JP2020156072A - Antenna attachment device - Google Patents

Abstract

To provide, in a radio network system in an office building, an antenna attachment device having high seismic strength which can appropriately house, with ease in a short time, a target radio communicable terminal within a communicable range, causing neither a directional change of the radio wave radiation pattern of an antenna to be installed on a system ceiling, nor an electromagnetic interference to a neighboring radio sensor network.SOLUTION: An antenna unit (a generic term of an antenna attachment device and an antenna device mounted thereon) has a structure of sliding at least in a second straight line direction in a grid structure of a system ceiling.SELECTED DRAWING: Figure 1

Description

Detailed description of the invention

The present invention affects the radio wave radiation pattern of an antenna device in a wireless network system composed of an antenna device placed on the system ceiling of an office building, a wirelessly communicable sensor placed in the office, a computer (hereinafter, PC), and the like. The present invention relates to an antenna mounting device capable of accommodating a sensor and a PC within a wireless communication range by sliding the installation position.

In office buildings in an increasingly sophisticated information-oriented society, there is an increasing demand for the construction of wireless network systems for data communication using sensors, PCs and antenna devices. At the construction site where a wireless network system is actually constructed in such an office building, the antenna device is installed so that the target sensor, PC, etc. are housed within the communicable range of the antenna and do not interfere with other communication areas. There is an increasing demand for antenna mounting devices that can set the position accurately and in a short time.

As shown in [FIG. 15], a conventional antenna mounting device in this field has an antenna mounting suspension bolt 41 suspended from concrete in the ceiling or the like, and two or more steady rest suspension bolts 42. A steady rest metal fitting 43 is provided at the tip (lower end) of these three or more bolts. Further, a mounting flat plate 44 is provided below the steady rest metal fitting 43, and an antenna mounting hardware 45 is provided at the lower end thereof. The antenna device 46 is attached to the antenna mounting hardware 45. If you want to change the direction of the radio wave radiation pattern of the antenna device 46 in the vertical direction (vertical direction), that is, if you want to make it slanted, for example, change the angle of the antenna mounting hardware 45 with respect to the antenna mounting suspension bolt 41 or the mounting flat plate 44. In this state, for example, when it is desired to change the orientation (orientation in the horizontal direction) of the antenna device 46, the mounting flat plate 44 is rotated around the antenna mounting suspension bolt 41 as a central axis. By rotating these two axes, the target sensor, PC, and the like are housed within the communicable range of the antenna device.

Further, in the case of the patent document, the wall surface of the building to which the antenna is attached can be rotated in two axes in the horizontal direction and the vertical direction in order to improve the consistency regardless of the direction of the wall surface of the building to which the antenna is attached. A flat antenna mounting device for receiving satellite broadcasts is disclosed.

JP-A-63-174405

In the case of the patent document, it is a flat antenna mounting device for receiving satellite broadcasts that can rotate in two axes in the horizontal and vertical directions, and from the viewpoint of handling on the ceiling of the office, and the target wireless communication sensor and PC are antennas. There is a problem from the viewpoint of properly storing the device within the communicable area of the device.

The conventional antenna mounting device shown in FIG. 15 mainly has the following first to second problems.
First, in order to properly accommodate the target wirelessly communicable sensor and PC placed in the office within the communicable range of the antenna device, loosen the antenna mounting hardware and the bolts that mount the mounting flat plate, respectively. The direction of the radio wave emission pattern of the antenna device must be adjusted using two axes. Therefore, there is a problem that adjustment is difficult and takes time, and a long time is required with a plurality of workers. Secondly, when the direction of the radio wave radiation pattern is changed in order to widen the communicable range of the antenna device, the radiation region is significantly changed by changing the angle slightly. As a result, the problem of causing radio interference in the adjacent wireless sensor network is likely to occur. FIG. 16 shows the situation of this problem.

An object of the present invention is to solve the above-mentioned problems of the conventional antenna mounting device. That is, the antenna mounting device of the present invention is less likely to cause radio interference in the adjacent wireless sensor network, and can easily and quickly communicate with the target wirelessly communicable sensor, PC, etc. located in the office. It makes it possible to properly store within the possible range.

The antenna mounting device according to claim 1 is a wireless network system including an antenna device arranged on the system ceiling of an office building having a grid-like structure, a wirelessly communicable sensor arranged in the office, and a computer. An antenna mounting device that mounts and supports the antenna device on the system ceiling, the antenna mounting frame that slidably supports the antenna device in the first linear direction, and the antenna mounting frame on the system ceiling in the first linear direction. It is characterized in that it is provided with a slide mounting means for slidably mounting in the second linear direction orthogonal to the antenna.

The antenna mounting device according to claim 2 is further provided with a main body portion in which the antenna mounting base slidably supports the antenna device in the first linear direction and both ends of the main body portion in the first linear direction. The slide mounting means is fixed to the side surface portion, the folded portion, and the system ceiling, and has a side surface portion having a side surface orthogonal to the first linear direction and a folded portion having a folded surface orthogonal to the side surface. It is characterized in that it is composed of fixing brackets for the purpose.

The antenna mounting device according to claim 3 is further characterized in that a hole for tightening the antenna device is formed as an elongated hole extending in the first linear direction in the main body portion.

The antenna mounting device according to claim 4 is further characterized in that a hole through which a coaxial connector protruding from the antenna device toward the ceiling side penetrates is formed in the main body portion as an elongated hole extending in the first linear direction. ..

The antenna mounting device according to claim 5 is further characterized in that the outer width between the side surface portions of the antenna mounting base is slightly smaller than the inner width of the grid-like structure.

