KR102586337B1 - air blower - Google Patents

Abstract

A blower device with wings attached to a motorized device.

Description

Motor-integrated blower {air blower}

The present invention relates to a device that forcibly transports air or other gases, and more specifically, to a device that transfers air currents by transmitting electrical energy to rotary blades.

Therefore, in addition to general blowers, it can be applied to the field of blowing technology such as fans, circulators, ventilators, vacuum cleaners, hair dryers, humidifiers, air purifiers, dust collectors, dryers, and fan heaters.

A blower is a device that transports air or other gases. A common method is to rotate a propeller using the power of a motor to transfer energy to the air current. The propeller transfer device uses the pressure difference between airflow flowing on the front and back of the blade, which inevitably results in energy loss due to centrifugal force and vibration and noise during the rotation of the propeller. The technology to reduce such energy loss and side effects is the technology behind this invention. In addition, most power devices are installed in the center where air flow flows, which causes an obstacle to smooth flow and increases the cross-sectional area or acts as a factor in energy loss. Background technology is to solve these problems.

Application number: 10-2003-0099320 (December 29, 2003)

Induction motor structure and principles, DC motor structure and principles

Embodiments of the present invention solve various shortcomings of existing propeller devices. In other words, the space occupied by the motor in the center of the wing is made into a centripetal force passage through which airflow flows well, and the energy loss factors of existing blowers are eliminated, vibration and noise are minimized, and durability is impaired due to the imbalance of power between the center and the tip of the wing. Solving the problem is the problem we want to solve.

According to one aspect of the present invention, while a typical blower uses power to rotate a blade provided on a rod-shaped rotating shaft to move air currents, the present invention is a method of combining a transfer device within an electric power device. That is, the diameter of the rotating shaft of the existing power device is enlarged to make it tubular so that airflow can pass through, and a rotor that constitutes the power device is provided on the outer diameter of the pipe and a stator that can rotate the rotor is provided on the outside. Wings are attached to the inside of the tube, and when power is supplied to the stator, energy is transmitted by rotating the tube and wings. By expanding the total amount of airflow flowing inside the tube, the energy of the gas coming out of the discharge port is compressed and blown out without loss, thereby increasing the airflow. is to move quickly. In addition, in order to increase energy efficiency, the principle of a bladeless fan is applied to form a space penetrating from the inlet to the outlet in the center of the wing, fundamentally eliminating the resistance that inevitably occurs in the center of the existing propeller, and using that space to transmit centripetal force. It is used as a passage. A blower device including such a solution can be provided.

Energy consumption generated between the blower and devices including the blower according to an embodiment of the present invention can be minimized. In addition, energy loss due to centrifugal force is reduced and converted to a centripetal force device to transmit most of the energy in the same direction. In addition, noise and vibration generated from the power transmission process and propeller are minimized, and an efficient device suitable for eco-friendly energy use is implemented.

Representative diagram: Projection appearance according to an embodiment of the present invention
1 is an exploded perspective view according to an embodiment of the present invention
Figure 2 is a side development view according to an embodiment of the present invention
Figure 3 is a rear projection development view according to an embodiment of the present invention.
4 is a rear projection view according to an embodiment of the present invention.
Figure 5 is a cross-section and airflow flow chart according to an embodiment of the present invention.
Figure 6 shows the arrangement of wings, resistance, and centripetal force according to an embodiment of the present invention.
Figure 7 is an exploded perspective view of a general electric motor, which is an element technology of the present invention.
Figure 8 is a principle diagram of a bladeless fan illustrating the background technology of the present invention.
Figure 9 is an example circuit diagram for controlling the rotation speed of the present invention.
Figure 10 is an application example of the present invention, a perspective view of the blower projection
Figure 11 is an example of application of the present invention, a perspective view of a fan projection
Figure 12 is a picture of the electric motor blocking the airflow intake, which is the problem part of the present design.

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

As shown in Figures 1 and 2, the blower according to an embodiment of the present invention

Main body (A1): An intake port of a certain shape is formed on one side to suck in airflow, and a space for installing a stator (D1) and rotor (C1) is provided on the other side. Inside the main body (A1), one or more bearings (A2) are inserted into the rotation space of the rotary tube (B1) to enable the rotary tube (B1) to rotate smoothly inside the main body. If necessary, the intake port may be provided separately from the main body in a certain size and shape.

