KR100749627B1 - Plasma display apparatus with built-in antenna - Google Patents

Abstract

According to the present invention, an antenna embedded plasma display device includes a panel displaying an image, a frame supporting the panel on a rear surface of the panel, and a circuit unit driving the panel, wherein the frame includes a chassis base supporting the panel. And a predetermined arrangement of conductive reinforcements coupled to a rear side of the chassis base in a long bar shape to prevent twisting or bending of the chassis base, wherein at least some of the reinforcements are connected to an antenna connection terminal. Characterized in forming an antenna. Therefore, since the analog TV receiving antenna and / or FM radio receiving antenna can be installed inside the PDP, there is no need to install a separate antenna externally, and there is no need to waste unnecessary space for installing and connecting the external antenna. .

Description

Plasma display with built-in antenna {PLASMA DISPLAY APPARATUS WITH BUILT-IN ANTENNA}

1 is a schematic exploded perspective view of a PDP according to an embodiment of the present invention;

2 to 4 are schematic diagrams showing that an antenna is installed on the back of a frame of a PDP according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: PDP 120: panel

150: chassis base 155, 155 ': reinforcement

160: circuit part 200, 200 ': antenna

250, 250 ': Antenna connection

The present invention relates to an antenna-embedded plasma display device in which at least a part of an array of reinforcing members which are coupled to the rear of the chassis base in a long bar shape to prevent twisting or bending of the chassis base.

Recently, many flat display devices (CRTs) have been developed to replace Cathode Ray Tubes (CRTs). Representative examples of such flat panel display devices include liquid crystal display devices (LCDs), electro-luminescence display devices (ELDs), field emission display devices (FEDs), and plasmas. And a display panel (PDP; Plasma Display Panel).

Among such flat panel display apparatuses, the PDP displays an image by plasma discharge, which has the advantages of enabling complete digital implementation and relatively large screen implementation compared to other flat panel display apparatuses.

Such a PDP is composed of a filter assembly, a panel, a heat conductive sheet, a chassis base, a circuit part, a connection member, a protective plate, and various additional devices housed inside the front / rear case.

The PDP can be connected to an external receiver (set-top box) to display digital broadcasts or to connect to a home theater, such as a DVD, to display movies. However, in addition to these applications, users can watch analog TV using the PDP. It may be. In order to watch analog TV, a separate TV receiving antenna is required. If the antenna can be built using a wide surface of the PDP, there is no need to install a separate antenna externally, and unnecessary space is required by installing and connecting an external antenna. There is no need to waste it.

In addition, users may wish to listen to FM radio embedded in a home theater. Likewise, a separate FM radio reception antenna is required to listen to FM radio. If the antenna can be built using the wide side of the PDP, the external receiver such as a home theater with an FM radio and the FM reception built into the PDP can be used. By connecting the connecting terminal of the antenna to the connector, there is no need to install a separate antenna to the outside, and there is no need to waste unnecessary space due to the installation and connection of the external antenna.

The present invention is to solve the above problems, at least some of the array of reinforcing materials are coupled to the rear of the chassis base in a long bar (bar) shape to prevent the twist or bending of the chassis base to form an antenna, the inside of the PDP The purpose is to install an analog TV receiving antenna and / or an FM radio receiving antenna.

In order to achieve the above object, an antenna embedded plasma display device according to the present invention is provided.

A panel for displaying an image, a frame for supporting the panel on the back of the panel, and a circuit portion for driving the panel, wherein the frame includes a chassis base for supporting the panel and a twist or bending of the chassis base. And a predetermined arrangement of conductive reinforcements coupled to the back of the chassis base in a long bar shape, wherein at least some of the reinforcements are connected to the antenna connection terminals to form an antenna.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic exploded perspective view of a PDP according to an embodiment of the present invention.

Referring to the drawings, the plasma display apparatus 100 includes a panel 120, a thermal conductive sheet 130, an adhesive member 140, a chassis base 150, a circuit unit 160, a connection member 170, and a protective plate 180. And an antenna 200.

