CN215647903U - Machine room power monitoring device based on Internet of things - Google Patents

Abstract

The utility model provides a machine room power monitoring device based on the Internet of things, which comprises: the mounting structure comprises a shell and a mounting groove arranged on the shell; the mounting grooves are arranged in parallel along the longitudinal direction of the shell; further comprising: the heat dissipation device and the environment monitor are arranged in different mounting grooves; the heat dissipation device comprises a heat dissipation shell, a radiator, a heat dissipation groove and a heat inductor; the heat radiator is arranged in the heat radiation shell, the heat radiation groove and the heat inductor are both fixed on the front end face of the heat radiation shell, and the heat radiation groove is used for providing a heat radiation channel for the heat radiator; the heat inductor is electrically connected with the radiator and used for monitoring the temperature of the machine room power monitoring device and controlling the operating power of the radiator according to the temperature. The utility model can solve the technical problem that the power monitoring device of the machine room cannot radiate the power monitoring device.

Description

Machine room power monitoring device based on Internet of things

Technical Field

The utility model relates to the field of machine rooms, in particular to a machine room power monitoring device based on the Internet of things.

Background

Along with the development of the network era, more and more computers and related control equipment are stored in a machine room, so that the environment of the machine room is very important, and in order to avoid equipment damage caused by poor environment, a machine room power environment monitoring device based on the internet of things is generally adopted to monitor the internal environment of the machine room.

In the prior art, although the machine room power environment monitoring device based on the internet of things can monitor the environment of a machine room, the machine room power environment monitoring device is lack of a heat dissipation function, and can generate a large amount of heat in long-term operation work.

However, the heat is accumulated inside the machine room power environment monitoring device based on the internet of things, which not only affects the normal operation of the machine room power environment monitoring device, but also may cause equipment damage.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a machine room power monitoring device based on the Internet of things, which can solve the technical problem that the machine room power monitoring device cannot radiate heat of the machine room power monitoring device.

The utility model provides a machine room power monitoring device based on the Internet of things, which comprises: the mounting groove is arranged on the shell;

the mounting grooves are arranged in parallel along the longitudinal direction of the shell;

further comprising: the heat dissipation device and the environment monitor are arranged in different mounting grooves; wherein,

the heat dissipation device comprises a heat dissipation shell, a heat radiator, a heat dissipation groove and a heat inductor;

the heat radiator is arranged in the heat radiation shell, the heat radiation groove and the heat sensor are both fixed on the front end face of the heat radiation shell, and the heat radiation groove is used for providing a heat radiation channel for the heat radiator;

the heat inductor is electrically connected with the radiator and used for monitoring the temperature of the machine room power monitoring device and controlling the operating power of the radiator according to the temperature.

Optionally, the environment monitor includes a wireless transmission device, an infrared photosensitive device and a display screen;

the infrared photosensitive device and the display screen are both positioned on the front end face of the environment monitor, and the wireless transmission device is arranged on the top end face of the environment monitor;

the infrared photosensitive device is electrically connected with the wireless transmission device, and the wireless transmission device is wirelessly connected with handheld equipment of a worker;

the infrared photosensitive device is used for monitoring the size and the number of winged insects in the machine room;

the wireless transmission device is used for transmitting the winged insect information monitored by the infrared photosensitive device to the handheld equipment of the staff.

Optionally, the infrared photosensitive device includes a fresnel lens, a pyroelectric sensor, a band-pass amplifier, a comparator, and a light control circuit;

and the two groups of infrared light sensing devices are respectively positioned at two sides of the display screen.

Optionally, the environment monitor further comprises a temperature sensor, a humidity sensor and a smoke sensor;

the temperature sensor, the humidity sensor and the smoke sensor are all connected with a control panel, and the control panel is connected with the display screen;

the display screen is used for displaying data of the machine room environment monitored by the temperature sensor, the humidity sensor and the smoke sensor.

