KR102800161B1 - Blower-fan structure - Google Patents

Abstract

The present invention relates to a blower structure.
The purpose of the present invention is to provide a blower structure that can be installed by changing the discharge direction of the blower outlet to a horizontal direction, a vertical direction, or an inclined direction, and to reduce vibration and noise while discharging wind to stably blow wind.
According to the present invention, since the discharge port is made in advance and the product is completed by selectively combining parts according to the customer's request, there is an advantage in that manufacturing is easy and efficient, and process management can be maintained efficiently.
In addition, according to the present invention, the blower outlet can be installed by changing the discharge direction to horizontal, vertical, or inclined, and can stably blow air by reducing vibration and noise while discharging wind.
In addition, according to the present invention, it is possible to stably blow wind by reducing vibration and noise while exhausting wind from the blower.

Description

{Blower-fan structure}

The present invention relates to a blower structure in which an intake port can be selectively installed on the left or right side of a housing.

A blower is a device that draws in air using an impeller or blade built into the case and discharges it in a desired direction. Normally, if the pressure ratio of the gas at the discharge port and the inlet port is less than 1.1, it is called a fan, and if it is 1.1 or more and less than 2.0, it is called a blower.

Meanwhile, conventional blowers had to have their suction ports fixedly installed on only one side of the housing, and since the outlet of the outlet had to be decided in advance as being horizontal or vertical, they had to be manufactured, which meant that they had to wait until a manufacturing order came in, which resulted in very low work efficiency and productivity. In addition, there was the problem that once the outlet of the outlet was manufactured in a horizontal or vertical direction, it could not be installed in a different direction.

Korean Patent Publication No. 10-2019-0082302 Korean Patent Registration No. 10-2256429 Korean Patent Registration No. 10-2256239 Korean Patent Registration No. 10-2236429

The present invention aims to provide a blower structure capable of selectively installing an intake port on the left or right side of a blower housing, and changing the discharge direction of a blower discharge port to a horizontal or vertical direction and an inclined direction, and for stably blowing air by reducing vibration and noise while discharging wind.

According to one embodiment of the present invention, a blower structure comprises: a housing; an outlet formed at a predetermined portion of a periphery of the housing and through which wind is discharged from the inside of the housing; an intake port formed on a left or right wall of the housing and through which wind is introduced into the inside of the housing; a finishing plate installed on an opposite side wall so as to intake air to one side; and an intake port selectively installed together with the finishing plate on the left or right wall of the housing; an intake port formed on the left and right side walls of the housing and through which wind is introduced into the inside of the housing; an impeller which rotates by being axially supported by the shaft and a bearing within the housing about a shaft positioned at the center axis of the intake port as a rotation axis in order to introduce wind from the outside of the housing through the intake port; a rectangular frame attached to the left and right side walls of the housing and capable of being joined to the housing by bolts or screws so that the exhaust port can be directed in a horizontal direction, a vertical direction, or an inclined direction; a support member capable of supporting the rectangular frame on the ground; and a plurality of support fixing bolts and nuts for connecting the rectangular frame and the support member.

The above-mentioned support fixing bolt comprises: a cylindrical bolt casing having one end perforated with a hole smaller in diameter than the support, the inside being hollow, and the other end having a screw thread formed to penetrate the support and be coupled with the nut; a first spring provided inside the bolt casing and having an outer diameter equal to the inside diameter of the bolt casing so as to be provided to match the inside diameter of the bolt casing, a hooking portion protruding around the hole perforated at one end of the bolt casing; a hooking plate having a central axis penetrating the first spring inside the bolt casing and between the first spring and the second spring; a protrusion portion in the direction of the central axis of the second spring to fix the second spring at the hooking plate; and a hooking portion that hooks the first spring in the inside of the bolt casing and the hooking plate; an inertia weight protruding outward from one end of the bolt casing; and an inner wall inside the bolt casing whose one end is supported by the hooking plate and the protrusion portion and whose other end is not perforated inside the bolt casing. When vibration occurring in the blower structure is transmitted to the square frame, including the second spring provided in between, the vibration occurring in the blower structure can be alleviated by the inertia of the inertia of the support fixing bolt moving in the opposite direction of the vibration.