The antenna mounting device according to claim 6 is further characterized in that the fixing bracket has a fixing piece fixed to the antenna mount and a locking piece elastically locked to the lattice structure. ..

The antenna mounting device according to claim 7 is characterized in that the fixing piece extends outward so as to be able to straddle the upper part of the lattice-like structure and is connected to the locking piece.

In the antenna mounting device of claim 8, holes for tightening each other are further formed in the fixing bracket and the antenna mounting base, and at least one of the holes becomes an elongated hole in the first linear direction. It is characterized by being.

The antenna mounting device according to claim 9 is further characterized in that the main body of the antenna mounting base can be expanded and contracted in the first linear direction.

The antenna mounting device according to claim 10 is a wireless network system including an antenna device arranged on the system ceiling of an office building having a grid-like structure, a wirelessly communicable sensor arranged in the office, and a computer. An antenna mounting device that mounts and supports the antenna device on the system ceiling, the antenna mounting pedestal that supports and supports the antenna device and has a longitudinal direction, and the antenna mounting pedestal on the system ceiling in a direction orthogonal to the longitudinal direction. It is characterized by being provided with a slide mounting means for slidably mounting the antenna.

The antenna mounting device according to claim 11 is the antenna mounting device according to claim 9, further comprising a main body portion in which the antenna mounting base supports the antenna device and has a longitudinal direction, and both ends in the longitudinal direction of the main body portion. It has a side surface portion which is connected to the portion and has a side surface orthogonal to the longitudinal direction and a folding portion having a folding surface orthogonal to the side surface, and the slide mounting means is the side surface portion, the folding portion and the system. It is characterized in that it is composed of fixing brackets for fixing to the ceiling.

The antenna mounting device according to claim 12 is further characterized in that the outer width between the side surface portions of the antenna mounting base is slightly smaller than the inner width of the grid-like structure.

The antenna mounting device according to claim 13 further has a fixing piece in which the fixing bracket is fixed to the antenna mounting base and a locking piece elastically locked to the lattice-like structure. It is characterized in that the locking piece and the locking piece are integrally formed.

The antenna mounting device according to claim 14 is further characterized in that the fixing piece extends outward so as to straddle the upper part of the lattice-like structure and is connected to the locking piece.

The antenna mounting device according to claim 15 further has holes for tightening formed in the fixing bracket and the antenna mounting base, respectively, and at least one of the holes is a long hole in the longitudinal direction. Features

The antenna mounting device according to claim 16 is further characterized in that the main body of the antenna mounting base can be expanded and contracted in the longitudinal direction.

According to the antenna mounting device according to the first aspect, the radiation direction and the radiation range of radio waves are not adjusted by two axes, but the antenna mounting device itself is perpendicular to the horizontal plane of the system ceiling in the longitudinal direction (first straight line direction). In addition to sliding in the second straight line direction, the antenna device can be slid in the longitudinal direction of the antenna mounting device to adjust the position, so that the communicable area can be communicated without changing the radiation direction (direction of radiation). Can be easily adjusted in a short time. That is, since the antenna device is only moved back and forth and left and right by the antenna mounting device for position adjustment, and the direction of the radio wave radiation pattern of the antenna device is not changed by changing the angle of the two axes, other adjacent antenna devices are used. It is less likely to cause radio interference to the wireless network system, and accurate work at the construction site can be achieved in a short time.

According to the antenna mounting device according to claim 2, since the slide mounting means is composed of a side surface portion in the longitudinal direction of the main body portion, a folded portion, and a fixing bracket for fixing to the system ceiling, a large-scale configuration is provided. The configuration can be inexpensive and easy to manufacture without the need for it.

According to the antenna mounting device according to claim 3, since the hole for tightening the antenna device is formed as a long hole extending in the first linear direction, the antenna device is provided by the length of the long hole. It can be attached by sliding it in the longitudinal direction. Moreover, since it is a tightening means using a long hole, it can be achieved with an inexpensive and simple structure.

According to the antenna mounting device according to claim 4, since the hole through which the coaxial connector protruding from the antenna device to the ceiling side penetrates is formed in the main body as an elongated hole extending in the first linear direction, the antenna device is provided. The coaxial connector does not get in the way when sliding in the first straight direction.

According to the antenna mounting device according to claim 5, since the outer width between both side surfaces of the antenna mounting base is slightly smaller than the inner width of the grid-like structure, the antenna mounting base can be easily and easily mounted on the system ceiling. It can be accommodated in the inner width of the lattice structure.

According to the antenna mounting device according to claim 6, since the fixing bracket has a fixing piece fixed to the antenna mount and a locking piece elastically locked to the lattice structure. With a simple structure, the antenna mounting device can be fixed to the system ceiling and elastically locked to prevent rattling.

According to the antenna mounting device according to claim 7, even when the ceiling plate supporting the weight of the antenna mounting device falls, the fixing bracket extends outward so that the fixing bracket can straddle the upper side of the lattice structure. Therefore, the fixing bracket can support the weight of the antenna mounting device.

According to the antenna mounting device according to claim 8, holes for tightening each other are formed in the fixing bracket and the antenna mounting base, and at least one of the holes becomes an elongated hole in the first linear direction. Therefore, even if the thickness or width of the grid-like structure on the system ceiling in the horizontal direction changes slightly, the mounting position can be changed by the length of the elongated hole. That is, it can correspond to a lattice-like structure having a different thickness or width.

According to the antenna mounting device according to claim 9, since the main body of the antenna mounting base can be expanded and contracted in the first linear direction, it can be mounted even if the system ceiling grid width is different.