Optionally, the mounting groove is provided with a dust-proof device, and the dust-proof device is arranged in one mounting groove; wherein,

the heat dissipation device is located at the upper end of the environment monitor, and the dustproof device is arranged at the lower end of the environment monitor.

Optionally, the dust-proof device comprises a dust suction groove, a dust storage box and a fan;

the dust suction groove is arranged on the front end face of the dustproof device;

the dust storage box is inserted into the dustproof device and can be drawn out relative to the dustproof device;

the fan is arranged in the dustproof device and is opposite to the dust suction groove.

Optionally, the dust-proof device further comprises a first switch button and a second switch button; wherein,

the first switch button and the second switch button are both arranged on the front end face of the dustproof device;

the first switch button is electrically connected with the fan and used for controlling the on and off of the fan;

the second switch button is used for controlling the opening and locking of the dust storage box.

Optionally, a thermistor is arranged in the heat sensor;

the resistance value of the thermistor is reduced along with the increase of the temperature, so that the power of the radiator is increased along with the increase of the temperature.

Optionally, the radiator is a plurality of pneumatic motors.

Optionally, the housing is a cuboid cabinet-shaped structure, the housing comprises a side wall, a top plate and a bottom plate, wherein,

the side wall is arranged between the top plate and the bottom plate and is fixedly connected with the top plate and the bottom plate;

the side wall, the top plate and the bottom plate of the shell are all anti-corrosion plates;

a signal terminal is arranged on the top plate of the shell;

and the bottom plate of the shell is provided with rollers.

Optionally, the distance sensing device is arranged on the side wall of the shell;

the distance sensing device is used for measuring the distance from the shell to equipment in the machine room.

The machine room power monitoring device based on the Internet of things is provided with the heat dissipation device, so that heat dissipation processing can be performed on the machine room power monitoring device. In addition, the heat sensor is arranged to monitor the machine room power monitoring device, and the heat dissipation power of the radiator is controlled according to the temperature of the machine room power monitoring device, so that the machine room power monitoring device can be accurately controlled, and energy is saved.

According to the machine room power monitoring device based on the Internet of things, the infrared photosensitive device is arranged on the environment monitor, so that the winged insects in the machine room can be monitored, the winged insects entering the machine room can be processed in time, and the damage of the winged insects to equipment in the machine room is reduced.

According to the machine room power monitoring device based on the Internet of things, the dust prevention device is arranged, dust accumulated on the machine room power monitoring device can be conveniently treated, and the dust storage box is arranged to collect the dust, so that secondary pollution is prevented.

Drawings

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

Fig. 1 is a schematic structural diagram of an embodiment of a machine room power monitoring device based on the internet of things;

fig. 2 is a schematic structural diagram of a heat dissipation device of an embodiment of the machine room power monitoring device based on the internet of things;

FIG. 3 is a schematic structural diagram of an environment monitor of an embodiment of the machine room power monitoring device based on the Internet of things;

fig. 4 is a schematic structural diagram of a dustproof device of an embodiment of the machine room power monitoring device based on the internet of things;

fig. 5 is a schematic view of the working principle of the machine room power monitoring device based on the internet of things.

Description of reference numerals:

10: a machine room power monitoring device;

20: a housing;

21: mounting grooves;

22: a heat sink;

221: a heat dissipating housing;

222: a heat sink;

223: a heat sensor;

224: a heat sink;

23: an environmental monitor;

231: a wireless transmission device;

232: an infrared light sensing device;

233: a display screen;

24: a dust-proof device;

241: a dust suction groove;

242: a dust storage box;

243: a first switch button;

244: a second switch button;

25: a distance sensing device;

26: a side wall;

261: a dust-proof plate;

27: a top plate;

28: a base plate;

29: a signal terminal;

30: a roller;

40: a handheld device;

50: and a control panel.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, 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 some, but not all, embodiments of the present invention. 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.

The terms "comprises" and "comprising," and any variations thereof, in the description and claims of this invention and the above-described drawings, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

An exemplary application scenario of the embodiment of the present invention is described below.