The panel 120 displays an image by discharge generated by a driving signal provided from a circuit element formed in the circuit unit 160. To this end, the panel 120 forms a partition, an electrode, a phosphor, a dielectric, and a protective film between the two substrates 120a and 120b to form a space in which discharge occurs, that is, a discharge cell. The discharge cell is also filled with an inert gas that emits ultraviolet rays in the wavelength band that excite the phosphor during discharge. The panel 120 is connected to the circuit unit 160 by a Tape Carrier Package (TCP) 170 in the form of a chip-on-film in which a flexible printed circuit (FPC) or some driving chips are mounted.

The thermal conductive sheet 130 is inserted between the panel 120 and the chassis base 150 to transfer heat generated from the panel 120 when the PDP is driven to the chassis base 150 or to dissipate heat to heat the panel 120. To prevent it from rising sharply. In addition, the thermal conductive sheet 130 evenly distributes the temperature distribution of the non-uniform panel 120, thereby preventing the panel 120 from being damaged or malfunctioned due to a local temperature difference. The heat conducting sheet 130 is preferred for the normal operation of the PDP different from the attachment method and the role depending on the material of the chassis base 150. For example, when the material of the chassis base 150 is a material having good thermal conductivity and heat dissipation characteristics such as metal, the thermal conductive sheet 130 is in close contact with the chassis base 150. In this case, a considerable amount of heat generated from the panel 120 is transferred to the chassis base 150 by the heat conductive sheet 130 to radiate heat, and part of the heat is radiated by the heat conductive sheet 130. On the other hand, when the material of the chassis base 150 is not good thermal conductivity and heat dissipation characteristics, such as plastic, the thermal conductive sheet 130 and the chassis base 150 is installed to have a predetermined interval. At this time, most of the heat generated in the panel 120 is radiated by the thermal conductive sheet 130, it is possible to maintain a constant temperature of the panel 120.

The adhesive member 140 fixes the panel 120 to the chassis base 150. To this end, the adhesive member 140 is formed in the form of a strip or frame in the edge portion of the thermal conductive sheet 130, as shown in Figure 1, thereby fixing the panel 120 to the chassis base 150. As the adhesive member 140, it is possible to use an adhesive, an adhesive sheet and an adhesive tape. The adhesive member 140 may vary the thickness and shape of the attachment method and the adhesive member 140 according to the characteristics of the chassis base 150. As described above, in the case of using a chassis base of poor thermal conductivity and heat dissipation characteristics, it is preferable to provide a space between the adhesive members 140. The reason why the adhesive members 140 are spaced apart at predetermined intervals is to facilitate heat dissipation of the thermal conductive sheet 130 by allowing air to flow through the space between the adhesive members 140. In addition, it is preferable to form a gap in which air can be distributed by increasing the thickness of the adhesive member 140 to dissipate the heat conductive sheet 130. On the other hand, when using the chassis base of the material having good thermal conductivity and heat dissipation characteristics, the shape and shape of the adhesive member 140 should be determined and used so that the thermal conductive sheet 130 and the chassis base 150 can be in close contact.

The chassis base 150 fixes the panel 120 by the adhesive member 140, and also supports and fixes the circuit unit 160 by fastening members such as bosses and screws. The chassis base 150 serves as a support member of the panel 120 and simultaneously radiates heat generated from the panel 120 and the circuit unit 160 to the outside, and is usually made of metal for grounding the circuit unit 160. It is made of aluminum. Recently, as the PDP becomes thinner, the thickness of the chassis base 150 is required to be thinner, but when the thickness of the chassis base 150 becomes thinner, the function of supporting the panel is weakened. Therefore, in order to prevent twisting or bending of the chassis base 150 which may be generated while the thickness of the chassis base 150 becomes thin, a reinforcing material 155 is installed on the rear surface of the chassis base 150 to prevent the chassis base 150. Strengthen it. In the present invention, the chassis base 150 and the reinforcement 155 are collectively referred to as a frame. On the other hand, recently, due to the development of circuit and panel design, the power consumption of the PDP module is reduced and the amount of electro magnetic interference (EMI) and heat generation are decreasing. Efforts to replace the chassis base are ongoing. In addition to the material cost advantages, the plastic chassis base has the advantage of low cost, simple process, and reduced weight and noise of the module by injection molding.

