CN110418040B

CN110418040B - Intelligent security monitoring device

Info

Publication number: CN110418040B
Application number: CN201910626784.1A
Authority: CN
Inventors: 张晓卫
Original assignee: Beijing Zhongsheng Guohua Engineering Technology Co Ltd
Current assignee: Beijing Zhongsheng Guohua Engineering Technology Co ltd
Priority date: 2019-07-11
Filing date: 2019-07-11
Publication date: 2020-11-06
Anticipated expiration: 2039-07-11
Also published as: CN110418040A

Abstract

The invention provides an intelligent security monitoring device, which comprises a transformer and a PT temperature sensor; the cover body is of an arc-shaped shell structure, the front end surface and the rear end surface of the cover body are respectively embedded with a left radiating fan and a right radiating fan, and the rear end of the cover body is provided with an installation seat of the shell seat structure; a wiring harness pipe penetrates between the mounting seat and the cover body, and the part of the wiring harness pipe, which is positioned on the cover body, is electrically connected with a lamp holder for mounting a camera head; install microcontroller and transformer in the housing chamber of mount pad, the fan stops the heat dissipation action after the temperature drops to the temperature of controller programming to for the structural rationality of further improvement thermal diffusivity of blowing, still be equipped with rational in infrastructure arc in the cover, form the gas collection air current, increase thermal diffusivity still is equipped with the fin structure at cover outer wall, further accelerates the thermal diffusivity, when functional obtaining the improvement, structural more reasonable.

Description

Intelligent security monitoring device

Technical Field

The invention belongs to the technical field of monitoring devices, and particularly relates to an intelligent security monitoring device.

Background

The monitoring system is one of the most applied systems in the security system, the construction site monitoring system suitable for the market is a handheld video communication device, and video monitoring is the mainstream at present. Present above-mentioned monitoring device is for improving the control quality, reach no dead angle monitoring mode, mostly be naked formula during its installation, because monitoring device covers internal camera or camera lamp and pencil pipe and is connected the use in the lump, can produce higher heat, the heat is finally concentrated in the cover internal, summer comes temporarily, we are when maintenance camera equipment, can discover often, the pencil pipe of rubber material can take place ageing phenomenon, this is mainly because rubber pencil pipe takes place to warp under the high temperature effect, meet the physics phenomenon that takes place after the cold, can influence the life of rubber pipe, thereby also can influence camera or camera lamp that its end is connected.

Disclosure of Invention

In order to solve the technical problems, the invention provides an intelligent security monitoring device, which aims to solve the problems that the existing monitoring device is mostly exposed when being installed in order to improve monitoring quality and achieve a dead-angle-free monitoring mode, and a camera or a camera lamp in a cover body of the monitoring device is connected with a wire harness pipe for use, so that high heat is generated, the heat is finally concentrated in the cover body, and when camera equipment is maintained in summer, the phenomenon that the wire harness pipe made of rubber materials is aged is often found when the camera equipment is maintained.

The invention relates to an intelligent security monitoring device, which is achieved by the following specific technical means:

an intelligent security monitoring device comprises a cover body, a glass plate, a cooling fan, an air collecting plate, a wire harness pipe, a polyurethane sleeve pipe, a wire outlet hole, a lamp holder, an embedded ring, an embedded strip, a cooling fin, a fan wire, a wire routing seat, a wire routing groove, a mounting seat, a microcontroller, a transformer and a PT100 temperature sensor; the cover body is of an arc-shaped shell structure, the front end surface and the rear end surface of the cover body are respectively embedded with a left radiating fan and a right radiating fan, and the rear end of the cover body is provided with an installation seat of the shell seat structure; a wiring harness pipe penetrates between the mounting seat and the cover body, and the part of the wiring harness pipe, which is positioned on the cover body, is electrically connected with a lamp holder for mounting a camera head; a microcontroller and a transformer are arranged in a shell cavity of the mounting seat, and the microcontroller and the transformer are electrically connected with an external power supply and an existing camera power supply assembly; the electric connection line of the microcontroller and the transformer runs in the wire harness tube and is electrically connected with the lamp holder; the wire bundle pipe is provided with a circular wire outlet, one group of fan wires extend out of the wire outlet and are electrically connected with the two groups of radiating fans at the two sides of the cover body in a control manner; the glass plate is positioned in the shell of the cover body, positioned at the front side of the cover body and provided with a circular lamp hole.