Example one

Fig. 1 is a schematic structural diagram of an embodiment of a machine room power monitoring device based on the internet of things; fig. 2 is a schematic structural diagram of a heat dissipation device of an embodiment of the machine room power monitoring device based on the internet of things; FIG. 3 is a schematic structural diagram of an environment monitor of an embodiment of the machine room power monitoring device based on the Internet of things; fig. 4 is a schematic structural diagram of a dustproof device of an embodiment of the machine room power monitoring device based on the internet of things; fig. 5 is a schematic view of the working principle of the machine room power monitoring device based on the internet of things.

As shown in fig. 1, the utility model provides a machine room power monitoring device 10 based on the internet of things, which includes: the environment monitoring device comprises a shell 20, a heat radiator 22, an environment monitor 23 and a dustproof mechanism, wherein a plurality of mounting grooves 21 are arranged on the shell 20, the mounting grooves 21 are arranged on a side wall 26 positioned on the front end surface of the shell 20, three mounting grooves 21 are arranged in parallel along the longitudinal direction (the direction a in the drawing) of the shell 20, and the heat radiator 22 is arranged in the mounting groove 21 positioned at the uppermost end of the shell 20 and is fixedly connected with the mounting groove 21; the environment monitor 23 is arranged in the mounting groove 21 below the heat sink 22 and is fixedly connected with the mounting groove 21; the dustproof mechanism is arranged in the lower mounting groove 21 of the environment monitor 23 and is detachably connected with the mounting groove 21.

In this embodiment, the casing 20 is a rectangular cabinet-shaped structure, and the casing 20 includes a side wall 26, a top plate 27 and a bottom plate 28, wherein the side wall 26 is disposed between the top plate 27 and the bottom plate 28 and fixedly connected to both the top plate 27 and the bottom plate 28, and specifically, the four side walls 26 are disposed around the top plate 27 and the bottom plate 28, so that the whole casing 20 is a rectangular cabinet-shaped structure; the side wall 26, the top plate 27 and the bottom plate 28 are all corrosion-resistant plates; in addition, a signal transmitting device is provided on the top plate 27 of the housing 20, a wheel 30 is provided on the bottom plate 28 of the housing 20, and four wheels 30 are rotatably mounted on the bottom plate 28 of the housing 20 by fixing bars.

Further, as shown in fig. 1, a signal terminal 29 may be further disposed on the top plate 27 of the housing 20, the signal terminal 29 is connected to the environment monitor 23, and the signal terminal 29 is configured to transmit the environment data monitored by the environment monitor 23 to the control board 50, and then transmit the environment data to the handheld device 40 of the staff through the wireless transmission device 231, so that the staff can conveniently view the environment data of the machine room in real time.

It should be noted that the handheld device 40 may be a terminal device such as a computer, a mobile phone, and a tablet computer.

As shown in fig. 2, in a further embodiment of the present application, a heat sink 22 may be installed in the installation groove 21 located at the uppermost end of the case 20, and the heat sink 22 may include a heat dissipation case 221, a heat sink 224, a heat dissipation groove 222, and a heat sensor 223; a radiator 224 (not shown in the figure) is arranged inside the heat dissipation casing 221, and the radiator 224 is used for radiating heat for the machine room power monitoring device 10; the heat dissipation groove 222 and the heat sensor 223 are fixed to the front end surface of the heat dissipation housing 221.

Further, the heat dissipation groove 222 may include a plurality of bar-shaped plate-shaped structures, and the plurality of bar-shaped plate-shaped structures are disposed at intervals on the heat dissipation housing 221 so as to form a heat dissipation channel between the plurality of bar-shaped plate-shaped structures; the heat sensor 223 is electrically connected to the radiator 224, and the heat sensor 223 is configured to monitor the temperature of the machine room power monitoring apparatus 10 and control the operating power of the radiator 224 according to the temperature, so as to achieve the effect that the higher the temperature is, the higher the power of the radiator 224 is, and the lower the temperature is, the lower the power of the radiator 224 is.

