KR101822396B1 - System for room pressure maintenance using a pressure sensor and inverter fan - Google Patents

Abstract

The present invention relates to a system for maintaining an indoor pressure by using a pressure sensor and an inverter fan, and more specifically, to a system for maintaining indoor pressure by using a pressure sensor and an inverter fan, which prevents an over-pressure and automatically maintains the indoor pressure at a predetermined pressure. To this end, according to the present invention, the system for maintaining the indoor pressure by using a pressure sensor and an inverter fan comprises: a first pressure sensor installed in an indoor place; a second pressure sensor installed in an outdoor place; an exhaust fan exhausting indoor air to the outside; a pressure maintaining unit including an inverter fan supplying air to the inside; and an automatic pressure maintaining device controlling the rotational speed of the inverter fan in accordance with the difference between the indoor pressure provided by the first pressure sensor and the indoor pressure provided by the second pressure sensor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pressure sensor and an inverter fan,

The present invention relates to an indoor pressure maintenance system using a pressure sensor and an inverter fan, and more particularly, to an indoor pressure maintenance system using an inverter fan and a pressure sensor that automatically maintains indoor pressure at a predetermined pressure, .

Generally, in order to exert the function of the ventilation or ventilation of the interior of the building, the air to be supplied and the air to be exhausted should flow smoothly.

In recent years, as the buildings have become higher and larger, and the appearance has been emphasized, the window structure has been changed to a closed type due to environmental pollution or stability. As a result, the ventilation of the building exterior wall is difficult, And the air inside the building is exhausted to the outside through the ventilation device or fresh outside air is supplied to the inside of the building.

Such a ventilating apparatus is constituted such that an inverter fan is installed on a ventilation duct disposed on a ceiling of a building, and the air is supplied or exhausted according to the operation of the inverter fan, and an air purifying filter or the like is provided in the duct, Or may be configured to control the room temperature by being equipped with a hot air fan or a cooler.

However, in the conventional ventilating apparatus, the amount of air to be supplied or the amount of air to be exhausted should be inflow or outflowed into the room. However, since the room is a closed space, the flow of air is not natural, Is not smoothly performed.

Further, in the conventional ventilator, when the capacity expansion is required, most of the existing ventilators must be replaced, which increases the replacement cost. In addition, the conventional ventilator has a large initial investment cost, and it is difficult to quickly respond to rapid pressure change due to the characteristics of the ventilator.

Korean Patent Publication No. 2009-0050504 (entitled " Intelligent Ventilation Control System Having Energy Saving Function " Korean Patent Laid-Open Publication No. 2014-0105143 (entitled: Cargo Window Air Conditioning System)

A problem to be solved by the present invention is to provide an indoor pressure maintaining system which is low in initial investment and maintenance cost.

Another problem to be solved by the present invention is to provide an indoor pressure maintaining system capable of quickly responding to rapid pressure changes.

Another problem to be solved by the present invention is to provide an indoor pressure maintaining system capable of rapidly expanding the pressure maintaining device at a low cost when the expansion of the pressure maintaining device is required.

Another problem to be solved by the present invention is to propose a method for supplying air to a long distance.

Another object of the present invention is to provide an indoor pressure maintaining system capable of preventing condensation.

To this end, the indoor pressure maintenance system using the pressure sensor and the inverter fan of the present invention includes a first pressure sensor installed in the room, a second pressure sensor installed in the outdoors, an exhaust fan for exhausting air in the room to the outside, And a controller for controlling the rotational speed of the inverter fan according to the difference between the pressure of the room provided from the first pressure sensor and the pressure of the room provided from the second pressure sensor, Device.

The indoor pressure maintaining system using the pressure sensor and the inverter fan according to the present invention measures the indoor and outdoor pressures and automatically controls the air flow rate to the room by controlling the rotation speed of the inverter fan according to the measured pressure difference There are advantages.

In addition, since the present invention does not require a duct, the installation cost is reduced and the construction period is shortened as compared with a structure in which an existing duct is required.

In addition, the present invention can prevent the cold air from being supplied to the room by heating the air supplied to the room by installing an electric coil therein.

In addition, the present invention adjusts the angle of the diffuser according to the temperature of the air supplied to the room, so that air supplied to the room can be moved to a long distance.

FIG. 1 illustrates an indoor pressure maintaining system using a pressure sensor and an inverter fan according to an embodiment of the present invention.
2 shows a pressure holding unit according to an embodiment of the present invention.
3 is a view illustrating a structure of an inverter fan according to an embodiment of the present invention.
4 shows a diffuser according to an embodiment of the present invention.
5 shows a diffuser according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The foregoing and further aspects of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

FIG. 1 illustrates an indoor pressure maintaining system using a pressure sensor and an inverter fan according to an embodiment of the present invention. Hereinafter, an indoor pressure maintaining system using a pressure sensor and an inverter fan according to an embodiment of the present invention will be described in detail with reference to FIG.

