WO2021010384A1 - Communication system configured using waveguide antenna - Google Patents

Abstract

[Problem] To provide a communication system configured using a waveguide antenna that transmits construction site monitoring information, etc., more reliably to a supervisory center, etc., via a simple structure, said system being capable of being attached, detached, and reused. [Solution] The waveguide antenna is configured from a radio wave leakage unit 2 for allowing radio waves to be transmitted to the inside and to leak from a portion of a side wall, and a single-pipe unit 3 for length-adjustably connecting the radio wave leakage unit 2 and an input connector 6 with a single pipe, the input connector 6 being connected to a wireless access point, and a wireless device and a wireless terminal performing wireless communication therebetween via the leaked radio waves among the radio waves transmitted from the wireless access point.

Description

Communication system with waveguide antenna

The present invention relates to a communication system using a waveguide antenna, and in particular, uses a waveguide antenna that has a radio wave leaking portion and leaks radio waves, and waves the waveguide antenna at the time of temporary construction of a construction site such as a high-rise building. It relates to a communication system using a waveguide antenna, which is used as a guide for vertical wireless communication and forms a wireless communication network with a planar wireless mesh on each floor of a high-rise building.

At construction sites such as buildings and civil engineering buildings these days, by monitoring the environment of the construction site using various environmental sensors, it is necessary to thoroughly prevent disasters at each construction site and prevent accidents of site workers. Is desired. In addition, it is desired to achieve high quality control in on-site construction by performing various on-site construction inspections and acquisition of construction data by making full use of IT equipment.

This environmental monitoring includes, for example, measurement of meteorological conditions such as temperature, humidity, rainfall, wind direction, wind speed, and snowfall at construction sites, oxygen concentration, carbon dioxide concentration, carbon monoxide concentration, generation of toxic gas, and flammable gas. Measurements such as the occurrence of It is desirable that the measurement results of these environmental monitoring are collected at the construction site and transmitted as communication data to a monitoring center or the like provided in the construction site or in a remote place by wireless LAN or the like. This environmental monitoring and the communication system of the measurement results can prevent the outbreak of fire at the construction site, poisoning by toxic gas of field workers, explosion by flammable gas, and infection by virus.

In addition, by using this environmental monitoring and the communication system of the measurement results, for example, heavy rain, sunshine, snowfall, strong winds, storms, etc. can be predicted in advance by measuring weather data at the construction site, and health measures for field workers such as heat stroke can be taken. It is possible to take measures in advance for damage and destruction of construction materials due to strong winds, and damage to construction finishing materials due to sudden heavy rain during construction.

As a system similar to the communication system using this waveguide antenna, there is a leaky coaxial system using LCX (leakage coaxial cable). This leaky coaxial system is a wireless broadcasting system that transmits a radio wave signal to a terminal device or the like by a transmission cable using wireless communication, and is a system in which a slit is provided in the leaky coaxial cable and the electromagnetic wave leaked from the slit is used as an antenna. ..

Patent Document 1 discloses a wireless communication system that is easy to install and remove and can be suitably used as a temporary communication system for a high-rise building under construction. Here, a hollow waveguide that can be extended in the vertical direction is provided inside the high-rise building according to the progress of construction, and a base station antenna is placed inside the hollow waveguide, and each floor of the high-rise building is equipped with an antenna. It is described that openings are formed in the hollow waveguides and tubular radiation guides are provided so as to project from the peripheral edges of the openings toward the room.

Patent Document 2 discloses a communication wave transport system that allows an electromagnetic wave from an access point to reach a wireless terminal to prevent multipath interference indoors. Here, the communication wave transport medium has a rectangular or circular opening shape made of a metal material, and the effective opening size is ½ or more of the wavelength of the electromagnetic wave to be propagated, and this transmission medium. It is described that the indoor end portion of the above is shaped so as to be folded toward the interior, and the joint portion of the transmission medium is provided with an electromagnetic wave leakage prevention shield.

