CN116744089B - Sensor monitoring device based on network transmission - Google Patents

Abstract

The invention belongs to the technical field of monitoring, and particularly provides a sensor monitoring device based on network transmission, which comprises a monitoring body, wherein a camera end of the monitoring body is provided with a slot, a cover plate capable of shielding a camera when ascending is arranged on the slot, a support frame is arranged at the bottom of a fixed end of the monitoring body, the support frame consists of two parts, one part of the support frame is fixed on a carrier plate part at the bottom of the monitoring body, an assembly cavity is arranged on the inclined plate part, a push plate provides a pull-down force for a steel wire, the other end of the steel wire can upwards lift the cover plate of the camera end in a pull-up mode, and after the cover plate is upwards lifted along the slot, the camera of the camera end is covered in the monitoring body so as to achieve the aim of protecting the camera, so that the camera can resist severe weather and prolong the service life when being used in the environment.

Description

Sensor monitoring device based on network transmission

Technical Field

The invention relates to the technical field of monitoring, in particular to a sensor monitoring device based on network transmission.

Background

The monitoring system is one of the most applied systems in security systems, the more suitable building site monitoring system on the market is handheld video communication equipment, and video monitoring is currently the mainstream. The change of the ground over the sky occurs from the earliest analog monitoring to the digital monitoring of the heat of fire in the previous years to the video monitoring of the network of the current state of the prior art.

The monitoring device consists of a monitoring body, a supporting frame, a network module, a remote module and the like, wherein the network module and the remote module are arranged in the body, the front end of the camera is positioned at the body, and the camera is covered by a machine body outer cover to form peripheral protection, so that strong light can be shielded at the periphery of the camera. However, in the sudden rainy weather, the camera is still exposed in the application environment, which may cause the camera to be damaged to different degrees, for example, in the strong rainy or hail weather, the strong rainy or hail may impact the camera, which may cause the position of the camera to change, and may directly crush the camera.

Disclosure of Invention

The invention aims to solve the technical problem that the service life can be prolonged when monitoring severe weather by arranging the rolling bodies at the bottom of the monitoring body and driving the cover plate to cover the camera by the rolling bodies.

The technical proposal of the invention is that the sensor monitoring device based on network transmission comprises a monitoring body, wherein the camera end of the monitoring body is provided with a slot, a cover plate capable of shielding the camera when ascending is arranged on the slot, the bottom of the fixed end of the monitoring body is provided with a support frame, the support frame consists of two parts, one part of the support frame is fixed on a carrier plate part at the bottom of the monitoring body, the other part of the support frame is fixed on a sloping plate part which is at the rear end of the carrier plate part and slopes downwards, the sloping plate part is provided with an assembly cavity, the assembly cavity is arranged in a slope manner according to the slope direction of the sloping plate part, a detection cabin is fixed in the assembly cavity, one end of the detection cabin extends to the slope top end of the assembly cavity, the other end of the detection cabin extends to the slope bottom end of the assembly cavity, the top end of the assembly cavity is provided with a horizontal cavity which is parallel to the lower part of the monitoring body, the horizontal cavity is communicated with the inclined top end of the assembly cavity, the inclined top end of the detection cabin is provided with a filling port which is vertically communicated with the horizontal cavity, a gap is reserved between the top end of the filling port and the bottom surface of the monitoring body, two sides of the gap are communicated with two sides of the monitoring body, a trigger mechanism is arranged in the detection cabin, one end of the detection cabin facing the filling port is communicated with the filling port, the trigger mechanism comprises a buffer sleeve assembly and a trigger rod, the buffer sleeve assembly consists of two layers of sleeves which are internally and externally matched in a sliding manner and a spring between the two sleeves, and the trigger rod penetrates through the top end of the detection cabin to enter the filling port and is provided with a push plate;

the inclined top of assembly chamber is equipped with the rolling element, the rolling element is located the below of filling port, the rolling element is followed the slope bottom surface of assembly chamber can roll from top to bottom, the downside of rolling element relies on in the push pedal, the top of push pedal is connected with the steel wire, the steel wire upwards passes the filling port by the bottom rear end of control body runs through to in the control body, and by the camera end of control body is worn out the back and is connected on the apron.

