CN115751032A - Mine monitoring device based on electric power big data - Google Patents

Abstract

The invention relates to a mine monitoring device, in particular to a mine monitoring device based on electric power big data. The invention aims to provide a mine monitoring device based on electric power big data, which can adjust the monitoring position and is convenient for carrying out omnibearing and dead-angle-free monitoring on each area of an opencast coal mine. A mine monitoring device based on electric power big data comprises a supporting plate, an annular sliding rail, a sliding block, a movable plate frame and the like; the utility model discloses a portable electronic device, including backup pad, backup pad top fixed mounting has annular slide rail, the gliding style is connected with two sliders and is the symmetry setting on the annular slide rail, two fixed mounting has movable grillage between the slider upper end. The first infrared monitoring camera moves to a proper position randomly, then the first infrared monitoring camera continuously swings in a reciprocating mode to monitor the electric power big data in the opencast coal mine, and the functions of monitoring all areas of the opencast coal mine without dead angles are achieved.

Description

Mine monitoring device based on electric power big data

Technical Field

The invention relates to a mine monitoring device, in particular to a mine monitoring device based on electric power big data.

Background

The large electric data come from various links such as power generation, power transmission, power distribution, power consumption and scheduling of electric power production and electric energy use, in an opencast coal mine, the large electric data need to be collected to carry out systematic processing and analysis, thereby realizing real-time monitoring on the equipment power consumption condition of a mining area, further, the large data analysis and an electric power system model are combined, the electric power equipment of the mining area can be diagnosed, optimized and predicted, the reliable, economic and efficient operation of the electric power equipment of the mining area is guaranteed, when the large electric power data in the opencast coal mine are abnormal, the electric power equipment of the mining area cannot normally operate, corresponding processing can be conveniently carried out by a worker in time by receiving the large data information and feeding back the abnormal large electric power data, but the operation equipment of the mining area is more, can be randomly parked, the traditional monitoring equipment is fixedly installed, monitoring dead angles easily exist, the mining area range is wide, and the traditional monitoring equipment can complete real-time monitoring on the mining area only by arranging a large number of monitoring cameras.

Disclosure of Invention

Therefore, need to traditional supervisory equipment fixed mounting, there is the control dead angle easily, and the mining area wide range, traditional supervisory equipment need arrange a large amount of surveillance cameras just can accomplish the problem of the real time monitoring to the mining area and improve, designs one kind and can adjust the monitoring position, is convenient for carry out the mine monitoring device based on electric power big data of all-round, no dead angle monitoring to each region of opencut coal mine.

The utility model provides a mine monitoring device based on electric power big data, including backup pad, annular slide rail, slider, movable plate rack, driver part, fixed branch, toothed disc, porous rotation axis one, driving gear, mining area dead angle detection part one and controller, backup pad top fixed mounting has annular slide rail, the sliding type is connected with two sliders and is the symmetry setting on the annular slide rail, two fixed mounting has movable plate rack between the slider upper end, be equipped with driver part on the movable plate rack, backup pad middle part fixed mounting has fixed branch, fixed branch upper end is connected with movable plate rack rotary type, fixed branch lower part fixedly connected with toothed disc, movable plate rack lower part one side rotary type is connected with porous rotation axis one, porous rotation axis one is gone up to open has a plurality of draw-in grooves, porous rotation axis one lower extreme fixedly connected with driving gear, driving gear and toothed disc meshing, be equipped with mining area dead angle detection part one on the movable plate rack, be equipped with the controller on the fixed branch and be located between toothed disc and the movable plate rack.

Further explain, the drive part is including support, biax gear motor, fixed cover, inclined plane pole one, coupling spring and inclined plane pole two, fixedly connected with support on the activity grillage, fixed mounting has biax gear motor on the support, the controller passes through circuit connection with biax gear motor, fixedly connected with fixed cover on two output shafts of biax gear motor is located the top fixed cover is close to one side slidingtype of controller and is connected with inclined plane pole one, be connected with coupling spring between inclined plane pole one and the fixed cover that is located the top, be located the below fixed cover is close to one side slidingtype of controller and is connected with inclined plane pole two, be connected with coupling spring between inclined plane pole two and the fixed cover that is located the below, the one end card that controller was kept away from to inclined plane pole two is gone into in one of them draw-in groove of porous rotation axis one.