The circuit unit 160 is formed by dividing into several pieces of substrates for driving the PDP. That is, the circuit unit 160 includes a power supply unit, a logic circuit unit, an address driver, a scan driver, a sustain driver, and driving buffer boards. The power supply unit supplies power to the driving circuit and the panel and is equipped with an AC / DC converter that converts an external AC voltage into a DC voltage. The logic circuit unit receives an image signal, separates and controls a signal to be sent to an address driver, a scan driver, and a sustain driver, and automatically adjusts power. Each driver receives a signal from a logic circuit and transmits the signal to each driver chip, and each driver chip distributes a logic circuit command to each electrode. The driving buffer boards are installed between each driving unit and the panel 120, and the driving signal from each driving unit is provided to the panel 120 via the driving buffer board. In addition, the driving buffer boards are connected to the panel 120 by a connection member 170 such as TCP or FPC.

The protective plate 180 protects the connection member 170 together with the front case and the rear case from external shocks, and transfers heat generated from the connection member 170 to a heat dissipation member (not shown), and also directly radiates some heat. By preventing the damage and malfunction of the connecting member 170.

The antenna 200 may be an antenna for receiving an analog TV broadcast or an FM broadcast. As described above, the frame is coupled to the chassis base 150 supporting the panel 120 and the back of the chassis base 150 in a long bar shape to prevent twisting or bending of the chassis base 150. It consists of a predetermined arrangement of the reinforcement 155, in the present invention at least a portion of the reinforcement 155 forms an antenna (200).

Here, when the frame is made of a metal material, an insulating member (not shown) that insulates the two needs to be interposed between the reinforcement forming the antenna 200 and the chassis base 150. If there is no insulating member, the chassis base 150 and the antenna 200 are electrically connected and lose their directivity. Therefore, there is no meaning of installing the antenna 200 to receive radio waves.

In this case, when the reinforcing member constituting the antenna 200 is coupled to the chassis base 150 by a fastening member (not shown), the fastening member needs to be made of an insulating material or wrapped with an insulating material. Similarly, to maintain the directionality of the antenna.

When the antenna 200 is an antenna for receiving an FM broadcast, the antenna 200 is electrically connected to an antenna connection terminal exposed out of the PDP case, and an external device equipped with an FM radio is provided with a connector. This antenna is electrically connected to the antenna connection terminal. Coaxial cable may be used as the connector.

In addition, when the antenna 200 is an antenna for receiving an analog TV broadcast, the antenna 200 may be directly connected to a circuit portion (a circuit portion for processing a signal applied from an antenna) inside the PDP. Alternatively, the antenna 200 is electrically connected to an antenna connection terminal exposed out of the PDP case, and the circuit unit inside the PDP is electrically connected to a TV receiving terminal (not shown) exposed out of the PDP case, and the antenna connection terminal and the It is also possible to connect between TV receiving terminals using a connector. In the latter case, the antenna connection terminal can function as an FM reception antenna when connected to an external FM radio using a connector, and function as an analog TV reception antenna when connected to a TV reception terminal of the PDP.

In addition, an antenna for receiving analog TV broadcast and an antenna for receiving FM broadcast may be separately installed and fixed on the frame. This is because the frequency bands used by the TV and the FM radio are different, so that the reception sensitivity can be improved when the shape of the antenna for receiving the shape is appropriate for each frequency band used. In the case of the VHF, the TV uses the frequency of 54 to 216 Mhz, and the UHF uses the frequency of the 470 to 890 Mhz band, while the radio uses the frequency of the 87.5 to 140.0 Mhz band.