As a further preferable mode, two sides of the supporting frame are respectively fixed with a drainage plate positioned at two sides of the pouring opening, the two drainage plates extend upwards from two sides of the monitoring body, the top ends of the two drainage plates are respectively provided with a collecting plate which is gradually inclined outwards from the outer side of the monitoring body, the inner faces of the collecting plates are guide part drainage faces, the inner faces of the drainage plates are bottom drainage faces, and rainwater can be drained into the assembly cavity.

As a further preferable mode, the rolling body is a hollow sphere, a scoop is arranged on the rolling body, the scoop is communicated with the inside and the outside of a hollow inner cavity of the rolling body, and when the rolling body is static at the top end of the assembly cavity and is positioned in the pouring opening, the scoop of the rolling body faces away from the pushing plate and is leaned against the direction of the pushing plate to face to the lower part of the pouring opening.

As a further preferable mode, the number of the rolling bodies is several, the number of the rolling bodies is arranged along the width direction of the assembly cavity, and the rolling bodies are simultaneously leaned on the pushing plate, and the directions of the spoon openings on the number of the rolling bodies are consistent.

As a further preferable mode, the inclined bottom end of the inclined plate part of the supporting frame is provided with an upward vertical fixing part, and the fixing part is provided with a fixing hole.

As a further preferable mode, the bottom of the assembly cavity is provided with a plurality of leakage holes along the inclined trend of the bottom of the assembly cavity, the bottom of the detection cabin is communicated with the assembly cavity, the bottom of the detection cabin is parallel to the inclined bottom of the assembly cavity, a gap is reserved between the bottom of the detection cabin and the inclined bottom of the assembly cavity, and two adjacent rolling bodies are connected through connecting rods, so that a gap is reserved between the two adjacent rolling bodies.

As a further preferable mode, the slot is formed in the bottom side of the camera head end of the monitoring body, two threading holes are symmetrically formed in two sides of the camera head end of the monitoring body, the steel wire is provided with branches at the camera head end of the monitoring body, one branch of the steel wire is downwards connected to one side of the top end of the cover plate through one side threading hole, and the other branch of the steel wire is downwards connected to the other side of the top end of the cover plate through the other side threading hole.

As a further preference, the hinge groove has been seted up at the bottom middle part of apron, there is the depression bar through the articulated shaft switching in the hinge groove, pressure sensor is installed to the bottom of control body, the free end of depression bar upwards inclines and is located pressure sensor's downside, the articulated shaft in the hinge groove adopts the articulated shaft of torsional spring, and one free end elasticity of torsional spring is contradicted on the articulated end bottom surface of depression bar, another free end elasticity of torsional spring is contradicted in the hinge groove, the control is internal including installing at least with pressure sensor electric connection's remote transmission module, the remote transmission module with the control module in the control body is through net terminal joint transmission to the terminal equipment.

Compared with the prior art, the invention has the advantages that a small part of ice fog falls into the filling opening from the two sides of the monitoring body under the action of strong wind, the ice fog weight in the filling opening is increased, the push plate is positioned in the filling opening, one surface of the push plate faces the filling opening, the other surface of the push plate is positioned in the assembly cavity, and the bottom surface of the push plate is in sliding contact with the inclined surface because the bottom surface of the inner cavity of the assembly cavity is an inclined surface, so that when the ice fog weight in the filling opening exceeds the supporting force of the springs at the opposite side of the push plate, the surface of the push plate facing the filling opening is caused to move from a high position to a low position due to the fact that the extrusion force received by the push plate is greater than the supporting force of the springs, the springs are pressed at the same time, the springs are forced to compress and shorten, meanwhile, the push plate provides a lower pulling force to the steel wire, the other end of the steel wire is pulled upwards, and the cover plate covers the camera at the camera end in the monitoring body after the upward lifting along the slot, so that the camera is protected, and the camera is protected against severe weather, and the service life is prolonged. Hail can melt gradually due to improvement of weather, after the hail melts, the hail leaks onto the bottom surface of the assembly cavity from the bottom end of the push plate in a liquid state, namely, the hail leaks into a low-level area of the assembly cavity gradually, at the moment, acting force on one side of a pouring opening of the push plate surface is gradually reduced, when acting force on the side is smaller than resilience force of a spring supported on the other side of the push plate, the spring can rapidly release elasticity and recover length, and thrust is formed on the push plate through a sleeve so as to push the push plate to be reset into the pouring opening again, a steel wire loses tension, the length is released downwards at one end of the camera, a cover plate automatically descends along a slot, the camera is exposed outside again, and the normal use state is recovered after potential safety hazard is eliminated.

