KR102623874B1 - antenna apparatus for elevator with rotating reflection pannel - Google Patents

Abstract

The present invention relates to an antenna device for an elevator equipped with a reflective panel whose angle is adjustable.
The antenna device of the present invention is an elevator antenna device installed outside the elevator to wirelessly transmit and receive data with the communication module of the elevator moving up and down within the elevator space, comprising: a frame (10); a bottom plate (20) mounted on the frame (10) and on which an antenna (21) is installed to protrude upward; A plurality of reflections are installed radially in succession along the circumference of the bottom plate 20, are rotatably coupled to the bottom plate 20, partially overlap each other on the sides, and have an upper side that is wider than the lower side. Panel 30 and; It is configured to include a rotation drive device 40 that rotates the reflective panels.
According to the present invention, in constructing an antenna device capable of transmitting and receiving data with a communication module installed in an elevator, the reflector of the antenna device is rotatable so that the reflection angle of radio waves is adjusted according to the movement of the elevator, thereby improving wireless transmission and reception. It can be accomplished smoothly.
As a result, smooth wireless communication can be achieved in a fast-moving elevator within a closed elevator space.

Description

Antenna apparatus for elevator with rotating reflection panel}

The present invention relates to an antenna device for an elevator, and in particular for an elevator equipped with a reflective panel whose angle is adjustable to enable smooth communication by adjusting the angle according to the distance from the elevator. It is about an antenna device.

With the spread of smartphones, everyone now carries a smartphone with them at all times, and can now access the Internet anytime, anywhere and exchange various information in addition to calling or texting.

In particular, the activation of social network services (SNS) through smartphones is further increasing users' utilization of smartphones.

In this way, communication devices such as smartphones have already become firmly established as necessities of life.

People share various information and converse with others through smartphones, not only when riding the subway or bus, but also while walking.

We live in an age where information can be accessed through smartphones anytime, anywhere, but access to such information is blocked especially inside elevators.

This is due to electromagnetic wave blocking for the safety of elevator operation.

In addition, recently, there has been an increasing number of cases where devices that display advertisements or news are installed inside elevators and various advertisements or news are provided through these devices. However, there are many difficulties in connecting to these devices by wire, so wireless data communication Although there is a demand for it, there are still many difficulties in enabling stable transmission and reception of wireless signals.

Accordingly, there is a need for research into ways to enable communication devices to maintain wireless network access even inside the elevator without affecting the safe operation of the elevator.

As a related technology, "Elevator Communication Relay System" (Korean Patent Publication No. 10-1141515, Patent Document 1) installs a communication repeater at the top of the elevator car, and the signal received from the communication repeater is installed outside the top of the elevator car. While an FSO transceiver that converts and transmits space optics signals is installed, a communication relay system consisting of an FSO transceiver that transmits the signals received from the FSO transceiver in the elevator shaft to an external communication network has been disclosed.

However, as recent buildings have become taller and the transmission/reception distance has increased, there are also limitations to the method using the FSO transceiver due to radio wave reflection and scattering in closed spaces.

KR 10-1141515 (2012.04.24)

The antenna device for an elevator of the present invention is intended to solve the problems occurring in the prior art as described above. In constructing an antenna device capable of transmitting and receiving data with a communication module installed in an elevator, the reflector of the antenna device is made rotatable. The purpose is to adjust the reflection angle of radio waves according to the movement of the elevator so that wireless communication can be carried out more smoothly.

In order to solve the above problems, the elevator antenna device equipped with a reflective panel whose angle is adjustable according to the present invention is installed outside the elevator to wirelessly transmit and receive data with the communication module of the elevator moving up and down within the elevator space. An antenna device for an elevator, comprising: a frame (10); a bottom plate (20) mounted on the frame (10) and on which an antenna (21) is installed to protrude upward; A plurality of reflections are installed radially in succession along the circumference of the bottom plate 20, are rotatably coupled to the bottom plate 20, partially overlap each other on the sides, and have an upper side that is wider than the lower side. Panel 30 and; It is configured to include a rotation drive device 40 that rotates the reflective panels.

In the above configuration, a control device 50 that controls the operation of the rotation drive device 40 is further provided.

In addition, the control device 50 is characterized in that it is configured to control the operation of the rotation drive device 40 according to the distance from the elevator.

In addition, the control device 50 includes a distance detection unit 51 that detects the distance to the elevator; an angle calculation unit 52 that calculates the rotation angle of the reflective panel based on the distance data provided from the distance detection unit 51; It is characterized by comprising a drive control unit 53 that controls the rotation drive device 40 according to the angle calculated by the angle calculation unit 52.

