KR920006197Y1 - Door open apparatus of vtr - Google Patents

Abstract

No content.

Description

Doa open device of home appliance

1 is a circuit diagram of the subject innovation.

2 and 3 are operational waveform diagrams of the present invention.

4 is a state in which the optical sensor attached to the front door.

5 is a light sensor configuration.

6 is a light sensor installation of the cassette housing.

7 is a logic circuit according to the configuration of FIG.

8 is another embodiment of the present invention.

9 is a flowchart of the present invention.

* Explanation of symbols for main parts of the drawings

1: power supply unit 2: multivibrator

3: electromagnet 4: door

5: stationary magnet 6: switch unit

7: Differentiator 8: Switching pulse generator

9: door opening part 11: cassette housing

12: cassette tape A, B: light sensor

The present invention relates to a door open device of a home appliance, in particular, to automatically "open" the door of the front of the VTR set.

In the case of home appliances, especially VTRs, in terms of product design, the front door with various operation keys is being converted into a one door method. Therefore, the set should open the front door every time. This front door open "operation" operation is to be performed by the user manually, the door open operation was inconvenient.

In addition, since the VTR must press various operation keys every time the set is operated, the automatic opening function of the front door is required to avoid the inconvenience of having to "open" the front door.

Similar prior arts include Utility Model Registration Application No. 89-4141 and Utility Model Registration Application No. 86-10231, but the former is a technical content that allows the hidden door to be "open" only when the cassette tape is seated in the VTR. The latter is a technology that allows the door to be "open" only when the power is supplied to the switch. In the former case, the door is directly opened by the user in the case of the one door open method, in which the cassette insert is not installed in the front door. In addition, there is no hidden door in the front door open door VTR, so the present invention cannot be applied.In the latter case, a separate door open switch must be installed, and the door open switch is pressed after opening the door. Since it was necessary to press, the operation was inconvenient.

In order to solve the above disadvantages, the present invention allows the opening and closing of the door of the front of the VTR to automatically open the door by inserting a switch or a cassette. When the power is "on" by the power switch, the front door is automatically opened. And the powder is "off" when the user closes the door.

In other words, the present invention generates a switching pulse when the power switch is checked "on", and controls the power supply unit and drives the door opening unit, thereby opening the front door together with the driving of the set, and closing the door in the above state. By controlling the power supply to "off" the powder, the front door is "off" with the powder "on" and the powder is "off" with the closing of the front door.

Looking at the present invention as described in detail based on the accompanying drawings as follows.

1 is an embodiment circuit diagram of the present invention, a switch unit 6 for detecting on / off of a door switch SW1 and a power switch SW2, and a differentiator 7 for differentiating a detection signal of the door switch SW1. And a switching pulse generator 8 for generating a switching pulse according to the output of the differentiator 7 and the output of the power switch SW2, and driven by a switching pulse generated by the switching pulse generator 8. A power supply unit 1 for supplying the operating power of the power supply unit 1 and a door open unit 9 for "opening" the front door by a switching pulse of the switching pulse generator 8.

At this time, the switching pulse generator 8 multiplies the output terminal D of the T-flop flop FFl and the differential output of the differentiator 7 by the AND gate AN1, and then outputs the AND gate AN1. And the sensing output of the over-power switch SW2 is applied to the input terminal T of the T-flip flop FF1, and the door opening unit 9 outputs the output of the T-flip flop FF1 to the multivibrator MM1. After delaying for a predetermined time in the transistor (Q1) (Q2) to drive the output of the multi-vibrator 2 is configured to drive the electromagnet (3).

Here, the electromagnet 3 is wound to have the same polarity as the stator magnet 5 installed in the door 4 when the transistors Q1 and Q2 are operated and the power is supplied.

4 is an optical sensor attached state diagram of the front door (4), the optical sensor (A) (B) is installed at the opposite position of the main body 10 and the door (4), and the optical sensor (A) ( The configuration diagram of B) is as shown in FIG.

That is, the light sensor (B) for the light emitting body (4) and the light receiving sensor (A) for the main body (10) are configured at opposite positions, but the light sensor (A) (B) is mounted on a bracket having deflection. It is fixed to prevent malfunction by external light.

In addition, when the cassette tape is to open the front door according to the insertion, as shown in FIG. 6, light beams A and B are installed on the left and right sides of the cassette housing 11 into which the cassette tape 12 is inserted.

If the optical sensor (A) (B) is installed in the cassette housing 11 as described above, a logic circuit as shown in FIG. 7 must be configured to prevent malfunction in tape extraction.

That is, the optical sensor output is logically multiplied at the AND gate AN2 with the output of the door switch SW1 through the inverter 11, and the output of the AND gate AN2 comes with the output of the power switch SW2. It is configured to be applied to the input terminal T of the T-flip flop FFl after being ORed at the gate ORl.