Drawings

Fig. 1 is a schematic diagram of a first structure of a sensor monitoring device based on network transmission according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a second structure of a sensor monitoring device based on network transmission according to an embodiment of the present invention;

FIG. 3 is a schematic side view plane structure of a sensor monitoring device based on network transmission according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a sensor monitoring device based on network transmission after being cut away according to an embodiment of the present invention;

fig. 5 is an enlarged schematic diagram of a portion a of the sensor monitoring device according to the embodiment of the present invention, which is led out from fig. 4;

fig. 6 is a schematic plan view of a camera end of a sensor monitoring device based on network transmission according to an embodiment of the present invention;

fig. 7 is a schematic three-dimensional structure of a sensor monitoring device based on network transmission after being cut away according to an embodiment of the present invention;

fig. 8 is a schematic structural diagram of a sensor monitoring device based on network transmission according to an embodiment of the present invention when rolling elements are arranged together.

In the figure: 1. monitoring the body; 2. a slot; 3. a cover plate; 4. a support frame; 5. a carrier plate portion; 6. a sloping plate part; 7. an assembly chamber; 8. a detection cabin; 9. a horizontal cavity; 10. a filling port; 11. a trigger mechanism; 12. a buffer sleeve assembly; 13. a trigger lever; 14. a sleeve; 15. a spring; 17. a push plate; 18. a rolling element; 19. a steel wire; 20. a drainage plate; 21. a collection plate; 22. a spoon opening; 23. a fixing part; 24. a fixing hole; 25. a leak hole; 26. a hinge groove; 27. a compression bar; 28. a pressure sensor; 29. and a threading hole.

Detailed Description

The foregoing and other embodiments and advantages of the invention will be apparent from the following, more complete, description of the invention, taken in conjunction with the accompanying drawings. It will be apparent that the described embodiments are merely some, but not all, embodiments of the invention.

In one embodiment, as shown in fig. 1-8.

The sensor monitoring device based on network transmission provided by the embodiment comprises a monitoring body 1, wherein a camera end of the monitoring body 1 is provided with a slot 2, a cover plate 3 capable of shielding a camera when ascending is arranged on the slot 2, a supporting frame 4 is arranged at the bottom of a fixed end of the monitoring body 1, the supporting frame 4 consists of two parts, one part of the supporting frame is fixed on a carrier plate part 5 at the bottom of the monitoring body 1, the other part of the supporting frame is fixed on a sloping plate part 6 at the rear end of the carrier plate part 5 and is inclined downwards, the sloping plate part 6 is provided with an assembly cavity 7, the assembly cavity 7 is obliquely arranged according to the inclined direction of the sloping plate part 6, a detection cabin 8 is fixed in the assembly cavity 7, one end of the detection cabin 8 extends to the inclined top end of the assembly cavity 7, the other end of the detection cabin 8 extends to the inclined bottom end of the assembly cavity 7, the top end of the assembly cavity 7 is provided with a horizontal cavity 9, the horizontal cavity 9 is parallel below the monitoring body 1, the horizontal cavity 9 is communicated with the inclined top end of the assembly cavity 7, the inclined top end of the detection cabin 8 is provided with a filling port 10 communicated with the horizontal cavity 9 up and down, the inside the detection cabin 8 is provided with a trigger mechanism 11, the inside the detection cabin 8 faces the trigger mechanism 10 and the bottom surface of the detection cabin 10 and the trigger mechanism 12 and the inner side of the detection cabin 10 are matched with the buffer sleeve 13, the two end 13 and the inner side of the trigger sleeve are matched with the buffer sleeve, and the inner side 13 and the trigger sleeve, and the inner side of the buffer sleeve is formed by the trigger assembly 13, and the trigger sleeve is matched with the two ends, and the top end 13, and the top 13, 13 and the buffer sleeve is matched with the inner part and the buffer sleeve, and the inner sleeve, and the upper part and the end and the upper part and the lower part, and the lower part is provided with the upper part;

