JPS60141191A - Input control circuit for motor blower - Google Patents

Abstract

PURPOSE:To stably control with less irregularity by controlling the gate of a bidirectional thyristor while utilizing the features of safety provision due to the use of a leakage transformer and controlling the input of a motor driven blower. CONSTITUTION:When a shortcircuit switch 9 is OFF, the electromotive force of a tertiary winding L3 is V2, and V2<V3. Thus, the charge of a capacitor C2 is delayed, and the turning ON time of a bidirectional thyristor 3 is delayed. Accordingly, a motor driven blower 2 is driven by the set low input. On the other hand, when a shortcircuit switch 9 is closed, the electromotive force of the winding L3 is V3 and V3>V2. Thus, the charge of the capacitor C2 is fast, and the turning ON time of the thyristor 3 is accelerated, thereby driving the blower 2 with the maximum input.

Description

TECHNICAL FIELD OF THE INVENTION The present invention relates to an electric blower input control circuit in a vacuum cleaner.

Technical background of the invention No. 11 shows a conventional control circuit. First, an electric blower (2) and a bidirectional thyristor (
3) are connected in series. And - next core T
A leakage transformer T is provided in which a primary winding wound around , is connected to an AC power source (1).

As shown in Fig. 2, this leakage transformer T includes a leakage core T having a gap G, an intermediate core T forming a magnetic resistance to restrict the flow of magnetic flux to the side, and a metal core T. However, a switch (4) is connected between both ends of the secondary winding wound around the intermediate core T. This switch (4) is installed on the hand-operated part of the hose, etc., and is connected to the leakage transformer T)
1) It is insulated from the side.

On the other hand, one end of the tertiary winding wound around the leakage core T is connected to the anode side of the bidirectional thyristor (31), and the other end is connected to the gate of the bidirectional thyristor (3) via the diode DI + D*. connected to the side.

Therefore, considering the leakage transformer TO operation, the second
As shown in the figure, the AC power supply +11 is connected to both ends of the negative winding.
is added, and the secondary winding is turned off by turning off the switch (4),
When both ends of are open, the magnetic flux Φ1 is the primary core TI +
Since the magnetic flux flows through the intermediate core T as shown by the broken line, only a small amount of magnetic flux flows on the leakage core T side due to the existence of the gap G, and the electromotive force at both ends of this tertiary winding is low. On the other hand, by turning on the switch (4), the secondary winding L!
When short-circuited, the magnetic resistance of the intermediate core T increases, magnetic flux Φ flows through the leakage core T as shown by the solid line, and the electromotive force at both ends of the tertiary winding 3 increases.

As a result, when the switch (4) is OFF and the electromotive force of the tertiary winding is low, the gate of the bidirectional thyristor (3) cannot be sufficiently driven due to the voltage drop caused by the diodes D, D, and the switch (4) is turned ON. However, when the electromotive force of the tertiary winding L3 increases by turning on the switch (4), the bidirectional thyristor (
3) is gate-triggered and turned ON.

According to such a conventional method, leakage transformer TK
Since the AC power supply (1) and the switch (4) can be completely separated, the switch (4) can be connected via the ground and the human body.
) Even if you touch the part, there is almost no leakage current and it is safe.

Problems with the Background Art However, according to such a conventional method, the switch (4
) Bidirectional thyristor (3)
There are only two modes: to keep the gate ON or to turn it OFF. As a result, even if the bidirectional thyristor (3) is employed, the input power of the electric blower (2) cannot be controlled, and its range of use is limited.

Purpose of the Invention The present invention has been made in view of the above points, and controls the input of an electric blower by controlling the gate of a bidirectional thyristor while taking advantage of the feature of ensuring safety by using a leakage transformer. The purpose is to obtain an electric blower input control circuit that can perform the following steps.

