JP7350593B2 - Wireless communication device mounting base and wireless communication device with mounting base - Google Patents

Description

The present invention relates to a wireless communication device mount and a wireless communication device with the mount, and relates to, for example, one that can ensure both wireless performance and heat dissipation performance.

In recent years, the use of the Internet has increased, and the demand for wireless repeaters has increased.
Wireless repeaters do not require wiring, so installation costs can be kept low and they can be installed in locations where wiring is difficult.
As a technique for installing such a repeater, there are techniques disclosed in the following Patent Documents 1, 2, and 3.

In the technology of Patent Document 1, in order to organize cables and save space, the main body housing, which has a flat cylindrical shape and has a connector on the bottom, is held upright by a stand. have.
In the technique of Patent Document 2, in order to attach a wireless communication device to a wall surface so as to maintain wireless communication performance, a bracket member is inserted between the wall surface and the casing of the wireless communication device, so that a predetermined distance can be maintained. The wireless communication device is fixed to the wall with the housing spaced apart from the wall.
In the technology of Patent Document 3, a magnet is used to facilitate attachment of a wireless slave unit to a steel door, etc., and in order to reliably prevent the influence of the magnet, iron door, etc. on wireless communication, the wireless slave unit is dropped into a bracket member. The wireless handset is fixed to the magnetic wall by the magnetic force of the magnet.

However, the technology disclosed in Patent Document 1 has a structure in which the main body housing is held upright by a stand, and when the built-in antenna is placed at the bottom of the main body, it is difficult to maintain good wireless performance due to the mounting surface conditions. It had drawbacks. Furthermore, since the heat radiation path to the lower part of the main body is blocked, the thermal design becomes difficult.
The technique of Patent Document 2 is limited to the case where the rod-shaped antenna is attached to extend in the direction along the wall surface, so it has the disadvantage that it does not mention the effect when using a built-in antenna. Ta. Furthermore, there was a drawback that no mention was made of the effect on heat radiation.
The technique disclosed in Patent Document 3 is limited to suppressing interference with wireless communication caused by magnets when installed on an iron door, and therefore has the disadvantage that it cannot be applied when a general-purpose built-in antenna is used. Furthermore, there was a drawback that no mention was made of the effect on heat radiation.

Japanese Patent Application Publication No. 2002-164808 Japanese Patent Application Publication No. 2008-92080 Japanese Patent Application Publication No. 2012-142894

The present invention aims to ensure both wireless performance and heat dissipation performance.