the inclined top of assembly chamber 7 is equipped with rolling element 18, and rolling element 18 is located the below of filling port 10, and rolling element 18 can roll from top to bottom along the inclined bottom surface of assembly chamber 7, and the downside of rolling element 18 relies on push pedal 17, and the top of push pedal 17 is connected with wire 19, and wire 19 upwards passes filling port 10 and runs through to monitor body 1 by monitor body 1's bottom rear end to connect on apron 3 after wearing out by monitor body 1's camera end.

In this embodiment, when ice fog weather comes, in addition to that most hail can directly hit the monitoring body 1, a small part of ice fog falls into the filling port 10 from two sides of the monitoring body 1 under the action of strong wind, so that the ice fog weight in the filling port 10 becomes larger and larger, the push plate 17 is located in the filling port 10, one surface of the push plate 17 faces the filling port 10, the other surface is located in the assembly cavity 7, the bottom end of the push plate 17 is in sliding contact with the inclined surface, therefore, when the ice fog weight in the filling port 10 exceeds the supporting force of the springs 15 on the opposite side of the push plate 17, the surface of the push plate 17 facing the filling port 10 is caused to travel from a high point to a low point due to the fact that the extrusion force received by the springs 15 is larger than the supporting force of the springs 15, and simultaneously the springs 15 are pressed and are forced to be compressed and shortened, meanwhile, the push plate 17 provides a downward pulling force to the steel wire 19, the other end of the steel wire 19 pulls the cover plate 3 upwards, and the cover plate 3 of the end of the steel wire 19 upwards covers the camera head 1, and the camera head can be covered by the camera head in a bad shape, and the camera can be protected in the camera head, and the camera can be used in the camera head is protected when the camera is in a bad weather. Hail can be gradually melted due to improved weather, after the hail is melted, the hail leaks onto the bottom surface of the assembly cavity 7 from the bottom end of the push plate 17 in a liquid state, namely gradually leaks into a low-level area of the assembly cavity 7, at the moment, acting force on one side of the pouring opening 10 of the surface of the push plate 17 is gradually reduced, when acting force on the side is smaller than resilience force of a spring 15 supported on the other side of the push plate 17, the spring 15 rapidly releases elasticity and recovers length, and thrust is formed on the push plate 17 through a sleeve 14 so as to push the push plate 17 to be reset into the pouring opening 10 again, a steel wire 19 loses tension, the length is downwards released at one end of a camera, a cover plate 3 automatically descends along a slot 2, the camera is exposed outside again, and the normal use state is recovered after potential safety hazards are eliminated.

From the arrangement mode of the steel wire 19, the fixed end of the steel wire 19 monitoring device extends out from the camera of the monitoring device after penetrating upwards, the structure for forming pulling action on the steel wire 19 in the direction of the fixed end is arranged on the support frame 4, the support frame 4 is a fixed support for fixing the monitoring device in an application scene, and the fixed support is in a straight line with the camera or the monitoring body 1, so that the structural characteristics are just utilized, the components or structures such as the detection cabin 8, the triggering mechanism 11, the push plate 17 and the pouring opening 10 are arranged on the support frame 4, the steel wire 19 can be ensured to be positioned on the same straight line, and the cover plate 3 can be ensured to stably rise along the slot 2 when the pulling action is carried out.