The above blower structure further includes a vibration detection sensor that measures a vibration frequency generated in the blower structure and a control unit that can adjust the intensity of vibration alleviation of the support fixing bolt, and the first spring and the second spring are made of a shape memory alloy that, when receiving an electrical signal from the control unit, remembers an expanded shape according to a temperature rise due to electrical resistance, and the control unit applies an electric signal to each of the first spring and the second spring based on the vibration frequency detected by the vibration detection sensor to adjust the stiffness of the first spring and the second spring, thereby actively alleviating vibration generated in the blower structure.

According to the present invention, the suction port can be selectively installed on the left or right side of the housing, so that the direction of the suction port or discharge port can be freely set, making it easy and efficient to manufacture the blower.

In addition, according to the present invention, since the suction port and the discharge port are made in advance and the product is completed by selectively combining the parts according to the customer's request, process management can be maintained efficiently.

In addition, according to the present invention, the blower outlet can be installed by changing the discharge direction to horizontal, vertical, or inclined, and can stably blow air by reducing vibration and noise while discharging wind.

In addition, according to the present invention, it is possible to stably blow wind by reducing vibration and noise while exhausting wind from the blower.

FIG. 1 is a drawing illustrating a blower structure (1) according to one embodiment of the present invention.
Figure 2 is a drawing of a blower structure (1) according to one embodiment of the present invention.
FIG. 3a is a drawing of a blower structure (1) according to another embodiment of the present invention.
FIG. 3b is a drawing of an intake port (300) and a finishing plate (310) that can be optionally installed in a housing (100) in a blower structure (1).
FIG. 4 is an enlarged drawing of a support fixing bolt (1000) of a blower structure (1) according to one embodiment of the present invention.
Figure 5 is a perspective projection of a support fixing bolt (1000).
Fig. 6 is a cross-sectional view of a support fixing bolt (1000).
FIG. 7 is a drawing showing an embodiment of the present invention in which a support fixing bolt (1000) actively alleviates vibration occurring in a blower structure (1).
Figure 8 is a drawing showing that a buffer part (2000) is additionally included in the support fixing bolt (1000).

In addition to the above-mentioned purpose, other purposes and features of the present invention will be clearly revealed through the description of the embodiments with reference to the attached drawings. Preferred embodiments of the present invention will be described in detail with reference to the attached drawings. In describing the present invention, if it is judged that a specific description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Hereinafter, a blower structure (1) according to one embodiment of the present invention will be described in detail with reference to the attached drawings.

FIG. 1 is a drawing showing a blower structure (1) according to one embodiment of the present invention. FIG. 2 is a drawing of a blower structure (1) according to one embodiment of the present invention. FIG. 3a is a drawing of a blower structure (1) according to another embodiment of the present invention. FIG. 3b is a drawing of a suction port (300) and a finishing plate (310) that can be optionally installed in a housing (100) in the blower structure (1).

Referring to FIGS. 1 to 3b, a blower structure (1) according to one embodiment of the present invention includes a housing (100), an outlet (200), an intake (300), an impeller (600), a square frame (700), a support (800), a support fixing bolt (1000), and a nut (1100).

The housing (100) can be made by cutting and welding a metal plate as the main body of the blower structure (1).

The outlet (200) is formed at a predetermined portion of the periphery of the housing (100) so that wind is discharged from inside the housing (100).

The suction port (300) is formed on the left or right wall of the housing (100) so that wind is introduced into the interior of the housing (100). A closing plate (310) is installed on the side wall opposite to the suction port (300) so that air is sucked only through the suction port (300). Optionally, the suction port (300) may be installed instead of the closing plate (310) so that air is sucked from the left and right walls of the housing (100). In this way, the suction port (300) may be optionally installed together with the closing plate (310) on the left or right wall of the housing (100).

The impeller (600) rotates around a shaft (400) located at the center axis of the suction port (300) inside the housing (100) and is supported by the shaft (400) and a bearing (500) to draw in wind from outside the housing (100) through the suction port (300).

A square frame (700) is attached to the left and right side walls of the housing (100), and the housing (100) can be connected by bolts or screws so that the discharge port (200) can face in the horizontal and vertical directions or in the inclined direction.