Patent Document 3 discloses a waveguide in consideration of the frequency and propagation mode of the transmitted electromagnetic wave. Here, the waveguide has an outer diameter of φ1 (distance D between the inner surfaces of the covering in a direction orthogonal to the direction of the electric field vector of the electromagnetic wave) so as to transmit microwaves of, for example, 5.8 GHz in the tube axis direction in TE11 mode. ) And inner diameter φ2 are set.

JP-A-2010-159564 Japanese Unexamined Patent Publication No. 2008-28549 Japanese Unexamined Patent Publication No. 2016-149650

Conventionally, at construction sites, information can be transmitted to places where telephone lines (3G, 4G, 5G) cannot reach, regarding acquired environmental monitoring, various on-site construction inspections using IT equipment, and transmission of construction data. I wasn't. In particular, it was difficult to communicate with the upper floors of high-rise buildings covered with construction materials such as concrete and steel frames that block radio waves, and long-distance communications such as in tunnels.

The communication system using this waveguide antenna is a communication system that monitors the environment of the construction site using various environmental sensors at the time of temporary construction work instead of the main equipment work at the construction site and transmits information to the monitoring center etc. It has been developed. Therefore, it is required that the manufacturing cost of the communication system itself is low and that the installation work of the communication system is a simple system. In addition, it must be a sturdy device that is unlikely to break down or cause communication accidents during temporary construction at a construction site.

In addition, it must be possible to easily attach it to other construction materials at the construction site, and to be able to easily remove it from other construction materials when the construction is completed. And it is important that it is attached to the construction material and not damaged when it is removed.

In addition, it must be a device that can be stocked in a warehouse as a temporary material, brought to a construction site, and used repeatedly. In other words, not only is it easy to install and remove, but it must also be easy to transport. Further, there is a problem that the device must not deteriorate in performance due to repeated reuse.

It is desirable that the communication system using this waveguide antenna be installed in a staircase at a construction site or in an antenna passage that penetrates a vertical system such as an elevator shaft. However, each floor of the building is composed of reinforced concrete or steel-framed reinforced concrete wall or floor material, or a floor material composed of a deck plate which is a composite structure of steel plate and concrete. Therefore, even in a staircase or the like where radio waves can easily pass, if concrete or the like has a complicated shape, the radio waves are blocked and there is a problem that the antenna passage does not allow radio waves to easily pass through the vertical system. Further, in the case of an elevator shaft, when it is used for a temporary elevator at the time of temporary installation, radio waves may be cut off, and there is a problem that wireless communication at the time of temporary installation is not stable.

Furthermore, at construction sites, the degree of perfection of the antenna passages themselves such as staircases and elevator halls generally changes depending on the progress of construction work, and there is a problem that it is necessary to respond to changes in the antenna passages each time. There is. In addition, the area of each floor on which radio waves should be transmitted may change depending on the progress of construction work, and there is a problem that the area of each floor on which radio waves should be transmitted must be flexibly changed each time.

On the other hand, the leaky coaxial system using the LCX (leakage coaxial cable) described above is not a temporary work like this communication system but a main work, and is a communication system that combines the functions of both the cable transmission line and the antenna. However, since the purpose of use is different from that of this device, the above problem cannot be solved.

The purpose of this application is to solve such problems and to reliably transmit information such as construction site monitoring results, site construction inspections and construction data to the monitoring center, etc. using construction materials that can be procured at the construction site, and to install and install. It is to provide a communication system with a waveguide antenna suitable for temporary equipment by making it removable and allowing it to be used repeatedly by rental.

Another purpose of the present application is to solve such a problem and to form a wireless communication network that reliably transmits information such as construction site monitoring results, site construction inspections and construction data to a monitoring center by using a waveguide antenna for construction. It is to provide a communication system with a simple waveguide antenna that flexibly responds to the progress of construction.