From the structure of the assembly chamber 7, since the assembly chamber 7 is designed as an inclined plane, and the push plate 17 is guided along the inclined plane of the assembly chamber 7 as a moving guide, and when the push plate 17 receives the acting force in the pouring opening 10, the inclined bottom surface of the assembly chamber 7 can be used as a moving guide, besides improving the stability, the structural characteristic that the inclined bottom surface of the assembly chamber 7 is the inclined plane is utilized to form a fall when moving from a high position to a low position, so as to ensure that the push plate 17 can smoothly slide to the low position when suffering hail impact in the embodiment, and smoothly drag the steel wire 19 upwards at the shooting end.

In this embodiment, since the rolling elements 18 are further disposed at the inclined top end of the assembly cavity 7, the rolling elements 18 are located below the filling opening 10, the rolling elements 18 can roll up and down along the inclined bottom surface of the assembly cavity 7, the descending side of the rolling elements 18 rests on the push plate 17, the top end of the push plate 17 is connected with the steel wire 19, the steel wire 19 passes through the filling opening 10 upwards, penetrates through the bottom rear end of the monitoring body 1 into the monitoring body 1, penetrates out of the image pickup end of the monitoring body 1 and is connected to the cover plate 3, the rolling elements 18 are a plurality of, the rolling elements 18 are arrayed along the width direction of the assembly cavity 7 and rest on the push plate 17 at the same time, and the directions of the spoon openings 22 on the rolling elements 18 are consistent. Because the number of the rolling bodies 18 is several, rolling contact is carried on the pushing plate 17, and the pushing plate 17 is located in the pouring opening 10 and pushed by the pushing plate 17, the spoon opening 22 of the rolling bodies 18 is located at the top position facing the pouring opening 10, so that strong rain or hail weather is temporary, part of rainwater can be directly poured into the pouring opening 10 to increase the weight of the pushing plate 17 facing one side of the pouring opening 10, and besides the rainwater or hail enters the rolling bodies 18 along the spoon opening 22, the weight of the rolling bodies 18 is increased by the rainwater or hail, and the weight is superposed on the rolling bodies 18, and the weight is acted on the pushing plate 17 together, so that the weight of the rolling bodies 18 and the pouring opening 10 is increased, and when the weight is increased to the pushing plate 17, the pushing plate 17 is pushed from a high position to a low position of the inclined bottom along the inclined bottom surface of the assembling cavity 7, and the rolling bodies 18 can roll along the inclined bottom surface of the assembling cavity 7, so that the effectiveness and the pushing speed of the pushing plate 17 can be improved when the pushing from the high position to the low position of the inclined bottom surface are increased, the pulling plate 17, the pulling speed of the pushing plate 17 is increased, the steel wire 19 is pulled by the pulling plate 19, the efficiency is improved, and the speed of the cover plate 19 is 3, and the cover 3 is pulled by the cover plate 19.

As shown in fig. 1, 2, 3 and 6, two sides of the supporting frame 4 are respectively fixed with a drainage plate 20 positioned at two sides of the filling opening 10, the two drainage plates 20 extend upwards from two sides of the monitoring body 1, and the top ends of the two drainage plates 20 are respectively provided with a collecting plate 21 gradually inclining outwards from the outer side of the monitoring body 1, the inner surface of the collecting plate 21 is a guiding part drainage surface, the inner surface of the self-drainage plate 20 is a bottom drainage surface, rainwater or hail can be drained into the assembly cavity 7, weight increase in the filling opening 10 is quickened temporarily in the weather, and the pushing plate 17 is quickened by utilizing weight increase to cover a camera for the cover plate 3 in a shorter time, so that the pushing action is completed.

The bottom of assembly chamber 7 has offered a plurality of weeping holes 25 along its slope trend, and the bottom surface of detection cabin 8 communicates with each other with assembly chamber 7, and the bottom of detection cabin 8 is parallel with the slope bottom surface of assembly chamber 7, leaves the clearance between the bottom of detection cabin 8 and the slope bottom surface of assembly chamber 7, connects through the connecting rod between two adjacent rolling bodies 18 for leave the seepage clearance between two adjacent rolling bodies 18.

