KR200393258Y1 - Double column Wheel Fan - Google Patents

Abstract

The present invention improves the efficiency of the wind pressure sucked from the fan and discharged backward by forming the blade of the fan in two stages, and also has a two-stage wheel fan that can prevent the efficiency decrease due to the wind pressure that is returned to the outside of the blades when the blade rotates. It starts.

The present invention forms an impeller on the outer periphery of the impeller to increase the blowing air generated by the rotation of the two impellers, to drive the bell mouse formed to rotate it on the impeller outer periphery, as well as to reduce the noise generation Fix the front fixed net on the front, the rear fixed net on the back, fix the fixed shaft fixed to these front and rear fixed net, and install the impeller in which the central impeller and the outer impeller are integrally installed, and the impeller The belt groove is formed so that the belt of the outer circumferential surface thereof is connected to the belt groove, and a motor is installed in the space between the casing and the impeller to drive the belt.

The present invention is divided into a central impeller and an outer impeller to reduce the air resistance due to the impeller rotation, and because the gasket is rotated in a closed state can drive the fan without loss of air resistance and pressure due to backflow, Driven by a belt connected to the outer peripheral surface of the impeller has a useful effect that can be driven without noise.

Description

Double column wheel fan

The present invention relates to a two-stage wheel fan, and more particularly, to improve the efficiency of the wind pressure sucked from the fan and discharged backward by forming the blade of the fan in two stages, as well as due to the wind pressure flowing back between the blade outer gap during rotation of the blade. The present invention relates to a two-stage wheel fan capable of preventing a decrease in efficiency.

As is well known, the fan causes the induction of air, and is composed of an impeller which causes flow and a casing which guides the flow of air to the impeller.

Such a fan includes an axial fan whose flow direction of the vane inlet and outlet coincides with the rotational axis so that air flow is generated in a direction parallel to the rotational axis of the vane, and a radial flow fan for increasing the pressure by centrifugal force; In addition, the axial and radial flows exist in the van, and are classified into a mixed flow fan used when an increase in flow rate and pressure is required at the same time.

Such fans are mainly used in air conditioning systems or various intake and exhaust systems, and various types of fans are used, ranging from small to large industrial fans such as computer cooling fans.

In addition, the fan is not only an air intake and air conditioner in a building, but also an important equipment in industrial manufacturing processes, power generation facilities, subways, and tunnels.

The basic structure of such a fan is coupled to the boss of the impeller to the rotary shaft coupled to the central portion of the casing as described above, by installing a motor for rotating the rotary shaft to rotate the impeller by the drive of the motor.

The fan directly rotates the impeller coupled to the motor, and thus the overall efficiency of the fan is reduced due to the resistance applied to the impeller, and the motor directly rotates the rotating shaft to generate noise, and extra space between the impeller and the casing As a result, the blowing air passing through the impeller flows back, thereby lowering the efficiency of the fan.

In addition, since the impeller is formed in only one stage, there is a limitation in structural deformation as well as a limitation in improving the efficiency of the fan by modifying the curved bending angle of the impeller.

An object of the present invention devised to solve the above problems is to provide a two-stage wheel fan to increase the blowing caused by the rotation of two or more impeller by forming an impeller of different angles overlapping the outer periphery of the impeller.

Another object of the present invention is to provide a two-stage wheel fan to drive the bell mouse formed to rotate it on the outer periphery of the impeller as well as to reduce noise.

Another object of the present invention is to provide a two-stage wheel fan to improve the efficiency of the fan as well as to prevent the loss of wind pressure due to the gap between the impeller and the casing.

In order to achieve the above object, the present invention provides a central impeller in which a plurality of wings are formed on the outer circumferential surface of the support, and a disc is integrally formed at the distal end of the central impeller, and a larger number of wings are formed on the outer circumferential surface of the disc than the central impeller. It proposes a two-stage wheel fan is installed impeller consisting of an outer impeller.

The present invention can be installed integrally inside the casing without a frame for installing the motor, and the belt driving the impeller is installed without being exposed to the outside, thereby improving aesthetics, and preventing foreign substances from being inserted into the belt. It is divided into the center impeller and the outer impeller, so it reduces air resistance due to the impeller rotation, and the gasket is rotated in close contact with the outer surface of the bell mouse, so the fan can be driven without loss of air resistance and pressure caused by backflow. And, since it is driven to the outer circumferential surface of the impeller, there is no noise, there is a useful effect that can be easily driven by adjusting the rotation ratio of the motor and the fan.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

As shown, the present invention includes a casing 10 having a predetermined shape, an impeller 30 rotatably installed in the casing 10, and a motor 50 for rotating the impeller 30. .

In addition, the casing 10 is made of various shapes such as square, circle, polygon, and has a predetermined thickness, the front and rear fixed net 11 and the rear fixed net 12 for supporting the support between the front and rear (33) Fix it.

The front fixing net 11 and the rear fixing net 12 are radially formed from the center, and a plurality of fixing nets are arranged in a circle or polygon, and at the ends of the fixing nets 11 and 12, the fixing rod 13 The fixing plate 14 is formed to be inserted and fastened.