In order to achieve the above object, the present invention has the following features:
(1) The invention according to claim 1 is a wireless communication device mounting base for mounting a wireless communication device for a communication line in which an internal antenna is arranged in a flat housing, the wireless communication device being placed flatly. a wireless communication device mounting surface having a first bonding surface and a second bonding surface formed side by side in the longitudinal direction, which are fixed in a fixed state ; A first recess formed lower than the first joint surface and the second joint surface, and the first recess are disposed facing each other at a predetermined distance from the wireless communication device mounting surface, and the first recess is formed to be lower than the second joint surface. The wireless communication device includes an installation surface that is fixed to an installation location, and a side surface that is formed between an outer periphery of the wireless communication device mounting surface and an outer periphery of the installation surface, avoiding the first recess. The first joint surface and the second joint surface of the mounting surface are formed at the highest position from the installation surface, so that the entire outer peripheral edge of the first joint surface and the entire outer peripheral edge of the second joint surface are formed. To provide a wireless communication device mounting stand characterized by having an open end .
(2) The invention according to claim 2 is a wireless communication device mounting base for mounting a wireless communication device for a communication line in which an internal antenna is arranged in a flat housing, the wireless communication device being placed flatly. a wireless communication device mounting surface having a first bonding surface and a second bonding surface formed side by side in the longitudinal direction, which are fixed in a fixed state ; A first recess formed lower than the first joint surface and the second joint surface, and the first recess are disposed facing each other at a predetermined distance from the wireless communication device mounting surface, and the first recess is formed to be lower than the second joint surface. an installation surface fixed to an installation location; and a side surface formed between an outer periphery of the wireless communication device mounting surface and an outer periphery of the installation surface, avoiding the first recess, and the first joint. The surface has a first upper surface and a second upper surface formed side by side in the transverse direction, and the second joint surface has a third upper surface and a fourth upper surface formed side by side in the transverse direction, The first upper surface, the second upper surface, the third upper surface, and the fourth upper surface are formed between the first upper surface and the second upper surface and between the third upper surface and the fourth upper surface. a second recess formed lower than the top surface; the second recess has a thickness that allows the wireless communication device to be inserted therein in a state where the wireless communication device is placed vertically; A wireless communication device mount is provided, characterized in that it has a fixing claw that is arranged and fixes the wireless communication device.
(3) In the invention according to claim 3, the first joint surface has a first upper surface and a second upper surface that are formed side by side in the transverse direction, and the second joint surface has a first upper surface and a second upper surface that are formed side by side in the transverse direction. A third upper surface and a fourth upper surface are formed side by side, and screws for fixing the wireless communication device are inserted into the first upper surface, the second upper surface, the third upper surface, and the fourth upper surface. 2. The wireless communication device mounting base according to claim 1, wherein a through hole is formed therein .
(4) In the invention according to claim 4, the first joint surface and the second joint surface are formed at both ends in the longitudinal direction , Alternatively, a wireless communication device mount according to claim 3 is provided.
(5) In the invention according to claim 5, the installation surface is spaced apart from the wireless communication device mounting surface by at least 1/12 of the longest wavelength of radio waves used by the internal antenna of the wireless communication device. There is provided a wireless communication device mounting base according to any one of claims 1 to 4, wherein the wireless communication device mounting bases are arranged opposite to each other.
(6) The invention according to claim 6 further comprises a magnet disposed on the installation surface for fixing to the installation location. A wireless communication device mount according to claim 1 is provided.
(7) In the invention according to claim 7, the first joint surface has a first upper surface and a second upper surface formed side by side in the transverse direction, and the second joint surface has a first upper surface and a second upper surface formed side by side in the transverse direction. The third upper surface has a third upper surface and a fourth upper surface formed side by side, and is formed between the first upper surface and the second upper surface and between the third upper surface and the fourth upper surface . 6. A second recess formed lower than the first upper surface, the second upper surface, the third upper surface , and the fourth upper surface. A wireless communication device mount according to claim 1 is provided.
(8) In the invention according to claim 8, the second recess is formed to have a width that allows the thickness portion to be inserted when the wireless communication device is placed vertically, and is disposed at both ends in the longitudinal direction; 8. The wireless communication device mount according to claim 7 , further comprising a fixing claw for fixing the wireless communication device.
(9) The invention according to claim 9 includes the wireless communication device mounting base according to any one of claims 1 to 8 , and the wireless communication device mounting base attached to the wireless communication device mounting base. A wireless communication device with a mounting base is provided, characterized in that it has a communication device.

According to the present invention, it is possible to ensure both wireless performance and heat dissipation performance depending on the shape of the mounting base.

It is a figure showing a mounting base. FIG. 3 is a diagram showing a repeater installed on a mounting base. FIG. 3 is a diagram showing a repeater installed on a mounting base.

(1) Outline of Embodiment The mounting base 1 (FIG. 1) includes joint surfaces 10a to 10d for fixing the repeater 2 in a flat state.
A recess 6a and a recess 6b are formed between the joint surface 10a and the joint surface 10c, and between the joint surface 10b and the joint surface 10d, respectively. A recess 7a and a recess 7b are formed between the surface 10c and the joint surface 10d, respectively.
When the repeater 2 is fixed on the mounting base 1 in a flat state, a space is formed on the back side of the repeater 2, and the recesses 6a and 6b and the recesses 7a and 7b become air circulation ports opening in four directions. The repeater 2 can be effectively cooled.
Furthermore, since the repeater 2 is fixed apart from the mounting surface at the mounting location by the mounting base 1, radio wave interference due to the mounting surface can be suppressed, and wireless quality can be maintained at a high level.