In order to achieve the above object, the communication system using the waveguide antenna according to the present invention has a radio wave leaking portion that transmits radio waves inside and leaks radio waves, and a radio wave leaking portion and an input connector having a length of a single pipe. It consists of a single tube that is adjustable and does not leak radio waves, an input connector is connected to the wireless access point, and the leaked radio waves from the radio waves transmitted from the wireless access point are used to connect the radio and wireless terminal. It is characterized by wireless communication.

With the above configuration, the communication system using the waveguide antenna according to the present invention is composed of a radio wave leakage portion and a single tube portion. The single pipe part can be manufactured to any length by using a single pipe that is often used for scaffolding at construction sites. Further, the connecting portion can be easily manufactured by using a flange joint generally used for connecting pipes. Therefore, this waveguide antenna can be manufactured using a material that can be easily procured at a construction site without using a special material. Further, the single tube portion, the radio wave leakage portion, and the connecting portion are joined by bolts or the like. Therefore, it can be easily installed and removed at the construction site. In addition, once manufactured, the waveguide antenna has no particularly complicated details, so it can be removed and easily reused at other construction sites. Furthermore, a plurality of sets can be produced and stored, and can be used repeatedly by rental as needed.

Further, in the communication system using the waveguide antenna according to the present invention, the input connectors at both ends of the waveguide antenna are connected to the wireless access point, and the wireless LAN transmitted from the radio is connected to the waveguide via the access point. It is transmitted to the antenna. Of the transmitted radio waves, the radio waves leaked from the radio wave leaking part perform wireless communication between the radio and the wireless terminals around the radio wave leaking part. That is, in the case of a high-rise building, the radio waves transmitted from the radio are reliably transmitted to each floor by the waveguide antenna as a wave guide to the vertical system, and the radio waves on each floor are transmitted via the radio access points provided on each floor. Information can be transmitted to wireless terminals.

Further, the communication system using the waveguide antenna according to the present invention preferably includes a connecting portion for connecting the radio wave leaking portion and the single tube portion. As a result, the communication system using the waveguide antenna according to the present invention is composed of a radio wave leakage portion, a single tube portion, and a connection portion.

Further, in a communication system using a waveguide antenna, it is preferable that the radio wave leaking portion is provided with a slot for leaking radio waves, and the single pipe portion is provided with a flange joint as a connecting hardware to a single pipe used at a construction site. .. As a result, the waveguide antenna according to the present invention can be manufactured using a material that can be easily procured at a construction site without using a special material. In addition, since each component can be connected to each other by bolting, it can be easily attached and detached at a construction site. The connection hardware is not limited to the flange joint, and other connection hardware may be used.

Further, in a communication system using a waveguide antenna, a radio wave leakage portion and a single tube portion are alternately arranged to form one unit, and a plurality of units are connected to form a waveguide antenna of an arbitrary length. Is preferably formed. As a result, the length of the waveguide antenna can be freely adjusted without wastefully leaking radio waves from the waveguide antenna, and the radio waves can be reliably transmitted inside the waveguide.

Further, in a communication system using a waveguide antenna, it is preferable to prepare dimensional adjustment rings having different plate thicknesses at the flange joint of the connecting portion and easily adjust the length by using one of them. As a result, the length can be adjusted at the construction site, and radio waves can be transmitted to any position on each floor.

Further, in a communication system using a waveguide antenna, it is preferable that a bellows portion or a vent tube that can accommodate a curved line or a broken line is attached to the connecting portion. As a result, it is possible to absorb construction errors at the construction site and transmit radio waves to an arbitrary position. Also, if the antenna passages are curved or bent, the waveguide antenna can follow them.

Further, in a communication system using a waveguide antenna, it is preferable that the radio wave leakage part is made of aluminum, stainless steel, or copper, and the single tube part is galvanized. As a result, the surface of the waveguide antenna such as the radio wave leakage portion and the single tube portion becomes smoother, and the inside of the waveguide antenna can be efficiently transmitted.

