KR100298935B1 - Output holding circuit of vacuum cleaner - Google Patents

Abstract

The present invention provides a vacuum cleaner including a volume for selecting an output level of the vacuum cleaner, a microcomputer for recognizing a selection value of the volume to vary the gate level of the triac for controlling AC power, and a motor for generating a vacuum force according to the gate output.

Step-down means for stepping down AC power between AC power and triac,

An input power monitoring unit for converting the step-down value of the step-down means into a DC level state and applying it to the microcomputer;

A microcomputer having a function of driving a gate in preference to the monitoring unit variation value when the volume is a low pressure value,

The step-down means is a transformer, and the input power monitoring unit comprises a diode for half-wave rectifying the step-down output on the secondary side of the transformer, a condenser for smoothing the half-wave rectification output, and a vacuum cleaner for distributing the smoothed output voltage to the microcomputer. Output holding circuit,

In order to maintain a constant state by relatively reducing the initial high level of the vacuum cleaner output level, an input power monitoring unit is provided to provide a variable current to the motor so that the output of the motor is constant, thereby improving the quality of the cleaner.

Description

Output holding circuit of vacuum cleaner

The present invention provides a vacuum cleaner including a volume for selecting an output level (vacuum degree) of a vacuum cleaner, and a microcomputer for recognizing a selection value of the volume to vary a gate level of the triac, wherein the AC power is reduced between the AC power source and the triac. A step-down means, an input power monitor for converting the step-down value of the step-down means into a DC level state and applied to the microcomputer; and a function of relatively reducing the gate current after recognizing through the monitor during initial operation according to the state of the volume. Including a microcomputer to perform a, since the current applied to the motor during the initial output of the vacuum cleaner to reduce the output of the motor to a certain level, and relates to an output holding circuit of the vacuum cleaner to improve the quality of the vacuum cleaner.

In general, a vacuum cleaner is a device for cleaning a room by sucking dust and the like with a vacuum suction force generated by generating a vacuum by the rotational force of the motor. Therefore, the vacuum cleaner is mainly connected to the housing (main body) for accommodating the motor and the dust suction filter (pouch), the suction connection (flexible) hose which is connected through the connecting means installed in the housing, and provides a passage for sucking dust, and the suction connection. It includes a flexible tube which is connected to the hose and stretchable and engages the suction means including a suction brush at the end. In addition, a handle coupled to the connection hose is provided with a switch (for example, a sliding volume) that turns on and off the power and selects the suction force from "strong" to "weak". This can be illustrated as shown in Fig. 1, the main body (housing) 1 for receiving a vacuum generating motor and suction filter, etc. to be described later, and a connection for transmitting the vacuum suction force and the power supply wire wound on the outer shell A flexible pipe 2-1, to which the hose 2, the suction hose 2-2 having a suction brush 2-3 is coupled to the connecting hose 2 and detachably coupled to the hose 2, and a connection hose ( 2) and the expansion pipe (2-1) and comprises a switch unit (3-1) having a sliding volume (3) for adjusting the suction level. In this case, when the volume 3 corresponding to the selection level of the switch unit 3-1 is set, the amount of suction force caused by the motor is set by the microcomputer to determine the value recognized therefrom. The evil gate is driven to control the output of the motor. In other words, the gate is controlled to a level corresponding to the "strong" state, and the gate is driven to the level corresponding to the "weak" state. This can be exemplified in a circuit representation as shown in Figure 2, the vacuum cleaner main body 1 to provide an AC power through the plug, the AC power applied to the main body 1 through a flexible connection hose (2) To be turned on and off (an illustration of the on and off means is omitted), the connecting hose 2 includes a volume 3 for selecting the suction force (output of the motor). The main body 1 includes a vacuum generating motor M, and the selection level of the volume 3 is recognized by the microcomputer 4 and based on the recognized value, the triac (Triax) 5) to drive the gate. The principle of gate control of the triac 5 is that the gate output power is applied from the time point at which the gate driving current is applied (for example, the time points t1, t2, t3 ...) of FIG. This is applied to the motor M. That is, the gate driving current application time is applied directly at 0 degrees and 360 degrees (in case of sine wave output) or at 90 degrees and 450 degrees (output In this case, the AC power is controlled by varying the output level according to the case where only half is applied, so that the volume ("strong", "medium", or "in") of the suction hose is installed in the connecting hose 2. Selecting the position (level) of the " about " causes the potentials of the both ends P1 and P2 of the microcomputer 4 to be changed accordingly, which is recognized by the microcomputer 4 (including analog digital conversion means). If the corresponding set current value is applied to output terminal P3, The gate current of the evil 5 is changed so that the output of the motor M can also be output at a selected level of "strong" to "weak", but the load of the motor varies depending on the clogged dust bag or the state of the floor. The vacuum cleaner can show the initial input provided by the motor and the corresponding vacuum degree as shown in Fig. 4, in order to generate the vacuum degree, the initial input is applied to the maximum at the initial stage and gradually decreases. In this case, the initial input power PP1 is usually 1000 to 1500 watts and starts to be sucked mainly at 300 to 1150 watts PP2, thus the initial power contributes significantly to the power consumption of the vacuum cleaner. In Japan, the power consumption of the vacuum cleaner is regulated to 1150 watts or less, while the suction power of 500 watts is the mainstream. There is no restriction on sales because there are no special regulations in Korea, but it is difficult to sell in the Japanese market which regulates the vacuum cleaner with the initial electric power exceeding 1500W.