8 is another embodiment configured by using a microcomputer instead of the differentiator 7 and the switching pulse generator 8 of the present invention, and the driving flowchart of the microcomputer 20 is shown in FIG. same.

Such a configuration explains the effect of the present invention.

In FIG. 1, when the front door is closed, the door switch SW1 is "on", and when the power switch SW2, which is a tac switch type, is pressed, the input terminal of the T-flip flop FF1 is pressed. Since one pulse is input to (T) as shown in FIG. 2, the output terminal D of the flip-flop FF1 outputs a high level as shown in FIG. 2. The output is applied to the AND gate AN1 through the buffer B1 and to the power supply unit 1 and the multivibrator 2.

Therefore, when the high level output of the flip-flop FF1 is applied to the power supply unit 1, the power supply B1 ⁺ (B2 ⁺ ) (B3 ⁺ ) required for driving the set is generated to drive the set, and the multivibrator 2 In this case, when the high level output of the flip-flop FF1 is applied, it is delayed for a predetermined time as shown in FIG. 2 and the output of the multivibrator 2 "turns on" the transistors Q1 and Q2. The electromagnet 3 is operated by causing the power source of the main power supply unit 1 to be applied to the electromagnet 3.

When the electromagnet 3 is operated, it has the same polarity as the stator magnet 5 installed in the door 4, so that the door 4 is moved about the fixed electromagnet 3 about the rotational axis of one side and is "open". .

In this way, the current of the multivibrator 2 falls to a low level after the current flows for a predetermined time so that the door 4 can be "open".

At this time, the output waveforms of the power switch SW2, the flip-flop FF1, and the multivibrator 2 are as shown in FIG.

That is, when the power switch SW2 is "on" in the initial state (when the door is closed), the flip-flop FF1 of the switching pulse generator 8 is operated, and the high-level output of the flip-flop FF1 is supplied to the power supply unit ( 1), the set 4 is driven and at the same time the multivibrator 2 is delayed for a certain time to operate the electromagnet 3, so that the door 4 is "open".

In this manner, when the power switch SW2 is "on" in the initial state, the set is operated and the door 4 is "open".

In the state in which the door 4 is "open", the door switch SW1 is in the "off" state, and the power switch SW2, which is a tack switch, is also in the off state. In this state, the user operates the installed inside of the door 4. The key is used to drive the set.

However, if the user closes the door 4 after finishing using the set, the powder is " off ".

That is, when the door 4 is closed after use of the set, the door switch SW1 is turned "on", and when the door switch SW1 is turned "on", one pulse is generated at the differentiator 7, which is an end gate. The output of the flip-flop FF1 falls to a low level by being applied to AN1) by applying one pulse to the input terminal T of the T-flip-flop FF1.

At this time, since the high level is applied to one side of the AND gate AN1 while the door 4 is "open", the differential pulse output from the differentiator 7 is flipped through the diode D3 after the AND gate AN1. Is applied to the flop FF1.

When the door 4 is closed in this way, the output of the flip-flop FF1 falls to the low level as shown in FIG. 3, and the output of the flip-flop FF1 is applied to the power supply 1 to turn off the power and wait. It will be converted into standby state that supplies only power (ST B ⁺ ).

Therefore, after closing the door (4) after pressing the power switch (SW2) after the set is used, closing the door (4) without the operation of the power switch (SW2), the powder is "off" convenient for use will be.

Partial waveform diagrams of the present invention for such power "on" and power "off" are as shown in FIG.

Meanwhile, in the present invention, the door switch is configured to be turned on and off as the switching means is opened and closed. However, as shown in FIG. 4, the optical sensor (A) and (B) may be attached to replace the main body 10 and the door. The photosensors (A) and (B) are omitted at opposing positions in (4) and the photosensors (A) and (B) sensing circuits for this are configured as in FIG. At this time, the optical sensor (A) (B) is fixed to the bracket configured to have a deflection to prevent malfunction by the general solar light.

That is, when the door 4 is closed, the light of the light emitting light sensor B is applied to the light receiving light sensor A, and the transistor QA is "turned on" so that the door switch SW1, which is a mechanical switch, is "on". If the high level is applied to the rear end of the differentiator 7 and the door 4 is "opened", the light of the light emitting light sensor B is not applied to the light receiving light sensor A and thus the transistor QA is turned on. By "turning off", the low level is applied to the rear end of the differentiator 7 in the same way that the door switch SW1 is "off".

Therefore, even if the optical sensor (A) (B) in the opposite position of the main body 10 and the door 4 in place of the mechanical door switch (SW1), the effect of the present invention is the same.

On the other hand, the case in which the door 4 is "open" even when the cassette tape is inserted in the same manner as in the present invention in which the door 4 is "opened" by the "on" operation of the powder switch SW2. Take a look.

To this end, as shown in FIG. 6, the optical sensors A and B are installed on the left and right axes of the cassette housing 11, and then a logic circuit as shown in FIG.