In addition, a communication system using a waveguide antenna is temporarily installed in an antenna passage extending vertically in a multi-story building, and radio waves are leaked by at least one radio wave leaking portion in the layer for transmitting radio waves to transmit radio waves. It is preferable to use a single tube portion having no slot hole in the layer that does not have a slot hole. As a result, radio waves can be intensively transmitted only to the layer on which radio waves are transmitted, and wireless communication can be made more efficient.

In addition, the communication system using the waveguide antenna transmits the leaked radio waves to the wireless access points provided on each floor, and transmits the radio waves from the wireless access points to each wireless terminal through the wireless mesh network provided on each floor. Is preferable. By forming a wireless mesh network of a communication system using a waveguide antenna in this way, radio waves are reliably transmitted from the lower floors to the upper floors or to the end of each floor in a high-rise building or the like. be able to. Conventionally, a wireless mesh network in this high-rise building has been constructed for each floor including the upper and lower floors, but this wireless mesh network has not been suitable for vertical communication of the high-rise building due to obstacles. However, this problem could be solved by using the wave guide for vertical communication. The same effect can be achieved by using LCX in a vertical series, but since the robustness of the system is required at the construction site, when compared with LCX where there is a risk of disconnection, this waveguide antenna Is superior.

Further, in a communication system using a waveguide antenna, it is preferable that the single tube portion is fixed to a temporary material in the antenna passage by a clamp tool, or is fixed to the iron portion of the deck plate. As a result, the single tube portion of the waveguide antenna can be easily fixed to a temporary material, a deck plate, or the like.

Further, it is preferable that the communication system using the waveguide antenna is provided with an input connector at the end, and the wireless access point connected to the wireless LAN and the input connector are connected by a coaxial cable to transmit radio waves. As a result, a coaxial cable or the like having good followability to a curve can be used for the connection with the input connector at the end. The connection between the wireless access point and the input connector is not limited to the coaxial cable, and may be another connecting member.

Further, in a communication system using a waveguide antenna, it is preferable to arrange at least one radio wave leaking portion in an antenna passage extending in a plane direction from a wireless access point to transmit radio waves in a plane direction. Thereby, by utilizing the present invention together with the wave guide, a wireless mesh for transmitting a wireless LAN to each wireless terminal in a high-rise building can be constructed.

Further, in a communication system using a waveguide antenna, a waveguide antenna composed of a plurality of systems is arranged in each antenna passage in the vertical system or the planar direction, and each waveguide antenna provides individual information in a high-rise building. It is preferable that the communication system transmits to each wireless terminal. As a result, as a communication system using a waveguide antenna, for example, the monitoring result of the construction site is transmitted by the first waveguide antenna, and information such as on-site construction inspection and construction data is transmitted to the second or third grade. It can be transmitted separately by another waveguide antenna, and interference of radio waves can be avoided.

Further, in a communication system using a waveguide antenna, it is preferable that each waveguide antenna has its own dedicated wireless access point. As a result, the monitoring results of the construction site can be transmitted separately using the first wireless access point, and information such as site construction inspection and construction data can be separated and transmitted using another wireless access point such as the second or third. It is possible to avoid radio wave interference.

Further, in a communication system using a waveguide antenna, it is preferable that each waveguide antenna is connected to a dedicated environmental sensor provided in a multi-story building and the collected environmental data is transmitted to a data center. .. As a result, it is possible to avoid interference of radio waves by making the waveguide antenna for data communication different for each environmental sensor.

Another purpose of the present application is to solve such problems, to form a wireless communication network that reliably transmits monitoring information of construction sites using waveguide antennas to monitoring centers, etc., and to flexibly respond to the progress of construction work. It is to provide a communication system by a simple waveguide antenna.

As described above, according to the communication system using the waveguide antenna according to the present invention, information such as the monitoring result of the construction site, the site construction inspection and the construction data can be surely obtained by using the construction material that can be procured at the construction site. It is possible to provide a communication system using a waveguide antenna suitable for temporary equipment by transmitting it to a monitoring center or the like, allowing it to be freely attached and detached, and enabling repeated use by rental.