It is an object of the present invention to solve this problem, and to provide an output holding circuit of a vacuum cleaner to relatively reduce the initial output of the vacuum cleaner to maintain a constant output.

To this end, the present invention monitors the gate by controlling the step-down means of the input power, the input power monitoring unit, and the input AC power according to the load so as to interlock the gate current to the microcomputer controlling the gate current in response to the state of the suction force. An output holding circuit of a vacuum cleaner including a microcomputer for interlocking driving is provided.

1 is a perspective view of a general vacuum cleaner,

2 is an output control circuit of a general vacuum cleaner,

3A is a triac applied power waveform diagram used in FIG. 1;

3B is an exemplary diagram of an output waveform of a triac used in FIG. 1;

4 is a degree of vacuum characteristic of the output of the motor,

5 is an output holding circuit diagram of the present invention;

6 is an output holding circuit diagram showing another example of the present invention;

7 is an output characteristic diagram of a motor according to the present invention.

Explanation of symbols for main parts of the drawings

10; step-down means 20; input power monitoring unit

T; trans D; diode

C1, C2; capacitor R1, R2, R3; resistance

That is, the present invention relates to a vacuum cleaner including a volume for selecting an output level of a vacuum cleaner, a microcomputer for recognizing a selection value of the volume, and a gate level of the triac for controlling AC power, and a motor generating a vacuum force according to the gate output. In

A step-down means for stepping down AC power between the AC power source and the triac, an input power monitoring unit for converting the step-down value of the step-down means into a DC level state and applying it to the microcomputer, and a current which is relatively smaller than the existing set value corresponding to the volume. Provides an output holding circuit of the vacuum cleaner including a microcomputer having a function of driving the gate to provide a constant.

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

5 is a circuit diagram of the present invention, in which a volume 3 for selecting an output level of a vacuum cleaner and a microcomputer 4 for varying the gate level of an AC power control triac 5 by recognizing a selection value of the volume 3 are shown in FIG. And a motor (M) for generating a vacuum force in accordance with the gate output, the vacuum cleaner comprising: step-down means (10) for stepping down AC power between an AC power source and a triac (5); The input power monitoring unit 20 converts the step-down value of the voltage into a DC level state and applies it to the microcomputer 4 and the gate driving output when the value of the monitoring unit 20 is applied when the volume 3 is set. And a microcomputer 4 having a function of driving the gate to decrease.

