CN211374894U - Monitoring device for environmental electromagnetic waves - Google Patents

Abstract

The application discloses monitoring devices of environment electromagnetic wave, the signal transmission pole is installed to the organism upper end, the second mounting disc has been cup jointed to the periphery of signal transmission pole, the second sleeve pipe is installed to the lower extreme of second mounting disc, second sleeve pipe lower extreme is equipped with sealed second sheathed tube first shielding apron, first detection chip is installed to the periphery of signal transmission pole, first wave absorption plate is installed to the periphery of first detection chip, be equipped with a plurality of second wave absorption holes on the second sleeve pipe, first mounting disc is still installed to the periphery of signal transmission pole, first sleeve pipe is installed to the lower extreme of first mounting disc, first sheathed tube lower extreme is equipped with sealed first sheathed tube second shielding apron, be equipped with a plurality of first wave absorption holes on the first sleeve pipe, the second detects the chip is installed to the periphery of signal transmission pole, install the second wave absorption plate on the second detects the chip, be equipped with the installation cavity in the organism, the singlechip that the signal transmission pole is connected is installed to the installation cavity. The utility model discloses can effectively improve the monitoring efficiency of environment electromagnetic wave.

Description

Monitoring device for environmental electromagnetic waves

Technical Field

The utility model relates to a monitoring facilities's technical field especially relates to an environmental electromagnetic wave's monitoring devices.

Background

Along with the development of economy and the improvement of living standard of people, the types and the number of household electrical appliance products are more and more. Especially in recent years, with the ever-increasing level of people's material culture, various household appliances such as: color TV, computer, microwave oven, electromagnetic oven, wireless telephone, mobile phone, etc. enter into thousands of households. Meanwhile, a plurality of high-voltage electric transmission lines, relay stations of a mobile phone network and the like are built around the users. These household appliances and electronic devices emit and leak electromagnetic waves of a certain intensity to the environmental space during use. Human beings living for a long time and exposed to electromagnetic wave radiation in an environment exceeding a safe dose can be killed or killed in a large area, and various diseases can be caused. According to statistics of relevant departments, electromagnetic wave radiation has become an important pollution source influencing the life of people nowadays.

Most of electromagnetic wave monitoring devices in the prior art adopt an integrated design, and a wave absorption plate is adopted for absorbing non-low-frequency electromagnetic waves and high-frequency electromagnetic waves, so that the electromagnetic wave acquisition efficiency is greatly reduced, and the accuracy of environmental electromagnetic wave data acquisition is reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that overcome prior art not enough and provide an environmental electromagnetic's monitoring devices.

Solve the technical problem, the utility model discloses take following technical scheme:

a monitoring device for environmental electromagnetic waves comprises a base, a machine body is mounted at the upper end of the base, a display screen is arranged on the machine body, a signal transmission rod is mounted at the upper end of the machine body, a second mounting disc is sleeved on the periphery of the signal transmission rod, a second sleeve is mounted at the lower end of the second mounting disc, a first shielding cover plate for sealing the second sleeve is arranged at the lower end of the second sleeve, a second detection cavity is formed by the second sleeve and the first shielding cover plate, a first detection chip is mounted on the periphery of the signal transmission rod, a first wave absorption plate is mounted on the periphery of the first detection chip, a plurality of second wave absorption holes communicated with the second detection cavity are formed in the second sleeve, a first mounting disc is further mounted on the periphery of the signal transmission rod, a first sleeve is mounted at the lower end of the first mounting disc, a second shielding cover plate for sealing the first sleeve is arranged at the lower end of the first sleeve, and a first detection cavity is, be equipped with a plurality of first wave absorption holes that communicate with first detection chamber on the first sleeve pipe, the periphery of signal transmission pole just installs the second in first detection intracavity and detects the chip, and the second is detected and is installed the second on the chip and inhale the ripples board, is equipped with the installation cavity in the organism, installs the singlechip that signal transmission pole is connected in the installation cavity.