It should be noted that the heat sensor 223 may include a temperature sensor and a thermistor connected to each other, wherein the resistance of the thermistor may decrease with the temperature, so that the power of the heat sink 224 increases with the temperature, so as to achieve the effect that the power of the heat sink 224 increases with the temperature, and the power of the heat sink 224 decreases with the temperature.

In addition, the technical solution of the present application includes, but is not limited to, implementing control of the power of the heat sink 224 by using a thermistor, and implementing control of the power of the heat sink 224 by using other methods as long as the operating power of the heat sink 224 can be increased along with the increase of the temperature.

Further, the heat dissipation housing 221 is provided with a fixing groove for installing the heat dissipation groove 222 and the heat sensor 223, and the heat dissipation groove 222 and the heat sensor 223 are fixed on the front end surface of the heat dissipation housing 221 through the fixing groove.

It should be noted that the shape of the fixing groove does not limit the protection scope of the present invention, and the fixing groove may be specifically set according to the shapes of the heat dissipation groove 222 and the heat sensor 223, and any fixing groove that can fix the heat dissipation groove 222 and the heat sensor 223 to the heat dissipation housing 221 falls within the protection scope of the present invention.

Further, in this embodiment, the heat sink 224 may be a plurality of small pneumatic motors, which are small in size and convenient to set, so that the mass of the heat sink 22 can be effectively reduced, and the mass of the machine room power monitoring device 10 can be reduced, thereby making the machine room power monitoring device 10 more portable.

The heat sink 224 is not limited to the pneumatic motor, and may have other heat dissipation structures as long as the heat dissipation structure can dissipate heat, which falls within the scope of the present invention.

The machine room power monitoring device 10 based on the internet of things in the embodiment can realize heat dissipation of the machine room power monitoring device by arranging the heat dissipation device 22, so that normal operation of the machine room power monitoring device is guaranteed. In addition, the heat sensor 223 is arranged to monitor the heat generated by the machine room power monitoring device 10, and the heat dissipation power of the heat sink 224 is controlled according to the temperature of the machine room power monitoring device 10, so that the machine room power monitoring device 10 can be accurately cooled, and energy is saved.

As shown in fig. 3, in a further embodiment of the present application, the environment monitor 23 comprises a wireless transmission device 231, an infrared photosensitive device 232 and a display screen 233; the infrared photosensitive device 232 and the display screen 233 are both positioned on the front end face of the environment monitor 23, and the wireless transmission device 231 is arranged on the top end face of the environment monitor 23; the infrared light sensing device 232 is electrically connected with the wireless transmission device 231, and the wireless transmission device 231 is wirelessly connected with the handheld equipment 40 of the staff; the infrared photosensitive device 232 is used for monitoring the size and the number of winged insects in the machine room; the wireless transmission device 231 is used for transmitting the flying insect information monitored by the infrared photosensitive device 232 to the handheld equipment 40 of the staff.

It should be noted that, an installation part for installing the infrared photosensitive device 232 and the display screen 233 is arranged on the environment monitor 23, and the infrared photosensitive device 232 and the display screen 233 are both connected with the installation part in a sealing manner, so that the internal structure of the environment monitor 23 can be prevented from being affected with moisture.

In this embodiment, there are two groups of infrared sensing devices 232, and the two groups of infrared sensing devices 232 are respectively located at two sides of the display screen 233; the infrared sensing device 232 includes a fresnel lens, a pyroelectric sensor, a band-pass amplifier, a comparator and a light control circuit.