That is, if the cassette tape 12 is not inserted into the cassette housing 11, a high level is output to the sensor output side as shown in FIG. 5, and when the cassette tape l2 is inserted, the light between the light sensors A and B is inserted. This is cut off so that the low level is output to the sensor output side.

The sensor output of the optical sensors A and B installed in the cassette housing 11 is inputted to the AND gate AN2 to which the door switch SW1 output is applied after being switched through the inverter 11 and the AND gate ( The output of AN2 is applied to the T-flip flop FF1 through the OR gate OR1 to which the output of the power switch SW2 is applied, so that when the cassette tape 12 is inserted into the cassette housing 11, the flip-flop FF1 is applied. ) Output is at a high level to perform the operation of opening the door (4).

In this case, the output of the optical sensors A and B installed in the cassette housing 11 is applied to the flip-flop FF1 through the logic gate as shown in FIG. 7 without being applied to the flip-flop FF1. The light between A) and (B) is blocked so that the powder is "off" to prevent this.

That is, even when the optical sensors A and B are blocked when the tape is extracted, the flip-flop is turned off by the AND gate AN2 when the door switch SW1 is "off" (the door is "open"). The pulse is not applied to (FF1) to prevent malfunction.

At this time, the output of the power switch (SW2) and the output of the light sensor (A) (B) is input to the oragate (OR1) is to enable the power of the set on / off also by the existing power switch (SW2). to be.

On the other hand, the same operation is performed even if the microcomputer 20 is configured as shown in FIG. 8 without configuring the differentiator 7 and the switching pulse generator 8 of the present invention.

In other words, the microcomputer 20 performs an internal program according to the door switch SW1, the power switch SW2, and the remote control key input to control the driving of the power supply unit 1 and the door opening unit 9, respectively. Control the operation of the function control unit.

The operation of the microcomputer 20 of FIG. 8 will be described based on the flowchart of FIG.

The microcomputer 20 first checks the input of the door switch SW1, and if the door 4 is not in the "open" state, checks the power switch SW2 to determine whether the power switch SW2 is "on". When the power switch SW2 is turned "on" while the door 4 is not "open", the power is "on" and the door 4 is "opened".

When the door 4 is "open", each function is performed according to the function key input and the door switch SW1 is checked to see if the door 4 is closed. When the door 4 is closed, the powder is "off". After finishing the operation.

When the door 4 is "open" by checking the door switch SW1, the power "on" state is checked and when the power is "on" state, each function according to the function key input is performed.

As described above, the present invention automatically turns off the front door of the VTR by turning the front door of the VTR to "off" when the switch is "on" and automatically closing the front door. Can be "opened".

Claims (5)

In the home appliance provided with the door 4 provided with the permanent magnet 5 and the electromagnet 3 installed in the main body at the opposite position of the permanent magnet 5, the door switch SW1 and the power switch SW2 are provided. Differential pulse input of the switch part 6 which checks the connection state, the differentiator 7 which generate | occur | produces a differential pulse at the time of connection of the said door switch SW1, and the time of connection of the said powder switch SW2, and the differentiator 7; A switching pulse generator 8 for generating a switching pulse at the time, a power supply 1 driven by a switching pulse of the switching pulse generator 8 to supply operating power, and switching of the switching pulse generator 8 The door open device of a home appliance, in which a door open part 9 for driving an electromagnet 3 is connected by delaying a pulse for a predetermined time. The door switch SW1 of the switch unit 6 is configured by installing an optical sensor (A) (B) at a position opposite to the main body (10) and the door (4). (B) is a door opening device of a home appliance, which is fixed to a bracket having deflection. According to claim 1, the door opening portion 9 is a multi-vibrator (2) for delaying the switching pulse of the switching pulse generator 8 for a predetermined time, and the transistor driven by the output of the multi-vibrator (2) (Q1) (Q2) and the door opening apparatus of the household electrical appliance which consists of the electromagnet (3) which is operated by the drive of said transistor (Q1) (Q2), and has the same polarity as the permanent magnet (5) installed in the door (4). . The method of claim 1. The switching pulse generator 8 applies the output of the power switch SW2 to the power supply unit 1 and the open-opening unit 9 through the flip-flop FF1, and is applied to the AND gate AN1 to differentiate the powder 7 The door open device of a home appliance configured to be applied to the input terminal T of the flip-flop (FF1) after being multiplied by the differential pulse output of the door switch (SW1). The optical sensor (A) (B) is installed on the left and right sides of the cassette housing (11) into which the cassette tape (12) is inserted, and the output of the optical sensor (A) (B) is an inverter (11). After that, the output of the door switch SW1 and the AND gate AN2 are configured to be logically multiplied, and the output of the AND gate AN2 is logically summed at the output of the power switch SW2 and the OR gate OR1 to generate a switching pulse. Door opening device of a home appliance configured to be applied to the unit (8).