Referring to FIG. 2, some of the conductive reinforcing materials 155 are connected to the antenna connection terminal 250 to form the antenna 200. The antenna 200 may be an analog TV receiving antenna. In the case of a TV receiving antenna, it may have a commonly used Yagi antenna structure, which includes a copier 156, a reflector 157 and a waveguide 158. As the number of waveguides increases, the directivity becomes sharper and the gain increases. Since the structure and role of the copier, the reflector and the waveguide are well known techniques, the description thereof will be omitted. In this embodiment, the copier 156, reflector 157 and waveguide 158 are arranged perpendicular to the ground when the panel is upright.

Referring to FIG. 3, the antenna 200 ′ may be an FM receiving antenna. In the case of the FM reception antenna, the reinforcement 155 ′ forming the antenna 200 ′ may be a reinforcement coupled to the chassis base 150 along the upper side of the chassis base 150. Some of the reinforcing members 155 'constituting the antenna 200' are electrically connected to the antenna connection terminal 250 '. The antenna connection terminal 250 ′ needs to be coupled to the chassis base while being spaced apart from the chassis base of the metal material or through an insulating member. However, the content of the present invention is not limited to the case where the antenna 200 'is an FM receiving antenna, and may be used as an analog TV receiving antenna.

In this case, the antenna 200 ′ may have a dipole structure or an arrangement thereof. A dipole antenna is an antenna that transmits and receives radio waves by connecting two conductors (elements) from both ends of a feeder line to both sides. In this case, the reinforcement 155 'constituting the antenna 200' needs to be separated in the middle portion. The dipole antenna may be constituted only by an element, or a loading coil for matching impedance or a balun element for blocking characteristic change of the antenna may be used, and the matter regarding the loading coil or balun element is well known. Will be omitted. Furthermore, a noise filter and an amplifier can also be used, which can be made using existing known techniques.

Referring to FIG. 4, a part of the conductive reinforcing material forms the Yagi antenna structure shown in FIG. 2, and another part of the conductive reinforcing material forms the dipole antenna structure shown in FIG. 3. Since the contents of the embodiment shown in FIG. 2 and the contents of the embodiment shown in FIG. 3 are applied in the same manner, a detailed description thereof will be omitted.

According to the antenna-embedded plasma display device according to the present invention, at least a part of an array of stiffeners coupled to the rear of the chassis base in a long bar shape to prevent twisting or bending of the chassis base is used as a component of the antenna. This makes it possible to install an analog TV receiving antenna and / or an FM radio receiving antenna inside the PDP. Therefore, there is no need to install a separate antenna to the outside, and there is no need to waste unnecessary space due to the installation and connection of the external antenna.

Although the present invention has been described with reference to the illustrated embodiments, it is merely exemplary, and the present invention may encompass various modifications and equivalent other embodiments that can be made by those skilled in the art. Will understand.

Claims (9)

A plasma display device comprising a panel for displaying an image, a frame for supporting the panel on a rear surface of the panel, and a circuit unit for driving the panel. The frame includes a chassis base for supporting the panel and a predetermined array of conductive reinforcements coupled to the rear of the chassis base in a long bar shape to prevent twisting or bending of the chassis base. And at least some of the reinforcing members are connected to an antenna connection terminal to form an antenna. The method of claim 1, And the frame is made of metal, and an insulation member for insulating the antenna is interposed between the reinforcing member constituting the antenna and the chassis base. The method of claim 2, And the reinforcing member forming the antenna is coupled to the chassis base by a fastening member, wherein the fastening member is made of an insulating material or wrapped with an insulating material. The method of claim 1, And the antenna is an analog TV receiving antenna. The method of claim 4, wherein And the antenna has a Yagi antenna structure including a copying machine, a reflector, and a waveguide. The method of claim 5, And said copier, reflector and waveguide are arranged perpendicular to the ground when the panel is erected. The method of claim 1, And the antenna is an FM receiving antenna. The method of claim 7, wherein And the reinforcing member forming the antenna is a reinforcing member coupled to the chassis base along an upper side of the chassis base. The method of claim 8, And the antenna has a dipole structure in which two conductors are connected at both ends of a feed line, or an arrangement thereof.

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