Stator (D1): Like the stator of an existing motor as shown in FIG. 7, it is inserted into one side of the inner diameter of the main body (A1) to generate rotating magnetic flux. To generate the magnetic flux, a connection line (C2) that transmits control information of a constant current and rotation speed is coupled. However, when the rotor (C1) is a winding type, the connection line (C2) may be connected or connected to the winding of the rotor (C1) in a certain form.

Connection line (C2): The connection line is provided as a device for supplying current from the power source to the stator (D1) and rotor (C1) or transmitting and receiving control information for controlling the rotation speed of the rotor (C1).

Rotor (C1): Coupled to the outer diameter of the rotary tube (B1) within the annular space to which the magnetic flux of the stator (D1) is applied, and generates a rotary magnetic flux in a certain direction through interaction with the stator (D1) to generate a rotary tube ( Rotational force is transmitted to B1). Additionally, the connection line (C2) can be connected or connected in a certain way depending on the type of motor (e.g., rotor winding type).

Rotating tube (B1): The rotor (C1) is coupled to the same axis on one outer diameter side of the rotating tube, at an inner diameter position corresponding to the stator (D1), and magnetic flux is formed in the stator (D1) as shown in the example in FIG. It is equipped to respond to changes in One or more wings of a certain shape as shown in Figure 6 are attached to one end of the inner tube. It rotates integrally with the rotor (C1), and simultaneously functions as a rotation axis of the example motor of FIG. 7 and as a propeller of an existing blower.

The rotary tube (B1), along with the stator (D1) and rotor (C1), can be applied in two or more sets to one device as needed. At this time, the shape and number of internal blades of the rotary tube (B1) may be different. For example, the front rotary tube can play a different role as a wing suitable for suction, and the rear rotary tube can play a different role as a wing suitable for compression. The diameter of the rotary tube may vary between the sizes of the inlet and the discharge port.

Discharge port (E1): It is combined with one side of the main body (A1) to form the rotation space of the rotary tube (B1) and is provided with a certain shape and cross section to prevent vortices from being generated in the airflow discharged to the rear of the rotary tube.

Support (F1): Can be used as a device to fix and erect the main body (A1) in a certain position and adjust the direction or height, and can be used as a passage for the connecting line (C2) and an installation space for the regulator. .

Operation: The existing motor stator in Figure 7 corresponds to the same function as the stator (D1), and the rotor corresponds to the same function as the rotor (C1). The rotating shaft whose diameter is enlarged to a certain size corresponds in function to the rotating tube (B1) and operates on the same principle as the existing motor. And the blades inside the rotary tube (B1) operate in correspondence with the blades of the existing blower. The rotational speed of the rotary tube (B1) can be adjusted by a speed regulator configured as the example circuit of FIG. 9.

A1: Main body, A2: Bearing, B1: Rotating tube, B2: Wing, C1: Rotor,
C2: Connection line, D1: Stator, E1: Discharge port, F1: Support,

Claims (1)

In a blowing device that moves air or other air currents,
On one side, an annular space of a certain shape is formed to suck in the incoming airflow, and on the other side, an inner diameter is provided with a space for a stator (D1) to be placed, and a main body (A1) having an annular space in the center;
A stator (D1) that is fixedly mounted on a certain part of the main body (A1) and generates a rotating magnetic flux corresponding to the rotor (C1);
A cylindrical space through which a certain amount of airflow can pass is provided on the inside, and one or more wings B2 of a certain shape capable of moving the airflow are provided at one end of the space, and at one end of the outer tube, an annular space inside the stator D1. A rotary tube (B1) to which the rotor (C1) is coupled so as to rotate independently;
A rotor (C1) that is coupled to a certain position where the magnetic flux of the outer stator (D1) of the rotary tube (B1) is applied and generates a rotating force;
When current is supplied to the blower, the rotor (C1) rotates, and the rotary tube (B1) coupled to the rotor (C1) is provided inside the rotary tube (B1) and has a hub and shaft at the center. Wingless (B2):
A blowing device characterized in that the inflow amount, speed, and pressure of the discharged airflow are increased by transferring energy to the airflow passing through the pipe through the action of the blade (B2).