In addition, the casing 10 forms a plurality of fixing holes 15 at positions corresponding to the radial fixing nets 11 and 12, and fixing holes 15 having the same length as the thickness of the impeller 20 at the rear of the casing 10. Step 16 is formed so that the rear fixing net 12 is fixed to the back of the). The shutter 17 is opened and closed by wind pressure at a position spaced apart from the step 16 by a predetermined distance, and the shutter frame 18 supporting the shutter 17 is fixed to both sides of the shutter 17.

In addition, the inner circumferential surface of the casing 10 is formed with a gasket fixing protrusion 19 is coupled to the gasket 20 is flowed forward when blowing. The gasket 20 is made of synthetic resin such as soft rubber having wear resistance and heat resistance.

In addition, the gasket 20 provides resistance to the impeller 30 rotating in a state in which the gasket 20 is in contact with the bell mouse 31 portion of the impeller 30 by a backflow blowing in the state where the gasket fixing protrusion 19 is installed. It is formed in one curved shape so as not to.

Such a gasket 20 seals a portion where the bell mouse 31 contacts, namely, the casing 10 and the bell mouse 31, by a backflowing blower, thereby preventing a loss of pressure therebetween.

 In addition, the impeller 30 integrally forms a support rod 33 into which the fixed shaft 32 is inserted in the center, and supports the bearing 33 on both sides so that the support shaft 33 rotates smoothly about the fixed shaft 32. 34), the front fixing net 11 and the rear fixing net 12 is fitted to both sides of the fixed shaft 32, to form a screw portion 36 to which the nut 35 is fastened.

In addition, a plurality of central impellers 40 are formed on the outer periphery of the center of the support stem 33, and a disk 41 parallel to the support stem 33 is integrally formed on the outer periphery of the central impeller 40. do. The disc 41 is formed integrally with the outer periphery of the plurality of central impeller 40 to form the outer impeller 42 on the outer periphery thereof, as well as the central impeller 40 and the outer impeller 42 rotate the same To be.

The central impeller 40 is formed in plural around the support bar 33, the outer impeller 42 formed on the outside thereof is formed twice the number of the central impeller 40. That is, if the wings of the central impeller 40 is four, the outer impeller 42 preferably forms two outer impellers 42 per blade of the central impeller 40.

In addition, if the wings of the central impeller 40 is eight, the outer impeller 42 wings are formed of 16 doubled. On the contrary, it is also possible to increase the number of wings of the outer impeller 42 by 1.5 times, 3 times, 4 times, or the like.

In addition, the outer peripheral edge of the impeller 42 is formed with a bell mouse 31 is formed to be curved to one side, and a plurality of belt grooves 43 to which the belt 55 is coupled to the outer peripheral surface thereof is formed.

In addition, the motor 50 is installed on the outer side of the impeller 30 to drive the impeller 30, preferably installed in the space formed between the corner portion of the casing 10 and the impeller 30. The motor 50 is integrally coupled to the pulley 51 for transmitting the driving force, the motor 50 is maintained in a safe installation state from vibrations due to the rotation of the drive shaft, as well as the position change due to the load of the motor 50 The fixing frame 52 fixed inside the casing 10 is fixed to prevent the back from occurring.

In addition, one end is fixed to the fixed shaft 32 on the rear surface of the motor 50, and the other end connects the fixing bar 54 to the bracket 53 on which the motor 50 is fixed. The bracket 53 protrudes in three directions on the rear surface of the motor 50 to fix it to the step 16 of the casing 10 so that the bracket 10 is firmly fixed to the casing 10 so that vibration is prevented when the motor 50 is driven. Install.

The belt 50 is wound around the motor 50 and the belt groove 43, and the belt 55 is installed to rotate the impeller 30 by driving the motor 50. The belt 55 adjusts tension. The idle roller 56 is installed, and the idle roller 56 has one end fixed to the fixing frame 52 and the other end of the turnbuckle 57 fixed to the idle roller 56.

The present invention made of such a configuration is coupled to the impeller 30 rotatably around the fixed shaft 32 in the casing 10, the bearing 34 is coupled to both sides of the smooth rotation. The front and rear fixing net 11 and the rear fixing net 12 is inserted into the fixing shaft 32 and the nut 35 is fastened thereto. In addition, the motor 50 is fixed to the casing 10, and the fixing frame 52, the bracket 53, and the like are fixed to the motor 50 so that the motor 50 is installed in a stable state.

In addition, the belt 55 is wound around the belt groove 43, the pulley 51, and the idle roller 56 of the impeller 30, and the impeller 30 is rotated as the belt 55 is rotated by the driving of the motor 50. To be combined. When the impeller 30 and the motor 50 are installed in this way, the fixing rod 13 inserted into the fixing hole 15 is inserted, and the impeller is fastened to the front fixing net 11 and the rear fixing net 12 by fastening nuts. It is coupled to support the support bar 33 of (30).

In addition, the shutter 17 is coupled to the shutter frame 18 at the rear of the impeller 30.

The present invention is such that when the power is applied to the motor 50, the motor 50 is driven, thereby the pulley 51 is rotated. By rotating the pulley 51, the belt 55 rotates the bell mouse 31 of the impeller 30 so that the impeller 30 rotates.