In addition, the rotation driving device 40 includes a wire connection member 41 installed on the back of the reflection panel 30 and having a wire through hole 41a formed therein; A wire (42) installed to continuously penetrate the wire penetration hole (41a) of the adjacent wire connection member (41); A lower pipe body (43a) connected to both sides of the frame 10 and having an empty interior, an upper pipe body (43b) slidably fitted to the lower pipe body (43a), and a lower pipe body (43a) A lifting frame (43) connected to the upper pipe body (43b) and consisting of a vertical movement device (43c) that moves the upper pipe body (43b) in the vertical direction; A bobbin (44a) is installed on the upper pipe body (43b) and has the wire 42 wound thereon, and is installed on the upper pipe body (43b) and has a shaft connected to the bobbin (44a) to form the bobbin (44a). A wire winding device 44 configured to rotate the reflective panel 30 connected to the wire connecting member 41 by pulling or unwinding the end of the wire 42 and consisting of a drive motor 44b that rotates in both directions. When controlling the reflective panel 30 to rotate upward, the drive control unit 53 provides an upward movement signal to the vertical movement device 43c and causes the drive motor 44b to move the wire 42. When a signal to pull is provided and the reflective panel 30 is controlled to rotate downward, a downward movement signal is provided to the vertical movement device 43c and a signal to cause the drive motor 44b to unwind the wire 42. It is characterized by providing.

According to the present invention, in constructing an antenna device capable of transmitting and receiving data with a communication module installed in an elevator, the reflector of the antenna device is rotatable so that the reflection angle of radio waves is adjusted according to the movement of the elevator, thereby improving wireless transmission and reception. It can be accomplished smoothly.

As a result, smooth wireless communication can be achieved in a fast-moving elevator within a closed elevator space.

1 is a schematic diagram showing the installation concept of an elevator antenna device equipped with a reflective panel whose angle is adjustable according to the present invention.
Figure 2 is a perspective view showing an example of an antenna device for an elevator equipped with a reflective panel whose angle is adjustable according to the present invention.
Figure 3 is a perspective view showing the reflective panel in Figure 2 in an unfolded state.
Figure 4 is a configuration diagram showing an example of a control device in the present invention.
Figure 5 is a conceptual diagram showing a case where the distance detection unit of the control device is linked to the control system of the elevator in the present invention.

As shown in FIG. 1, the present invention is an elevator antenna device installed outside the elevator to wirelessly transmit and receive data with the communication module (A) of the elevator (2) moving up and down within the elevator space (1). It's about B).

In the drawing, the antenna device (B) is shown as being installed at the top of the lifting space (1), but this is shown for ease of understanding and its position can be freely adjusted.

The antenna device for an elevator of the present invention includes a frame 10, a floor plate 20, a reflective panel 30, and a rotation drive device 40, and a control device 50 can be additionally installed here. there is.

Hereinafter, the configuration of the present invention will be described in detail as follows.

In FIG. 1, the frame 10 is shown in a stick shape, but this is only an example for ease of understanding, and may be formed in various shapes to suit the installation location and installation target.

The bottom plate 20 has a circular plate shape as shown in the attached drawing, and an antenna (feeder) of reference numeral 21 is installed on the bottom surface to protrude upward.

The antennas 21 may be installed singly or in plural numbers spaced apart from each other.

At this time, a hinge 22 may be installed on the floor plate 20 by bending a steel plate radially into a circle along the installation position of the reflective panel 30 or by integrally fixing a pipe.

Although not shown, the antenna 21 may be configured in the form of a multi-tube to adjust its height, and is connected to a driving device (actuator) for height adjustment and connected to a control device 50 to be described later to adjust the height. It may be configured to automatically adjust.

As shown in the attached drawing, the reflective panel 30 is rotatably coupled to the bottom plate 20 through a hinge 22.

In the drawing, the hinge shaft 31 is bent into a circle and the lower part is partially cut to be inserted into the portion serving as the hinge 22. However, the configuration of the present invention is not limited to this.

In the above-mentioned configuration, the hinges 22 are arranged at a constant angle with respect to the center of the floor plate, so that the reflective panel 30 can be configured to rotate while being twisted about the center of the floor plate 20.

When the reflective panels 30 are arranged at a certain angle, the radially arranged reflective panels 30 can create short and accurate high-frequency communication with a resonator caused by eddy currents in the cavity.

A plurality of these reflective panels 30 are installed radially in succession along the circumference of the bottom plate 20.

At this time, it is preferable that adjacent reflective panels 20 partially overlap each other on the sides so that the reflective panels 20 can be deployed smoothly.

In addition, it is desirable that the upper side is wider than the lower side so that no empty space is formed between the reflective panels 30 when deployed widely.