Summary of the Invention The present invention connects a switch and a voltage drop element in series to a secondary winding wound around an intermediate core that forms a magnetic resistance for restricting the flow of magnetic flux to the leakage core side. By connecting a short-circuit switch in parallel to the drop-down element, the voltage-drop element connected state is ensured as well as the open state and short-circuit state of the secondary winding, and the electromotive force of the tertiary winding of the leakage core is controlled. The device is configured to control the input power of the electric blower by controlling the gate of the bidirectional thyristor.

Embodiment of the Invention A first embodiment of the invention will be described based on FIG. Components that are the same as those shown in FIGS. 1 and 2 are designated by the same reference numerals, and description thereof will be omitted. First, a gate trigger circuit (6) mainly composed of a variable characteristic negative resistance element PUT (5) is provided on the gate side of the bidirectional silicon risk (3). This PUT (5) u resistance &, R? It turns on when a voltage determined by this resistor -+R7 is applied to the anode side.

For this reason, a constant voltage is applied to both ends of the resistor "6+R?", which is obtained by applying the AC power supply (1) through the resistor RIo, full-wave rectifying it with diodes D and ~D6, and making it constant voltage with the Zener diode ZD through the resistor R0. On the other hand, PUT (51
The anode of is connected to the midpoint of the connection between the resistor Rm and the capacitor C2, and the diode D, ~DI! is connected to both ends of this resistor Rm + capacitor C3. A rectified output is applied.

A tertiary winding wound around a leakage core T is connected to the rectifier circuit formed by the diodes D, to D, and t. In addition, the cathode side of PUT (5) is connected to resistors R, , R,
is connected to the gate of the thyristor (7) via the thyristor (7).

This thyristor (7) is connected to a diode D along with a resistor R8.
.

- Connected to the rectified output side by D6. And the thyristor (power, diode DI + in parallel to the resistor R8
Dt is connected, and the connection midpoint of the diode D1 + Dt is connected to the gate of the bidirectional thyristor (3), and a resistive island is interposed between it and the anode.

On the other hand, a switch (8) and a resistor R11 as a voltage drop element are connected in series to both ends of the secondary winding wound around the intermediate core T, and a short-circuit switch (9) is connected in parallel to this resistor R11. ) are connected. These switches +8)
f9), the resistor R11 is provided at the proximal portion of the hose.

In such a configuration, the operation of PUTf5) will now be considered. This PUT (5) connects its gate terminal to resistors R,,R? When biased with the divided voltage, the capacitor C2 is charged by the current supplied from the tertiary winding Ls through the diodes D and D□, and this charging voltage becomes the voltage determined by the resistor Ry. ON when reached
It is something to do. Tsumashi, resistor R6, R? The trigger voltage of PUT f5) changes depending on how the bias is applied. Further, the ON timing changes depending on the charging cycle of the capacitor C3.

At the bottom of the hose, the switch (8) is set to O.
In the case of an FF, the electromotive force of the secondary winding and the tertiary winding with both ends open is a low voltage V. Then, by turning on the switch (8) and turning off the short-circuit switch (9), the resistor R11 is connected across the secondary winding A La, and the electromotive force of the secondary winding a La becomes a voltage. N't (V2>
V+). Furthermore, when both the switch (8) and the short circuit switch (9) are turned on, the secondary winding L! ), an electromotive force ys(vs>Vs) t is generated at both ends of the tertiary winding L6. Sokote, P.U.
T (511c ”) !, E next winding 1 m When the electromotive force of La is V8, it will not turn on, and when the electromotive force is ■, the phase is controlled so that it is the lowest setting input, and the electromotive force is V3.
The characteristics of the PUT (5) are determined by setting the bias by the resistors R, , R, so that the input is maximum when .

In any case, if the switch (8) is ON and the shorting switch (9) is OFF, or if the switch (8) is ON and the shorting switch (9) is also ON, PtJ'I' (5) becomes OFF.
When the thyristor (7) is triggered, the anode of this thyristor (7) receives not only the rectified output from the diodes D, ~D6, but also the electric blower (2) and the bidirectional thyristor (3). Gate.

