KR960006223Y1 - Auto docking circuit for notebook docking station - Google Patents

Abstract

None.

Description

Automatic Docking Circuit of Notebook Docking Station

1 is a block diagram of a conventional notebook docking station.

2 is an automatic docking circuit diagram of a laptop docking station of the present invention.

3 is an explanatory view of the operation of the motor and gear of the docking station.

(b) is an explanatory view of the operation of coupling or disconnecting the notebook and the docking station.

4 is a signal waveform diagram of each part at the time of automatic power supply.

5 is a signal waveform diagram of each part in the automatic ejection operation.

* Explanation of symbols for main parts of the drawings

11 control unit 12 clock generator

12-1: Multi Vibrator 12-2: Counter

13: motor drive part S1-S4: Schmitt trigger

SW1: Coupling complete switch SW2: Ejection complete switch

The present invention relates to a notebook docking station, and more particularly, to an automatic docking circuit of a notebook docking station that allows the user to perform the desired docking operation by controlling the motor by the automatic / manual selection key.

FIG. 1 is a block diagram of a conventional notebook docking station. As shown in FIG. 1, when a notebook is inserted into a docking station, the notebook is detected and coupled by an optical sensor, and then the docking outputs a control signal according to the power on / off state of the notebook. Control unit 1 for outputting a control signal for supplying power to the station, and a motor mechanism driven in accordance with the control signal of the control unit 1 to adjust the direction of driving, stopping and rotation of the motor to couple or take out the notebook It consists of a part (2).

Referring to the operation of the conventional circuit configured as described above is as follows.

When the notebook is inserted into the docking station, the control unit 1 detects this by the optical sensor and outputs a control signal for coupling the notebook to the motor mechanism unit 2.

The motor mechanism part 2 receiving the control signal from the controller 1 rotates the motor in the forward direction to couple the notebook. When the coupling is completed, the switch SW1 is turned on to output the combined signal.

The control unit 1 receiving the combined signal outputs a signal for stopping the motor and checks the power on / off state of the notebook, and controls to take out the notebook to the mechanism unit 2 when the power is on. It outputs a signal and supplies power to the docking station and the notebook after a predetermined time when the notebook is turned off.

In order to remove the notebook from this power supply, you must first turn it off and press the eject key.

As described above, in the related art, when the notebook is inserted, the docking station and the notebook are unconditionally supplied after a predetermined time when the notebook is connected and the power is turned off. In addition, after the power is supplied, it must be turned off and press the eject switch was separated because there was a problem that has a problem.

It is an object of the present invention to provide an automatic docking circuit of a laptop docking station that can perform a user's desired docking operation by allowing the motor to be controlled using an automatic / manual mode switching switch to solve the conventional problems.

The automatic docking circuit diagram of the notebook docking station to solve the object of the present invention outputs a control signal for coupling or ejecting the notebook, and when the notebook is coupled to check the state of the automatic / manual mode and the power on / off state of the notebook If the notebook is powered on, it outputs a control signal to eject the notebook regardless of the auto / manual mode.If the notebook is powered off and in manual mode, the notebook is powered off while waiting for the next command. A control unit for outputting a control signal for supplying power to the docking station after a predetermined time delay by a natural signal in the automatic mode, a clock generator for generating a delay signal to the control unit when the notebook is turned off and in the automatic mode; The motor driving unit for driving the motor in accordance with the control signal of the control unit All.

Hereinafter, with reference to Figures 2 to 5 attached to an embodiment of the present invention in detail as follows.

2 is an automatic docking circuit diagram of a laptop docking station according to the present invention. As shown in the drawing, a control signal for coupling or unloading a notebook is output as well as a state in an auto / manual mode and a notebook power on / off state when the notebook is coupled. If the notebook is powered on, the controller outputs a control signal to eject the notebook regardless of the auto / manual mode.If the notebook is off and in manual mode, it waits for the next command in the combined state. In the off state and the automatic mode, the control unit 1 outputs a control signal for supplying power to the docking station after a predetermined time delay by the delay signal, the Schmitt triggers S1-S4, the resistors R1, and the capacitor C1. It is composed of a multi-vibrator (12-1), Schmitt trigger (S3, S4) and a counter (12-2) consisting of a notebook in the power off state When the motor is inserted in the idle state, the clock generator 12 generates a delay signal for supplying power after a predetermined time delay, and drives the motor according to the control signal of the controller 11. It consists of the motor drive part 13.

When described in detail with reference to Figures 3 to 5 with respect to the operation and effects of the present invention configured as described above.