It further explains, first mining area dead angle detection part is including porous rotation axis two, promotion driving lever, belt pulley, flat belt two, transfer line, fluting cambered plate, leading truck, swing span, infrared monitoring camera and fixed mounting panel, activity grillage upper portion rotary type is connected with porous rotation axis two and is located the biax gear motor top, it has a plurality of draw-in grooves to open on the porous rotation axis two, the one end card that controller was kept away from to bevel lever one is gone into to one of them draw-in groove on the porous rotation axis two, side fixedly connected with fixed mounting panel on the activity grillage, porous rotation axis two is connected with the fixed mounting panel rotary type, the last rotary type of fixed mounting panel is connected with the promotion driving lever, promote driving lever lower part and two upper portions fixedly connected with belt pulleys of porous rotation axis, two around flat belt two between the belt pulley, one side rotary type that the movable grillage was kept away from to the fixed mounting panel is connected with the transfer line, transfer line one end fixedly connected with fluting cambered plate upper end and fluting cambered plate slidingly connected, the other end fixedly connected with leading truck, the sliding type is connected with the swing span on the vertical direction of leading truck, the one end fixedly connected with infrared monitoring camera that the swing span keeps away from the leading truck.

The multi-hole rotary table further comprises a height adjusting part, the height adjusting part is arranged on the movable plate frame and connected with the second porous rotary shaft, the height adjusting part comprises an L-shaped support plate, a guide rod, a two-way screw rod and a thread movable frame, the L-shaped support plate is fixedly connected to the upper side of the movable plate frame, the guide rod is fixedly connected between the L-shaped support plate and the fixed mounting plate, the two upper ends of the two porous rotary shafts are fixedly provided with the two-way screw rod, the upper end of the two-way screw rod is connected with the L-shaped support plate in a rotating mode, the thread movable frame is connected with the guide rod in a sliding mode through threads, and the thread movable frame is connected with the rotary frame in a rotating mode.

The mining area dead angle detection component II is arranged on the threaded movable frame and is connected with the L-shaped support plate, the mining area dead angle detection component II comprises a corrugated plate, supports, two infrared monitoring cameras, a connecting rod, a sliding frame, a reset spring and a transmission plate, the corrugated plate is arranged on one side, close to the L-shaped support plate, of the threaded movable frame, the corrugated plate is connected with the L-shaped support plate in a sliding mode, the two supports are fixedly arranged on the upper portion of the L-shaped support plate and are symmetrically arranged, the two infrared monitoring cameras are rotatably connected between the two supports and located above the infrared monitoring cameras, the connecting rod is fixedly connected to two ends of the two infrared monitoring cameras, the sliding frame is connected to the upper portion of the L-shaped support plate in a sliding mode and is in contact with the corrugated plate, the two reset springs are connected between the sliding frame and the L-shaped support plate, and the transmission plate is rotatably connected between the connecting rod and the sliding frame.

The infrared monitoring camera system further comprises an installation support plate and a protective cover, wherein the installation support plate is fixedly installed in the middle of the L-shaped support plate, the protective cover is fixedly connected onto the installation support plate, the infrared monitoring camera II is located in the protective cover, and the infrared monitoring camera I is located below the protective cover.

The friction plate is characterized by further comprising a friction rod and a compression spring, the friction rod is connected to the other side of the movable plate frame in a sliding mode, the lower end of the friction rod is in contact with the upper side face of the supporting plate, and the compression spring is connected between the friction rod and the movable plate frame.

The invention has the beneficial effects that:

1. the first infrared monitoring camera swings back and forth to monitor dead angles in the opencast coal mine, so that large-scale monitoring of electric power big data in the opencast coal mine is facilitated; the driving gear reverses and can move around the gear disc, so that the first infrared monitoring camera moves to a proper position, then the first infrared monitoring camera continuously swings in a reciprocating mode to monitor electric power big data in the opencast coal mine, the first infrared monitoring camera can randomly move to the proper position to conduct all-dimensional monitoring, and the function of conducting dead-angle-free monitoring on each area of the opencast coal mine is achieved.

2. The two-way screw rod rotates to drive the screw thread movable frame to reciprocate up and down, and the screw thread movable frame reciprocates up and down to drive the swing frame and the infrared monitoring camera to reciprocate up and down, so that the monitoring range of the infrared monitoring camera is further enlarged.

