.

As shown in fig. 1 and 2, when the first motor 131 drives the rotating shaft 132 to rotate, the rotating shaft 132 drives the driving ring 137 to rotate through the driving rod 133, since the driving ring 137 is located in the third through-slot 1352, when the driving ring 137 rotates, the driving rod slides in the first through-slot 1391 first, at this time, the notch of the third through-slot 1352 is opposite to the second through-slot 136, the lower end of the swing link 138 is located right below the mounting plate 134, as the driving ring 137 continues to rotate, the driving rod slides from the first through-slot 1391 into the second through-slot 1392, so that the notch of the third through-slot 1352 gradually separates from the second through-slot 136, at this time, the driving rod drives the rotating plate 1351 to rotate, so that the notch of the third through-slot 1352 gradually rotates towards the supporting rod 1, as the driving rod moves in the second through-slot 1392, the rotating plate 1351 is gradually rotated to a position where the notch of the third through-slot 1352 deviates from the second through-slot 136, at this time, the driving rod slides from the second through-slot 1392 into the third through-slot 1393, when the rotating plate 1351 is not rotated, as the driving ring 137 continues to rotate, the driving rod slides from the third groove 1393 into the other second groove 1392, because the other end of the second groove 1392 is communicated with the first groove 1391, the rotating plate 1351 rotates again, during the rotation of the rotating plate 1351, the notch of the third groove 1352 rotates from the direction close to the strut 1 to the position communicated with the second groove 136, at this time, the driving rod enters the first groove 1391 again, and circulates back and forth in sequence, during this time, the monitoring probe 11 on the oscillating rod 138 rotates from the position right below the just started mounting plate 134 to the position right above the mounting plate 134 in the direction away from the strut 1, and then returns from the position right above to the position right below the mounting plate 134. The drive rod 133 may pass through the second through slot 136.

As shown in fig. 1 and 2, the swing link 138 is driven by the first power element to rotate within a range of 0 to 180 °, that is, the lower end of the mounting plate 134 rotates to the center of the notch of the second through slot 136, at this time, the monitoring probe 11 on the mounting block 12 on the swing link 138 is always located outside the outer ring of the driving ring 137 along with the swing of the swing link 138, so that the monitoring probe 11 is convenient to monitor, at this time, in the rotating process of the monitoring probe 11 along with the rotating plate 1351, the height of the monitoring probe 11 is adjusted, and the angle is located at different height positions along with the swing link 138, so that the angle monitored by the monitoring probe 11 is also changed.

As shown in fig. 3, or, the driving member includes a first rotating rod 14 rotatably disposed at the upper end of the supporting rod 1, both ends of the first rotating rod 14 extend out of the supporting rod 1, a second motor 141 for driving the first rotating rod 14 to rotate is disposed on the outer wall of the supporting rod 1, a hemispherical connecting groove 142 is disposed at one end of the first rotating rod 14 away from the second motor 141, at this time, the diameter of the outer wall of the first rotating rod 14 where the connecting groove 142 is disposed is large, a hemispherical connecting block 143 is rotatably connected to the connecting groove 142, a second rotating rod 144 is disposed at one end of the connecting block 143 away from the bottom of the connecting groove 142, the mounting block 12 is disposed at one end of the second rotating rod 144 away from the first rotating rod 14, at this time, the second rotating rod 144 is moved in the up-down swinging direction, so that the connecting block 143 can rotate in the connecting groove 142, and at this time, the height of the monitoring probe 11 on the second rotating rod 144 is adjusted; a connecting piece which drives the second rotating rod 144 to rotate when the first rotating rod 14 rotates is arranged in the connecting groove 142, a supporting plate 145 is arranged on the outer wall of the supporting rod 1, the supporting plate 145 is positioned below the second rotating rod 144, a first air cylinder 146 is hinged to the supporting plate 145, a piston rod of the first air cylinder 146 is hinged to a driving block 147, and the driving block 147 is sleeved on the outer wall of the second rotating rod 144.