This impeller 30 is rotated about the fixed shaft 32 coupled to the center of the support 33, the front fixed net 11 and the rear fixed net 12 is in a state in which the impeller 30 is stable It is firmly supported to rotate.

When the impeller 30 rotates in this way, the wind is sucked from the front through the central impeller 40 and the outer impeller 42, and the air is discharged to the rear. The shutter 17 installed at the rear by the wind pressure is the shutter frame 18. It is rotated to the upper center and opened.

The wind passing through the impeller 30 proceeds backward through the open shutter 17, and part of the wind exiting the rear flows back toward the impeller 30. By the reverse flow, the gasket 20 coupled to the gasket fixing protrusion 21 is pushed toward the front side to seal the casing 10 and the bell mouse 31. As such, the gasket 20 is in close contact with the bell mouse 31 curved in an arc shape, and the bell mouse 31 continuously rotates.

In addition, the curved portion of the bell mouse 31 is formed to a large radius to the front side to increase the amount of air sucked from the front side, the central impeller 40 is strongly intake of the air in the center portion to discharge to the rear, the outside The impeller 42 sucks and discharges air from the outer diameter of the central impeller 40 to the tip of the impeller 30.

In addition, the outer impeller 42 has a larger number of wings than the central impeller 40, thereby reducing the centrifugal force resistance due to the centrifugal force rotating the impeller 30. This not only makes the impeller 30 rotate smoothly, but also further improves the efficiency of the fan.

In addition, as shown in Figure 5 can be carried out by changing the position of the turnbuckle 57 for adjusting the tension of the belt 55, connecting the pulley 51 and the belt groove 43 by the belt 55 In addition, the driving of the impeller 30 in a gear meshing method or the like is also possible.

In this way, the present invention can be integrally installed inside the casing without a separate frame for installing the motor, and the belt driving the impeller is installed without being exposed to the outside, thereby improving the aesthetics and inserting and contaminating foreign substances on the belt. And the central impeller and the external impeller are rotated to maximize the amount of air discharged due to the impeller rotation, and is rotated in a closed state by the gasket, so the fan can be driven without loss of air resistance and pressure due to backflow. It can be driven by the outer circumferential surface of the impeller, so that the rotation ratio between the motor and the fan can be easily adjusted without the resistance of the flowing air, and the effective effect that enables efficient driving without noise and air resistance generated by the belt and the reduction gear There is.

Figure 1 is an exploded perspective view showing a two-stage wheel fan of the present invention.

Figure 2 is a cross-sectional view showing a two-stage wheel fan of the present invention.

Figure 3 is a front view partially showing a two-stage wheel fan of the present invention.

Figure 4 is a rear view partially showing a two-stage wheel fan of the present invention.

Figure 5 is a front view showing another embodiment of a two-stage wheel fan according to the present invention.

* Description of the symbols for the main parts of the drawings

10: Casing 11: Front Net

12: Rear security net 13: Fixed span

14: fixing plate 15: fixing hole

16: step 17: shutter

18: shutter frame 20: gasket

21: gasket fixing protrusion

30: Impeller 31: Bellemouth

32: fixed shaft 33: support

34: bearing 35: nut

36: thread

40: center impeller 41: disc

42: outer impeller 43: belt groove

50: motor 51: pulley

52: fixed frame 53: bracket

54: fixing bar 55: belt

56: idle roller 57: turnbuckle

Claims (8)

A central impeller 40 having a plurality of wings formed on an outer circumferential surface of the support stem 33, The disc 41 is integrally formed at the front end of the central impeller 40 and the impeller 30 is formed of an outer impeller 42 having a larger number of wings on the outer circumferential surface of the disc 41 than the central impeller 40. Two-stage wheel fan, characterized in that. The method of claim 1, The outer impeller 42 is a two-stage wheel fan, characterized in that the increased number of times, such as 1.5 times, 2 times, 3 times the number of the center impeller 40 wings. The method of claim 1, The outer impeller (42) is a two-stage wheel fan, characterized in that the outer circumferentially curved in one direction and coupled to the drive connecting means such as a belt (55). The method of claim 1, The support section 33 is a fixed shaft 32 is inserted into the center thereof, the front fixing net 11 and the rear fixing net 12 is fixed to both sides thereof to support the impeller 30, characterized in that Two-stage wheel fan. The method of claim 1, Two-stage wheel fan, characterized in that the rear of the impeller (30) is installed to be rotatable shutter (17) opened and closed by the wind pressure generated by the drive of the impeller (30). The method of claim 1, The motor 50 for driving the impeller 30 is a two-stage wheel fan, characterized in that installed in the space between the casing (10) and the impeller (30). The method of claim 1, Two-stage wheel fan, characterized in that the sealing gasket 20 is installed between the outer side of the impeller 30 and the gasket fixing protrusion 21 of the casing (10). The method of claim 6, The motor 50 is fixed to the fixed frame 52, the brackets 53 and the fixed bar 54, two-stage wheel fan, characterized in that installed firmly to prevent vibration when driving.