As shown in fig. 4 and 8, the rolling elements 18 are hollow spheres, the rolling elements 18 are provided with scoop openings 22, the scoop openings 22 are communicated with the inside and outside of the hollow inner cavity of the rolling elements 18, when the rolling elements 18 are static at the top end of the assembly cavity 7 and are positioned in the pouring opening 10, the scoop openings 22 of the rolling elements 18 face to the lower side of the pouring opening 10 against the push plate 17, all the rolling elements 18 are connected together so as to facilitate uniform rolling, when the rolling elements 18 are static at the top end of the assembly cavity 7 and are positioned in the pouring opening 10 (initial position), the push plate 17 pushes the lower scoop openings 22 to keep the scoop openings 22 open to the top of the pouring opening 10, so that the rolling elements 18 can receive rainwater and hail in the first time, in the rolling process, the poured rainwater is poured on the inclined bottom surface of the assembly cavity 7 by the scoop openings 22, when the drain holes 25 on the inclined bottom surface of the assembly cavity 7 are used for uniformly discharging rainwater or hail in the pouring opening 10 and the rolling body 18, and the drain holes 25 are tiny holes when the low position of the assembly cavity 7 is discharged through the drain holes 25, the rainwater or hail can not be completely discharged in a short time, and can be always poured into the pouring opening 10 when the rainwater or hail is not stopped, namely the weight of the push plate 17 is always increased, the push plate 17 is always stopped and left at the low position of the assembly cavity 7, the push plate 17 always pulls the steel wire 19, the steel wire 19 is always in a pull-down state, the other end of the steel wire 19 always covers the cover plate 3 on the front side of the camera, the camera is always protected until the weather is recovered to be normal, the rainwater or hail is not poured into the pouring opening 10 any more, and the rainwater or hail is leaked downwards through a gap between the bottom surface of the assembly cavity 7 and the inclined bottom surface in a liquid state after being melted, when the weight gain of the push plate 17 is reduced to be smaller than the supporting force of the spring 15 at the other side, the spring 15 can rapidly release the elastic force and restore the length, the push plate 17 is pushed to form pushing force through the sleeve 14, so that the push plate 17 is pushed to be restored to the pouring opening 10 again, meanwhile, the push plate 17 pushes the rolling bodies 18 into the pouring opening 10 again, at the moment, the steel wires 19 lose tension, the length is downwards released at one end of the camera, the cover plate 3 automatically descends along the slot 2, the camera is exposed outside again, and the normal use state is restored after the potential safety hazard is eliminated.

As shown in fig. 1, the slot 2 is formed at the bottom side of the camera end of the monitoring body 1, two symmetrical threading holes 29 are formed on two sides of the camera end of the monitoring body 1, the steel wire 19 is provided with branches at the camera end of the monitoring body 1, one branch of the steel wire 19 is downwards connected to one side of the top end of the cover plate 3 through one side threading hole 29, the other branch of the steel wire 19 is downwards connected to the other side of the top end of the cover plate 3 through the other side threading hole 29, and the two sides are stressed when the cover plate 3 is pulled upwards, so that the operation is more stable.

In another embodiment, the middle part of the bottom end of the cover plate 3 is provided with a hinge groove 26, a pressure bar 27 is connected in the hinge groove 26 through a hinge shaft, the bottom of the monitoring body 1 is provided with a pressure sensor 28, the free end of the pressure bar 27 is inclined upwards and positioned at the bottom side of the pressure sensor 28, the hinge shaft in the hinge groove 26 adopts a torsion spring type hinge shaft, one free end of the torsion spring is elastically abutted against the bottom surface of the hinge end of the pressure bar 27, the other free end of the torsion spring is elastically abutted against the hinge groove 26, the monitoring body 1 at least comprises a remote transmission module which is electrically connected with the pressure sensor 28, and the remote transmission module and the monitoring module in the monitoring body 1 are jointly transmitted to terminal equipment through a network terminal.