3. Reciprocating motion about the wave plate can drive carriage reciprocating motion about, reciprocating motion about the carriage can drive connecting rod and the reciprocal swing of infrared surveillance camera head two through the driving plate, lets infrared surveillance camera head two can monitor the big data of electric power in the opencut coal mine on a large scale, and infrared surveillance camera head two can assist infrared surveillance camera head one to monitor, can all-roundly, monitor the big data of electric power in the opencut coal mine without dead angle.

4. Under the elastic force effect of the pressure spring, the friction rod is tightly attached to the supporting plate, so that the friction rod and the movable plate frame can be kept stable after moving, and the first infrared monitoring camera and the second infrared monitoring camera can stably move to conduct all-dimensional monitoring.

Drawings

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

FIG. 2 is a schematic view of a first partial body structure according to the present invention.

Fig. 3 is a schematic diagram of a second partial body structure according to the present invention.

Fig. 4 is a perspective view of a third embodiment of the present invention.

Fig. 5 is a perspective view of a fourth embodiment of the present invention.

Fig. 6 is a partially sectional perspective view of the present invention.

Fig. 7 is a schematic view of the present invention in a partially cut-away and disassembled perspective structure.

Fig. 8 is a partial perspective view of the dead-space detecting component for a mining area according to the present invention.

Fig. 9 is a schematic structural view of a fifth partial body according to the present invention.

Fig. 10 is a schematic structural view of a sixth partial body according to the present invention.

Fig. 11 is a schematic partial perspective view of a second mining area dead angle detection component according to the present invention.

Reference numerals: 1_ support plate, 21_ annular slide rail, 22_ slide block, 23_ movable plate frame, 3_ drive part, 31_ support, 32_ biaxial speed reduction motor, 33_ fixed sleeve, 34_ inclined rod I, 35_ connecting spring, 36_ inclined rod II, 41_ fixed support rod, 411_ gear disc, 42_ multi-hole rotating shaft I, 43_ driving gear, 5_ mine area dead angle detection part I, 51_ multi-hole rotating shaft II, 52_ pushing rod, 53_ belt pulley, 54_ flat belt II, 55_ transmission rod, 56_ slotted arc panel, 57_ guide frame, 58_ swing frame, 59_ infrared monitoring camera I, 510_ fixed mounting plate, 6_ controller, 7_ height adjustment part, 71 \\\ L-shaped support plate, 72_ guide rod, 73_ bidirectional screw rod, 74_ threaded movable frame, 8_ mine area dead angle detection part II, 81_ corrugated plate, 82_ support, 83_ infrared monitoring camera head II, 84_ connecting rod, 85_ sliding frame, 86_ return spring, 87_ transmission plate, 91_ dead angle detection part 92_ friction plate, 101_ friction plate, and 102_ friction 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.

Example 1

The utility model provides a mine monitoring device based on big data of electric power, as shown in fig. 1-8, including backup pad 1, annular slide rail 21, slider 22, activity grillage 23, driver part 3, fixed branch 41, toothed disc 411, porous rotation axis 42, driving gear 43, mining area dead angle detection part 5 and controller 6, 1 top fixed mounting in backup pad has annular slide rail 21, the sliding type is connected with two sliders 22 and is the symmetry setting on annular slide rail 21, two the welding has activity grillage 23 between the slider 22 upper end, be equipped with driver part 3 on the activity grillage 23, 1 middle part fixed mounting in backup pad has fixed branch 41, fixed branch 41 is vertical setting, fixed branch 41 upper end is connected with activity grillage 23 rotary type, fixed branch 41 lower part fixedly connected with toothed disc 411, activity 23 lower part one side rotary type is connected with porous rotation axis 42, it has a plurality of draw-in grooves to open on the porous rotation axis 42, porous rotation axis 42 lower extreme fixedly connected with driving gear 43, driving gear 43 meshes with toothed disc 411, driving gear 411 can move around being equipped with on the movable grillage 23 round the movable grillage 23 move around the mining area 5 all-round control dead angles on the mining area data detection part 5 and the dead angle on the mining area, the control data detection part 5 and the controller 6.