As shown in fig. 3, the connecting member is arranged so that the first rotating rod 14 drives the second rotating rod 144 to rotate, thereby changing the monitoring angle of the monitoring probe 11 on the second rotating rod 144, and the piston rod of the first cylinder 146 drives the second rotating rod 144 to swing up and down through the driving block 147, that is, changing the height of the monitoring probe 11, which is convenient for adjusting the height and angle of the monitoring probe 11 at the same time.

As shown in fig. 3, the connecting member includes a plurality of first sliding grooves 148 formed in an outer wall of the connecting block 143, a second sliding groove 149 corresponding to the first sliding groove 148 is formed in a groove wall of the connecting groove 142, balls 1491 are embedded in the first sliding groove 148 and the corresponding second sliding groove 149, the first sliding groove 148 is distributed along a length direction of the connecting block 143, when the first cylinder 146 drives the second rotating rod 144 to swing up and down, the connecting block 143 moves in the connecting groove 142, and at this time, the rollers move back and forth in the first sliding groove 148 and the second sliding groove 149, so that the connecting block 143 moves in the connecting groove 142 as the second rotating rod 144 swings, and the arrangement of the outer rollers enables the first rotating rod 14 to drive the second rotating rod 144 to rotate when rotating, thereby facilitating adjustment of the angle of the monitoring probe 11.

As shown in fig. 4 and fig. 5, alternatively, the driving member includes a vertical plate 15 disposed at the upper end of the supporting rod 1, a horizontal extending rod 151 is disposed on the vertical plate 15, a U-shaped supporting rod 152 is disposed on the extending rod 151, a cross-shaped swinging rod 153 is rotatably connected to opposite ends of the supporting rod 152, that is, the swing lever 153 is connected by two lever bodies crossing each other perpendicularly, opposite ends of the swing lever 153 are rotatably connected with opposite ends of the support lever 152, in addition, the opposite ends are rotatably connected with rectangular frames 154, the size of the rectangular frame 154 is larger than that of the support rods 152, that is, when the rectangular frame 154 moves, the influence of the support rod 152 on the rectangular frame 154 is small, a U-shaped fixing rod 155 is disposed at one end of the rectangular frame 154 away from the support rod 152, the mounting block 12 is disposed on the fixing rod 155, and a second power member for driving the rectangular frame 154 to rotate around the two rod body directions of the cross-shaped swing rod 153 is disposed on the vertical plate 15.

As shown in fig. 4 and 5, the second power member includes a second cylinder 156 and a third cylinder 157, one ends of which are hinged to the vertical plate 15, and piston rods of the second cylinder 156 and the third cylinder 157 are hinged to one side of the rectangular frame 154 and are respectively located at the long side and the wide side of the rectangular frame 154. And the two hinge points are respectively collinear with the central line axes of the two rod bodies of the swing rod 153. Facilitating the swinging of the rectangular frame 154.

As shown in fig. 4 and 5, at this time, when the second air cylinder 156 works, the long side of the rectangular frame 154 is driven to swing up and down, so that the rectangular frame 154 rotates around one rod body of the swing rod 153, at this time, the angle of the mounting block 12 on the fixing rod 155 and the angle of the monitoring probe 11 on the mounting block 12 are changed in the rotating process, and then, when the third air cylinder 157 works, the wide side of the rectangular frame 154 is driven to swing up and down, so that the rectangular frame 154 rotates around the other rod body of the swing rod 153, and the height position of the monitoring probe 11 is changed.

As shown in fig. 4 and 5, a U-shaped swing plate 158 is disposed on the outer wall of the rectangular frame 154 at a position hinged to the second cylinder 156 and the third cylinder 157, spherical driving balls 1581 are disposed on the piston rods of the second cylinder 156 and the third cylinder 157, and an insertion groove for inserting the driving balls 1581 is disposed on the swing plate 158. The driving ball 1581 is arranged to drive the rectangular frame 154 to rotate better by the second cylinder 156 and the third cylinder 157.

As shown in fig. 4 and 5, in order to facilitate installation of the driving ball 1581, a tapered rod 1582 is provided on the driving ball 1581, one end of the tapered rod 1582 with a small taper is connected to the outer wall of the driving ball 1581, and one end of the tapered rod 1582, which is far away from the driving ball 1581, is provided as a cylinder and is in threaded connection with the piston rods of the second cylinder 156 and the third cylinder 157. It is now convenient to mount the drive balls 1581 on the second cylinder 156 and the third cylinder 157.