The current continues even if the diode DI, resistor R8, thyristor (7), and diode D4 are all connected. This current continues to flow until the bidirectional thyristor (3) turns on and the voltage across its terminals drops, so even if the load is an inductive load such as an electric blower (2), the bidirectional thyristor (3) will definitely be triggered. Also, even after the bidirectional thyristor (3) is turned on, the thyristor (7) flows through the diodes D, ~D6! ! Since the bidirectional thyristor (3) is maintained in the ON state by the current, even if the bidirectional thyristor (3) is turned on due to vibration of the main current, it is turned off again. Similarly, even if the polarity of the AC power supply (1) is reversed, the diode DB + thyristor (7) and the diode D! Current flows through the bidirectional thyristor (3
) will definitely turn on.

6. When the short circuit switch (9) is OFF, the electromotive force of the tertiary winding L3 is V. Since v,<v, the charging of capacitor C7 is slow and the bidirectional thyristor (
Since the turn-on time of 3) is delayed, the electric blower (2) is driven with the set low input. On the other hand, when the short circuit switch (9) is ON, the electromotive force of the tertiary winding is V, and Vs>'b, so the capacitor C
Since charging of I is fast and the turn-on time of the bidirectional thyristor (3) is accelerated, the electric blower (2) is driven at the maximum input. In this way, the electric blower (2)
input power will be controlled. Then, the stop is performed by turning off the switch (8).

Next, a second embodiment of the present invention will be described based on FIG. 4. In this embodiment, a variable resistor VR is used instead of the resistor R11.
, is used. And this variable resistance VB, O
Since the slider aω also serves as a short-circuit switch, the fourth
If you slide it to the position shown by the dashed line in the figure, the variable resistance VB
, is shorted and becomes the maximum input.

In any case, according to the embodiment described above, the control is performed in two stages: minimum input and maximum input, but according to this embodiment, the variable resistor VR, the secondary winding L! The resistance component connected to the tertiary winding can be adjusted steplessly and continuously, and the electromotive force generated in the tertiary winding can also be adjusted continuously at V, ~v3, and the electric blower (
2) The long sword can be fully continuously variable controlled. As a result, the input can be gradually increased and a quiet start can be achieved.

Further, a third embodiment of the present invention will be explained with reference to FIG. In this embodiment, a diode DI11 is used as a voltage drop element in place of the resistor R11. This diode D
I3 may be connected in any direction. According to this embodiment,
Switch (when 81 is ON, short circuit switch (9)
If it is ON, the secondary winding L2 is short-circuited, but if the short-circuit switch (9) is OFF, the secondary winding L2 is short-circuited by the diode DIl+, and the AC power supply (1
), the secondary winding mLt will be shorted (in the forward direction of the diode D), and the other half cycle will open the secondary winding mLt.

Therefore, if we look at the electromotive force of the tertiary winding L8, the AC power supply (1
) (when the secondary winding L2 is opened), the electromotive force decreases by half a cycle (when the secondary winding L2 is opened), and the minimum input of the dynamic blower (2) is set accordingly. In addition, capacitor C
Reference numeral 8 is for providing an averaged output during ON and OFF for each half cycle to the capacitor C2.

According to this embodiment, since the half-wave characteristic of the diode DI11 is utilized, the control has less variation and is stable compared to the resistance type and the type.

A fourth embodiment of the present invention will now be described with reference to FIG. 6'. In this embodiment, in place of the resistor R11, diodes DI4 + Dlfi connected in parallel with opposite polarities are used.
At least one set or more of these are connected in series as shown with subscripts a, b, . . . .