Drive part 3 is including support 31, biax gear motor 32, fixed cover 33, inclined plane pole one 34, coupling spring 35 and two 36 of inclined plane pole, fixedly connected with support 31 on the activity grillage 23, install biax gear motor 32 through the rivet on the support 31, controller 6 passes through circuit connection with biax gear motor 32, controller 6 is used for controlling turning to of biax gear motor 32, fixed mounting has fixed cover 33 on two output shafts of biax gear motor 32, is located the top one side slidingtype that fixed cover 33 is close to controller 6 is connected with inclined plane pole one 34, be connected with coupling spring 35 between inclined plane pole one 34 and the fixed cover 33 that is located the top, be located the below fixed cover 33 is close to one side slidingtype of controller 6 and is connected with inclined plane pole two 36, be connected with coupling spring 35 between two 36 and the fixed cover 33 that is located the below, the one end card that controller 6 was kept away from to inclined plane pole two 36 is gone into one of them draw-in groove of porous rotation axis one 42, two 36 of inclined plane pole can only drive porous rotation axis one 42 towards one direction and rotate.

The mining area dead angle detection part 5 is including two 51 of porous rotation axis, promotion driving lever 52, belt pulley 53, two 54 of flat belt, transfer line 55, fluting arc panel 56, leading truck 57, swing span 58, infrared monitoring camera 59 and fixed mounting panel 510, activity grillage 23 upper portion rotary type is connected with two 51 of porous rotation axis and is located biax gear motor 32 top, it has a plurality of draw-in grooves to open on two 51 of porous rotation axis, controller 6 is kept away from to sloping pole 34 one of them draw-in groove of going into on two 51 of porous rotation axis, sloping pole 34 is the level setting, sloping pole 34 can only drive two 51 of porous rotation axis and rotate towards a direction, fixed mounting panel 510 is installed through the bolt to the side on the activity grillage 23, two 51 of porous rotation axis are connected with fixed mounting panel 510, the last rotation type of fixed mounting panel 510 promotes 52, promote driving lever 52 lower part and two 51 of porous rotation axis upper portion fixedly connected with 53, two around having two 54 of flat belt pulley between the belt pulley 53, one side of fixed mounting panel 510 is connected with the swing span 56, fixed mounting bar 56 one end fixed mounting bar 56 is connected with the swing span 56 and the infrared monitoring camera swing span 56, the swing span 56 drives the swing span of the infrared monitoring camera head panel 58 and drives the swing span of the swing span and the infrared monitoring camera head panel 58, the infrared monitoring camera 59 can monitor dead angles in the opencast coal mine, and large-range monitoring of electric power big data in the opencast coal mine is facilitated.

Firstly, the support plate 1 is installed at the central position of an open pit coal mine through bolts, when large electric power data in the open pit coal mine need to be monitored, the controller 6 controls the double-shaft speed reduction motor 32 to rotate clockwise, the double-shaft speed reduction motor 32 to rotate clockwise drives the fixing sleeve 33 located below to rotate clockwise through the output shaft located below, the fixing sleeve 33 located below to rotate clockwise drives the bevel rod II 36 to rotate clockwise, the multi-hole rotating shaft I42 does not rotate, the double-shaft speed reduction motor 32 to rotate clockwise drives the fixing sleeve 33 located above to rotate clockwise through the output shaft located above, the fixing sleeve 33 located above to rotate clockwise drives the bevel rod I34 to rotate clockwise, the bevel rod I34 to rotate clockwise drives the multi-hole rotating shaft II 51 to rotate clockwise, one of the belt pulleys 53 to rotate, the other belt pulley 53 to drive the deflector rod 52 to rotate, the deflector rod 56, the transmission rod 55, the guide frame 57, the swing frame 58 and the infrared monitoring camera 59 to rotate, the deflector rod II 33 to rotate anticlockwise, the infrared monitoring gear 32 to drive the infrared monitoring gear 32 to rotate anticlockwise, the fixing sleeve 33 located above to rotate anticlockwise, the infrared monitoring gear 32 to rotate, the large-hole driving gear 32 to rotate anticlockwise, the blind pit coal mine, the control the output shaft 32 to rotate anticlockwise, the infrared monitoring gear 32 to rotate, the contra the infrared monitoring gear 32, the contra-hole driving gear 32, make infrared surveillance camera head 59 remove to suitable position, after infrared surveillance camera head 59 removed suitable position, stop reversing and continue to rotate in the same direction through controller 6 control biax gear motor 32, infrared surveillance camera head 59 continues reciprocating swing and supervises the big data of electric power in the opencut coal mine, reciprocate in proper order, can let infrared surveillance camera head 59 carry out all-round supervision after removing suitable position at random, reached and to having carried out the function that no dead angle was supervised to each region in opencut coal mine, after the supervision finishes, stop operating through controller 6 control biax gear motor 32.