As shown in fig. 4 and 5, a plurality of ventilation holes 1583 are formed in the vertical plate 15, the ventilation holes 1583 reduce the influence of wind speed on the deformation of the vertical plate 15, triangular reinforcing rib plates 1584 are arranged on the two sides of the vertical plate 15 at the upper end of the supporting rod 1, and the connection strength between the vertical plate 15 and the supporting rod 1 is enhanced due to the arrangement of the reinforcing rib plates 1584.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims

1. The utility model provides an intelligent highway monitor of electron, is including setting up branch (1) subaerial and monitor (11) of setting in branch (1) upper end, its characterized in that, monitor (11) are installed on installation piece (12), branch (1) upper end is equipped with and drives monitor (11) change angle and high driving piece simultaneously.

2. The electronic intelligent road monitoring probe according to claim 1, wherein the driving member comprises a placing groove (13) formed at the upper end of the supporting rod (1), a first motor (131) is arranged at the bottom of the placing groove (13), a rotating shaft (132) is rotationally connected to the placing groove (13) of the supporting rod (1), the rotating shaft (132) is driven by the first motor (131), an upper end of the rotating shaft (132) extends out of the upper end of the supporting rod (1), an L-shaped driving rod (133) is arranged at the extended end of the upper end of the supporting rod (1), a mounting plate (134) is arranged on the outer wall of the upper end of the supporting rod (1), a first circular through groove (135) is formed in the mounting plate (134), a second through groove (136) communicated with the first through groove (135) is formed in the upper end face of the mounting plate (134), and a rotating plate (1351) is rotationally connected to the first through groove (135), a third through groove (1352) communicated with and corresponding to the second through groove (136) is formed in the rotating plate (1351), the third through groove (1352) is a U-shaped groove, one end, far away from the rotating shaft (132), of the driving rod (133) is connected with an annular driving ring (137), the longitudinal section of the driving ring (137) is circular, the annular wall of the driving ring (137) enters the third through groove (1352) in the rotating plate (1351) through the second through groove (136), a swing rod (138) is arranged on the plate surface of the rotating plate (1351), one end of the swing rod (138) is arranged below the third through groove (1352), and an installation plate (134) extends out of the other end of the swing rod (138), the installation block (12) is arranged at one end, far away from the rotating plate (1351), when the rotating shaft (132) is driven by the first motor (131) to rotate, so that the driving rod (133) drives the driving ring (137) to rotate, the driving ring (137) is arranged on the outer wall of the driving ring (137) to drive the rotating plate (1351) to rotate in the first power through groove (135) And (3) a component.

3. An electronic intelligent road monitoring probe according to claim 2, wherein the first power member comprises a driving slot (139) provided in the outer wall of the driving ring (137) and a driven rod provided in the wall of the third through slot (1352) of the rotating plate (1351), one end of the driven rod being slidably connected to the driving slot (139), the driving slot (139) comprising a first slot (1391) for causing the notch of the third through slot (1352) to oppose the second through slot (136) when the driven rod is slid in the driving slot (139), and a second slot (1392) for causing the rotating plate (1351) to rotate in the first through slot (135) when the driven rod is slid in the driving slot (139), the second slot (1392) being spirally distributed along the outer wall of the driving ring (137) and causing the notch of the third through slot (1352) to gradually separate from or approach the second through slot (136), the driving groove (139) further comprises a third groove (1393) which is communicated with the second groove (1392) and enables the notch of the third through groove (1352) to deviate from the second through groove (136) when the driving rod moves in the driving groove (139), the first groove (1391) is positioned on the outer wall of the driving ring (137), the third groove (1393) is positioned on the inner wall of the driving ring (137), the second grooves (1392) are two and are respectively positioned at two ends of the first groove (1391), one ends, far away from the first groove (1391), of the two second grooves (1392) are communicated through the third groove (1393), and the connecting position of the driving rod (133) and the driving ring (137) is positioned at the upper end of the outer wall of the driving ring (137) corresponding to the midpoint of the first groove (1391).