Referring to FIG. 1, an indoor pressure maintaining system using a pressure sensor and an inverter fan includes an automatic pressure holding device, a first pressure sensor, a second pressure sensor, an exhaust fan, and a pressure holding unit. Of course, other configurations than the above-described configuration may be included in the indoor pressure maintenance system using the pressure sensor and the inverter fan proposed in the present invention.

The automatic pressure holding device 110 is connected to the first pressure sensor 120, the second pressure sensor 130 and the pressure holding unit 140. The automatic pressure holding device 110 receives pressure information from the first pressure sensor 120 and pressure information from the second pressure sensor 130. The automatic pressure holding device 110 controls the rotational speed of the inverter fan constituting the pressure holding unit 140 based on pressure information provided from the first pressure sensor 120 and the second pressure sensor 130.

The first pressure sensor 120 is installed at the first point, and measures the pressure at the first point. The first pressure sensor 120 provides the measured pressure (or pressure information) to the automatic pressure holding device 110. The first pressure sensor 120 is installed in the first indoor space, which is the first point of the room.

The second pressure sensor 130 is installed at the second point, and measures the pressure at the second point. The second pressure sensor 130 provides the measured pressure (or pressure information) to the automatic pressure holding device 110. The second pressure sensor 130 is installed outdoors. In connection with the present invention, the outdoor is not the exterior of the building but another space in the building where the first pressure sensor is not installed. That is, the second pressure sensor 130 is installed in the second space in the building, which is outside the first interior space.

The exhaust fan 150 exhausts the air in the room, and the pressure in the room is lowered by driving the exhaust fan 150. Generally, when the indoor pressure is lowered by driving the exhaust fan 150, the outdoor air flows into the room due to the pressure difference between the indoor and the outdoor. When the outdoor air flows into the room, noise is generated due to the movement of the air. In severe cases, the door or window shakes.

Therefore, the present invention proposes a pressure holding unit for supplying air into the room. The pressure holding unit 140 supplies air to the room in accordance with the control command of the automatic pressure holding device. Hereinafter, the pressure holding unit will be described in detail.

2 shows a pressure holding unit according to an embodiment of the present invention. Hereinafter, a pressure holding unit according to an embodiment of the present invention will be described in detail with reference to FIG.

According to Fig. 2, the pressure holding unit includes a frame, an inlet cover, an electrostatic filter, an inverter fan, a damper, a prefilter, a fluid guide, an outlet cover and a diffuser. Of course, other configurations than the above-described configuration can be included in the pressure maintaining unit proposed in the present invention.

The frame 141 forms the basic frame of the pressure holding unit.

The inlet cover 142 is formed at one end of the frame, and is formed at a portion where air flows in from the outside. The inlet cover 142 is located outdoors so that outside air can be introduced through the inlet cover 142.

The electrostatic filter 143 is formed inside the frame 141, and filters foreign substances contained in the air introduced from the outside.

The inverter fan 144 flows air from the outside and rotates to supply the introduced air to the room. The inverter fan 144 changes the rotational speed in accordance with the control command of the automatic pressure holding device. In other words, when the amount of air to be supplied is increased, the rotational speed of the inverter fan 144 increases, and when the amount of air required to supply air decreases, the rotational speed of the inverter fan 144 increases .

The inverter fan 144 is installed inside the frame 141, and the detailed structure of the inverter fan 144 will be described later.

The damper 145 controls the amount of air blown through the inverter fan 144 and the flow of air. The air blown from the inverter fan 144 is blown through the entire area of the fluid guide 146 or is blown through a part of the area of the fluid guide 146 as the damper 145 rotates. The air blown by the inverter fan 144 is blown to the entire area of the fluid guide 146 without the resistance of the damper 145. In this case, In contrast, when the damper 145 is not the same as the blowing direction, the air blown by the inverter fan 144 strikes the damper 145, so that the air blown from the inverter fan 144 flows through the fluid guide 146 ).

The pre-filter 147 filters the foreign matter contained in the air once again by the inverter fan 144.

The fluid guide 146 functions to guide the filtered air to the pre-filter 147 in the direction of the outlet cover 148. The fluid guide 146 is also formed inside the frame.

The outlet cover 148 is provided at the other end of the frame 141, and is formed especially inside the room. A diffuser (see FIG. 4) is formed on the outlet cover 148, so that the outlet cover 148 forms a cavity in the center so that a diffuser can be formed. The diffuser is mounted on the cavity of the outlet cover 148.