Example 2

On the basis of embodiment 1, as shown in fig. 9-10, the infrared monitoring camera further includes a height adjusting component 7, the height adjusting component 7 is disposed on the movable plate frame 23 and connected to the second porous rotating shaft 51, the height adjusting component 7 is configured to allow the first infrared monitoring camera 59 to reciprocate up and down to adjust the monitoring height of the first infrared monitoring camera 59, so as to further increase the monitoring range of the first infrared monitoring camera 59, the height adjusting component 7 includes an L-shaped support plate 71, a guide rod 72, a bidirectional screw 73 and a threaded movable frame 74, the side of the movable plate frame 23 is welded with the L-shaped support plate 71, the guide rod 72 is fixedly connected between the L-shaped support plate 71 and the fixed mounting plate 510, the guide rod 72 is vertically disposed, the two upper ends of the second porous rotating shaft 51 are fixedly mounted with a bidirectional screw 73, the upper end of the bidirectional screw 73 is rotatably connected to the L-shaped support plate 71, the threaded movable frame 74 is slidably connected to the guide rod 72, the guide rod 72 has a guiding effect on the threaded movable frame 74, the bidirectional screw 73 rotates to drive the threaded movable frame 74 to drive the reciprocating movable frame 59, thereby driving the reciprocating monitoring camera 59 to reciprocate up and down the infrared monitoring camera monitoring height adjusting frame 58.

When the second porous rotating shaft 51 rotates, the second porous rotating shaft 51 drives the bidirectional screw 73 to rotate, the bidirectional screw 73 rotates to drive the threaded movable frame 74 to reciprocate up and down, the threaded movable frame 74 reciprocates up and down to drive the swinging frame 58 and the first infrared monitoring camera 59 to reciprocate up and down, and the monitoring range of the first infrared monitoring camera 59 is further enlarged.

Example 3

On the basis of embodiment 2, as shown in fig. 10 and 11, the system further includes a second mining area dead angle detection component 8, the second mining area dead angle detection component 8 is disposed on the threaded movable frame 74 and connected to the L-shaped support plate 71, the second mining area dead angle detection component 8 is used for assisting the first infrared monitoring camera 59 in monitoring and can monitor large electric power data in an opencast coal mine in an all-around and dead angle-free manner, the second mining area dead angle detection component 8 includes a corrugated plate 81, brackets 82, a second infrared monitoring camera 83, a connecting rod 84, a sliding frame 85, a return spring 86 and a transmission plate 87, the corrugated plate 81 is disposed on one side of the threaded movable frame 74 close to the L-shaped support plate 71, the corrugated plate 81 is slidably connected to the L-shaped support plate 71, the two brackets 82 are fixedly mounted on the upper portion of the L-shaped support plate 71 and symmetrically disposed, the second infrared monitoring camera 83 is rotatably connected between the two brackets 82 and located above the first infrared monitoring camera 59, the second infrared monitoring camera 83 is used for assisting the first monitoring camera 59, the two brackets 82 are connected to the reciprocating sliding frame 85, the sliding frame 85 is connected to the reciprocating connection between the two brackets 85, and the reciprocating connection between the two brackets 85 and the reciprocating connection between the waveguide support plate 71.

The thread movable frame 74 can drive the corrugated plate 81 to reciprocate up and down during reciprocating movement, the corrugated plate 81 can drive the sliding frame 85 to reciprocate left and right during reciprocating movement, the sliding frame 85 can drive the connecting rod 84 and the infrared monitoring camera II 83 to reciprocate through the transmission plate 87 during reciprocating movement left and right, the infrared monitoring camera II 83 can monitor electric power big data in an opencut coal mine on a large scale, the infrared monitoring camera II 83 can assist the infrared monitoring camera I59 to monitor, and the electric power big data in the opencut coal mine can be monitored in an all-round and dead-corner-free mode.

Example 4

On the basis of the embodiment 2, as shown in fig. 1, the infrared monitoring camera further includes an installation support plate 91 and a protective cover 92, the installation support plate 91 is fixedly installed in the middle of the L-shaped support plate 71, the protective cover 92 is fixedly connected to the installation support plate 91, the second infrared monitoring camera 83 is located in the protective cover 92, the first infrared monitoring camera 59 is located below the protective cover 92, and the protective cover 92 is used for protecting the first infrared monitoring camera 59 and the second infrared monitoring camera 83 and preventing the first infrared monitoring camera 59 and the second infrared monitoring camera 83 from being exposed to the sun.