The antenna mounting device according to claim 10 can be slidably mounted on a lattice structure in a direction orthogonal to the longitudinal direction, and therefore, if it is necessary to slidably mount the device in a direction orthogonal to the lattice-shaped structure. The antenna mounting device itself may be mounted by turning it 90 degrees. In this case as well, since the angle of the two axes is not adjusted, the communicable area can be easily adjusted in a short time. That is, the antenna device only slides in one direction with the mounting direction for position adjustment by the antenna mounting device, and does not change the direction of the radio wave radiation pattern of the antenna device. It is less likely to cause radio interference to the network system, and accurate work at the construction site can be achieved in a short time.

According to the antenna mounting device according to claim 11, since the slide mounting means is composed of the side surface portion, the folded portion, and the fixing bracket for fixing to the system ceiling, a large-scale configuration is not required. The configuration can be inexpensive and easy to manufacture.

According to the antenna mounting device of claim 12, the outer width between both side surfaces of the antenna mounting base is slightly smaller than the inner width of the grid-like structure, so that the antenna mounting base can be reasonably used as a grid-like structure on the system ceiling. It can be easily and comfortably fitted in the inner width of the antenna.

According to the antenna mounting device according to claim 13, since the fixing bracket has a fixing piece fixed to the antenna mount and a locking piece elastically locked to the grid-like structure, it is easy. With this structure, the antenna mounting device can be fixed to the system ceiling and prevent rattling in the event of an earthquake.

According to the antenna mounting device according to claim 14, similar to the antenna mounting device according to claim 7, even if the ceiling plate supporting the weight of the antenna mounting device falls, the fixing bracket is placed on the upper side of the lattice structure. Since it extends outward so that it can be straddled, the fixing bracket can support the weight of the antenna mounting device.

According to the antenna mounting device according to claim 15, holes for tightening each other are formed in the fixing bracket and the antenna mounting base, and at least one of the holes becomes an elongated hole in the first linear direction. Therefore, even if the thickness or width of the grid-like structure on the system ceiling in the horizontal direction changes slightly, the mounting position can be changed by the length of the elongated hole. That is, it can correspond to a lattice-like structure having a different thickness or width.

According to the antenna mounting device according to claim 16, since the main body of the antenna mounting base can be expanded and contracted in the longitudinal direction, it can be mounted even if the grid width of the system ceiling is different.

An exploded perspective view showing the first embodiment of the present invention. Perspective view showing the first embodiment of the present invention A vertical sectional view showing a ceiling portion in a state where the first embodiment of the present invention is attached. Enlarged exploded perspective view of the part circled in FIG. 3 (a) Perspective view of the fixing bracket according to the first embodiment of the present invention. Explanatory drawing for slide-adjusting the communicable range in the first embodiment of the present invention Top view showing the communicable range before adjustment in the first embodiment of the present invention. Top view showing the adjusted communicable range in the first embodiment of the present invention. An exploded perspective view showing a second embodiment of the present invention. An exploded perspective view showing a third embodiment of the present invention. Perspective view showing a third embodiment of the present invention An exploded perspective view showing a fourth embodiment of the present invention. Explanatory drawing which shows the communicable range before adjustment of the 3rd Embodiment of this invention Explanatory drawing which shows the communication possible range after adjustment of the 3rd Embodiment of this invention Explanatory drawing which shows the communicable range before adjustment of the 3rd Embodiment of this invention Explanatory drawing which shows the communication possible range after adjustment of the 3rd Embodiment of this invention Schematic diagram showing a network configuration of an office building to which the present invention is applied Explanatory drawing about adjustment method of communication range using conventional antenna attachment device Explanation of communication range adjustment and radio interference using a conventional antenna mounting device

As an embodiment of the present invention, a first embodiment, a second embodiment, a third embodiment, and a fourth embodiment will be described in detail with reference to FIGS. 1 to 14.

An example of a wireless network system configuration of an office building to which any of these plurality of embodiments of the antenna mounting device of the present invention is applied will be described with reference to FIG.

In the office, there are a plurality of antenna units (the antenna mounting device of the present invention and the antenna device mounted therein are collectively referred to as an antenna unit) due to the communication range, communication capacity, number of communication target terminals, and the like. It is divided into blocks. Here, the network system configuration is divided into two. That is, in the office, the antenna unit 33a is divided into two groups, a plurality of terminals 33aa such as sensors and PCs capable of wireless communication, and a plurality of terminals 33ab such as sensors and PCs capable of wireless communication with the antenna unit 33b. Therefore, a communicable range 33ar by the antenna unit 33a and a communicable range 33br by the antenna unit 33b are set in each group. The antenna unit 33a and the antenna unit 33b are installed so that mutual interference of radio waves does not occur.

The antenna unit 33a and the antenna unit 33b are installed in the ceiling and are connected to the amplification device / transmission / reception device 32 by a high-frequency coaxial cable. The transmission / reception signals of a plurality of terminals 33aa and 33bb such as target sensors and PCs in the office are converted into an antenna unit 33a and an antenna unit 33b, a high-frequency coaxial cable 31, an amplification device / transmission / reception device 32, and a wireless signal, and then the antenna unit. 33c, after being converted into a digital signal by the transmission / reception device 38 via the transmission / reception device antenna 37 in the data management room, work status data, business information data, etc. are processed and stored in the computer data management device 39 by the computer data management device 39. Manage accumulation, etc.

Further, the data acquisition instruction of the plurality of terminals 33aa and 33bb such as the sensor and the PC is output as an instruction signal from the computer data management device 39, and the plurality of terminals 33aa such as the sensor and the PC pass through the reverse course. And it is transmitted to 33bb.