When the notebook is inserted into the docking station, the control unit 11 receives a high signal through the optical sensor. Accordingly, the control unit 11 outputs a control signal for coupling the notebook, outputs a high signal through the terminal (MP1) and a low signal through the terminal (MP2), the motor driver 13 controls the control. Drive to rotate in the forward direction according to the signal.

On the contrary, when the low signal is output through the terminal MP1 and the high signal is output through the terminal MP2, the motor driving unit 13 drives the motor to rotate in the opposite direction (reverse rotation) with respect to the forward direction according to the control signal. Let's do it.

In this case, the process of coupling and disconnecting the notebook according to the rotation of the motor will be described with reference to (a) and (b) of FIG. 3. As shown in the drawing, as the motor rotates, the gears G1 and G2 move in the direction of the arrow. Rotating, this causes the translator (a) latch to move up and down, left and right to join or disconnect the notebook.

In the above, since the notebook is inserted, the motor is rotated in the forward direction to be coupled. When the notebook is coupled in this way, the coupling completion switch SW1 is mechanically pressed, and the control unit 11 receiving the signal corresponding thereto stops the motor by outputting a control signal for stopping the motor. Thus, the motor is prevented from rotating after the notebook is engaged.

If you need to remove the notebook, rotate the motor in reverse direction to separate the notebook and take it out. When the notebook is completely taken out as described above, the ejection completion switch SW2 is mechanically pressed, and the control unit 11 which receives a signal corresponding thereto stops the motor by outputting a control signal for stopping the motor. Thus, the motor is prevented from rotating even when the notebook is taken out.

When the notebook is in a coupled state, the control unit 11 outputs a control signal according to the notebook power on / off state and the state of the key selected by the user. First, if the notebook power is on regardless of the auto / manual mode, the motor Eject the notebook by rotating it backwards. If the notebook is powered off in the manual mode, it stays in that state and waits for the next command.

On the contrary, when the notebook is turned off in the automatic mode, the notebook waits until the delay signal output from the clock generator 12 becomes high and then supplies power to the notebook and the docking station. The resulting waveform diagram is as shown in FIG.

Referring to the operation of the clock generator 12, a constant clock pulse output to the multivibrator 12-1 including the resistor R1, the capacitor C1, and the Schmitt triggers S1 and S2 is a clock of the controller 11. It is applied to the terminal CLK and to the input terminal 1A of the counter 1202.

At this time, since the signal from the terminal PWR of the control unit 11 is low in the initial state before the notebook is inserted, the Schmitt trigger S3 outputs a high signal, and the high signal and the low from the coupling completion switch SW1. The Schmitt trigger (S4) receiving the signal also outputs a high signal. Therefore, the counter 12-2 is in a clear state and outputs a low signal through the output terminal 2Q, and applies it to the control unit 11 as a delay signal.

However, after the notebook is inserted, when the high signal is output from the switch SW1, the Schmitt trigger S4 outputs a low signal. Accordingly, the counter 12-2 is cleared and the output terminal is released after a predetermined time. The high signal is output through (2Q). The high signal is input to the control unit 11 as a delay signal.

When the high signal is received from the counter 12-2 as described above, the controller 11 outputs a control signal for supplying power to the notebook and the docking station through the terminal PWR. Thus, the Schmitt trigger S3 receives the high signal. Will print Accordingly, the Schmitt trigger S4 outputs a low signal again, and the control unit 11 is in a state of receiving a delay signal having a low state as in the initial state.

And, both the eject key and the power key can be operated in the automatic and manual state. However, if you remove the power from the automatic state or operate the power key, turn off the docking station first, wait until the delay signal becomes high, and operate according to the selected key. The waveform diagram of each part is shown in FIG. same.

On the other hand, if the user pulls out the notebook again before the latch catches on the notebook, the docking station is ready to accept the notebook again. In addition, when the motor suddenly loses power while rotating and becomes an ambiguous state that is neither coupled nor disconnected, logic is configured to be either coupled or disconnected when the power is turned on again.

As described in detail above, the present invention allows the motor to suddenly lose power during rotation and become either of a combination or disconnection when the power is turned on again, and use the automatic / manual selection key to create a docking state desired by the user. It can be effective.

Claims (1)

If the notebook is powered on, it outputs a control signal to eject the notebook regardless of the auto / manual mode.If the notebook is off and in manual mode, the notebook is powered off while waiting for the next command. A controller for outputting a control signal for supplying power to the docking station after a predetermined time delay by a delay signal in the automatic mode, a clock generator for generating a delay signal in the controller when the notebook is turned off and in the automatic mode; The automatic docking circuit of the notebook docking station, characterized in that configured as a motor drive unit for driving a motor to couple or take out the notebook according to the control signal of the controller.