Further, according to the communication system using the waveguide antenna according to the present invention, wireless communication that reliably transmits information such as the monitoring result of the construction site, the site construction inspection and the construction data to the monitoring center or the like by using the waveguide antenna. It is possible to form a network and provide a communication system using a simple waveguide antenna that flexibly responds to the progress of construction work.

It is a side view which shows the schematic component structure of one Embodiment of the waveguide antenna which concerns on this invention. It is a perspective view and the side view which shows the shape and structure of the radio wave leakage part of a waveguide antenna. It is a perspective view and sectional view which shows the shape and structure of the single tube part of a waveguide antenna. It is a perspective view, a cross-sectional view, and the side view of the bellows part which show shape and structure of the connection part of a waveguide antenna. It is a perspective view which shows the shape and structure of the input connector of a waveguide antenna. It is explanatory drawing which shows one Example of the wireless communication system by the wave guide installed in the antenna passage. It is explanatory drawing which shows the evaluation result on the 2nd floor of a high-rise building in which a waveguide antenna is not installed. It is explanatory drawing which shows the evaluation result on the 9th floor of a high-rise building in which a waveguide antenna is not installed. It is explanatory drawing which shows the evaluation result on the 2nd floor of the high-rise building where the waveguide antenna is installed. It is explanatory drawing which shows the evaluation result on the 9th floor of the high-rise building where the waveguide antenna is installed.

(Construction of waveguide antenna)
Hereinafter, the waveguide antenna 1 according to the present invention will be described in detail with reference to the drawings. FIG. 1 shows a schematic configuration of one embodiment of the waveguide antenna 1 according to the present invention in a component configuration diagram. FIG. 1A shows a radio wave leaking portion 2 that leaks radio waves and connecting portions 4 provided at both ends of the radio wave leaking portion 2 as component configurations of the waveguide antenna 1. The radio wave leakage portion 2 is provided with a slot hole 7. Further, in FIG. 1 (b), the waveguide antenna 1 in which the single tube portion 3 is connected to the component configuration of FIG. 1 (a) and the input connector 6 is further connected to the end portion of the waveguide antenna 1. Shows the basic unit of. Further, FIG. 1C shows the component configuration of the waveguide antenna 1 including three radio wave leakage portions 2.

As described above, the waveguide antenna 1 according to the present invention is composed of a radio wave leakage portion 2, a connection portion 4, and a single tube portion 3 as a basic unit. By repeatedly connecting this basic unit, a predetermined length can be obtained. By installing the waveguide antenna 1 in the antenna passage extending vertically at the construction site, it can be used as a wireless communication system at the construction site. Here, the "antenna passage extending in the vertical system at the construction site" is defined without preventing the waveguide antenna 1 from extending in the vertical system at the construction site such as a high-rise building such as a staircase and an elevator shaft. Refers to an antenna passage that can leak radio waves from the radio wave leakage unit 2 on each floor of the building. Here, since the radio wave is transmitted inside the waveguide antenna 1 and not inside the antenna passage, it is used as a hollow waveguide by a steel pillar, a mast of a crane, and a metal pipe as in Patent Document 1. It's different from doing.

(Components of waveguide antenna)
2 to 6 show the shape and function of each component of the waveguide antenna 1. FIG. 2A is a perspective view of the radio wave leaking portion 2, and FIG. 2B is a side view of the radio wave leaking portion 2. FIG. 3 is a perspective view and a cross-sectional view showing the shape and configuration of the single tube portion 3. 4 (a) and 4 (b) are perspective views and cross-sectional views showing the shape and configuration of the connecting portion 4. Further, FIG. 4C shows a bellows portion 14 used for the connecting portion 4 in order to correspond to a curved surface. FIG. 5 is a perspective view showing the shape and configuration of the input connector 6.