In this embodiment, when the cover plate 3 is lifted, the steel wire 19 is pulled upwards, and the steel wire 19 is pulled upwards, because the pouring port 10 where the push plate 17 is located is subjected to weight increase caused by rainwater and hail in severe weather, the severe weather is known to be temporary, besides the cover plate 3 can cover the camera, the cover plate 3 is lifted, the pressure bar 27 is driven to lift, and the pressure bar 27 lifts upwards, and the pressure sensor 28 sends a signal to the remote transmission module through contact with the sensing probe of the pressure sensor 28, and the remote transmission module sends an alarm to the terminal equipment, so that the purpose of remote early warning of the weather is achieved. Since the pressure lever 27 is hinged to the cover plate 3, the pressure lever 27 does not affect the cover plate 3 to cover the front end of the camera, that is, when the cover plate 3 is lifted to cover the front end of the camera, the cover plate 3 can still move upward smoothly due to the fact that the pressure lever 27 can rotate even if the pressure lever 27 is lifted to contact with the pressure sensor 28 to generate a signal.

The inclined bottom end of the inclined plate part 6 of the support frame 4 is provided with an upward vertical fixing part 23, and the fixing part 23 is provided with a fixing hole 24 for fixing the inclined plate part in a mounting environment.

The above-described orientation is not intended to represent a specific orientation of each component in the present embodiment, but is merely provided to facilitate description of the embodiments, and is set by referring to the orientation in the drawings, and it is essential that the specific orientation of each component be described according to the actual installation and actual use thereof and the orientation that is habitual to a person skilled in the art, and this is described.

The above-described embodiments are provided to further explain the objects, technical solutions, and advantageous effects of the present invention in detail. It should be understood that the foregoing is only illustrative of the present invention and is not intended to limit the scope of the present invention. It should be noted that any modifications, equivalent substitutions, improvements, etc. made by those skilled in the art without departing from the spirit and principles of the present invention are intended to be included in the scope of the present invention.

Claims (7)

1. The utility model provides a sensor monitoring device based on network transmission, its characterized in that includes control body (1), slot (2) have been seted up to the camera end of control body (1), install apron (3) that can shelter from the camera when rising on slot (2), support frame (4) are installed to the stiff end bottom of control body (1), support frame (4) are by two parts constitution, one part is fixed support plate portion (5) of control body (1) bottom, another part is fixed on support plate portion (5) rear end and downward sloping swash plate portion (6), set up on swash plate portion (6) assembly chamber (7), assembly chamber (7) are according to the slope orientation slope setting of swash plate portion (6), assembly chamber (7) internal fixation has detection cabin (8), the one end of detection cabin (8) extends to the slope top of assembly chamber (7), the other end of detection cabin (8) extends to the slope bottom of assembly chamber (7), assembly chamber (7) are equipped with horizontal chamber (9) are equipped with in parallel to horizontal chamber (9) the horizontal chamber (1), the automatic detection device is characterized in that a filling opening (10) which is vertically communicated with the horizontal cavity (9) is formed in the inclined top end of the detection cabin (8), a gap is reserved between the top end of the filling opening (10) and the bottom surface of the monitoring body (1), two sides of the gap are communicated with the two sides of the monitoring body (1), a trigger mechanism (11) is arranged in the detection cabin (8), one end of the detection cabin (8) facing the filling opening (10) is communicated with the filling opening (10), the trigger mechanism (11) comprises a buffer sleeve assembly (12) and a trigger rod (13), the buffer sleeve assembly (12) is composed of two layers of sleeves (14) which are in sliding fit together and springs (15) which elastically support the two sleeves (14), and the trigger rod (13) penetrates through the top end of the detection cabin (8) to enter the filling opening (10) and is provided with a push plate (17);