The first embodiment of the antenna mounting device 1 of the present invention used in the network system as described above will be described in detail with reference to FIGS. 1 to 7. The antenna mounting device 1 of the first embodiment is characterized in that it can slide in the first linear direction 1M and the second linear direction 2M orthogonal to this direction. Details will be described later.

FIG. 1 is an exploded perspective view of the antenna device 6 and the antenna mounting device 1. The white arrows in FIG. 1 indicate the direction in which the antenna device 6 is mounted on the antenna mounting device 1.

The antenna mounting device 1 and the antenna device 6 are installed in the ceiling. At this time, in order to perform wireless communication with the target sensor in the office or a terminal such as a PC, the antenna device 6 is attached to the antenna mounting device 1 with the element surface 9 on the front facing downward (in the office). Can be installed. An antenna device bolt 8 for attaching to the antenna attachment device 1 is attached to the back surface of the antenna device, and a high frequency connector jack 7 for connecting the high frequency connector plug 13 and the high frequency coaxial cable 14 is attached. It is installed.

In order to allow the antenna device 6 to slide in the first linear direction 1M while the antenna mounting device 1 supports the antenna device 6, a long hole through which the antenna device bolt 8 can penetrate is formed in the antenna mounting frame main body 1a. 2 and an elongated hole 3 through which the high-frequency connector jack 7 can pass are provided. As disclosed in FIGS. 2 and 3, after the antenna device bolt 8 has penetrated the elongated hole 2, the antenna device 6 is attached to the antenna by screwing the nut 12 that locks the bolt to the antenna device bolt 8. It is supported by the device 1.

A side surface portion 4 and a folded-back portion 5 are connected to the antenna mounting base main body 1a so that the antenna mounting device 1 can slide in the second linear direction 2M orthogonal to the first linear direction 1M.

A fixing bracket 11 for mounting the antenna mounting device 1 on the grid-like structure on the system ceiling is mounted on the antenna mounting device 1. In order to attach the fixing bracket 11 to the antenna mounting device 1, the fixing bracket mounting hole 10 of the antenna mounting base main body 1a is used. That is, the positions of the fixing bracket mounting hole 10 and the elongated hole 11c provided in the fixing bracket 11 shown in FIG. 4 are adjusted, and the screw 11t for locking the fixing bracket penetrating between the two and the fixing bracket are locked. Tighten and fix with the nut 11n. It is also possible to use suitable commercially available bolts and nuts for this tightening and fixing. At this time, the position can be adjusted in the longitudinal direction by adjusting the mounting position of the fixing bracket 11 with respect to the antenna mounting base main body 1a using the elongated hole 11c.

FIG. 2 is a perspective view showing a state in which the antenna device 6 is mounted on the antenna mounting device 1 according to the first embodiment of the present invention. In the antenna mounting device 1 of the first embodiment, the antenna device 6 is moved by loosening the antenna device bolt 8 and the nut 12 that locks the bolt and shifting the antenna device bolt 8 along the tightening elongated hole 2. In the supported state, the antenna mounting frame main body 1a can be slid in the longitudinal direction, that is, in the first linear direction 1M. Details will be described later.

Further, the antenna mounting device 1 itself can slide inside the grid structure 15 in the second linear direction 2M orthogonal to the first linear direction 1M while being supported by the grid structure 15. .. This will also be described later.

FIG. 3A shows a ceiling portion installed in a grid-like structure of a system ceiling such as an office building in a state where the antenna mounting device 1 according to the first embodiment of the present invention supports the antenna device 6. The vertical cross section is shown. FIG. 3 (b) is an enlarged view of the portion circled in FIG.

As the name suggests, the lattice-like structure 15 is a structure assembled in a lattice pattern, but rock wool (rock wool) or the like is used so as to block the opening of the lattice-like structure 15 to form a ceiling. A sound absorbing plate 16 having a heat insulating property using the above is laid out. The vertical cross section of the lattice structure 15 is formed in a substantially inverted T shape having a flange portion 15a at the lower portion and a head portion 15b described later at the upper portion, and the sound absorbing plate 16 is formed on the substantially inverted T-shaped flange portion 15a. It is placed. Since the outer width of the antenna mounting base main body 1a, that is, the length between the side surfaces 4 of the antenna mounting bases on both sides of the antenna mounting device 1, is slightly smaller than the inner width between the heads 15b of the lattice structure 15. , It can be easily installed in the lattice structure 15. The antenna mounting base folded-back portion 5 is placed on the back surface of the ceiling, which is the upper surface of the sound absorbing plate 16. In order for the antenna mounting base folding portion 5 to be mounted on the sound absorbing plate 16, the thickness of the antenna device 6 needs to be the same as or smaller than the height of the antenna mounting base side surface portion 4.

The antenna device bolt 8 of the antenna device 6 penetrates the tightening elongated hole 2 of the antenna mounting device 1 and is fixed by a nut 12 for locking the bolt. The high-frequency connector jack 7 penetrates the elongated hole of the antenna mounting frame main body 1a, and the high-frequency connector plug 13 connected to the high-frequency coaxial cable 14 is connected there.

When it is desired to fix the antenna device 6 in the antenna mounting device 1 at an optimum position for sliding along the first linear direction 1M, first, loosen the nut 12 that locks the bolt of the antenna mounting frame main body 1a. Next, the antenna device 6 is slid along the first linear direction 1M, and the nut 12 for locking the bolt is tightened and fixed at the optimum position. Further, when it is desired to slide the antenna mounting device 1 along the second linear direction 2M, the antenna mounting base side surface portion 4 and the antenna mounting base folding portion 5 are slid along the grid-like structure 15 and the sound absorbing plate 16. , Install in the optimum position.