As a result, when the short-circuit switch (9) is short-circuited, the input is set to the maximum, and when the short-circuit switch (9) is OFF, the electromotive force of the tertiary winding L8 decreases due to the forward voltage drop of the diode DI4 + D, and the electromotive force of the tertiary winding L8 decreases, and the output voltage of the PUT (5) decreases. It is set to output a low input trigger signal. Specifically, diode DI41 + D + IIa in parallel is about 0.6 to 0.
．． There is a voltage drop of about 75 V, and diode D1 is added to this.
4b, DI! Since the parallel circuit 'b is connected in series, the voltage can be dropped by approximately 1.2 V in total.

According to this embodiment, since the forward voltage drop of the diodes DI4 + DIll is utilized, there is less control variation and stable control is possible compared to the resistor R11 method.

In this embodiment, as shown in FIG. 7, the terminal that short-circuits both ends of the diodes DI4a + DI4b is a.

Diode D. + ] Short-circuit switch (with C as the floating open terminal)
If 9a) is provided, the electric blower can be controlled in +21t-2 steps or more so that the short circuit switch (9a) provides the maximum input when the C terminal is connected, the intermediate input when the B terminal is connected, and the minimum input when the C terminal is connected. . Of course, diode DI4 + D
,.

It is clear that if more sets of 2 are connected, switching control of 4 stages or the like can be performed.

Effects of the Invention The present invention adopts the leakage transformer method as described above, and has a circuit configuration that includes a variable characteristic negative resistance element in the gate trigger circuit of a bidirectional thyristor. A switch and a voltage drop element are connected in series between the next windings, and a short circuit switch is connected in parallel to this voltage drop element, so the electromotive force generated in the tertiary winding of the Silly Ketsuge core can be changed by the 0N10FF of the switch. It is possible to trigger a characteristic variable negative resistance element by using a variable resistance element, and therefore, gate control of a bidirectional thyristor can be performed and input control of an electric blower can be performed.In this case, if a variable resistance is used as a voltage drop element, a stepless can perform input control,
Further, by using a diode and utilizing its half-wave rectification effect or forward voltage drop, stable control with less variation can be performed.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram showing a conventional example, FIG. 2 is a side view showing the operation of the leakage gate, FIG. 3 is a circuit diagram showing a first embodiment of the present invention, and FIG. The circuit diagram showing the second embodiment, the fifth factor is the circuit diagram showing the third embodiment of the present invention, the circuit diagram showing the fourth embodiment of the present invention, and the seventh factor.
The figure is a circuit diagram showing a modified example. l... AC power supply, 2... electric blower, 3... bidirectional thyristor, 5... characteristic variable negative resistance element, 6...
...Gate trigger circuit, 8...Switch, 9...Short switch, T, ...-Next side core, T, ...Intermediate core, T3...Leak Tsuji core, Ll...-Next volume line,
L,...Secondary winding, L,...Tertiary winding, R11...
・Resistance, VR,...variable resistance, lO...slider, D
IS~D...Diode application person Tokyo Seiki Co., Ltd.

Claims (1)

[Scope of Claims] 1. A leakage transformer is provided in which an electric blower and a bidirectional thyristor are connected in series to an AC power source, and a primary winding wound around a secondary core is connected to the AC power source. One end of the tertiary winding wound around the leakage coil 7 of this leakage transformer is connected to the anode side of the bidirectional thyristor, and the other end is connected to the anode side of the variable characteristic negative resistance element of the gate trigger circuit. , a switch and a voltage drop element are connected in series between both ends of a secondary winding wound around the intermediate core forming a magnetic resistance that restricts the flow of magnetic flux to the leakage core side of the leakage transformer, and this voltage An electric blower input control circuit characterized in that a short circuit switch is connected in parallel to a drop element. 2. The electric blower input control circuit according to claim 1, wherein the voltage drop element is a resistor. 3. The electric blower manual control circuit according to claim 1, wherein the voltage drop element is a variable resistor, and the slider 7 also serves as a short-circuit switch. 4. The electric blower input control circuit according to claim 1, wherein the voltage drop element is a diode. 5. The voltage drop element is a set of diodes connected in parallel with opposite polarities, and at least one set of these is connected in series. Electric blower input control circuit.