The protective cover 92 is used for protecting the first infrared monitoring camera 59 and the second infrared monitoring camera 83, the first infrared monitoring camera 59 and the second infrared monitoring camera 83 are prevented from being exposed to the sun, and the service life of the first infrared monitoring camera 59 and the second infrared monitoring camera 83 is prolonged.

Example 5

On the basis of the embodiment 1, as shown in fig. 2, the friction plate support further comprises a friction rod 101 and a pressing spring 102, the friction rod 101 is connected to the other side of the movable plate support 23 in a sliding manner, the lower end of the friction rod 101 contacts with the upper side of the support plate 1, the pressing spring 102 is connected between the friction rod 101 and the movable plate support 23, and under the elastic force of the pressing spring 102, the friction rod 101 is tightly attached to the support plate 1, so that the friction rod 101 and the movable plate support 23 can be kept stable after moving.

Initially, the friction rod 101 contacts the support plate 1, the hold-down spring 102 is compressed, when the driving gear 43 reverses to move around the gear disc 411, the driving gear 43 drives the first multi-hole rotating shaft 42, the movable plate frame 23 and the slider 22 to move along the annular slide rail 21, the movable plate frame 23 moves to drive the friction rod 101 and the hold-down spring 102 to move, the friction rod 101 disengages from the support plate 1, the hold-down spring 102 drives the friction rod 101 to move downward, the movable plate frame 23 continues to move to drive the friction rod 101 and the hold-down spring 102 to continue to move, the friction rod 101 comes into contact with the support plate 1 again, the support plate 1 presses the friction rod 101 to move upward, under the elastic force of the hold-down spring 102, the friction rod 101 is tightly attached to the support plate 1, so that the friction rod 101 and the movable plate frame 23 can be kept stable after moving, and the first infrared monitoring camera 59 and the second infrared monitoring camera 83 can stably move for omnidirectional monitoring.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a mine monitoring device based on electric power big data, characterized by: comprises a support plate (1), an annular slide rail (21), sliders (22), a movable plate frame (23), a driving part (3), a fixed support rod (41), a gear disc (411), a first porous rotating shaft (42), a driving gear (43), a first mine area dead angle detection part (5) and a controller (6), wherein the annular slide rail (21) is fixedly arranged at the top of the support plate (1), the annular slide rail (21) is slidably connected with two sliders (22) and symmetrically arranged, two movable plate frames (23) are fixedly arranged between the upper ends of the sliders (22), the driving part (3) is arranged on the movable plate frame (23), the fixed support rod (41) is fixedly arranged in the middle of the support plate (1), the upper end of the fixed support rod (41) is rotatably connected with the movable plate frame (23), the lower part of the fixed support rod (41) is fixedly connected with the gear disc (411), one side of the lower part of the movable plate frame (23) is rotatably connected with the first porous rotating shaft (42), a plurality of clamping grooves are formed in the first porous rotating shaft (42), the lower end of the first porous rotating shaft (42) is fixedly connected with the driving gear (43), the driving gear disc (43) is meshed with the gear disc (411), the movable plate frame (23) and the first mine area dead angle detection part (5), the fixed supporting rod (41) is provided with a controller (6) and is positioned between the gear disc (411) and the movable plate frame (23).

2. The mine monitoring device based on the electric power big data as claimed in claim 1, wherein: drive part (3) are including support (31), biax gear motor (32), fixed cover (33), inclined plane pole one (34), connecting spring (35) and inclined plane pole two (36), fixedly connected with support (31) is gone up in activity grillage (23), fixed mounting has biax gear motor (32) on support (31), controller (6) and biax gear motor (32) pass through circuit connection, fixedly connected with fixed cover (33) on two output shafts of biax gear motor (32), be located the top one side slidingtype that fixed cover (33) are close to controller (6) is connected with inclined plane pole one (34), be connected with connecting spring (35) between inclined plane pole one (34) and the fixed cover (33) that are located the top, be located the below one side slidingtype that fixed cover (33) are close to controller (6) is connected with inclined plane pole two (36), be connected with connecting spring (35) between inclined plane pole two (36) and fixed cover (33) that are located the below, one of them porous rotation axis (42) is gone into to one end that controller (6) is kept away from to inclined plane pole two (36).