In the practical application process, infrared rays radiated by an object are focused and concentrated through the Fresnel lens so as to improve the detection sensitivity; the sensing distance can be increased through the pyroelectric sensor so as to enlarge the monitoring range; can make infrared photosensitive device 232 play the effect at the homoenergetic round the clock through light-operated circuit, can make things convenient for the winged insect in the response environment through two sets of infrared photosensitive device 232 like this, fly into the computer lab in the winged insect, infrared photosensitive device 232 senses the infrared ray wavelength of winged insect, then through wireless transmission device 231 in with information transfer to staff's handheld device 40, can make the staff learn the size and the quantity of winged insect fast what, make things convenient for the staff to clear up as early as possible, inside in order to prevent to get into equipment because of the winged insect, and lead to the inside components and parts of equipment to damage. As shown in fig. 5, the machine room power monitoring apparatus 10 based on the internet of things in the embodiment may further include a control board 50, where the control board 50 is configured to control the operation of the whole machine room power monitoring apparatus 10. The control board 50 is connected with the display screen 233, the signal terminal 29, the wireless transmission device 231, the heat sensor 223 and the heat sink 224, and when the control board is in operation, the signal terminal 29 can be used for receiving and transmitting data information of the environment monitor 23 and data information of the distance sensing device 25; the control board 50 can transmit the information received by the signal terminal 29 to the display screen 233, and also can transmit the information received by the signal terminal 29 to the handheld device 40 of the worker through the wireless transmission device 231, so that the information such as data of the environment in the machine room can be checked through the display screen 233 and the handheld device 40 of the worker. The control board 50 may also be connected to the heat sensor 223 and the pneumatic motor, so that the working power of the pneumatic motor is controlled by the data information monitored by the heat sensor 223.

It should be noted that, the machine room power monitoring device 10 based on the internet of things in this embodiment may further include a power supply, and the power supply is connected with the control board 50 and is used for providing electric energy.

Further, the environmental monitor 23 further includes a temperature sensor, a humidity sensor, and a smoke sensor control board 50; the temperature sensor, the humidity sensor and the smoke sensor are all connected with the control panel 50, and the control panel 50 is connected with the display screen 233; the display screen 233 is used for displaying data of the machine room environment monitored by the temperature sensor, the humidity sensor and the smoke sensor.

In the practical application process, the temperature sensor is used for monitoring the temperature of the machine room, the humidity sensor is used for monitoring the humidity of the machine room, the smoke sensor is used for monitoring the smoke of the machine room, the temperature sensor, the humidity sensor and the smoke sensor transmit the monitored data to the control panel 50, and the control panel 50 is connected with the display screen 233, so that the environmental data of the machine room on the same day can be seen on the display screen 233.

It should be noted that the sensors arranged on the environment monitor 23 are not limited to the temperature sensor, the humidity sensor and the smoke sensor, and other sensors may be arranged if other data of the environment in the machine room need to be monitored, and any device arranged to monitor the environment in the machine room is within the protection scope of the technical solution of the present application.

In a further embodiment of the present application, as shown in fig. 4, the dust-proof device 24 is disposed in one of the mounting grooves 21; wherein, the heat sink 22 is located at the upper end of the environment monitor 23, and the dust-proof device 24 is arranged at the lower end of the environment monitor 23.

Further, the dust-proof device 24 includes a dust suction groove 241, a dust storage box 242, and a fan; the dust suction groove 241 is provided at the front end surface of the dust-proof device 24; the dust storage box 242 is inserted into one side of the dust-proof device 24, and the dust storage box 242 is drawn out with respect to the dust-proof device 24; the fan is disposed inside the dust prevention device 24 and opposite to the dust suction groove 241.

It should be noted that the dust storage box 242 may be drawn out from one side of the dust-proof device 24, or may be drawn out from a front end surface where the dust suction groove 241 is provided, and the structure of the dust storage box 242 does not limit the protection scope of the present invention, and it belongs to the protection scope of the present invention that the dust storage box 242 can store dust and can be drawn out from the dust-proof device 24.

Further, the dust suction groove 241 in the present embodiment may be a plate-shaped structure provided with a plurality of through holes. The dust suction groove 241 may have another structure, and a specific shape may be set according to specific circumstances as long as dust can be easily sucked.