(2) Details of the embodiment FIG. 1 is a diagram showing a mounting base 1 according to the present embodiment, and FIGS. 1(a) to (c) show a perspective view, a front view, and a bottom view, respectively. ing.
The mounting base 1 is a stand having a substantially rectangular parallelepiped shape with a size of approximately 175×50×25 mm and a weight of approximately 65 g, which functions as a wireless communication device mounting base for mounting a wireless communication device.
In this embodiment, a wireless repeater is installed as an example of a wireless communication device.
The installation surface 18 of the mounting base 1 (FIG. 1(c), the bottom surface of the mounting base 1) has a substantially rectangular shape, and as shown in FIG. 1(a), the long side direction is the longitudinal direction, and the short side is The side direction is defined as the lateral direction, and the direction from the installation surface 18 to a surface (upper surface) on which a repeater 2 (described later) is attached is defined as the height direction.
The mounting base 1 is made of resin (such as polycarbonate) to prevent radio wave interference with wireless communication devices.

There are two types of installation modes for the repeater 2 with respect to the mounting base 1: horizontal installation and vertical installation. First, these will be explained using FIGS. 2 and 3.
FIG. 2 is a diagram showing the repeater 2 fixed to the mounting base 1 in a flat state. FIGS. 2(a) to 2(c) show a perspective view, a front view, and a side view, respectively.

The repeater 2 (Fig. 2(a)) is a flat plate-shaped relay wireless communication device with a size of about 145 x 100 x 28 mm and a weight of about 270 g, and has an internal antenna for a wireless communication line inside the housing. is installed.
The repeater 2 is, for example, a gateway device, and includes an antenna for connecting to a LAN (local area network) and an antenna for connecting to a WAN (wide area network) (none of which are shown) in the housing. In addition, it is equipped with a group of ports for connecting various cables on the side that makes up the longitudinal thickness.
Hereinafter, regarding the flat surface of the mounting base 1 (the surface with the largest area), the surface fixed to the mounting base 1 will be referred to as the back surface, and the surface opposite to this will be referred to as the front surface.

The repeater 2 is installed, for example, in an ATM (automatic teller machine), and mediates communication with a bank server, or wirelessly connects a terminal installed in an office or factory to the Internet.
Furthermore, for example, it is also possible to remotely control the mega solar system by connecting the dedicated port to the control device of the mega solar panel.

The surface of the repeater 2 includes a large number of ventilation holes 5 formed on about half of one side in the longitudinal direction, and also includes ventilation holes 5 formed in a row in the width direction near the opposite end. . A large number of similar ventilation holes 5 are also formed on the back surface.
Although not shown, a metal heat sink is attached to the semiconductor device disposed on the substrate inside the repeater 2, and the heat sink is cooled by the air flowing in and out from the vent 5.
The temperature of the semiconductor device during operation reaches approximately 80 degrees Celsius even if it is air-cooled with a heat sink, and how to keep it cool is extremely important for stable operation of the repeater 2. .

When installed in a flat state, the mounting base 1 is fixed to the center of the back surface of the repeater 2 so that the longitudinal direction of the mounting base 1 and the longitudinal direction of the repeater 2 are aligned.
By attaching the repeater 2 to the mount 1, a mount-equipped wireless communication device is configured that includes a wireless communication device mount and a wireless communication device attached to the wireless communication device mount.