Further: a circle of inlaid ring is inlaid on the periphery of each radiating fan, and inlaid strips are connected between every two adjacent radiating fans.

Further: the panel and the ring are made of aluminum alloy materials and are of integral structures, and a row of radiating fins are arranged on the bottom side of the panel.

Further: the wiring seat is of a rectangular rubber seat structure, a T-shaped wiring groove is formed in the wiring seat, and the fan wire is wired in the groove cavity.

Further: the wind collecting plates are of arc-shaped plate structures, are positioned on the inner cavity wall of the cover body in a bilateral symmetry mode, and are positioned on the third side of the front end of the cable harness tube.

Further: a through hole is formed in the position, close to the front side, of the pipeline of the wire harness pipe, and a polyurethane sleeve pipe with a cylindrical pipe structure is embedded in the through hole.

Further: the inner of the polyurethane sleeve is in interference fit with a PT100 temperature sensor, and an electrical connecting wire of the PT100 temperature sensor is also wired in a tube cavity of the wire harness tube and is electrically connected with the microcontroller and the transformer in a control mode.

Further: the radiating fins extend downwards, the length of the radiating fins is far greater than the vertical size of the cover body, the same inlaid strips are of Z-shaped bending structures, and the length of the bottom sides of the inlaid strips also extends downwards.

Compared with the prior art, the invention has the following beneficial effects:

the design adds the functions of the prior camera device, a left group of four cooling fans and a right group of four cooling fans are arranged on the outer cover of the camera device, a PT100 temperature sensor is arranged in the cover body, a controller for controlling the sensor and the action of a cooling fan is arranged in a shell cavity of a rear side mounting seat of the camera device, thus, when the temperature in the camera device is higher, the generated heat is induced to drive the two sets of heat dissipation fans to blow and dissipate heat of the rubber wire harness pipe in the cover, so that the rubber wire harness pipe is cooled, and the fans stop heat dissipation after the temperature is reduced to the temperature programmed by the controller, and for the rational in infrastructure nature of further improvement thermal diffusivity of blowing, still be equipped with rational in infrastructure arc in the cover, form the gas collection air current, increase thermal diffusivity, still be equipped with the fin structure at cover body outer wall, further accelerate the thermal diffusivity, when the functionality obtains improving, structural more reasonable.

Drawings

FIG. 1 is a schematic diagram of the present invention.

Fig. 2 is an enlarged schematic view of the part a of the present invention from fig. 1.

Fig. 3 is a schematic view of the rear view structure of the present invention.

Fig. 4, fig. 5 and fig. 6 are all schematic internal structures of the present invention.

Fig. 7 is a schematic view of the internal structure of the mounting base of the present invention.

FIG. 8 is a schematic view of the cross-section B of the present invention, which is drawn from FIG. 7.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a cover body; 2. a glass plate; 3. a heat radiation fan; 4. a wind-collecting plate; 5. a harness tube; 501. a polyurethane sleeve; 502. a wire outlet hole; 503. a lamp socket; 6. inlaying a ring; 7. embedding strips; 701. a heat sink; 8. a fan line; 9. a wiring seat; 901. a wiring groove; 10. a mounting seat; 11. a microcontroller; 12. a transformer; 13. PT100 temperature sensor.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

As shown in figures 1 to 8:

the invention provides an intelligent security monitoring device, which comprises: the temperature control device comprises a cover body 1, a glass plate 2, a heat radiation fan 3, an air collecting plate 4, a wire harness pipe 5, a polyurethane sleeve 501, a wire outlet hole 502, a lamp holder 503, an insert ring 6, an insert strip 7, a heat radiation fin 701, a fan wire 8, a wire routing seat 9, a wire routing groove 901, a mounting seat 10, a microcontroller 11, a transformer 12 and a PT100 temperature sensor 13; the cover body 1 is of an arc-shaped shell structure, the front end surface and the rear end surface of the cover body are respectively embedded with a left radiating fan 3 and a right radiating fan 3, and the rear end of the cover body 1 is provided with an installation seat 10 of the shell seat structure; a wiring harness tube 5 penetrates between the mounting seat 10 and the cover body 1, and the part of the wiring harness tube 5 positioned on the cover body 1 is electrically connected with a lamp holder 503 for mounting a camera head; a microcontroller 11 and a transformer 12 are installed in a shell cavity of the mounting seat 10, and the microcontroller 11 and the transformer 12 are electrically connected with an external power supply and an existing camera power supply assembly; the electrical connection line of the microcontroller 11 and the transformer 12 runs into the wire harness tube 5 and is electrically connected with the lamp holder 503; the wire harness pipe 5 is provided with a circular wire outlet 502, wherein one group of fan wires 8 extends out of the wire outlet 502 and is electrically connected with the two groups of cooling fans 3 on the two sides of the cover body 1 in a control manner; the glass plate 2 is positioned in the shell of the cover body 1, is positioned at the front side of the cover body 1 and is provided with a circular lamp hole.