The support (800) supports the square frame (700) on the ground. Since the square frame (700) is fixedly connected to the housing (100), vibrations generated in the blower structure (1) are transmitted to the support (800) through the square frame (700).

The support fixing bolt (1000) and nut (1100) secure the square frame (700) and the support (800).

Referring to FIG. 2, a square frame (700) can be attached to the left and right side walls of the housing (100) and installed so that the discharge port (200) faces horizontally.

Also, referring to FIG. 3a, a square frame (700) can be attached to the left and right side walls of the housing (100) and installed so that the discharge port (200) faces vertically, i.e., upward.

In this way, since frame fastening holes are formed in the horizontal and vertical directions at positions that match the fastening holes formed in the square frame (700) so that the square frame (700) can be attached to the left and right side walls of the housing (100) and fastened with bolts and nuts, it is easy to choose whether to fix the discharge port (200) of the housing (100) in the horizontal or vertical direction, so that the production of a blower capable of various wind discharge directions is conveniently and efficiently achieved.

Fig. 4 is an enlarged view of a support fixing bolt (1000) of a blower structure (1) according to one embodiment of the present invention. Fig. 5 is a perspective projection of the support fixing bolt (1000). Fig. 6 is a cross-sectional view of the support fixing bolt (1000).

Referring to FIGS. 4 to 6, the support fixing bolt (1000) includes a bolt casing (1010), a first spring (1020), an inertia weight (1030), and a second spring (1040).

The bolt casing (1010) has one end perforated with a hole smaller than the diameter, is hollow inside, and has a cylindrical shape with a screw thread formed at the other end to penetrate the support (800) and be coupled with the nut (1100).

The first spring (1020) is provided inside the bolt casing (1010) and has an outer diameter equal to the inner diameter of the bolt casing (1010) so as to be provided to match the inner diameter of the bolt casing (1010). One end of the spring is caught on a hook (1011) that protrudes around a hole perforated at one end of the bolt casing (1010).

The inertia weight (1030) has a central axis penetrating the first spring (1020) inside the bolt casing (1010) and has a catch plate (1031) between the first spring (1020) and the second spring (1040).

In addition, the inertia weight (1030) protrudes outward from one end of the bolt casing (1010) and has a protrusion (1032) in the direction of the central axis of the second spring (1040) to fix the second spring (1040) to the engaging plate (1031).

The inertia weight (1030) has a central axis penetrating the first spring (1020) inside the bolt casing (1010) and has a catch plate (1031) between the first spring (1020) and the second spring (1040).

In addition, the inertia weight (1030) has a protrusion (1032) in the direction of the central axis of the second spring (1040) to fix the second spring (1040) to the engaging plate (1031), and has a engaging portion (1011) that engages the first spring (1020) on the engaging plate (1031) and the inside of the bolt casing (1010), and protrudes outward from one end of the bolt casing (1010).

The second spring (1040) is provided inside the bolt casing (1010), with one end supported by the catch plate (1031) and the protrusion (1032) and the other end between the inner wall of the bolt casing (1010) that is not perforated.

Here, when the vibration occurring in the blower structure (1) is transmitted to the square frame (700), the inertia weight (1030) of the support fixing bolt (1000) moves in the opposite direction of the vibration due to inertia, thereby alleviating the vibration occurring in the blower structure (1).

FIG. 7 is a drawing showing an embodiment of the present invention in which a support fixing bolt (1000) actively alleviates vibration occurring in a blower structure (1).

Referring to FIG. 7, the blower structure (1) may further include a vibration detection sensor (1300) that measures the vibration frequency generated in the blower structure (1) and a control unit (1200) that can adjust the intensity of vibration relief of the support fixing bolt (1000).

The vibration detection sensor (1300) is a conventionally known technology, and may be a method of detecting the vibration frequency whenever a magnetic weight attached to the end of a spring moves vertically and approaches a reed switch, or may be formed by a combination of a gravity sensor, an acceleration sensor, etc.

Here, the first spring (1020) and the second spring (1040) may be made of a shape memory alloy that remembers an expanded shape according to a temperature increase due to electrical resistance when receiving an electrical signal from the control unit (1200).