The diffuser guides the air delivered through the fluid guide 146 to a remote location in the room. Generally, when there is no diffuser, the air supplied through the outlet cover 146 drops to the lower end of the outlet cover 148. [ In order to solve this problem, the present invention proposes a diffuser through the outlet cover 148 so that the air supply can move the air to a far point in the room. The detailed structure of the diffuser will be described later.

According to the present invention, the outside air is supplied to the room via a diffuser formed in an inlet cover, an electrostatic filter, an inverter fan, a prefilter, a fluid guide, and an outlet cover.

In addition, the present invention proposes a method of heating air flowing into a room by installing an electric coil inside a pressure holding unit. That is, when cold air enters the room in the winter, it heats the cold air using an electric coil, and the heated air flows into the room.

3 is a view illustrating a structure of an inverter fan according to an embodiment of the present invention. Hereinafter, the structure of the inverter fan according to one embodiment of the present invention will be described in detail with reference to FIG.

According to Fig. 3, the inverter fan includes a motor, an impeller, a support frame, and a support plate. Of course, other configurations than the above-described configuration may be included in the inverter fan proposed in the present invention.

The motor 144a rotates the impeller 144b using the electric power transmitted from the outside. The motor 144a adjusts the rotational speed of the impeller 144b according to the magnitude of the supplied power according to the control command provided from the automatic pressure holding device.

The impeller 144b is connected to the motor 144a and rotated by the motor 144a. In connection with the present invention, the motor 144a is arranged so as to be positioned on the indoor side relative to the impeller 144b.

The support plate 144c is formed in a flat plate shape, and an empty hole is formed at the center. Air is introduced from the outside via the empty hole formed in the support plate 144c.

And the support frame 144d performs the function of supporting the inverter fan. The support frame 144d functions to stably fix the impeller 144b to the motor. One side of the support frame 144d is fixed to the base plate, and the other side of the support frame 144d is fixed to the motor case for housing the motor. The impeller 144b is positioned between the support plate and the motor.

4 shows a diffuser according to an embodiment of the present invention. Hereinafter, a diffuser according to an embodiment of the present invention will be described in detail with reference to FIG.

Referring to FIG. 4, the diffuser has a first circular frame of a circular shape with an empty cavity in a circular shape, a plurality of blades formed inside the first circular frame, a second circular frame formed inside the blade, And a lattice frame having a lattice shape formed inside the frame is located.

The grating frame 149a is located in the center of the diffuser as shown in Fig. The grid frame 149a functions to finely grind the supplied air.

The second circular frame 149b is located outside the grating frame 149a and serves to support the grating frame 149a. In addition, the second circular frame 149b fixes one side of the blade 149c and performs the function of supporting the blade 149c.

The blade 149c is positioned between the first circular frame 149d and the second circular frame 149b and is formed at an angle slant. As shown in FIG. 4, a plurality of blades 149c are formed at regular intervals with reference to the second circular frame 149d. The blade 149c functions to supply the supplied air to a long distance.

As shown in Fig. 4, the diffuser of the present invention forms a plurality of blades 149c on the outside of the lattice frame and the lattice frame. Air is supplied to the room through the grid frame and the blade 149c constituting the diffuser. Also, as described above, air is finely crushed using the grid frame 149a located relatively inward, and the air is supplied to a far distance in the room by using the blade 149c located on the relatively outside. To be more specific, the diffuser of the present invention forms a blade 149c on the outer side and a grid frame 149a on the inner side to supply the finely pulverized air to a long distance of the room.

The first circular frame 149d is located outside the blade and serves to support the other side of the blade 149c. The air supply distance of the air supplied to the room is changed according to the inclined angle of the blade 149c.

As described above, when the damper coincides with the air blowing direction, the air blown from the inverter fan is blown into the entire area of the fluid guide, so that the blown air is supplied to the room through the grid frame and the blades. On the other hand, when the damper does not coincide with the blowing direction, the air blown from the inverter fan is blown to the edge of the fluid guide, so that the blown air is supplied to the room through the blades rather than the center grid frame. As described above, according to the present invention, air is supplied to the room through a specific structure among the structures constituting the diffuser by using the damper.

In addition, the blades perform the function of supplying air to a long distance in the room, and use this to control the operation of the damper according to the temperature of the incoming air. Relatively hot air, like in summer, is light in weight and travels a long distance even when air is fed into the room using grid frames and blades. Compared to winter, relatively cold air is heavy, and when air is supplied to the room using grid frames and blades, it can not be moved to a long distance. Accordingly, the present invention operates the damper so that the direction of the damper does not coincide with the direction of the air blown from the inverter fan, so that air is supplied to the room through the blades of the diffuser. When air is supplied to the room through the blades, the air is supplied to a relatively long distance as described above.