Wherein: the periphery of the heat dissipation fan 3 is also embedded with a circle of inlaid ring 6, that is, two sets of four heat dissipation fans 3 are installed on the cover body 1 together with the inlaid ring 6, and the two adjacent heat dissipation fans 3 are connected with an inlaid strip 7 together, and the inlaid strip 7 connects the two adjacent sets of heat dissipation fans 3 in a structure.

Wherein: the panel 7 and the panel ring 6 are made of aluminum alloy with good heat dissipation characteristics, and are of integral structures, and a row of heat dissipation fins 701 are arranged on the bottom side of the panel 7 to form a surface heat dissipation condition, so that the waste heat generated on the whole cover body 1 can be dissipated downwards, when the fan 3 is not in operation, the waste heat left on the cover body 1 is dissipated naturally, and the surface heat dissipation structure formed by the above structures is shown in fig. 1 and 3.

Wherein: the wiring seat 9 is a rectangular rubber seat structure, a T-shaped wiring groove 901 is formed in the rubber seat structure, the fan line 8 is wired in the groove cavity, the wiring regularity of the fan line 8 is improved, and the structural rationality is improved, as shown in fig. 2.

Wherein: the wind-collecting plates 4 are arc-shaped plate structures, are positioned on the inner cavity wall of the cover body 1 in a bilateral symmetry mode and are positioned on the third side of the front end of the wire harness pipe 5, the description structure is shown in fig. 4 and fig. 6, the two wind-collecting plates 4 are arranged in the cover body 1 and positioned on two sides of the wire harness pipe 5, and cold air blown in by the fan sets on two sides can be collected, so that air cannot flow out quickly, and is discharged outwards after being suspended for a period of time, and the wire harness pipe 5 on the inner side can realize heat exchange and heat dissipation conditions for a long time.

Wherein: a through hole is formed in the front side of the pipe of the harness pipe 5, and a polyurethane sleeve 501 with a cylindrical pipe structure is embedded in the through hole, the structure is shown in fig. 4 and 8, and the polyurethane sleeve 501 is inserted into the harness pipe 5 to form an extending upward extension pattern.

Wherein: the PT100 temperature sensor 13 is interference fitted in the polyurethane bushing 501, and an electrical connection line of the PT100 temperature sensor 13 is also routed in a lumen of the harness pipe 5, and is electrically connected with the microcontroller 11 and the transformer 12, as shown in fig. 4 and fig. 8, that is, the PT100 temperature sensor 13 is just located in the cover body 1, and senses the high-temperature gas generated in the cover body 1, and feeds back the command to the microcontroller 11 in the mounting base 10 shown in fig. 7 through the electrical connection line, according to the coding value range, the microcontroller 11 selectively feeds back the command to the cooling fan 3, so as to determine whether the cooling fan 3 is operating, and when the temperature in the cover body 1 is high and is greater than the range value of the microcontroller 11, the cooling fan 3 rotates to cool the harness pipe 5.

Wherein: the radiating fins 701 extend downwards to present a larger radiating range, the length of the radiating fins 701 is far larger than the vertical dimension of the cover body 1, the same inlaid strip 7 is of a Z-shaped bending structure, the length of the bottom side also extends downwards, the radiating range of the radiating structure is also increased, the heat dissipation performance of the inlaid strip 7 and the radiating fins 701 is utilized, the surface of the cover body 1 is subjected to surface-area heat dissipation, the heat dissipation performance is auxiliarily acted with the radiating fan 3, meanwhile, the heat generated in the rotating process of the radiating fan 3 is used for synchronously radiating, the heat is finally radiated from the cover body 1, and the surface is not radiated in a cavity, so that the heat of the wiring pipes 5 in the cover body 1 can not be increased to the maximum extent, and the structural rationality is further improved.