Shape memory alloys (SMA) exhibit shape memory effects and superelasticity behaviors that cannot be found in general metals or alloys. Since the shape memory effect was discovered in nickel-titanium (Ni-Ti) alloys, it has been widely commercialized. Nitinol, a nickel-titanium series shape memory alloy, can generate a lot of energy per unit volume and has excellent corrosion resistance and biocompatibility. It also has excellent characteristics as an actuator because it has a long service life of more than 100,000 cycles. The operating temperature and stiffness can be controlled by the ratio of nickel-titanium.

At this time, the control unit (1200) controls the stiffness of the first spring (1020) and the second spring (1040) by sending an electric signal to each of the first spring (1020) and the second spring (1040) based on the vibration frequency detected by the vibration detection sensor (1300), thereby actively alleviating the vibration occurring in the blower structure (1).

Figure 8 is a drawing showing that a buffer part (2000) is additionally included in the support fixing bolt (1000).

The buffer part (2000) has a ring shape, and the body (2010) is formed of a titanium metal, which is a highly elastic material, and the side wall of the body (2010) surrounds the circumference and is divided to protrude inwardly and penetrate the second spring (1040) through a hole of the central axis. Accordingly, the elasticity of the second spring (1040) is supplemented while the second spring (1040) is stretched.

Although the present invention has been described with specific details such as specific components and limited examples and drawings, these have been provided only to help a more general understanding of the present invention, and the present invention is not limited to the above examples, and those with common knowledge in the field to which the present invention pertains can make various modifications and variations from this description.

Therefore, the idea of the present invention should not be limited to the described embodiments, and all things that are equivalent or equivalent to the claims described below as well as the claims are included in the scope of the idea of the present invention.

1: Blower structure
100: Housing
200: outlet
300: Inlet
400: Shaft
500: bearing
600: Impella

Claims (3)

housing;
An exhaust port formed at a predetermined portion of the periphery of the housing through which wind is discharged from the inside of the housing;
An intake port formed on the left or right wall of the housing to allow wind to flow into the interior of the housing, a closing plate installed on the opposite side wall to allow air to be sucked in from one side, and selectively installed together with the closing plate on the left or right wall of the housing;
An impeller that rotates inside the housing while being supported by the shaft and bearings, with the shaft located at the center axis of the suction port as the rotation axis to draw in wind from outside the housing through the suction port;
A square frame attached to the left and right side walls of the housing and capable of being joined by bolts or screws so that the discharge port can be directed in a horizontal and vertical direction or an inclined direction;
A support capable of supporting the above square frame on the ground; and
A plurality of support fixing bolts and nuts for connecting the above square frame and the above support;
It is composed of,
The above support fixing bolts are,
A cylindrical bolt casing having one end perforated with a hole smaller than the diameter, the inside being hollow, and the other end having threads formed to penetrate the support and engage with the nut;
A first spring, which is provided inside the bolt casing and has an outer diameter equal to the inner diameter of the bolt casing so as to fit the inner diameter of the bolt casing, and has one end caught on a hook protruding around a hole perforated at one end of the bolt casing;
An inertia weight having a central axis penetrating the first spring inside the bolt casing, a catch plate between the first spring and the second spring, a protrusion in the direction of the central axis of the second spring to fix the second spring to the catch plate, a catch portion that catches the first spring on the catch plate and inside the bolt casing, and protruding outward from one end of the bolt casing; and
A second spring, one end of which is supported by the catch plate and the protrusion and the other end is provided between the inner wall of the bolt casing that is not perforated, inside the bolt casing;
Including, when the vibration occurring in the blower structure is transmitted to the square frame, the vibration occurring in the blower structure is alleviated by the inertia of the inertia of the support fixing bolt moving in the opposite direction of the vibration.
The above blower structure is,
A vibration detection sensor that measures the vibration frequency generated in the above blower structure; and
A control unit capable of adjusting the intensity of vibration relief of the above-mentioned support fixing bolt;
Including more,
The first spring and the second spring are made of a shape memory alloy that, when receiving an electrical signal from the control unit, remembers an expanded shape according to a temperature rise due to electrical resistance, and the control unit supplies an electric signal to each of the first spring and the second spring based on a vibration frequency detected by the vibration detection sensor to adjust the stiffness of the first spring and the second spring, thereby actively alleviating vibration occurring in the blower structure, characterized in that the blower structure; delete delete