The step-down means 10 is a transformer (T), the input power monitoring unit 20 is a diode (D) for half-wave rectifying the step-down output on the secondary side of the transformer (T), and the capacitor (C1) for smoothing the half-wave rectification output , C2), and distribution resistors R1 and R2 for distributing the smoothed output voltage to the microcomputer 4.

According to the present invention configured as described above, the AC power plug (not shown) of the vacuum cleaner is connected to an outlet, and the volume 3 is operated to adjust the position of the volume 3 so as to come to a desired designated position among desired strong and weak states, When the switch (not shown) is turned on, AC power is applied to the motor M generating the vacuum. In this case, of course, the microcomputer 4 is connected to the gate of the triac 5 for controlling the power supply for driving the motor, and the data corresponding to the basic output value and the compensation output value according to the state of the volume 3 are preliminarily. Storage is required. For example, when the volume 3 in the "weak" state is designated, the microcomputer 4 outputs the corresponding standard gate output through the output terminal P3. The AC power is then applied to the motor M via the triac 5. This is controlled by the microcomputer 4 to reduce the existing motor input a1 to the input a2 as shown in FIG. 7. Thus, the initial input is reduced relatively to provide the desired initial input (eg 1150 watts or less). When the connection hose 2 is brought into contact with the site to be cleaned by driving the motor M in this way, the vacuum force drops from the instant and the current decreases instantaneously. The present invention then increases the gate current of the triac 5 through the output stage P3 to increase the output if necessary. This can compensate for the decrease in output during inhalation. When the initial generation of the vacuum in the above, the operation of the power switch (you can check whether there is an input from the input power monitoring unit 20) and the state of the volume (3) in conjunction with the initial state of the initial generation of the vacuum motor Figure 7 It is provided by reducing the gate current level of the triac 5 to be lowered from the existing position a1 to the position a2 of the present invention. In other words, during the initial excessive input, the gate current is reduced to reduce the power consumption, thereby obtaining a constant output level. This contributes to the export to Japan, especially since it can meet the Japanese specification that leads to reduced energy consumption by limiting excessive output of the initial input to, for example, 1150 watts or less.

In another embodiment of the present invention, as shown in FIG. 6, the resistor R3 is used as the step-down means 10, and the input power monitoring unit 20 also includes a diode D, a capacitor C1 and C2, and a resistor ( It can illustrate that consisting of R1, R2). Since the functions and operations are similar except for the equivalent physical differences, detailed descriptions of the configuration and operation will be omitted. Preferably, the resistor R3 is preferably a small value in consideration of heat generation.

The present invention described above is not limited to the above-described embodiments and drawings, and various permutations, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be apparent to those who have

As described above, according to the present invention, when the initial input of the vacuum cleaner is excessively applied, the microcomputer outputs a gate current which is relatively reduced in the microcomputer so that the initial output of the vacuum cleaner is kept constant so that the energy consumption of the vacuum cleaner can be reduced. do. In addition, when the degree of vacuum decreases relatively, the gate current of the amount to recover is added and applied so that the output can be maintained continuously to make the output of the vacuum cleaner constant.

Claims (2)

A vacuum cleaner comprising a volume for selecting an output level of a vacuum cleaner, a microcomputer for varying a gate level of an AC power control triac by recognizing a selected value of the volume, and a motor for generating a vacuum force according to the gate output. Step-down means for stepping down AC power between AC power and triac, An input power monitoring unit for converting the step-down value of the step-down means into a DC level state and applying it to the microcomputer; And a microcomputer having a function of relatively reducing the initial gate current when the volume is set to drive the motor and applying the same to the gate. The method of claim 1, wherein the step-down means is a trans, The input power monitoring unit comprises a diode for half-wave rectifying the step-down output on the secondary side of the transformer, a capacitor for smoothing the half-wave rectifying output, and a distribution resistor for distributing the smoothed output voltage to the microcomputer. Holding circuit.