A fixing bracket 11 is used to fix the antenna mounting device 1 so as not to deviate from the optimum position. FIG. 4 is a perspective view of the fixing bracket 11 of the antenna mounting device 1 according to the first embodiment of the present invention. The fixing bracket 11 has a fixing piece 11a fixed to the antenna mounting base main body 1a and a V-shaped locking piece 11b connected to the fixing piece 11a. The locking piece 11b is composed of a locking base piece 11b1 connected to the fixing piece 11a and a locking tongue piece 11b2 connected to the locking base piece 11b1 in a V shape. The angles of the V-shaped locking base piece 11b1 and the locking tongue piece 11b2 can be elastically changed. That is, when a force is applied from both outer sides, the V-shaped angle becomes smaller, and when the force is removed, the V-shaped angle returns to the original angle. An elongated hole 11c is formed in the fixing piece 11a, and a screw 11t for locking the fixing bracket and a nut 11n for locking the fixing bracket are applied to the elongated hole 11c and the fixing bracket mounting hole 10, and the fixing piece 11a is an antenna mount. It is fixed to the mounting body 1a. It is also possible to use suitable commercially available bolts and nuts for this tightening and fixing. The fixed piece 11a extends outward across the head portion 15b of the grid-like structure 15, and the locking source piece 11b1 bent at 90 degrees extends downward in the drawing, and is V-shaped from there. The tip of the locking tongue piece 11b2 bent in elastic contact with the outer surface of the lattice structure 15 to lock it. The position of the fixing piece 11a is adjusted by adjusting the positions of the elongated hole 11c of the fixing piece 11a and the fixing bracket mounting hole 10 according to the inner width of the lattice structure 15 and the width (thickness) of the head portion 15b. can do. That is, the length of the entire antenna mounting device 1 including the mounting bracket 11 in the first linear direction 1M can be adjusted by utilizing the elongated hole 11c of the fixing bracket 11. Further, even if the sound absorbing plate 16 falls due to an earthquake or the like because the fixed piece 11a straddles the head portion 15a of the grid-like structure 15, the fixed piece 11 is a grid-like structure in the antenna mounting device. You can reduce the risk of getting caught in 15 and falling.

It is important that the locking piece 11b has elastic properties. This is because when the antenna mounting device 1 is mounted on the grid-like structure 15 on the system ceiling, the fixing brackets 11 are mounted on both sides of the antenna mounting device 1 and the antenna mounting device 1 is lowered and fitted from above the paper surface of FIG. 3A. At that time, since the locking tongue piece 11b2 gets over the head portion 15b of the grid-like structure 15, the V-shaped angle formed by the locking original piece 11b1 and the locking tongue piece 11b2 is once narrowed, and the locking tongue piece is narrowed. After the 11b2 gets over the head 15a, the V-shaped angle returns so as to elastically widen, and the tip of the locking tongue piece 11b2 comes into contact with the side surface of the grid-like structure 15. Therefore, it becomes extremely easy to mount the antenna mounting device 1 on the grid-like structure. Further, since the locking tongue piece 11b2 is caught on the head portion 15b, the antenna mounting device has an effect of not easily falling off from the grid-like structure. The elastic modulus of the locking piece 11b may be designed according to the situation, and can be easily locked even if the thickness or width of the grid-like structure on the system ceiling in the horizontal direction is slightly changed.

In FIGS. 1, 2, and 3, one fixing bracket 11 is used at each end of the antenna mounting base main body 1a, but a plurality of fixing brackets 11 may be used, and the plurality of fixing strengths have higher fixing strength. Increases and seismic strength increases. Further, the fixing bracket 11 can also be applied to the antenna mounting device of the second embodiment, the third embodiment and the fourth embodiment of the present invention.

Next, FIG. 5 shows a method of installing the antenna mounting device 1 according to the first embodiment of the present invention in the grid-like structure 15 on the ceiling, sliding it, and storing it within the communicable range of the antenna device 6. , 6 and 7 will be described.

One of the features of the antenna mounting device 1 in the first embodiment of the present invention is that the antenna mounting device 1 is located in a grid-like structure on the system ceiling without changing the biaxial rotation directions in the horizontal and vertical directions as in the conventional case. By sliding 17M in the straight line direction 1M or the second straight line direction 2M (see FIG. 5), the target sensor and the terminal such as a PC can be accurately stored in the communicable range in a short time, and , Do not cause or reduce radio interference in the adjacent wireless network system. The antenna mounting device 1 according to the first embodiment of the present invention and the antenna device 6 mounted therein are collectively referred to as an antenna unit 17. The second embodiment, the third embodiment, and the fourth embodiment are also referred to as antenna units.

When the antenna unit 17 according to the first embodiment of the present invention is installed at the first installation location 24 in the grid-like structure 15 on the system ceiling, the communicable range of the antenna unit 17 is as shown in FIG. There may be a terminal 23 such as an external sensor or a PC. This is an example in the case where terminals such as sensors and PCs capable of communicating with the antenna unit 17 in FIG. 5 are arranged radially around the antenna unit 17 as shown in FIG.

In the first embodiment of the present invention, when the target communicable sensors and terminals such as PCs are radially installed around the antenna unit 17, the antenna device 6 supported by the antenna mounting device 1 is installed. By sliding the antenna mounting device 1 along the first linear direction 1M from the initial position and sliding the antenna mounting device 1 along the second linear direction 2M in the lattice structure, all the target sensors and PCs, etc. The terminal can be stored within the communicable range (see FIG. 7).

In the first embodiment of the present invention, the target sensor, a terminal such as a PC, or the like can be easily stored within the communicable range simply by adjusting the slide along the first linear direction 1M and the second linear direction 2M, and can be easily stored in the field. The adjustment time can be shortened, the occurrence of electromagnetic interference in the adjacent wireless communication system or the like can be eliminated or reduced, and the construction quality can be improved.