the automatic monitoring device is characterized in that a rolling body (18) is arranged at the inclined top end of the assembly cavity (7), the rolling body (18) is located below the pouring opening (10), the rolling body (18) can roll up and down along the inclined bottom surface of the assembly cavity (7), the descending side of the rolling body (18) depends on the push plate (17), a steel wire (19) is connected to the top end of the push plate (17), the steel wire (19) upwards penetrates through the pouring opening (10) from the rear end of the bottom of the monitoring body (1) to the inside of the monitoring body (1), and is connected to the cover plate (3) after penetrating out from the camera end of the monitoring body (1); the slot (2) is formed in the bottom side of the camera end of the monitoring body (1), two threading holes (29) are symmetrically formed in the two sides of the camera end of the monitoring body (1), the steel wire (19) is provided with branches at the camera end of the monitoring body (1), one branch of the steel wire (19) is downwards connected to one side of the top end of the cover plate (3) through one side threading hole (29), and the other branch of the steel wire (19) is downwards connected to the other side of the top end of the cover plate (3) through the other side threading hole (29).

2. The sensor monitoring device based on network transmission according to claim 1, wherein two sides of the supporting frame (4) are respectively fixed with a drainage plate (20) positioned at two sides of the filling port (10), the two drainage plates (20) extend upwards from two sides of the monitoring body (1), collecting plates (21) gradually inclining outwards from the outer side of the monitoring body (1) are respectively arranged at the top ends of the two drainage plates (20), the inner face of the collecting plates (21) is a drainage surface, the inner face of the drainage plates (20) is a bottom drainage surface, and rainwater can be drained into the assembly cavity (7).

3. A sensor monitoring device based on network transmission according to claim 2, characterized in that the rolling body (18) is a hollow sphere, the rolling body (18) is provided with a scoop (22), the scoop (22) is communicated with the inside and the outside of the hollow cavity of the rolling body (18), and when the rolling body (18) is static at the top end of the assembly cavity (7) and is positioned in the filling port (10), the scoop (22) of the rolling body (18) faces away from the push plate (17) and faces to the lower part of the filling port (10) depending on the direction of the push plate (17).

4. A network transmission-based sensor monitoring device according to claim 3, characterized in that the number of rolling bodies (18) is several, the number of rolling bodies (18) being arranged in the width direction of the assembly chamber (7) and simultaneously resting on the push plate (17), the scoop (22) direction on the number of rolling bodies (18) being identical.

5. The sensor monitoring device based on network transmission according to claim 4, wherein an upward vertical fixing portion (23) is arranged at the inclined bottom end of the inclined plate portion (6) of the supporting frame (4), and a fixing hole (24) is formed in the fixing portion (23).

6. The sensor monitoring device based on network transmission according to claim 5, wherein a plurality of leakage holes (25) are formed in the bottom of the assembly cavity (7) along the inclined trend of the assembly cavity, the bottom surface of the detection cabin (8) is communicated with the assembly cavity (7), the bottom end of the detection cabin (8) is parallel to the inclined bottom surface of the assembly cavity (7), a gap is reserved between the bottom end of the detection cabin (8) and the inclined bottom surface of the assembly cavity (7), and two adjacent rolling bodies (18) are connected through connecting rods, so that a gap is reserved between two adjacent rolling bodies (18).

7. The sensor monitoring device based on network transmission according to claim 6, wherein a hinge groove (26) is formed in the middle of the bottom end of the cover plate (3), a pressing rod (27) is connected in the hinge groove (26) through a hinge shaft, a pressure sensor (28) is installed at the bottom of the monitoring body (1), the free end of the pressing rod (27) is inclined upwards and located at the bottom side of the pressure sensor (28), the hinge shaft in the hinge groove (26) adopts a torsion spring type hinge shaft, one free end of the torsion spring is elastically abutted against the bottom surface of the hinge end of the pressing rod (27), the other free end of the torsion spring is elastically abutted against the inside of the hinge groove (26), and the monitoring body (1) at least comprises a remote transmission module which is electrically connected with the pressure sensor (28), and the remote transmission module and the monitoring module in the monitoring body (1) are jointly transmitted to a terminal device through a network terminal.