KR0124260Y1 - Connection structure between liquid crystal display device and circuit board - Google Patents

Abstract

In the module of the liquid crystal display element 53, electrodes 55 and 56 sequentially formed at minute intervals on the PCB 51 and the liquid crystal display element 53, and zebras having the conductors 57 sequentially formed to correspond thereto. In order to prevent the short circuit caused by the minute pitch gap between the electrodes 55 and 56 and the conductor 57 when the connector 52 is connected, the PCB 52 and the liquid crystal display element 53 are formed. The electrodes 1 and 2 are formed in two rows, and the two rows are alternately crossed, and the corresponding conductors 3 of the zebra connector 52 are alternately crossed in two rows so that the adjacent electrodes 1 and 2 are alternately formed. The pitch spacing of 2) can be doubled to prevent shorts due to the fineness of the pitch spacing.

Description

Connection structure between liquid crystal display device and circuit board

1 is an exploded perspective view showing a connection structure of a liquid crystal display device and a circuit board according to the present invention.

2 is a perspective view showing a connection structure of a conventional liquid crystal display element and a circuit board.

3 is a cross-sectional view showing a module for a general liquid crystal display device.

* Explanation of symbols for main parts of the drawings

1,2 electrode 3: conductor

The present invention relates to a connection structure between a liquid crystal display element and a circuit board, and more particularly, the distance between the terminals of the pattern formed on the above-described parts, etc., is extremely minute when the liquid crystal display element, the zebra connector, and the circuit board are connected. The present invention relates to a connection structure of a liquid crystal display device and a circuit board which can prevent a short circuit that is generated.

In general, the liquid crystal display element is used as the information display device of the OA device and home appliances, which is applied to the optical anisotropy of the liquid crystal which is an intermediate phase between the solid and the liquid.

The above-mentioned types of liquid crystals are usually nematic, cholesteric, or static. In the field of information display, a nematic liquid crystal is used, and a liquid crystal is applied in response to a weak voltage applied to the liquid crystal in the optical anisotropy of the liquid crystal. The light transmittance of is changed.

Herein, the liquid crystal display device operated according to the above-described operating principle includes a phase and a lower plate in which transparent electrodes are formed to face each other on an orthogonal axis to form a matrix, and the molecular array direction of the protection of the transparent electrode and the liquid crystal. It is composed of an alignment film applied on the upper surface of the upper surface and a liquid crystal injected between the upper and lower plates in order to induce a polarization plate. .

The liquid crystal has been developed as a twisted nematic (TN) type and a super twisted nematic (STN) type and a strong dielectric liquid crystal and a thin film transistor (TFT) type. Currently, the TN type and the STN type have been put to practical use.

In general, the operation of a TN type or STN type liquid crystal display device is performed by applying a predetermined power supply through a driving circuit formed on a PCB substrate to a transparent electrode formed in a matrix, and changing the twist angle of the liquid crystal by the power supply. The predetermined amount of display is performed by passing only a predetermined portion of the light amount of the backlight provided on the rear surface of the display element.

Of course, in order to use the liquid crystal display element having the above-described configuration, a module capable of supporting the liquid crystal display element and withdrawing the transparent electrode formed on the liquid crystal display element to the outside is required, which is illustrated in FIG. As described above, the zebra gun 52 is seated on a predetermined position on the PCB substrate 51 to which the large-scale integrated circuit 50 and the plurality of components are attached, and the liquid crystal display element 53 is mounted on the zeolite gun 52. The bezel 54, which can support the liquid crystal display element 53, is fixed to the PCB substrate 51 to form a module.

Here, since the large-scale integrated circuit 50 is not only bulky to be installed inside the bezel 54 but also closes to the liquid crystal display element 53, the large-scale integrated circuit 50 may cause interference by using the double-sided PCB substrate 51 and the substrate 51. Attached to the lower portion of the zebra gun connector 52 is to energize the PCB substrate 51 and the liquid crystal display element 53.