Further, the dust-proof device 24 further includes a first switch button 243 and a second switch button 244; wherein, the first switch button 243 and the second switch button 244 are both arranged on the front end surface of the dust-proof device 24; the first switch button 243 is electrically connected with the fan, and the first switch button 243 is used for controlling the on and off of the fan; the second switch button 244 is used to control the opening and locking of the dust storage bin 242.

It should be noted that the dust-proof device 24 includes a dust suction groove 241 and a cavity structure surrounded by the side wall of the dust storage box 242, and a fan (not shown) is disposed in the cavity, and the fan can be fixed on the top end surface of the cavity, and the fan is opposite to the dust suction groove 241, so that the dust can be sucked into the dust storage box 242 from the dust suction groove 241, and then the dust can be collected. The type of the fan is not limited herein, and it is within the scope of the present disclosure as long as the fan can suck dust into the dust storage box 242.

In this embodiment, through the dust keeper 24 who sets up, can deposit the case 242 with dust initiative inspiration, can open the fan of dust keeper 24 through first shift knob 243 among the dust keeper 24, after a period of time, the staff can close first shift knob 243 to open second shift knob 244, then deposit case 242 with the dust and take out, and deposit case 242 with the dust and take out and clear up, deposit case 242 through setting up fan and dust like this and can conveniently collect the dust, prevent secondary pollution.

It should be noted that, a monitoring device may be further disposed on the dust-proof device 24, and the monitoring device is configured to monitor the volume and the quality of the dust in the dust storage box 242, and when the monitoring device monitors that the dust in the dust storage box 242 is too much accumulated, the monitoring device may send a cleaning signal to notify the worker to clean the dust storage box 242.

According to the machine room power monitoring device 10 based on the Internet of things, the dust prevention device 24 is arranged, dust accumulated on the machine room power monitoring device 10 can be conveniently treated, and the dust storage box 242 is arranged to collect the dust, so that secondary pollution is prevented.

Further, a distance sensing device 25 may be further disposed on the side wall 26 of the housing 20, a dust-proof plate 261 may be further disposed on the same side wall 26 where the sensing device is disposed, the dust-proof plate 261 may be used for dust prevention, and the distance sensing device 25 may be used for measuring a distance from the housing 20 to equipment in the machine room.

Specifically, the distance sensing device 25 converts the physical variation amount from the monitoring device to the object into the distance, so that the problem that the distance between the devices cannot pass through due to too small distance can be avoided when the machine room power monitoring device is moved and placed.

The machine room power monitoring device 10 based on the internet of things is provided with the heat dissipation device 22, so that heat dissipation processing can be performed on the machine room power monitoring device 10. In addition, the heat sensor 223 is arranged to monitor the machine room power monitoring device 10, and the heat dissipation power of the heat radiator 224 is controlled according to the temperature of the machine room power monitoring device 10, so that the machine room power monitoring device 10 can be accurately controlled, and energy is saved.

According to the machine room power monitoring device 10 based on the Internet of things, the infrared photosensitive device 232 is arranged on the environment monitor 23, so that flying insects in a machine room can be monitored, the flying insects entering the machine room can be timely processed, and damage of the flying insects to equipment in the machine room is reduced.

According to the machine room power monitoring device 10 based on the Internet of things, the dust prevention device 24 is arranged, dust accumulated on the machine room power monitoring device 10 can be conveniently treated, and the dust storage box 242 is arranged to collect the dust, so that secondary pollution is prevented.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be considered as limiting the present invention.

Unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integral to one another; either directly or indirectly through intervening media, may be used in either the internal or the external relationship of the two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations. Furthermore, the terms "first", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the utility model has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. The utility model provides a computer lab power monitoring device based on thing networking which characterized in that includes: the mounting groove is arranged on the shell;

the mounting grooves are arranged in parallel along the longitudinal direction of the shell;

further comprising: the heat dissipation device and the environment monitor are arranged in different mounting grooves; wherein,

the heat dissipation device comprises a heat dissipation shell, a heat radiator, a heat dissipation groove and a heat inductor;

the heat radiator is arranged in the heat radiation shell, the heat radiation groove and the heat sensor are both fixed on the front end face of the heat radiation shell, and the heat radiation groove is used for providing a heat radiation channel for the heat radiator;

the heat inductor is electrically connected with the radiator and used for monitoring the temperature of the machine room power monitoring device and controlling the operating power of the radiator according to the temperature.

2. The machine room power monitoring device based on the Internet of things of claim 1, wherein the environment monitor comprises a wireless transmission device, an infrared photosensitive device and a display screen;

the infrared photosensitive device and the display screen are both positioned on the front end face of the environment monitor, and the wireless transmission device is arranged on the top end face of the environment monitor;

the infrared photosensitive device is electrically connected with the wireless transmission device, and the wireless transmission device is wirelessly connected with handheld equipment of a worker;

the infrared photosensitive device is used for monitoring the size and the number of winged insects in the machine room;

the wireless transmission device is used for transmitting the winged insect information monitored by the infrared photosensitive device to the handheld equipment of the staff.

3. The machine room power monitoring device based on the Internet of things of claim 2,

the infrared photosensitive device comprises a Fresnel lens, a pyroelectric sensor, a band-pass amplifier, a comparator and a light control circuit;

and the two groups of infrared light sensing devices are respectively positioned at two sides of the display screen.

4. The machine room power monitoring device based on the internet of things as claimed in claim 3, wherein the environment monitor further comprises a temperature sensor, a humidity sensor and a smoke sensor;

the temperature sensor, the humidity sensor and the smoke sensor are all connected with a control panel, and the control panel is connected with the display screen;

the display screen is used for displaying data of the machine room environment monitored by the temperature sensor, the humidity sensor and the smoke sensor.

5. The machine room power monitoring device based on the Internet of things as claimed in any one of claims 1 to 4, further comprising a dustproof device, wherein the dustproof device is arranged in one of the mounting grooves; wherein,

the heat dissipation device is located at the upper end of the environment monitor, and the dustproof device is arranged at the lower end of the environment monitor.

6. The machine room power monitoring device based on the Internet of things of claim 5, wherein the dustproof device comprises a dust suction groove, a dust storage box and a fan;

the dust suction groove is arranged on the front end face of the dustproof device;

the dust storage box is inserted into the dustproof device and can be drawn out relative to the dustproof device;

the fan is arranged in the dustproof device and is opposite to the dust suction groove.

7. The machine room power monitoring device based on the Internet of things of claim 6,

the dustproof device also comprises a first switch button and a second switch button; wherein,

the first switch button and the second switch button are both arranged on the front end face of the dustproof device;

the first switch button is electrically connected with the fan and used for controlling the on and off of the fan;

the second switch button is used for controlling the opening and locking of the dust storage box.

8. The machine room power monitoring device based on the Internet of things as claimed in any one of claims 1 to 4, wherein the radiator is a plurality of pneumatic motors.

9. The machine room power monitoring device based on the Internet of things as claimed in any one of claims 1 to 4, wherein the housing is of a rectangular cabinet-shaped structure, the housing comprises side walls, a top plate and a bottom plate, wherein,

the side wall is arranged between the top plate and the bottom plate, and the side wall is fixedly connected with the top plate and the bottom plate;

the side wall, the top plate and the bottom plate of the shell are all anti-corrosion plates;

a signal terminal is arranged on the top plate of the shell;

the bottom plate of the shell is provided with rollers.

10. The machine room power monitoring device based on the Internet of things as claimed in any one of claims 1 to 4, further comprising a distance sensing device, wherein the distance sensing device is arranged on a side wall of the shell;

the distance sensing device is used for measuring the distance from the shell to equipment in the machine room.

Images