4. The electronic intelligent road monitoring probe according to claim 1, wherein the driving member comprises a first rotating rod (14) rotatably disposed at the upper end of the supporting rod (1), the supporting rod (1) extends from both ends of the first rotating rod (14), a second motor (141) for driving the first rotating rod (14) to rotate is disposed on the outer wall of the supporting rod (1), a hemispherical connecting groove (142) is disposed at one end of the first rotating rod (14) far from the second motor (141), a hemispherical connecting block (143) is rotatably connected to the connecting groove (142), a second rotating rod (144) is disposed at one end of the connecting block (143) far from the bottom of the connecting groove (142), the mounting block (12) is disposed at one end of the second rotating rod (144) far from the first rotating rod (14), a connecting member for driving the second rotating rod (144) to rotate when the first rotating rod (14) rotates is disposed in the connecting groove (142), branch (1) outer wall is equipped with backup pad (145), backup pad (145) are located the below of second bull stick (144) just it has first cylinder (146) to articulate on backup pad (145), it has drive piece (147) to articulate on the piston rod of first cylinder (146), drive piece (147) cover is established at second bull stick (144) outer wall.

5. An electronic intelligent road monitoring probe as claimed in claim 4, wherein the connecting member comprises a plurality of first sliding grooves (148) formed in the outer wall of the connecting block (143), a second sliding groove (149) corresponding to the first sliding groove (148) is formed in the groove wall of the connecting groove (142), balls (1491) are embedded in the first sliding groove (148) and the corresponding second sliding groove (149), and the first sliding groove (148) is distributed along the length direction of the connecting block (143).

6. The electronic intelligent road monitoring probe as claimed in claim 1, wherein the driving member comprises a vertical plate (15) disposed at the upper end of the supporting rod (1), a horizontal extending rod (151) is disposed on the vertical plate (15), a U-shaped supporting rod (152) is disposed on the extending rod (151), cross-shaped swinging rods (153) are rotatably connected to opposite ends of the supporting rod (152), opposite ends of the swinging rods (153) are rotatably connected to opposite ends of the supporting rod (152), a rectangular frame (154) is rotatably connected to opposite ends of the swinging rods (153), the size of the rectangular frame (154) is larger than that of the supporting rod (152), a U-shaped fixing rod (155) is disposed at one end of the rectangular frame (154) departing from the supporting rod (152), the mounting block (12) is disposed on the fixing rod (155), and a second rod body direction for driving the rectangular frame (154) to rotate around the cross-shaped swinging rods (153) is disposed on the vertical plate (15) A power member.

7. An electronic intelligent road monitoring probe as claimed in claim 6, wherein the second power member comprises a second air cylinder (156) and a third air cylinder (157) with one ends hinged to the vertical plate (15), piston rods of the second air cylinder (156) and the third air cylinder (157) are hinged to one side of the rectangular frame (154) and the hinged positions are respectively located at the long side and the wide side of the rectangular frame (154).

8. The electronic intelligent road monitoring probe according to claim 7, wherein the outer wall of the rectangular frame (154) is provided with a U-shaped swing plate (158) at a position hinged with the second cylinder (156) and the third cylinder (157), the piston rods of the second cylinder (156) and the third cylinder (157) are respectively provided with a spherical driving ball (1581), and the swing plate (158) is provided with an embedded groove for embedding the driving ball (1581).

9. The electronic intelligent road monitoring probe according to claim 8, wherein a tapered rod (1582) is arranged on the driving ball (1581), one end of the tapered rod (1582) with a smaller taper is connected with the outer wall of the driving ball (1581), and one end of the tapered rod (1582) far away from the driving ball (1581) is arranged to be a cylinder and is in threaded connection with piston rods of the second cylinder (156) and the third cylinder (157).

10. The electronic intelligent road monitoring probe according to claim 9, wherein the vertical plate (15) is provided with a plurality of ventilation holes (1583), and triangular reinforcing rib plates (1584) are arranged at the upper end of the supporting rod (1) on two sides of the vertical plate (15).