When the repeater 2 installed in a flat state is viewed in the lateral direction of the mounting base 1 (FIG. 2(b)), the recess 6 formed in the mounting base 1, which will be described later, allows the repeater 2 to be placed on the back side in the lateral direction. A heat radiation path is formed.
On the other hand, when viewed in the longitudinal direction of the mounting base 1 (FIG. 2(c)), a heat dissipation path in the longitudinal direction is formed on the back surface of the repeater 2 by a recess 7, which will be described later, formed in the mounting base 1.
In this way, a heat radiation space that is open in the longitudinal direction and the lateral direction is formed on the back surface of the repeater 2, and the repeater 2 can be efficiently cooled.
Furthermore, since the installation position of the repeater 2 is set apart from the mounting location by the height of the mounting base 1, it is possible to reduce radio wave interference due to the mounting location and suppress deterioration of wireless quality.

FIG. 3 is a perspective view showing the repeater 2 fixed to the mounting base 1 in a vertical position.
When fixing in a vertical position, the longitudinal end of the repeater 2 is inserted into a groove formed in the longitudinal direction on the top surface of the mounting base 1 (formed by extending the recess 7 in the longitudinal direction as described later). By inserting and fitting, the repeater 2 is fixed to the mounting base 1.
As described above, the repeater 2 can be installed on the mounting base 1 in a horizontal or vertical position, so depending on the size and shape of the installation location where the repeater 2 is installed, etc. The mounting form can be selected accordingly.

Next, returning to FIG. 1, the structure of the mounting base 1 will be described in detail.
As shown in FIG. 1(b), projecting parts 12a and 12b with a thickness of about half the height h of the mounting base 1 are formed at both ends of the mounting base 1 in the longitudinal direction. has been done.
The width of the overhanging portion 12 (if the overhanging portions 12a and 12b are not particularly distinguished, they will simply be referred to as the overhanging portion 12; the same applies to other components) is the same as the width of the mounting base 1. The length in the longitudinal direction is the extent necessary for arranging a through hole 13 and a claw button 8 (FIG. 1(a)), which will be described later.

As shown in FIG. 1(a), at the four corners of the overhanging portion 12 (that is, at the four corners of the mounting base 1), there are through holes 13a to 13d for screwing the mounting base 1 into screw holes at the installation location. (13a not shown) is formed in the height direction.
A counterbore is formed in the through hole 13 to prevent interference between the screw head and the overhanging portion 12 when screwing, and also to prevent the screw head from protruding excessively.

Bonding surfaces 10a to 10d for bonding the back surface of the repeater 2 are formed on the longitudinally inner side of the projecting portion 12.
The joint surfaces 10a to 10d are formed at a height h (FIG. 1(b)) higher than the upper end surface of the overhang portion 12 and parallel to the installation surface 18 (bottom surface of the mounting base 1).

The joint surfaces 10a and 10b are arranged on one side in the longitudinal direction, and the joint surfaces 10c and 10d are arranged on the other side in the longitudinal direction. It functions as a wireless communication device mounting surface having a first joint surface (joint surfaces 10a, 10b) and a second joint surface (joint surfaces 10c, 10d) formed in parallel.
The first joint surface and the second joint surface are formed at both ends (both end regions) of the mounting base 1 in the longitudinal direction.

Through holes 14a to 14d through which screws are inserted are formed in the joint surfaces 10a to 10d, respectively. The through hole 14 is formed at the same position as the screw hole formed on the back surface of the repeater 2, and when the back surface of the repeater 2 is in contact with the joint surface 10, the back surface shown in FIG. The repeater 2 can be screwed to the mounting base 1 by inserting a screw into the through hole 14 and tightening the screw.