The rotation driving device 40 is configured to rotate the reflective panel.

An example of the rotation drive device 40 may be composed of a wire connection member 41, a wire 42, a lifting frame 43, and a wire winding device 44 installed on each reflective panel 30.

As can be seen from the drawing, a tubular wire connecting member 41 with a wire through hole 41a formed in the horizontal direction is installed on the back (outer surface) of each reflective panel 30.

In addition, the wire 42 is installed to continuously penetrate the wire penetration hole 41a of the wire connection member 41 provided in each adjacent reflective panel 30.

The lifting frame 43 consists of a lower pipe body (43a), an upper pipe body (43b), and a vertical movement device (43c).

The lower pipe body (43a) is connected to both sides of the frame (10) and is made of an empty pipe.

The upper pipe body (43b) is slidably coupled to the lower pipe body (43a).

The lower part of the vertical movement device (43c) is connected to the lower pipe body (43a) and the upper part is connected to the upper pipe body (43b), and is configured to move the upper pipe body (43b) in the vertical direction.

In the drawing, the vertical movement device 43c is shown as an example consisting of a hydraulic or pneumatic actuator, but is not limited thereto.

The wire winding device 44 is configured to rotate the reflective panel 30 by pulling or unwinding one end or both ends of the wire 42.

An example of the wire winding device 44 may include a bobbin 44a on which a wire is wound, and a drive motor 44b configured to rotate the bobbin 44a in both directions.

The bobbin (44a) is installed in the upper pipe (43b) as shown, and the end of the wire (42) is wound.

The drive motor 44b is installed on the upper pipe body 43b and has a shaft connected to the bobbin 44a to rotate the bobbin 44a in both directions.

If, in the above configuration, the lifting frame 43 is not provided and only the wire winding device 44 is provided, the reflective panel 30 can be easily rotated to spread widely, but in the opposite case, that is, the reflective panel 30 is moved upward. Rotation may not be performed smoothly due to the tension or tension of the wire 42.

In addition, the height of the wire connection member 41 changes according to the rotation of the reflective panel 30, and in this process, a height difference with the bobbin 44a occurs, which may prevent smooth operation.

However, when the lifting frame 43 is provided and operates in conjunction with the operation of the drive motor 44b, the upper pipe body 43b moves downward when the reflective panel 30 is rotated downward.

In the above configuration, a control device 50 that controls the operation of the rotation drive device 40 may be further provided.

At this time, the control device 50 is preferably configured to control the operation of the rotation drive device 40 according to the distance from the elevator A, specifically, the distance from the communication module A mounted on the elevator.

For this purpose, the control device 50 includes a distance detection unit 51 that detects the distance to the communication module of the elevator, and an angle calculation unit that calculates the rotation angle of the reflective panel 30 based on the distance data provided from the distance detection unit 51. (52) and a drive control unit 53 that controls the rotation drive device 40 according to the angle calculated by the angle calculation unit 52.

An example of the distance detection unit 51 may be composed of a data storage unit 51a that is connected to the elevator control system 60, receives data on the floor location of the elevator 2 in real time, and stores the received data in real time. there is.

Specifically, the elevator control system 60 is provided with a switch-in input unit 61 for each floor that the user presses to use the elevator, and an operation control unit 62 that controls the operation of the elevator according to the input data. A sensing unit 63 is installed in the elevator space of each floor and provides the current floor-specific location information of the elevator to the operation control unit whenever the elevator is located. The data storage unit 51a is connected to the operation control unit 62 and the operation control unit 62. It may be electrically connected and configured to receive and store floor-specific location information of the current elevator inputted to the operation control unit 62.

Another example of the distance detection unit 51 is a distance detection sensor that can directly measure the position of the elevator 2 within the elevator space 1.

In other words, by installing a transmitter that emits an infrared signal or a receiver that receives an infrared signal in an elevator, and installing a receiver that receives the signal or a transmitter that transmits the signal as a pair at the top or bottom of the elevator space, the time it takes to receive the signal is reduced. Depending on the calculation, you can also measure the distance.

The angle calculation unit 52 is configured to calculate the rotation angle of the reflective panel based on distance data provided from the distance detection unit 51 using a calculation formula input into a program in advance.

The calculation formula can be applied by calculating the relationship between the radio wave reception rate according to the relationship between the distance of the elevator and the rotation angle of the reflective panel through repeated experiments.

The drive control unit 53 controls the operation of the rotation drive device 40, more specifically the drive motor 44b and the vertical movement device 43c, according to the angle calculated by the angle calculation unit 52.