As described above, in order to energize the liquid crystal display element 53 and the PCB substrate 51, as shown in FIG. 2, the electrodes 55 are spaced at minute intervals sequentially between the PCB substrate 51 and the liquid crystal display element 53. As shown in FIG. The PCB 56 and the liquid crystal display device are formed of a zebra connector 52 in which the conductors 57 are sequentially formed in one row so as to arrange the 56 columns in one row and correspond to the electrodes 55 and 56. 53).

Here, an external signal is applied to the liquid crystal display element 53 by the contact between the electrodes 55 and 56 and the zebra connector 52. The spacing between these electrodes and the pitch of the conductor 57 is Since it is usually as fine as 0.4mm, high precision is required to make it contact correctly.

However, as described above, the pitch gap between the conductors 57 formed on the zebra connector 52 is minimized while the pitch between the electrodes 55 and 56 of the PCB 51 and the liquid crystal display 53 is minute. As a result of the fine formation, a short was generated between the electrodes 55 and 56.

Therefore, an object of the present invention is to connect the electrodes formed on the PCB substrate and the liquid crystal display device in the module of the liquid crystal display device with the electrodes sequentially formed at minute intervals, and to connect the zebra connectors having the conductors sequentially formed therebetween. The present invention provides a connection structure between a liquid crystal display device and a circuit board which can prevent a short caused by a fine pitch interval.

In order to realize the above object, the present invention forms two rows of electrodes formed on a PCB and a liquid crystal display, and two rows are alternately formed, and a corresponding conductor of a zebra connector is alternately formed in two rows. By expanding the pitch interval of the adjacent electrode by two times, it is characterized in that it is configured to prevent a short due to the fineness of the pitch interval.

Hereinafter, a preferred embodiment of the present invention with reference to the accompanying drawings.

1 is an exploded perspective view illustrating a connection structure of a liquid crystal display device and a PCB substrate according to the present invention, in which the electrodes 1 and 2 are formed in the PCB substrate 51 and the liquid crystal display element 53 in two rows as well. It is formed on both sides so as to cross, and the conductor 3 is formed in the zebra connector 52 so as to alternate in two rows.

As described above, the zebra connector 52 is seated on the PCB substrate 51 on which the electrode 1 is formed, and then the liquid crystal display element 53 is seated on the zebra connector 52 and the bezel 54 is attached thereto. In addition to fixing, it forms a module.

Here, when the zebra connector 52 is seated on the PCB substrate 51, the conductor 3 formed on the zebra connector 52 and the electrode 1 formed on the PCB substrate 51 correspond to each other. Since the pitch interval between the electrodes 1 adjacent to each other extends twice as much as when the electrodes 55 are continuously formed, the possibility of short generation between the electrodes 1 is significantly reduced.

Of course, when the zebra connector 52 and the liquid crystal display element 53 are in contact with each other, as described above, the pitch spacing between the electrodes 2 is doubled, so that short generation is significantly reduced.

At this time, as described above, the spacing between the columns of the electrodes 1, 2 and the conductors 3 formed in two rows is different from the electrodes 1 of the other rows when the conductors 3 are in close contact with the electrodes 1, 2. 2, and the signal is transmitted to the liquid crystal display element 53 by the contact of the conductor 57, the PCB substrate 51 and the liquid crystal display element 53.

As described above, the present invention is formed by forming two rows of electrodes formed on the liquid crystal display device and the PCB and alternately crossing them at predetermined intervals, and forming the conductors of the zebra gun connector in close contact with each other by successively crossing the rows in two rows. As the pitch interval between the teeth becomes wider, there is an advantage that can prevent the short.

Claims (1)

The electrodes 55 and 56 formed on the PCB substrate 51 and the liquid crystal display element 53 are sequentially arranged in one row, and the conductors 57 of the zebra connector 52 which are in contact therewith are sequentially arranged in one row and contacted with each other. In the liquid crystal display device and the circuit board connection structure configured to transmit a signal, a pole (1, 2) is formed on the PCB substrate (51) and the liquid crystal display device (53) in order to alternate in two rows, and is in contact with the zebra. A structure for connecting a liquid crystal display device and a circuit board, characterized in that the conductors 3 of the connector 52 are alternately formed in two rows.