In the embodiment of the present invention, the aperture of the first wave absorbing hole is larger than the aperture of the second wave absorbing hole.

The embodiment of the utility model provides an in, be equipped with first shielding sleeve pipe between first shielding apron and the signal transmission pole.

The embodiment of the utility model provides an in, be equipped with second shielding sleeve between second shielding apron and the signal transmission pole.

The embodiment of the utility model provides an in, the install bin is installed to the singlechip upper end, installs gaseous detection chamber in the install bin, is equipped with a plurality of air inlets on the organism, is equipped with a plurality of air inlet channels that run through install bin and organism in the organism, and air inlet channel and gaseous detection chamber intercommunication are installed the third in the gaseous detection chamber and are detected the chip, install a plurality of gaseous detection probe on the third detects the chip.

In the embodiment of the utility model, the thickness of the first wave-absorbing plate is less than that of the second wave-absorbing plate.

The utility model has the advantages that: when in use, low-frequency electromagnetic waves can enter the second detection cavity through the second wave-absorbing hole, the low-frequency electromagnetic waves are absorbed by the first wave-absorbing plate in the second detection cavity and then are acquired by the first detection chip, the acquired data enter the single chip microcomputer through the signal transmission rod to be processed, the processed data are displayed on the display screen, high-frequency electromagnetic waves can enter the first detection cavity through the first wave-absorbing hole and are absorbed by the second wave-absorbing plate in the first detection cavity, then the second detection chip is used for data acquisition, the acquired data enters the single chip microcomputer for processing through the signal transmission rod, therefore, data acquisition of the high-frequency and low-frequency electromagnetic waves can be realized, data acquisition and analysis of the low-frequency and high-frequency electromagnetic waves in the environment are improved, display is carried out on the display screen, and the electromagnetic wave monitoring efficiency is improved.

Other features and advantages of the present invention will be disclosed in more detail in the following detailed description and the accompanying drawings.

Drawings

Fig. 1 is a schematic structural diagram of a device for monitoring environmental electromagnetic waves according to the present invention;

fig. 2 is a cross-sectional view of a second sleeve of the device for monitoring environmental electromagnetic waves of the present invention;

fig. 3 is a cross-sectional view of a first sleeve in the device for monitoring environmental electromagnetic waves of the present invention;

fig. 4 is a cross-sectional view of the body of the device for monitoring environmental electromagnetic waves of the present invention.

The figures are numbered:

1. a base; 2. a body; 3. a display screen; 4. a signal transmission rod; 5. an air inlet; 6. a first sleeve; 7. a first wave absorption hole; 8. a second mounting plate; 9. a second sleeve; 10. a second wave absorption hole; 11. a first mounting plate; 12. a first detection chip; 13. a first absorber plate; 14. a first shielding sleeve; 15. a second detection chamber; 16. a first shielding cover plate; 17. a second detection chip; 18. a second wave absorbing plate; 19. a first detection chamber; 20. a second shielding cover plate; 21. a second shielding sleeve; 22. a single chip microcomputer; 23. an air inlet channel; 24. installing a box; 25. a gas detection chamber; 26. a gas detection probe; 27. a third detection chip; 28. and (7) installing a cavity.

Detailed Description

The technical solutions of the embodiments of the present invention are explained and explained below with reference to the drawings of the embodiments of the present invention, but the embodiments described below are only preferred embodiments of the present invention, and not all embodiments. Based on the embodiments in the embodiment, other embodiments obtained by those skilled in the art without any creative work belong to the protection scope of the present invention.

In the following description, the appearances of the indicating orientation or positional relationship, such as the terms "inner", "outer", "upper", "lower", "left", "right", etc., are only for convenience in describing the embodiments and for simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and are not to be construed as limiting the invention.