As shown in FIG. 1(b), the height from the installation surface 18 to the joint surface 10 is set to h, and when the repeater 2 is installed flat on the mounting base 1, the back surface of the repeater 2 is The position is higher than the mounting surface of the installation location of the mounting base 1 by h.
The value of height h is set to a value that does not deteriorate the performance of the built-in antenna of repeater 2 due to radio wave interference when mounting base 1 is installed on a metal surface, and is set at the lowest radio frequency used by repeater 2. (that is, the longest wavelength λ), and is designed to ensure approximately λ/12 or more. This value was found through experiments. For example, if the lowest radio frequency used is 800 MHz, the wavelength λ=37.5 cm, so the height h should be λ/12=3 cm or more.
In this way, the mounting surface of the mounting base 1 is placed opposite to the mounting surface of the wireless communication device at a distance of at least one-twelfth of the longest wavelength of the radio waves used by the internal antenna of the wireless communication device.

A recess 6a is formed between the bonding surfaces 10a and 10c from the bonding surface 10a to the bonding surface 10c, and a concave portion 6a is formed between the bonding surfaces 10b and 10d in the same shape from the bonding surface 10b to the bonding surface 10d. A recess 6b is formed.
The recess 6 forms an opening through which cooling air flows in the transverse direction on the back surface of the repeater 2 when the repeater 2 is installed in a flat state. For this reason, the bottom surface of the recess 6 is formed as long as possible in the longitudinal direction and at a position lower than the joint surface 10.

In this way, the mounting base 1 has a first recess formed between the first joint surface (joint surfaces 10a, 10b) and the second joint surface (joint surfaces 10c, 10d), which is lower than both the joint surfaces. (recess 6).
Furthermore, a side surface 19b (FIG. 1(b)) is formed from the outer periphery (edge) of the recess 6b to the installation surface 18, avoiding the recess 6b. Side surfaces 19a are similarly formed on the opposing sides.
In this way, the mounting base 1 has a side surface formed between the outer periphery of the wireless communication device mounting surface and the outer periphery of the installation surface, avoiding the first recess, and the first recess between which the wireless communication device can be mounted. The wireless communication device includes an installation surface that is disposed facing the surface at a predetermined distance (height h) and fixed to the installation location of the wireless communication device.

Further, a recess 7a is also formed between the joint surfaces 10a and 10b that are arranged in the transverse direction. Similarly, a recess 7b is also formed between the joint surfaces 10c and 10d that are aligned in the transverse direction.
The recesses 7a and 7b constitute openings through which cooling air flows in the longitudinal direction when the repeater 2 is attached to the joint surface 10 in a flat state.

In this way, the first joint surface (joint surfaces 10a, 10b) has a first upper surface (joint surface 10a) and a second upper surface (joint surface 10b) formed side by side in the transverse direction, and the second joint surface The surfaces (joint surfaces 10c, 10d) have a third upper surface (joint surface 10c) and a fourth upper surface (joint surface 10d) formed side by side in the transverse direction, and there is a gap between the first upper surface and the second upper surface. , and second recesses (recesses 7a, 7b) formed between the third and fourth upper surfaces and lower than the respective upper surfaces.

In the longitudinal region from the joint surfaces 10a and 10b (i.e., the first joint surface) to the joint surfaces 10c and 10d (i.e., the second joint surface), when the repeater 2 is placed vertically, the A recess 7c into which the thick end portion is inserted, fitted and gripped extends from the recesses 7a and 7b.
In this way, the second recess (recess 7c) is formed to have a width that allows the thickness portion to be inserted into the wireless communication device when it is placed vertically.

The bottom surface of the recess 7c is formed at a lower position than the bottom surface of the recess 6, so that the recess 6 forms a ridgeline.
The corners of the edges are rounded and chamfered to prevent the cooling air flow from being disturbed.
By forming the recess 7c with a lower height inside the recess 6, the repeater 2 can be stored vertically, and when the repeater 2 is placed horizontally, cooling air can be The volume and space for convection on the back surface of the repeater 2 can be increased, and the cooling effect can be enhanced.
The thickness of the bottom surface of the recess 7c is made as thin as possible while ensuring the strength to hold the repeater 2 vertically or horizontally, thereby reducing weight and material costs.