More specifically, when controlling the reflective panel 30 to rotate upward, an upward movement signal is provided to the vertical movement device 43c and the drive motor 44b moves the wire 42 to the bobbin 44a. provide turn signals to

When controlling the reflective panel 30 to rotate downward, a downward movement signal is provided to the vertical movement device 43c and a signal is provided to cause the drive motor 44b to unwind the wire 42 from the bobbin 44a. do.

In addition, the control device 50 may be equipped with a separate main communication module 54 that wirelessly relays the external communication network and the elevator communication module.

Accordingly, the control device 50 calculates the rotation angle through the angle calculation unit 52 based on the distance data received from the distance detection unit 51, and moves the drive motor 44b, up and down under the control of the drive control unit 53. The operation of the mobile device (43c) is controlled to rotate the reflective panel (30) in real time, and the external communication network and the communication module (A) mounted on the elevator communicate wirelessly with each other through the main communication module (54). This allows signals to be transmitted smoothly without interruption.

In particular, by utilizing the rotation of the reflective panel 30 under the control of the control device 50, a designated area can be created to enable communication while minimizing interference and disruption from other radio waves.

In addition, the reflective panels 30 arranged at regular intervals have amplification by eddy currents, and the resonant wave boss can be supplied with a protruding resonance design, creating an ultra-high frequency field.

In addition, the communication module mounted on the elevator can provide a Wi-Fi signal inside the elevator to provide a wireless Internet environment to the mobile terminal carried by the user, or to provide a wireless Internet environment to tablets mounted in the elevator. There will be.

1: Elevating space 2: Elevator
A: Elevator communication module B: Antenna device
10: frame 20: bottom plate
21: antenna 22: hinge
30: Reflective panel 31: Hinge axis
40: wire connection member 41a: wire penetration hole
42: wire 43: lifting frame
43a: lower pipe body 43b: upper pipe body
43c: Up and down device 44: Wire winding device
44a: Bobbin 44b: Drive motor
50: Control device 51: Distance detection unit
51a: data storage unit 52: angle calculation unit
53: Drive control unit 54: Main communication module
60: Elevator control system 61: Switch input unit
62: operation control unit 63: sensing unit

Claims (5)

In the elevator antenna device installed outside the elevator to wirelessly transmit and receive data with the communication module (A) of the elevator (2) moving up and down within the elevator space (1),
Frame (10) and;
a bottom plate (20) mounted on the frame (10) and on which an antenna (21) is installed to protrude upward;
A plurality of reflections are installed radially in succession along the circumference of the bottom plate 20, are rotatably coupled to the bottom plate 20, partially overlap each other on the sides, and have an upper side that is wider than the lower side. Panel 30 and;
a rotation driving device 40 that rotates the reflective panels;
It is configured to include a control device 50 that controls the operation of the rotation drive device 40,
The control device 50 is configured to control the operation of the rotation drive device 40 according to the distance from the elevator,
The control device 50,
a distance detection unit 51 that detects the distance to the elevator;
an angle calculation unit 52 that calculates the rotation angle of the reflective panel based on the distance data provided from the distance detection unit 51;
It is configured to include a drive control unit 53 that controls the rotation drive device 40 according to the angle calculated by the angle calculation unit 52,
The rotation drive device 40,
A wire connection member (41) installed on the back of the reflective panel (30) and having a wire penetration hole (41a) formed therein;
A wire (42) installed to continuously penetrate the wire penetration hole (41a) of the adjacent wire connection member (41);
A lower pipe body (43a) connected to both sides of the frame 10 and having an empty interior, an upper pipe body (43b) slidably fitted to the lower pipe body (43a), and a lower body to the lower pipe body (43a). A lifting frame (43) connected to the upper pipe body (43b) and consisting of a vertical movement device (43c) that moves the upper pipe body (43b) in the vertical direction;
A bobbin (44a) is installed on the upper pipe body (43b) and has the wire 42 wound thereon, and is installed on the upper pipe body (43b) and has a shaft connected to the bobbin (44a) to form the bobbin (44a). A wire winding device 44 configured to rotate the reflective panel 30 connected to the wire connecting member 41 by pulling or unwinding the end of the wire 42 and consisting of a drive motor 44b that rotates in both directions. It is done,
When controlling the reflective panel 30 to rotate upward, the drive control unit 53 provides an upward movement signal to the vertical movement device 43c and signals the drive motor 44b to pull the wire 42. provide,
When controlling to rotate the reflective panel 30 downward, a downward movement signal is provided to the vertical movement device 43c and a signal is provided to cause the drive motor 44b to unwind the wire 42. ,
An elevator antenna device equipped with an angle-adjustable reflective panel. delete delete delete delete