Referring to fig. 1-4, an environmental electromagnetic wave monitoring device provided by the embodiment of the present invention includes a base 1, a body 2 is installed on the upper end of the base 1, a display screen 3 is disposed on the body 2, a signal transmission rod 4 is installed on the upper end of the body 2, a second mounting plate 8 is sleeved on the periphery of the signal transmission rod 4, a second sleeve 9 is installed on the lower end of the second mounting plate 8, a first shielding cover plate 16 for sealing the second sleeve 9 is disposed on the lower end of the second sleeve 9, the second sleeve 9 and the first shielding cover plate 16 form a second detection cavity 15, a first detection chip 12 is installed on the periphery of the signal transmission rod 4, a first wave absorbing plate 13 is installed on the periphery of the first detection chip 12, a plurality of second wave absorbing holes 10 communicated with the second detection cavity 15 are disposed on the second sleeve 9, a first mounting plate 11 is also installed on the periphery of the signal transmission rod 4, a first sleeve 6 is installed on the lower end of the first mounting plate 11, the lower extreme of first sleeve pipe 6 is equipped with sealed first sleeve pipe 6's second shielding apron 20, first sleeve pipe 6 forms first detection chamber 19 with second shielding apron 20, be equipped with a plurality of first wave absorption holes 7 that communicate with first detection chamber 19 on the first sleeve pipe 6, the periphery of signal transmission pole 4 just installs the second in first detection chamber 19 and detects chip 17, install second wave absorption plate 18 on the second detects chip 17, be equipped with installation cavity 28 in the organism 2, install the singlechip 22 that signal transmission pole 4 connects in the installation cavity 28. When the device is used, low-frequency electromagnetic waves can enter the second detection cavity 15 through the second wave absorption hole 10, the low-frequency electromagnetic waves are absorbed by the first wave absorption plate 13 in the second detection cavity 15 and then are subjected to data acquisition through the first detection chip 12, the acquired data enter the single chip microcomputer 22 through the signal transmission rod 4 to be processed, the processed data are displayed on the display screen 3, high-frequency electromagnetic waves can enter the first detection cavity 19 through the first wave absorption hole 7, the high-frequency electromagnetic waves are absorbed by the second wave absorption plate 18 in the first detection cavity 19 and then are subjected to data acquisition through the second detection chip 17, the acquired data enter the single chip microcomputer 22 through the signal transmission rod 4 to be processed, so that the data acquisition of the high-frequency electromagnetic waves and the low-frequency electromagnetic waves can be realized, the data acquisition and analysis of the low-frequency electromagnetic waves in the environment are improved, and the data are displayed on the display screen 3, thus, the electromagnetic wave monitoring efficiency is improved.

In the present embodiment, the aperture of the first wave absorption hole 7 is larger than the aperture of the second wave absorption hole 10. Through making the aperture of first wave absorption hole 7 be greater than the aperture of second wave absorption hole 10, so set up, realized that first sleeve 6 can absorb the high frequency electromagnetic wave, and increased the volume that the electromagnetic wave got into, improved the efficiency of monitoring.

In the present embodiment, a first shielding sleeve 14 is provided between the first shielding cover 16 and the signal transmission rod 4. The first shielding sleeve 14 is arranged between the first shielding cover plate 16 and the signal transmission rod 4, and the first shielding sleeve can block the electromagnetic waves entering the first sleeve 6, so that the electromagnetic waves are prevented from overflowing, and the monitoring efficiency and accuracy are improved.

In the present embodiment, a second shielding sleeve 21 is provided between the second shielding cover 20 and the signal transmission rod 4. A second shielding sleeve 21 is arranged between the second shielding cover plate 20 and the signal transmission rod 4, and the second shielding sleeve 21 can block the electromagnetic waves entering the second sleeve 9, so that the electromagnetic waves are prevented from overflowing, and the monitoring efficiency and accuracy are improved.