When in use: when the device is normally installed, the installation base 10 is installed on a building, and meanwhile, an electric component matched with the existing camera device is connected to the device, which is an electric connection mode in the prior art, the design is not additionally described, after the device is installed and used for a period of time, when the device is maintained, people often find that when the interior of the cover body 1 is opened for maintenance, the wire harness pipe 5 inside the device can be found to generate high temperature due to long-time electrifying work and electrifying work of the camera lamp installation base on the front side of the device, so that the wire harness pipe 5 is soft and deformed, particularly serious in summer, and weathers and skin breaking can be generated after the soft and deformation, after the heat dissipation structure with induction property is installed, the service life of the wire harness pipe 5 can be greatly prolonged, heat sensing work can be realized, the function characteristic of non-heat non-work is realized, and in terms of working principle, the PT100 temperature sensor 13 is just positioned in the cover body 1, the high-temperature gas generated in the cover body 1 is sensed, and an instruction is fed back to the microcontroller 11 in the mounting base 10 shown in fig. 7 through an electric connecting line, the microcontroller 11 selectively feeds back the instruction to the cooling fan 3 according to the coding numerical range, so that whether the cooling fan 3 operates or not is judged, and when the temperature in the cover body 1 is higher and is larger than the range value of the microcontroller 11, the cooling fan 3 rotates to cool the wire harness pipe 5.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims

1. The utility model provides an intelligent security monitoring device which characterized in that: the intelligent security monitoring device comprises a cover body (1), a glass plate (2), a cooling fan (3), an air collecting plate (4), a wire harness pipe (5), a polyurethane sleeve (501), a wire outlet hole (502), a lamp holder (503), an insert ring (6), an insert strip (7), a cooling fin (701), a fan wire (8), a wire routing seat (9), a wire routing groove (901), a mounting seat (10), a microcontroller (11), a transformer (12) and a PT100 temperature sensor (13); the heat-radiating cover is characterized in that the cover body (1) is of an arc-shaped shell structure, the front end surface and the rear end surface of the cover body are respectively embedded with a left heat-radiating fan and a right heat-radiating fan (3), and the rear end of the cover body (1) is provided with an installation seat (10) of a shell seat structure; a wiring harness tube (5) penetrates between the mounting seat (10) and the cover body (1), and the part of the wiring harness tube (5) positioned on the cover body (1) is electrically connected with a lamp holder (503) for mounting a camera head; a microcontroller (11) and a transformer (12) are installed in a shell cavity of the mounting seat (10), and the microcontroller (11) and the transformer (12) are electrically connected with an external power supply and an existing camera power supply assembly; the electric connection line of the microcontroller (11) and the transformer (12) runs into the wire harness tube (5) and is electrically connected with the lamp holder (503); the wire harness pipe (5) is provided with a circular wire outlet hole (502), wherein one group of fan wires (8) extend out of the wire outlet hole (502) and are electrically connected with the two groups of radiating fans (3) on the two sides of the cover body (1) in a control way; the glass plate (2) is positioned in the shell of the cover body (1), is positioned at the front side of the cover body (1) and is provided with a circular lamp hole;

a circle of inlaid ring (6) is also inlaid at the periphery of each radiating fan (3), and inlaid strips (7) are connected between two adjacent radiating fans (3);

the gib (7) and the gib ring (6) are made of aluminum alloy materials and are of integral structures, and a row of radiating fins (701) are arranged on the bottom side of the gib (7);

the wiring seat (9) is of a rectangular rubber seat structure, a T-shaped wiring groove (901) is formed in the wiring seat, and a fan wire (8) is wired in a groove cavity;

the wind collecting plates (4) are of arc-shaped plate structures, are positioned on the inner cavity wall of the cover body (1) in a bilateral symmetry mode, and are positioned on the third side of the front end of the wire harness pipe (5);

a through hole is formed in the position, close to the front side, of the pipeline of the wire harness pipe (5), and a polyurethane sleeve (501) with a cylindrical pipe structure is embedded in the through hole;

the PT100 temperature sensor (13) is in interference fit in the polyurethane sleeve (501), and an electrical connecting wire of the PT100 temperature sensor (13) is also wired in a tube cavity of the wire harness tube (5) and is electrically connected with the microcontroller (11) and the transformer (12) in a control way;

the radiating fins (701) extend downwards, the length of the radiating fins is far greater than the vertical size of the cover body (1), the same gibs (7) are of Z-shaped bending structures, and the length of the bottom side of the radiating fins also extends downwards.