In the recess 7a, when the repeater 2 is inserted into the recess 7c in a vertical position, the repeater 2 is attached to the mounting base 1 by being engaged with a claw groove formed on the side surface of the repeater 2 in the thickness direction. A fixing claw 9a for fixing is formed.
The fixed claw 9a includes a claw tip portion that protrudes into the region of the recess 7c, and a biasing portion that is fixed to the recess 7a and urges the claw tip portion to the claw groove of the repeater 2.
Further, a claw button 8a extends from the biasing portion into the space above the projecting portion 12a.

The fixed position of the fixed claw 9a is in a closed state where the tip of the claw locks and fixes the repeater 2. When the claw button 8a is pressed down, the biasing part is bent by the principle of leverage and the tip of the claw is closed. is pushed upward to release the lock and open.
A similar fixing claw 9b is also formed in the recess 7b, and a claw button 8b extends above the projecting portion 12b.
As described above, the mounting base 1 has fixing claws arranged at both ends in the longitudinal direction to fix the wireless communication device.

The tip end portion of the fixed claw 9 is wedge-shaped, with the upper surface sloped and the lower surface parallel to the installation surface 18.
When the repeater 2 is fixed to the mounting base 1 in a vertical position, when the repeater 2 is inserted into the recess 7c, the side surface of the thick part of the repeater 2 comes into contact with the wedge-shaped slope part of the fixing claw 9, and this Push it out.
Further, when the relay 2 is inserted, when the tip of the claw reaches the position of the groove of the claw of the relay 2, the tip of the claw fits into the groove of the claw due to the urging force of the urging portion.
Thereafter, the repeater 2 is fixed to the mounting base 1 by the fixing claw 9 urging the repeater 2 downward by the catch of the parallel surface of the wedge-shaped lower surface.

At this time, the operator will be able to recognize that the repeater 2 has been correctly attached to the mounting base 1 by the generation of a fitting sound such as a "click" and by the feeling of the tip of the claw falling into the claw groove. can.
On the other hand, when removing the repeater 2 from the mounting base 1, press down on the claw button 8 and push up the tip of the claw. pull it out in the direction.

In addition to the through holes 13 formed at the four corners, the mounting base 1 can also be screwed to the installation location through through holes 25a and 25b (FIG. 1(a)) formed in the recess 7c.
Furthermore, a magnet 21 formed of, for example, a neodymium magnet is screwed to the installation surface 18 (FIG. 1(c)).
The magnets 21a and 21b are formed in a flat plate shape, and are installed so that magnetic poles of the same polarity are flush with the installation surface 18.
Therefore, if the mounting surface at the installation location is made of a ferromagnetic material such as an iron plate, the mounting base 1 can be attached and fixed to the mounting surface using magnetic force.
Since the magnet 21 is provided on the bottom surface of the mounting base 1, a distance can be placed between the repeater 2 and the magnet 21, and radio wave interference caused by the magnet 21 can be reduced.
In this way, the mounting base 1 is provided with a magnet arranged on the installation surface for fixing to the installation location, taking into account the case where it is installed on a metal surface.

The embodiments described above can provide the following effects.
(1) By installing the mounting base 1 between the repeater 2 and the mounting surface, a space can be secured between the repeater 2 and the mounting surface, which eliminates the problem of deterioration of built-in antenna performance, that is, deterioration of wireless performance. can do.
(2) Since a heat radiation path can be secured by the recesses 7 and 6 provided in the mounting base 1, the heat radiation performance of the repeater 2 can be improved and thermal design can be facilitated.