In this embodiment, install bin 24 on the singlechip 22, install gaseous detection chamber 25 in the install bin 24, be equipped with a plurality of air inlets 5 on the organism 2, be equipped with a plurality of inlet chamber ways 23 that run through install bin 24 and organism 2 in the organism 2, inlet chamber way 23 and gaseous detection chamber 25 intercommunication, install the third in the gaseous detection chamber 25 and detect chip 27, install a plurality of gaseous detection probe 26 on the third detects chip 27. Through at singlechip 22 upper end installation install bin 24, establish gaseous detection chamber 25 in the install bin 24, a plurality of air inlets 5 on the organism 2, establish a plurality of air inlet chamber ways 23 with air inlet 5 intercommunication in the organism 2, air inlet chamber way 23 and gaseous detection chamber 25 intercommunication, installation third detection chip 27 in the gaseous detection chamber 25 to carry out gaseous detection through gaseous detection probe 26 in to gaseous detection chamber 25, so realized the detection to gas, the efficiency and the accuracy that have improved gaseous detection.

In the present embodiment, the thickness of the first wave-absorbing plate 13 is smaller than the thickness of the second wave-absorbing plate 18. By making the thickness of the first wave absorbing plate 13 smaller than that of the second wave absorbing plate 18, the efficiency and accuracy of the wave absorption detection in the first sleeve 6 can be improved.

The above only is the preferred embodiment of the present invention, not therefore the limit the patent protection scope of the present invention, all applications the equivalent structure transformation made by the contents of the specification and the drawings of the present invention is directly or indirectly applied to other related technical fields, and all the same principles are included in the protection scope of the present invention.

Claims (6)

1. The monitoring device for the environmental electromagnetic waves is characterized by comprising a base, a machine body is mounted at the upper end of the base, a display screen is arranged on the machine body, a signal transmission rod is mounted at the upper end of the machine body, a second mounting disc is sleeved on the periphery of the signal transmission rod, a second sleeve is mounted at the lower end of the second mounting disc, a first shielding cover plate for sealing the second sleeve is arranged at the lower end of the second sleeve, a second detection cavity is formed by the second sleeve and the first shielding cover plate, a first detection chip is mounted on the periphery of the signal transmission rod, a first wave absorption plate is mounted on the periphery of the first detection chip, a plurality of second wave absorption holes communicated with the second detection cavity are formed in the second sleeve, a first mounting disc is further mounted on the periphery of the signal transmission rod, a first sleeve is mounted at the lower end of the first mounting disc, a second shielding cover plate for sealing the first sleeve is arranged at the lower end of the first sleeve, the first sleeve and the second, be equipped with a plurality of first wave absorption holes that communicate with first detection chamber on the first sleeve pipe, the periphery of signal transmission pole just installs the second in first detection intracavity and detects the chip, and the second is detected and is installed the second on the chip and inhale the ripples board, is equipped with the installation cavity in the organism, installs the singlechip that signal transmission pole is connected in the installation cavity.

2. The apparatus for monitoring environmental electromagnetic waves of claim 1, wherein the first wave absorption hole has a larger aperture than the second wave absorption hole.

3. The apparatus for monitoring environmental electromagnetic waves of claim 1, wherein a first shielding sleeve is disposed between the first shielding cover and the signal transmission rod.

4. The apparatus for monitoring environmental electromagnetic waves of claim 1, wherein a second shielding sleeve is disposed between the second shielding cover and the signal transmission rod.

5. The apparatus for monitoring environmental electromagnetic waves as set forth in claim 1, wherein the single chip microcomputer has a mounting box mounted thereon, a gas detection chamber is mounted in the mounting box, the body has a plurality of gas inlets, a plurality of gas inlet channels are disposed in the body and extend through the mounting box and the body, the gas inlet channels are communicated with the gas detection chamber, a third detection chip is mounted in the gas detection chamber, and a plurality of gas detection probes are mounted on the third detection chip.

6. The apparatus for monitoring the environmental electromagnetic waves of claim 1, wherein the first wave-absorbing plate has a thickness less than the thickness of the second wave-absorbing plate.

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