3. The mine monitoring device based on the electric power big data as claimed in claim 2, wherein: mine area dead angle detection part one (5) including two (51) of porous rotation axis, promotion driving lever (52), belt pulley (53), flat belt two (54), transfer line (55), fluting arc panel (56), leading truck (57), swing span (58), infrared monitoring camera one (59) and fixed mounting panel (510), activity grillage (23) upper portion rotary type is connected with two (51) of porous rotation axis and is located biax gear motor (32) top, it has a plurality of draw-in grooves to open on two (51) of porous rotation axis, the one end card that controller (6) were kept away from in one of them draw-in groove on two (51) of porous rotation axis is gone into to bevel pole one (34), side fixedly connected with fixed mounting panel (510) on activity grillage (23), two (51) of porous rotation axis are connected with fixed mounting panel (510) rotary type, the last rotary type of fixed mounting panel (510) is connected with promotion driving lever (52), promotion driving lever (52) lower part and two (51) of porous rotation axis upper portion fixed connection belt pulley (53), two (54) are wound between belt pulley (53), fixed mounting panel (510) one side fixedly connected with fluting arc panel (55), the rotation axis rotary type (55), the upper end of the pushing deflector rod (52) is connected with the slotted arc panel (56) in a sliding mode, the other end of the transmission rod (55) is fixedly connected with a guide frame (57), the guide frame (57) is connected with a swinging frame (58) in a sliding mode in the vertical direction, and one end, far away from the guide frame (57), of the swinging frame (58) is fixedly connected with a first infrared monitoring camera (59).

4. The mine monitoring device based on the electric power big data as claimed in claim 3, wherein: still including height adjusting part (7), height adjusting part (7) are located movable grillage (23) and are connected with two (51) of porous rotation axis, height adjusting part (7) are including L type extension board (71), guide bar (72), two-way screw rod (73) and screw thread adjustable shelf (74), side fixedly connected with L type extension board (71) on movable grillage (23), fixedly connected with guide bar (72) between L type extension board (71) and fixed mounting board (510), two-way screw rod (73) of porous rotation axis two (51) upper end fixed mounting, two-way screw rod (73) upper end is connected with L type extension board (71) rotary type, have screw thread adjustable shelf (74) and be connected with guide bar (72) slidingly on two-way screw rod (73) through threaded connection, screw thread adjustable shelf (74) are connected with swing shelf (58) rotary type.

5. The mine monitoring device based on the electric power big data as claimed in claim 4, characterized in that: still including mining area dead angle detection part two (8), mining area dead angle detection part two (8) are located on screw thread adjustable shelf (74) and are connected with L type extension board (71), mining area dead angle detection part two (8) are including wave plate (81), support (82), infrared surveillance camera head two (83), connecting rod (84), carriage (85), reset spring (86) and driving plate (87), one side that screw thread adjustable shelf (74) is close to L type extension board (71) is provided with wave plate (81), wave plate (81) and L type extension board (71) slidingtype connection, L type extension board (71) upper portion fixed mounting has two supports (82) and is the symmetry and sets up, two be connected with infrared surveillance camera head two (83) and is located infrared surveillance camera head one (59) top between support (82) the rotary type, infrared surveillance camera head two (83) both ends fixedly connected with connecting rod (84), L type extension board (71) upper portion is connected with sliding frame (85) and sliding type drive plate (81) and is located infrared surveillance camera head one (59) top, be connected with sliding frame (85) sliding type extension board (85) and sliding type extension board (85), be connected with between L type extension board (71) rotary type extension board (85).

6. The mine monitoring device based on the electric power big data as claimed in claim 5, wherein: the infrared monitoring device is characterized by further comprising an installation support plate (91) and a protective cover (92), wherein the installation support plate (91) is fixedly installed in the middle of the L-shaped support plate (71), the protective cover (92) is fixedly connected to the installation support plate (91), the second infrared monitoring camera (83) is located in the protective cover (92), and the first infrared monitoring camera (59) is located below the protective cover (92).

7. The mine monitoring device based on the electric power big data as claimed in claim 6, wherein: still including friction lever (101) and housing spring (102), activity grillage (23) opposite side sliding connection has friction lever (101), side contact on friction lever (101) lower extreme and backup pad (1), be connected with housing spring (102) between friction lever (101) and the activity grillage (23).

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