KR930004115Y1 - Motors impeller for vacuum cleaner - Google Patents

Abstract

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Description

Impeller of vacuum cleaner motor

Figure 1 shows a conventional impeller, Figure 1a is a partially cutaway plan view, Figure 1b is a side view.

Figure 2 shows the structure of the impeller to which the present invention is applied, Figure 2a is a partial cutaway plan view, Figure 2b is a side view.

* Explanation of symbols for main parts of the drawings

1: Air inlet 1a: Air inlet area

7a: air outlet area 20: wing

The present invention relates to an impeller of a vacuum cleaner motor, and more particularly, to an impeller of a vacuum cleaner motor capable of achieving a high suction input without increasing the rotation speed of the motor.

An impeller structure of a rectifier motor generally used in a vacuum cleaner has an impeller top plate 2 having an air inlet 1 formed thereon as shown in FIG. 1A and FIG. 1B, and a shaft hole for coupling a motor shaft (not shown). 3) is formed by combining the impeller lower plate (4) is formed and a number of vanes (5) in the form of a spiral between them, the reference numeral 6 in the drawing is impeller upper plate, lower plate (2) (4) and The coupling hole of the vane 5 is shown.

Looking at the process of the air is sucked by the impeller configured as described above, first, when the power is applied to the motor rotates the impeller in the rotational speed difference between the air inlet (1) and the blade (5) located at the end of the air outlet (7) Negative pressure is generated on the air outlet port 7 so that air is sucked into the air inlet port 1 of the impeller, and the sucked air flows toward the air outlet port 7 as it collides and is induced on the wall surface of the wing 5. As this happens, such an action is continuously generated and the impeller continuously inhales air.

In the vacuum cleaner motor, the air suction input is determined by the pressure difference between the air inlet 1 pressure and the air outlet 7.

That is, the air suction input = the pressure of the air inlet-the pressure of the air outlet, where the air inlet (1) pressure refers to the general atmospheric state, and thus represents the atmospheric pressure regardless of the air flow rate, the air outlet (7) Pressure of Bernoulli's theoem

= By constant Being

Therefore, PαCONST-V ² becomes the air suction input α atmospheric pressure-(CONST-V ² ).

In the above equation, P: pressure, V: velocity, Z: potential energy, a: specific gravity of air, g: acceleration of gravity.

As can be seen from the above equation, in order to increase the air suction input, the air velocity V of the air outlet 7 must be increased.

However, in the conventional vacuum cleaner motor, it is difficult to expect the high absorption input, and in order to obtain the high absorption input, the rotation speed of the impeller must be increased. In this case, the rotation noise increases, the value of the product decreases, and the mechanical strength of the impeller arises. There was a high risk of breakage during rotation.

The present invention is to install a separate vane in order to solve the conventional defects as described above will be described by the accompanying drawings as follows.

As shown in FIG. 2A and FIG. 2B, between the impeller upper plate 2 on which the air inlet 1 is formed and the impeller lower plate 4 on which the shaft hole 3 is formed so as to couple the motor shaft (not shown). In the case where several wings 5 are provided in a spiral shape, a separate wing 20 is provided between the wing 5 and the wing 5 so that the air intake area 1a and the air discharge area 7a are the same. In the drawings, the same parts as in the conventional configuration are denoted by the same reference numerals.

The air intake process of the present invention configured as described above is the same as the conventional technology process, but in the impeller, by installing an additional wing 20, the air intake area 1a and the air discharge area 7a are the same.

Formula In A = A ₀ , V ₀ = V1. That is, the air speed of the air inlet 1 and the air speed of the air outlet 7 are equal.

Where A is the air inlet area, V is the air inlet flow rate A _{0 is the} air outlet area V ₀ is the air outlet flow rate.

In addition, since the velocity of air is inversely proportional to the area, the velocity at the air outlet 7 in this article is faster than that of the prior art configuration, so that PαCONST-V is PαCONST-. This results in a large drop in pressure.

As described above, the present invention has the same air inlet area (1a) and air outlet area (7a) by additionally installing a separate wing 20, so that the air velocity at the air outlet (7) in the prior art configuration In contrast, it becomes faster and can achieve high absorbing power without increasing the rotation speed of the impeller, and at the same time, it can achieve low noise as well as increase the coupling force of the upper and lower plates (2) and (4) of the impeller, which can damage the impeller rotation. You can minimize the risk.

Claims (1)

In the case where several wings 5 are spirally installed between the impeller upper plate 2 in which the air suction opening 1 is formed, and the impeller lower plate 4 in which the shaft hole 3 is formed so that the motor side is coupled, the wing Impeller of the vacuum cleaner motor, characterized in that the additional blade 20 is further provided so that the air inlet area (1a) and the air outlet area (7a) between the (5) and the blade (5).