An exploded perspective view of a second embodiment of the antenna mounting device of the present invention is shown in FIG. The second embodiment of the present invention is a development of the first embodiment, and is an embodiment that enables mounting even if the horizontal grid width of the system ceiling is different.

This will be described with reference to FIG. The antenna mounting base main body 1a is configured to be expandable and contractible along the first linear direction 1M. That is, the folded-back portion 5 and the side surface portion 4 of the antenna mounting base main body 1a are detachably separated from the remaining flat surface portion 1b of the antenna mounting base main body. The folded-back portion 5 and the side surface portion 4 form a part of the expansion / contraction portion 26, and the expansion / contraction flat surface portion 26a is connected to the side surface portion 4 to form an expansion / contraction portion 26 having an integrated U-shaped cross section as a whole. Consists of. The antenna mounting base main body 1b and the telescopic flat surface 26a form the antenna mounting main body 1a. A hole 28 is formed in the flat surface portion 1b of the antenna mounting base body for tightening the telescopic portion 26 to the flat surface portion 1b of the antenna mounting base main body. An elongated hole 27 is provided in the telescopic flat surface portion 26a corresponding to the hole 28. The elongated hole 27 is long in the first linear direction 1M so that the telescopic portion 26 can be moved and adjusted along the first linear direction 1M according to the lattice width.

In tightening the telescopic portion 26 to the flat portion 1b of the antenna mounting base main body, the telescopic flat portion 26a is placed on the flat portion 1b of the antenna mounting base main body and overlapped, and the elongated hole 27 is overlapped with the hole 28. Further, the expansion and contraction are adjusted according to the lattice width, and both are tightened. In this embodiment, screws 27t and nuts 27n are used to tighten the telescopic portion 26 to the flat surface portion 1b of the antenna mounting base body. Further, a fixing bracket mounting hole 10 is formed in the telescopic flat surface portion 26a, and the fixing bracket 11 is mounted as in the first embodiment.

The second embodiment of the present invention is a mode in which the antenna mounting device 1 to which the telescopic portion 26 is mounted can be expanded and contracted in the first linear direction 1M so that it can respond even if the inner width of the grid-like structure on the system ceiling changes. It is a form. Further, when the antenna mounting device 1 of the second embodiment of the present invention is installed in the lattice-shaped object 15 and the construction is adjusted on site, the antenna mounting device 1 of the first embodiment can be adjusted in the same manner as the antenna mounting device of the first embodiment. It is possible.

Next, the third embodiment of the present invention will be described in detail with reference to FIGS. 9, 10, 12, and 13. The third embodiment is an application of the first embodiment. That is, the antenna mounting devices of the first and second embodiments described so far can be adjusted to 1M in the first linear direction and 2M in the second linear direction, but depending on the arrangement of terminals and the office situation, the first It may not be necessary to adjust the linear direction 1M, and it may be necessary to adjust only the second linear direction 2M. The antenna mounting device 1S of the third embodiment is applied in such a case.

A third embodiment is an antenna mounting device 1S that can slide along the second linear direction 2M, and FIG. 9 shows a situation in which the antenna device and the antenna mounting device are disassembled. The white arrows in FIG. 9 indicate the direction in which the antenna device 6 is mounted on the antenna mounting device 1S.

The antenna mounting device 1 and the antenna device 6 are installed in the ceiling. At this time, in order to perform wireless communication with the target sensor in the office or a terminal such as a PC, the antenna device 6 is attached to the antenna mounting device 1S with the element surface 9 on the front facing downward (in the office). Can be installed. An antenna device bolt 8 for attaching to the antenna attachment device 1 is attached to the back surface of the antenna device, and a high frequency connector jack 7 for connecting the high frequency connector plug 13 and the high frequency coaxial cable 14 is attached. It is installed.

In the third embodiment, the antenna mounting device 1S is slidable along the second linear direction 2M, but the antenna device 6 is not slid along the first linear direction 1M. That is, the hole 2S for the antenna device bolt 8 and the hole 3S for the high frequency connector provided in the antenna mounting base main body 1Sa are not elongated holes.

When the antenna mounting device 1S slides along the second linear direction 2M while the antenna device 1S supports the antenna device 6, the side surface portion 4 connected to the antenna mounting base main body 1Sa is connected to the side surface portion 4 as in the first embodiment. This is performed using the folded-back portion 5. The antenna mounting device 1S is installed on the grid-like structure 15 on the system ceiling and fixed by the fixing bracket 11. In order to attach the fixing bracket 11 to the antenna mounting base main body 1Sa, the fixing bracket mounting hole 10 of the antenna mounting base main body 1Sa is used. The position of the mounting bracket 11 can be adjusted in the longitudinal direction by using the elongated hole of 11c shown in FIG.

FIG. 10 is a perspective view of a state in which the antenna device 6 is mounted on the antenna mounting device 1S of the third embodiment of the present invention. In the third embodiment, the antenna mounting device can be slid in the second linear direction 2M with the antenna device 6 supported by the antenna mounting device 1S.

Next, FIG. 12 shows a method of installing the antenna mounting device 1S according to the third embodiment of the present invention in the grid-like structure 15 on the ceiling, sliding it, and storing it within the communicable range of the antenna device 6. , FIG. 13 will be described. The antenna mounting device 1S according to the third embodiment of the present invention and the antenna device 6 mounted therein are collectively referred to as an antenna unit 20.