As shown in FIGS. 2A and 2B, slot holes 7 are provided at two locations in a part of the radio wave leakage portion 2. The slot hole 7 is provided at an angle opposite to that of the main shaft so that the radio wave transmitted inside the radio wave leakage unit 2 easily leaks.

FIG. 3 shows a clamp 5a for connecting the single tube portion 3 and one end of the single tube portion 3 to the connecting portion 4, and a clamp 5b for connecting the other end of the single tube portion 3 to the input connector 6. Is shown. As shown in FIG. 3A, the clamps 5a and 5b are provided with clamp fixing bolt holes 23. Then, the clamp itself is fixed to the single pipe portion 3 by the clamp fixing bolt 22. Further, the clamps 5a and 5b are provided with connecting bolt holes 25, and the single pipe portion 3, the connecting portion 4 and the input connector 6 are connected by the connecting bolts 24, respectively.

As the single pipe portion 3, the single pipe 9 which is often used as a temporary material at a construction site can be used as it is. Further, as for the clamps 5a and 5b, the lamps 5a and 5b that are often used as temporary materials at construction sites can be used as they are. Therefore, for the construction site, the waveguide antenna 1 can be manufactured from the construction materials used on a daily basis. In addition, the surplus single pipe 9 and clamps 5a and 5b can be returned to the construction site for use.

FIG. 4 shows the connection portion 4. FIG. 4A is a perspective view of the connecting portion 4, and FIG. 4B is a cross-sectional view of the connecting portion 4. Flange joints 8a and 8b are provided at both ends of the connection portion 4 in order to connect one end to the radio wave leakage portion 2 and the other end to the clamps 5a and 5b of the single pipe portion 3, and the flange joint 8a. , 8b are provided with connecting bolt holes 25 in the connecting direction, and are connected to the parts connected in each direction by the connecting bolt 24. In the flange joints 8a and 8b of the connecting portion 4, as shown in FIG. 4B, dimension adjusting rings 10 having different plate thicknesses are prepared, and the length of the connecting portion 4 can be adjusted by using one of them. It can be carried out.

Further, as shown in FIG. 4C, the connecting portion 4 can be provided with a bellows portion 14 in response to a case where the connection portion 4 changes in a curved shape. For the bellows portion 14, a member such as a flexible hose that can handle a curved line or a polygonal line is used. Then, the bellows portion 14 is provided with a seal so that the radio waves flowing through the connecting portion 4 do not leak. By utilizing the bellows portion 4, even if the linearity of the antenna passage changes, it can be sufficiently coped with.

FIG. 5 shows the shape and configuration of the input connector 6 of the waveguide antenna 1. A connector portion 18 is provided at the tip of the input connector 6 and is connected to the wireless access point 16 via a coaxial cable 17. Further, it has a connecting bolt hole 25 that connects the clamps 5a and 5b of the single pipe portion 3 with the connecting bolt 24.

(Communication system using wave guide)
FIG. 6 shows an embodiment of a wireless communication system using a wave guide 1 installed in an antenna passage. When used in a vertical radio communication system in a high-rise building, the waveguide antenna 1 is referred to as a wave guide 1 in the present specification. In FIG. 6, of the continuous high-rise buildings A floor 26, B floor 27, and C floor 28, monitoring is performed by the wireless mesh network 36 on the B floor 27 and the environment sensor 30, and the monitoring result is transmitted to the monitoring center and the like. To do.

A wireless access point 16 connected to a wireless LAN is installed at the end of the wave guide 1, and the wave guide 1 is connected to the wireless access point 16 by a coaxial cable 17. The wave guide 1 may be directly connected to the wireless access point 16. On the B floor 27, the radio wave leaked from the wave guide 1 is transmitted to the wireless access point 16 on the B floor 27 and transmitted to the wireless mesh network 36 of the wireless terminal 35 on the B floor 27.