To summarize, in the summer, the direction of the damper matches the direction of the air blown from the inverter fan. In winter, the direction of the damper does not match the direction of the air blown from the inverter fan.

In addition, the present invention uses the electric coil to heat the air supplied to the room, as described above, when the air entering the room is below the set temperature. When the air supplied to the room is heated, it is not necessary to adjust the angle of the damper. That is, according to the present invention, the angle of the damper is adjusted so that the air supplied to the room moves to a long distance, or the air supplied to the room is heated to move the air to a long distance in the room.

In addition, the present invention mounts a temperature sensor between the inverter fan and the damper, and adjusts the rotation angle of the damper by using the temperature of air blown by the temperature sensor installed. When the measured temperature of the air is relatively high as described above, the rotation angle of the damper is adjusted so that the air blown from the inverter fan can pass through the diffuser without resistance. Also. When the temperature of the measured air is relatively low, the rotation angle of the damper is adjusted so that the air blown from the inverter fan can move along the inner surface of the fluid guide by the damper.

In addition, the present invention is designed so that the inclination angles of the blades constituting the diffuser are different. As described above, the air passing through the diffuser by the angle of the blades is supplied to a long distance in the room. The present invention increases the inclination angle of the blade located at the lower end relatively, and reduces the inclination angle of the blade located at the upper end relatively. By increasing the inclination angle of the blade located at the lower end, the distance of the air passing through the blade located at the lower end is increased, so that the air passing through the blade located at the upper end is also supplied to the distance of the room by the air located at the lower end.

As described above, the present invention determines whether the damper is rotated or rotated according to the temperature of the air introduced from the outside.

Figure 5 shows the shape of a diffuser according to another embodiment of the present invention. Hereinafter, the shape of the diffuser according to another embodiment of the present invention will be described in detail with reference to FIG.

According to Fig. 5, the diffuser is formed only of the lattice frame without the configuration of the blade, unlike Fig. As described above, the present invention can be applied to a case in which the diffuser is formed only by a grating frame, in which case it is not necessary to supply air to a long distance of the room.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the scope of the present invention .

110: Automatic pressure holding device 120: First pressure sensor
130: second pressure sensor 140: pressure holding unit
150: exhaust fan 141: frame
142: inlet cover 143: electrostatic filter
144: inverter fan 145: damper
146: fluid guide 147: prefilter
148: Outlet cover 149: Diffuser
144a: motor 144b: impeller
144c: Support plate 144d: Support frame
149a: grid frame 149b: second circular frame
149c: blade 149d: first circular frame

Claims (4)

A first pressure sensor installed in the first indoor space in the building;
A second pressure sensor installed in a second space in a building outside the first space;
An exhaust fan for exhausting air in the first indoor space to the outside;
A pressure holding unit including an inverter fan for supplying air to the first indoor space; And
And an automatic pressure holding device for controlling the rotational speed of the inverter fan according to the difference between the pressure of the first indoor space provided from the first pressure sensor and the pressure of the second space provided from the second pressure sensor,
The pressure holding unit may include:
An inverter fan that rotates under the control of the automatic pressure holding device;
A damper for adjusting the flow of the air blown through the inverter fan;
A fluid guide through which the air blown through the damper moves;
And a diffuser positioned at a rear end of the fluid guide and supplying the blown air into the room,
The diffuser,
A first circular frame;
At least two blades formed inside the first circular frame;
And a grid frame having a lattice shape formed inside the blade,
The inclination angle of the blade formed at the lower end is relatively larger than the inclination angle of the blade formed at the upper end,
The damper includes:
Wherein when the temperature of the air to be blown is not more than a predetermined temperature, the blowing air is rotated so as to move to the wall surface of the fluid guide,
Wherein when the temperature of the air to be blown is equal to or higher than the set temperature, the damper rotates so as to be in parallel with the fluid guide so that the blown air can move through all the end faces of the fluid guide. Maintenance system.
The pressure control apparatus according to claim 1,
A frame having a box shape;
An inlet cover which is located at one end of the frame and into which air flows from the outside;
And an electrostatic filter for filtering the air introduced through the inlet cover,
Wherein the diffuser is located on a through hole formed in the outlet cover.
3. The apparatus of claim 2,
And a second circular frame formed inside the blade,
Wherein the grid frame is formed inside the second circular frame. ≪ RTI ID = 0.0 > 11. < / RTI >
The method according to claim 1,
And a temperature sensor mounted between the inverter fan and the damper,
And the rotation angle of the damper is adjusted by using the temperature of the blown air measured by the installed temperature sensor.

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