First, with reference to FIG. 12, an embodiment will be described in a case where the target communicable sensor, a terminal such as a PC, or the like is installed linearly along the second linear direction 2M around the antenna unit 20. ..

When the antenna unit 20 according to the third embodiment of the present invention is first installed in the grid-like structure 15 on the system ceiling, it is out of the communicable range of the antenna unit 20 as shown in FIG. 12 (a). There may be a terminal 23Sa such as a sensor or a PC. When the target communicable terminals such as sensors and PCs are installed linearly in the second linear direction 2M around the antenna unit 20, the antenna unit 20 is placed in the grid-like structure from the initial position. By sliding along the second linear direction 2M, all target sensors and terminals such as PCs can be housed within the communicable range. See FIG. 12 (b).

Next, with reference to FIG. 13, a case where the target communicable sensor, a terminal such as a PC, or the like is installed linearly in the first linear direction 1M, centering on the antenna unit 20 in the third embodiment. An embodiment will be described.

When the antenna unit 20 according to the third embodiment of the present invention is first installed in the grid-like structure 15 on the system ceiling, it is out of the communicable range of the antenna unit 20 as shown in FIG. 13 (a). There may be a terminal 23Sb such as a sensor or a PC.

When the target communicable sensor, PC, etc. are installed linearly along the first linear direction 1M around the antenna unit 20, first, the antenna unit 20 is rotated 90 degrees in the grid-like structure. (See 59 in FIG. 13). As a result, the target communication-enabled sensor, PC, or other terminal is installed along the second straight line direction 2M. Next, the antenna unit 20 is slid in the lattice structure along the second linear direction 2M (see 59 in FIG. 13). By this procedure, all the target sensors and terminals such as PCs can be housed within the communicable range. As a result, it is possible to prevent radio interference from occurring in the adjacent wireless communication system.

An exploded perspective view of a fourth embodiment of the antenna mounting device of the present invention is shown in FIG. The fourth embodiment of the present invention is a development of the third embodiment, and is an embodiment that enables mounting even if the horizontal grid width of the system ceiling is different.

This will be described with reference to FIG. The antenna mounting base main body 1Sa is configured to be expandable and contractible along the first linear direction 1M. That is, the folded-back portion 5 and the side surface portion 4 of the antenna mounting base main body 1Sa are detachably separated from the remaining antenna mounting base main body flat portion 1Sb. The folded-back portion 5 and the side surface portion 4 form a part of the telescopic portion 26, and form the telescopic portion 26 having a U-shaped cross section in which the telescopic flat surface portion 26a is connected to the side surface portion 4 and integrated. ing. The antenna mounting base main body 1Sb and the telescopic flat surface 26a form the antenna mounting main body 1Sa. The antenna mounting base body flat surface portion 1Sb is formed with a hole 28 for tightening the telescopic portion 26 to the antenna mounting base main body flat surface portion 1Sb. An elongated hole 27 is provided in the telescopic flat surface portion 26a corresponding to the hole 28. The elongated hole 27 is long in the first linear direction 1M so that the telescopic portion 26 can be adjusted along the first linear direction 1M according to the lattice width.

In tightening the telescopic portion 26 to the flat portion 1Sb of the antenna mounting base main body, the telescopic flat portion 26a is placed on the flat portion 1Sb of the antenna mounting base main body and overlapped, and the elongated hole 27 is overlapped with the hole 28. Further, the expansion and contraction are adjusted according to the lattice width, and both are tightened. In this embodiment, screws 27t and nuts 27n are used to tighten the telescopic portion 26 to the flat portion 1Sb of the antenna mounting base body. Further, a fixing bracket mounting hole 10 is formed in the telescopic flat surface portion 26a, and the fixing bracket 11 is mounted as in the third embodiment.

The antenna mounting device 1S of the fourth embodiment to which the telescopic portion 26 is mounted can be expanded and contracted in the first linear direction 1M, and can cope with changes in the inner width of the grid-like structure on the system ceiling. Further, when the antenna mounting device 1S of the fourth embodiment of the present invention is installed in the lattice structure 15 and adjusted in the field, the antenna mounting device 1S of the third embodiment is shown in FIGS. 12 and 13. Adjustments can be made in the same manner as described with reference.

The antenna mounting device of the present invention can be used for a network system for office building information management, a data management system for a production line in a manufacturing industry, a wireless control system for a distribution / delivery control center, and the like.