On the other hand, on the B floor 27, the environment sensor main body 31, and the environment sensor 30 including, for example, the temperature sensor box 32, the flammable gas sensor box 33, the virus detection box 34, etc., communicate wirelessly with the wave guide 1. An environmental measuring instrument such as the temperature sensor box 32 monitors the working environment at the construction site and transmits the monitoring result to the monitoring center or the like. In addition, the construction status and the like can be grasped by a surveillance camera 29 or the like provided at the construction site. Further, on-site construction inspection and construction data can be wirelessly communicated to a monitoring center or the like by using the wave guide 1.

(Evaluation result by wave guide)
FIG. 7 shows the evaluation results of radio wave measurement on the second floor of a high-rise building in which the wave guide 1 is not installed. Further, FIG. 8 shows the evaluation results of radio wave measurement on the 9th floor of a high-rise building in which the wave guide 1 is not installed. Further, FIG. 9 shows the evaluation results of radio wave measurement on the second floor of a high-rise building in which the wave guide 1 is installed. Further, FIG. 10 shows the evaluation results of radio wave measurement on the 9th floor of a high-rise building in which the wave guide 1 is installed. This evaluation was made on the 2nd and 9th floors of a 9-story skyscraper. 7 and 8 show the case where the wave guide 1 is not installed in the antenna passage of the elevator shaft or the staircase, and FIGS. 9 and 10 show the wave guide 1 in the antenna passage of the elevator shaft or the staircase. In this case, the received power level in the corridor or the strength of the radio wave is measured by RSSI (dB) depending on the installation of the wave guide 1, and the evaluation result is 6 levels (30 dB or more, 25 to 29 dB, 20 to 20 to). It is displayed in 24 dB, 15 to 19 dB, 15 to 19 dB, 10 to 14 dB, 9 dB or less).

In the measurement on the second floor where the reception level is relatively high, when the wave guide 1 in FIG. 7 is not installed, the maximum is 20 to 24 dB in the corridor around the staircase, but it is closed by a wall. It is 10 to 14 dB indoors. On the other hand, when the wave guide 1 of FIG. 10 is installed, the maximum is 30 dB or more in the corridor around the staircase, but it is 15 to 19 dB even in the room closed by the wall. It can be said that the effect of Wave Guide 1 appears across the board.

On the 9th floor where the reception level is relatively low, when the wave guide 1 shown in FIG. 8 is not installed, the reception power level is almost 9 dB or less. On the other hand, when the wave guide 1 of FIG. 9 is installed, the maximum is 30 dB or more in the corridor around the staircase, and it can be seen that the received power level of the second floor is maintained.

From the evaluation results of the radio wave measurement of these high-rise buildings, when the wave guide 1 is used, the received power level does not decrease so much on the upper floors, so that the wave guide 1 is stable in the height direction. Proven to have properties.

The configuration, shape, size, and arrangement of the waveguide antenna 1 or the wave guide 1 described in the above embodiments are only schematically shown to the extent that the present invention can be understood and implemented. Therefore, the present invention is not limited to the described embodiments, and can be changed to various forms as long as it does not deviate from the scope of the technical idea shown in the claims.

1 Coaxial antenna or wave guide, 2 Radio leak, 3 Single tube, 4 Connection, 5a, 5b clamp, 6 Input connector, 7 Slot hole, 8a, 8b Flange joint, 9 Single tube pipe, 10 Dimension adjustment Ring, 14 bellows, 16 wireless access point, 17 coaxial cable, 18 connector, 22 clamp fixing bolt, 23 clamp fixing bolt hole, 24 connecting bolt, 25 connecting bolt hole, 26 A floor, 27 B floor, 28 C floor , 29 Surveillance camera, 30 Environmental sensor, 31 Environmental sensor body, 32 Temperature sensor box, 33 Combustible gas sensor box, 34 Virus detection box, 35 Wireless terminal, 36 Wireless mesh network.

