JPS6159130B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a central cleaner having two or more suction fan motors built into its main body.

Traditionally, central cleaners have only one or two suction fan motors housed in the main body, and can only be operated by switching the cleaning hose.
All fan motors were always operating by turning them ON and OFF. Therefore, in the case of a powerful type with two built-in fan motors, when suction is drawn from the suction port provided near the main body, the suction force is too strong, causing inconvenience in operation.

In addition, in the case of a built-in fan motor, cleaning is limited to one suction port, and if two suction ports are used at the same time, the suction force weakens, making it difficult to perform sufficient cleaning.

The present invention solves the above-mentioned conventional drawbacks,
The embodiment will be explained below based on FIGS. 1 to 4.

In Figure 1, S _M is the main switch of the central cleaner body, M ₁ and M ₂ are the fan motors,
1 is a transformer relay that operates the fan motor _M1 , 2 is a transformer relay that operates the fan motor _M2 , S _R1 to S _R3 are hand switches at the suction port with a resistor R connected in series, and 3 is for the circuit of the hand switch. 4 is a voltage output detection circuit that detects the potential difference across the resistor r and extracts the output; 5 is a DC power supply circuit that operates the voltage output detection circuit 4; 6 is a voltage output detection circuit that responds to the output of the voltage output detection circuit 4; 7 is a switch circuit that opens and closes according to the output of the voltage output detection circuit.

When main switch S _M is turned on and hand switches S _R1 to S _R3 are all off, the current that flows through resistor r is i _O , and when hand switch S _R1 is turned on, the current that flows through resistor r is i ₁ , Hand switch S _R2 also
If the current flowing through the resistor r when turned on is i ₂ , then
The potential differences across the resistor r are i ₀ r, i ₁ r, and i ₂ r, respectively. Here, the voltages E ₁ and E ₂ are set so that O≦i ₀ r<E ₁ E ₁ <i ₁ r<E ₂ i ₂ r>E ₂ (see FIG. 2). Further, the switch circuit 6 is designed to be turned on at voltage _E1 , and the switch circuit 7 is designed to be turned on at voltage _E2 .

In Fig. 3, 8 is a socket provided with a resistor R;
9 is a hose having a hand switch S _R1 .

In Fig. 4, 10 is a tank, 11 is a tank suction port, 12 is a primary filter, 13 is a secondary filter,
14 is Patsukin. 15 is a fan motor case, inside which are fan motor _M1 and fan motor _M2.
is firmly attached.

Reference numeral 16 denotes a partition wall, which has a valve 17 on its upper part and separates the exhaust side space of the fan motor _M1 and the motor _M2 . 18 is an exhaust port of the fan motor case 15;
9 is a power cord, and 20 is a control wiring for indoor wiring.

Although not shown, the control circuit described in FIG. 1 is housed inside the fan motor case 15.

In the above configuration, to briefly explain the operation of the hose outlet installed indoors or at any other location and the main unit's fan motor, when using only one outlet, turn on the hose hand switch. Then, the fan motor _M1 always operates. This means that whether it is the hand switch S _R1 or the hand switch S _R2 , the fan motor _M1 always operates when one hand switch is turned on. Next, to use two hoses at the same time,
Fan motor _M1 and fan motor _M2 always operate at the same time. In this case, which switch is on hand?
Two fan motors are always operated when I turn it on.

When only the fan motor _M1 is operated, the air sucked in from the tank suction port 11 passes through the primary filter 12 and the secondary filter 13, and is then sent to the fan motor.
The air is discharged from _M1 to the outside through the exhaust port 18. In that case, the pressure on the suction side of the fan motor M ₂ that is not being operated becomes lower than the pressure on the exhaust side, and air escapes from the exhaust side to the suction side of the fan motor M ₂ . This results in a loss, so valve 1
7 to prevent air loss. When fan motor M ₁ and fan motor M ₂ are operated simultaneously, valve 17 is open.

The valve 17 with such function may be a one-way valve using a spring, or a fan motor with a magnet.
It may also be linked to the movement of _M2 . In short, any configuration is sufficient as long as the fan motor _M2 is open when it is in operation and closed when it is stopped.

As explained above, according to the central cleaner of the present invention, even when cleaning one place or multiple places at the same time, the number of operating fan motors is controlled accordingly, so the cleaning work can be done reliably and easily. Furthermore, even if the number of fan motors in operation is reduced, there is no reduction in efficiency due to air backflow.

[Brief explanation of the drawing]

Fig. 1 is a control circuit diagram of the central cleaner in an embodiment of the present invention, Fig. 2 is an explanatory diagram of the control of the same circuit, Fig. 3 is a circuit diagram of the central cleaner, and Fig. 4 is a full sectional view of the main body. be. 17...Valve, _M1 , _M2 ...Fan motor.

Claims (1)

[Claims] 1 A control circuit that automatically controls the number of fan motors in operation according to the number of suction hoses in use; A central cleaner characterized by comprising a valve that shuts off an air passage of a motor.