1 Antenna mounting device 1a Antenna mounting pedestal body 1b Antenna mounting pedestal body flat surface 1S Antenna mounting device 1Sa Antenna mounting pedestal body 1Sb Antenna mounting pedestal body flat surface 1M First straight direction 2 Tightening long hole 2M Second straight direction 2S Tightening hole 3 High-frequency connector long hole 3S High-frequency connector hole 4 Antenna mounting stand Side part 5 Antenna mounting stand folding part 6 Antenna device 7 High-frequency connector jack 8 Antenna device bolt 9 Antenna device element surface 10 Fixing bracket mounting hole 11 Fixing bracket 11a Fixing piece 11b Locking piece 11b1 Locking source piece 11b2 Locking tongue piece 11c Long hole 11t Screw for locking the fixing bracket 11n Nut for locking the fixing bracket 12 Nut for locking the bolt 13 High-frequency connector plug 14 High-frequency coaxial cable 15 Lattice Structure 15a Flange 15b Head 16 Sound absorbing plate 17 Antenna unit 17M Slide (movement) direction for adjusting the antenna unit 18 Communication range of the antenna unit 19 Communication of the antenna unit 20 Antenna unit 21 Communication of the antenna unit Possible range 22 Communicatable terminal of antenna unit 23 Terminal out of communicable range 23Sa Terminal out of communicable range 23Sb Terminal out of communicable range 24 Initial installation location of antenna unit 26 Telescopic part 26a Telescopic flat part 27 Telescopic part Long hole 27t for tightening the main body 27t Screw for tightening the telescopic part 27n Nut for tightening the telescopic part 28 Hole for tightening the telescopic part to the main body 29 Office building 30 Office building Ceiling 31 High-frequency coaxial Unit (connects high frequency connector and high frequency coaxial cable)
32 Amplifying device / transmitting / receiving device 33a Antenna unit 33b Antenna unit 33c Antenna unit 33aa 33a Multiple terminals capable of wireless communication 33bb 33b Communication range of multiple terminals 33ar 33a Communication range 33br 33b Communication range 34 In the office 35 Data management room 36 Transmission / reception radio waves in the data management room 37 Data management room Antenna for transmission / reception device 38 Transmission / reception device 39 Computer data management device 40 Anchor 41 Antenna mounting hanging bolt (all screws)
42 Anti-steady suspension bolt (all screws)
43 Steering bracket 44 Mounting flat plate 45 Antenna mounting hardware 46 Antenna device 47 High-frequency coaxial cable 50 Radio wave radiation pattern adjustment direction of antenna device 51 Antenna device PA (using conventional antenna mounting device)
51a Antenna device PA after angle adjustment
52 Direction of adjusting the angle of the antenna device PA to accommodate the PA group 53 Communicable range of the antenna device PA 54 Antenna device PA target wireless communication terminal group: PA group 55 Antenna device PB (conventional technology antenna mounting device) use)
56 51a causes radio interference to the PB group (the radiation range of radio waves changes)
57 Communicable range of antenna device PB 58 Radio-communicable terminal group for antenna device PB: PB group 59 Rotate 90 degrees and slide (move) along the second linear direction 2M.

Claims (16)

The antenna device in a wireless network system composed of an antenna device arranged on the system ceiling of an office building having a lattice structure, a sensor capable of wireless communication arranged in the office, and a computer is attached and supported on the system ceiling. In the antenna mounting device
The antenna mounting device has an antenna mounting base that slidably supports the antenna device in the first straight line direction, and the antenna mounting base is slidable on the system ceiling in a second straight line direction orthogonal to the first straight line direction. Slide mounting means to mount and
An antenna mounting device characterized by being equipped with. The antenna mounting base is a side surface having a main body portion that slidably supports the antenna device in the first straight direction and side surfaces that are connected to both ends of the main body portion in the first straight direction and are orthogonal to the first straight direction. It has a portion and a folded portion having a folded surface orthogonal to the side surface, and the slide mounting means is characterized by being composed of the side surface portion, the folded portion, and a fixing bracket for fixing to the system ceiling. The antenna mounting device according to claim 1. The antenna mounting device according to claim 2, wherein a hole for tightening the antenna device is formed in the main body as an elongated hole extending in the first linear direction. The antenna mounting device according to claim 2 or 3, wherein a hole through which a coaxial connector protruding from the antenna device toward the ceiling side penetrates is formed in the main body portion as an elongated hole extending in the first linear direction. The antenna mounting device according to claim 2, wherein the outer width between the side surface portions of the antenna mounting base is slightly smaller than the inner width of the lattice-shaped structure. The antenna mounting device according to claim 5, wherein the fixing bracket has a fixing piece fixed to the antenna mount and a locking piece elastically locked to the grid-like structure. The antenna mounting device according to claim 6, wherein the fixing piece extends outward so as to be able to straddle the upper part of the lattice-like structure and is connected to the locking piece. 2. The fixing bracket and the antenna mounting base are each formed with holes for tightening each other, and at least one of the holes is an elongated hole in the first linear direction. 7. The antenna mounting device according to any one of 7. The antenna mounting device according to claim 2, wherein the main body of the antenna mounting base can be expanded and contracted in the first linear direction. The antenna device in a wireless network system composed of an antenna device arranged on the system ceiling of an office building having a lattice structure, a sensor capable of wireless communication arranged in the office, and a computer is attached and supported on the system ceiling. In the antenna mounting device
The antenna mounting device includes an antenna mounting base that supports the antenna device and has a longitudinal direction, and a slide mounting means that slidably mounts the antenna mounting base on the system ceiling in a direction orthogonal to the longitudinal direction.
An antenna mounting device characterized by being equipped with. The antenna mounting base supports the antenna device and is connected to a main body portion having a longitudinal direction and both ends in the longitudinal direction of the main body portion, and has side surfaces orthogonal to the longitudinal direction and orthogonal to the side surfaces. 10. The aspect of claim 10, further comprising a folded-back portion having a folded-back surface, and the slide mounting means is composed of the side surface portion, the folded-back portion, and a fixing bracket for fixing to the system ceiling. Antenna mounting device. The antenna mounting device according to claim 11, wherein the outer width between the side surface portions of the antenna mounting base is slightly smaller than the inner width of the lattice-shaped structure. The fixing bracket has a fixing piece fixed to the antenna mounting base and a locking piece elastically locked to the lattice-like structure, and the fixing piece and the locking piece are integrally formed. 11. The antenna mounting device according to claim 11 or 12. The antenna mounting device according to claim 13, wherein the fixing piece extends outward so as to be able to straddle the upper part of the lattice-like structure and is connected to the locking piece. One of claims 11 to 14, wherein holes for tightening are formed in the fixing bracket and the antenna mounting base, respectively, and at least one of the holes is an elongated hole in the longitudinal direction. The antenna mounting device described in the section. The antenna mounting device according to claim 11, wherein the main body of the antenna mounting base is expandable and contractible in the longitudinal direction.