Claims (15)

1. It is composed of a radio wave leaking part that transmits radio waves inside and leaks the radio waves, and a single pipe part that connects the radio wave leaking part and the input connector with a single pipe so that the length can be adjusted and does not leak the radio waves. , The input connector is connected to the wireless access point, and the radio wave leaked from the radio waves transmitted from the wireless access point is used for wireless communication between the wireless device and the wireless terminal. Communication system by antenna.
2. The communication system using a waveguide antenna according to claim 1, wherein the communication system using a waveguide antenna is provided with a connecting portion for connecting the radio wave leakage portion and the single tube portion.
3. The communication system using the waveguide antenna according to claim 1 or 2, wherein the radio wave leaking portion is provided with a slot for leaking the radio wave, and the single pipe portion is the single pipe pipe used at a construction site. A communication system using a waveguide antenna, characterized in that a flange joint is attached as a connecting hardware to the.
4. The communication system using the waveguide antenna according to claims 1 to 3, wherein the radio wave leaking portion and the single tube portion are alternately arranged to form one unit, and a plurality of units are connected to each other. A communication system using a waveguide antenna, characterized in that a waveguide antenna of an arbitrary length is formed in the above.
5. The communication system using the waveguide antenna according to claims 2 to 4, wherein dimensional adjustment rings having different plate thicknesses are prepared at the flange joint of the connection portion, and the length is obtained by using one of them. A communication system using a waveguide antenna, which is characterized in that adjustment is performed.
6. The communication system using the waveguide antenna according to any one of claims 2 to 5, wherein a bellows portion or a vent tube capable of adapting to a curved line or a bent line is attached to the connection portion. Communication system using a waveguide antenna.
7. The communication system using the waveguide antenna according to any one of claims 1 to 6, wherein the radio wave leakage portion is made of aluminum, stainless steel, or copper, and the single tube portion is zinc-plated. A communication system using a waveguide antenna, which is characterized by being applied.
8. The communication system using the waveguide antenna according to any one of claims 1 to 7.
   It is temporarily installed in an antenna passage extending vertically in a multi-story building, and the radio wave is leaked by at least one radio wave leaking portion in the layer for transmitting the radio wave, and a slot hole is provided in the layer not transmitting the radio wave. A communication system using a waveguide antenna, which comprises using the single tube portion which does not have.
9. The communication system using the waveguide antenna according to claim 1, wherein the leaked radio wave is transmitted to the wireless access point provided on each floor, and the leaked radio wave is transmitted from the wireless access point through a wireless mesh network provided on each floor. A communication system using a waveguide antenna, which comprises transmitting the radio wave to each of the wireless terminals.
10. The communication system using the waveguide antenna according to claim 1 or 2, wherein the single tube portion is fixed to a temporary material in the antenna passage by a clamp tool, or is fixed to an iron portion of a deck plate. A communication system using a waveguide antenna.
11. The communication system using the waveguide antenna according to any one of claims 1 to 3, wherein a wireless access point having an input connector at an end and connected to a wireless LAN is coaxial with the input connector. A communication system using a waveguide antenna, which is characterized in that radio waves are transmitted by being connected by a cable.
12. The communication system using a waveguide antenna according to claim 4, wherein at least one radio wave leaking portion is arranged in an antenna passage extending in a plane direction from a wireless access point to transmit radio waves in the plane direction. Communication system with a waveguide antenna.
13. The communication system using the waveguide antenna according to any one of claims 1 to 5.
    The waveguide antenna composed of a plurality of systems is arranged in each antenna passage in the vertical system or the planar direction, and each waveguide antenna transmits individual information to each of the wireless terminals in a high-rise building. A communication system using a waveguide antenna, which is characterized by being a system.
14. The communication system using a waveguide antenna according to claim 6, wherein each waveguide antenna has a dedicated radio access point.
15. The communication system using the waveguide antenna according to claim 8, wherein each waveguide antenna is connected to a dedicated environmental sensor provided in the multi-story building, and the collected environmental data is collected. A communication system using a waveguide antenna, which is characterized by transmitting data to a data center.

Images