1 Mounting base 2 Relay 5 Ventilation port 6 Recess 7 Recess 8 Claw button 9 Fixed pawl 10 Joint surface 12 Projection 13 Through hole 14 Through hole 18 Installation surface 19 Side surface 21 Magnet 25 Through hole

Claims (9)

A wireless communication device mounting stand for mounting a wireless communication device for a communication line in which an internal antenna is arranged in a flat housing,
a wireless communication device mounting surface having a first bonding surface and a second bonding surface formed side by side in the longitudinal direction, on which the wireless communication device is fixed in a flat state;
a first recess formed between the first joint surface and the second joint surface and lower than the first joint surface and the second joint surface;
an installation surface that is arranged to face the wireless communication device mounting surface by a predetermined distance with the first recess in between, and is fixed to the installation location of the wireless communication device;
a side surface formed between the outer periphery of the wireless communication device mounting surface and the outer periphery of the installation surface, avoiding the first recess ;
The first bonding surface and the second bonding surface of the wireless communication device mounting surface are formed at the highest position from the installation surface, so that the entire outer periphery of the first bonding surface and the second bonding surface are connected to each other. The entire outer periphery is an open end,
A wireless communication device mounting stand characterized by: A wireless communication device mounting stand for mounting a wireless communication device for a communication line in which an internal antenna is arranged in a flat housing,
a wireless communication device mounting surface having a first bonding surface and a second bonding surface formed side by side in the longitudinal direction, on which the wireless communication device is fixed in a flat state;
a first recess formed between the first joint surface and the second joint surface and lower than the first joint surface and the second joint surface;
an installation surface that is arranged to face the wireless communication device mounting surface by a predetermined distance with the first recess in between, and is fixed to the installation location of the wireless communication device;
a side surface formed between the outer periphery of the wireless communication device mounting surface and the outer periphery of the installation surface, avoiding the first recess ;
The first joint surface has a first upper surface and a second upper surface formed side by side in the transverse direction,
The second joint surface has a third upper surface and a fourth upper surface formed side by side in the transverse direction,
The first upper surface, the second upper surface, the third upper surface, and the fourth upper surface are formed between the first upper surface and the second upper surface and between the third upper surface and the fourth upper surface. a second recess formed lower than the top surface;
The second recess is formed to have a width that allows a thickness portion to be inserted into the wireless communication device when it is placed vertically;
having fixing claws arranged at both ends in the longitudinal direction for fixing the wireless communication device;
A wireless communication device mounting stand characterized by: The first joint surface has a first upper surface and a second upper surface formed side by side in the transverse direction,
The second joint surface has a third upper surface and a fourth upper surface formed side by side in the transverse direction,
Through holes are formed in the first top surface, the second top surface, the third top surface, and the fourth top surface, through which screws for fixing the wireless communication device are inserted.
The wireless communication device mount according to claim 1, characterized in that: The first joint surface and the second joint surface are formed at both ends in the longitudinal direction,
The wireless communication device mount according to claim 1 , claim 2, or claim 3, characterized in that: The installation surface is disposed opposite to the wireless communication device mounting surface at a distance of 1/12 or more of the longest wavelength of radio waves used by the internal antenna of the wireless communication device.
The wireless communication device mount according to any one of claims 1 to 4 . a magnet disposed on the installation surface for fixing to the installation location;
The wireless communication device mount according to any one of claims 1 to 5, characterized in that the wireless communication device mount comprises: The first joint surface has a first upper surface and a second upper surface formed side by side in the transverse direction,
The second joint surface has a third upper surface and a fourth upper surface formed side by side in the transverse direction,
The first upper surface, the second upper surface, the third upper surface, and the fourth upper surface are formed between the first upper surface and the second upper surface and between the third upper surface and the fourth upper surface. a second recess formed lower than the top surface;
The wireless communication device mount according to any one of claims 1 and 4 to 6 . The second recess is formed to have a width that allows a thickness portion to be inserted into the wireless communication device when it is placed vertically;
having fixing claws arranged at both ends in the longitudinal direction for fixing the wireless communication device;
8. The wireless communication device mount according to claim 7 . A wireless communication device mounting stand according to any one of claims 1 to 8 ;
the wireless communication device attached to the wireless communication device mount;
A wireless communication device with a mounting base, comprising:

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