KR101144147B1 - Electronic diffuser of automatic pressure response - Google Patents

Abstract

The present invention relates to an electronic pressure diffuser of the automatic pressure response method, more specifically, the diffuser is installed to control the indoor air of the building is formed so as to control the air discharge while corresponding to the temperature load of each compartment, the network It is possible to control the temperature in real time, and the venturi type pressure responding device is formed inside, so that it is possible to respond to sudden air flow change without a separate air flow control device (VAV). will be.
In the present invention, the temperature is immediately measured by the intake air temperature sensor and the air supply temperature sensor, and thus the flow rate is adjusted in the central system. There is no need to install, since each device for measuring the amount of carbon dioxide is formed, there is an effect that does not need to install a separate corresponding system.

Description

ELECTRONIC DIFFUSER OF AUTOMATIC PRESSURE RESPONSE

The present invention relates to an electronic pressure diffuser of the automatic pressure response method, more specifically, the diffuser is installed to control the indoor air of the building is formed so as to control the air discharge while corresponding to the temperature load of each compartment, the network It is possible to control the temperature in real time, and the venturi type pressure responding device is formed inside, so that it is possible to respond to sudden air flow change without a separate air flow control device (VAV). will be.

Recently built apartments, office buildings or residential complexes are designed to maintain very high airtightness to minimize the consumption of heating and cooling energy, and in particular, most centrally controlled air conditioners are used to create a pleasant indoor environment. Install.

The air conditioner mainly includes a main duct connected to an air handling unit (AHU) and subducts for supplying air to each floor or each compartment. Each subduct is equipped with a number of diffusers.

The conventional diffuser is connected to the end of the subduct connected to the main duct, is fixed to the ceiling finish is installed.

The diffuser includes a method of manually adjusting the size of the inlet through which air is discharged (manual type) and a method of automatically adjusting the size of the inlet according to the temperature load using a motor (wind flow amount method).

The airflow type diffuser has been disclosed in the Republic of Korea Patent Publication No. 2010-25301, 2011-0108937.

In recent years, an electronic and electronic diffuser that can be centrally controlled can be developed so that the diffuser is electronically connected and connected to a network, and each diffuser responds to a temperature load while controlling the air discharge amount, that is, adjusting the size of the inlet. .

As described above, when air is equally supplied to the main duct connected to the air conditioner (AHU), since the temperature loads of the subducts are different from each other, the temperature load is reduced or stretched in the subduct of a certain layer or section. If you suddenly reduce or increase the air volume, the diffusers formed in each subduct of different floors will be impacted and it will be difficult to control the air volume. Is formed.

However, conventional air conditioners and diffusers have the following problems.

(1) Conventional diffusers do not directly measure the ambient temperature, so it is difficult to respond immediately to the temperature load.

(2) The airflow regulator is to be provided separately at the entrance of each subduct.

(3) Since air emissions cannot be controlled according to air quality, ie, the amount of carbon dioxide, a response system for the amount of carbon dioxide is formed separately.

In order to solve the above problems, the present invention is a cylindrical inlet pipe is formed, the discharge wing is formed to be in communication with the inlet pipe to be inclined downward to the outer periphery, is fixed at the top of the inlet pipe In the general electrical and electronic diffuser is formed by the operating system is operated by the motor, the flow control plate is formed at the lower end of the operating system,

A damper is formed in the rear of the inlet pipe connected to the communication tube,

The damper is formed with a body having an orifice portion having a reduced inner diameter therein, two fixing stems are formed across the inside, and a support rod penetrating the center of each fixing stem is formed, and at the end of the support rod is provided with a spring. The damper head is formed so as to be movable back and forth around the support rod, and a connector is formed at the other end of the support rod so as to transport the support rod forward and backward, and a position adjustment tool is formed at the end of the connector.

According to the electronic pressure diffuser of the automatic pressure response method of the present invention the following effects occur.

(1) Since the temperature is immediately measured by the intake air temperature sensor and the air supply temperature sensor, and the flow rate is adjusted by the central system, tracking to the temperature appropriate to the set temperature is smooth.

(2) Since the damper is installed directly on the diffuser, there is no need to install a separate airflow regulator.

(3) Since the devices for measuring the amount of carbon dioxide are formed separately, it is not necessary to install a corresponding system for the measurement of the amount of carbon dioxide.

1 is a cross-sectional view of an electronic pressure diffuser of the automatic pressure response method formed in a preferred embodiment of the present invention.
Figure 2 is a conceptual view of the operation of the electronic pressure diffuser of the automatic pressure response method formed in a preferred embodiment of the present invention.
Figure 3 is a conceptual view of the operation of the temper of the electronic pressure diffuser of the automatic pressure response method formed in a preferred embodiment of the present invention.
Figure 4 is an installation conceptual diagram of an electric pressure diffuser of the automatic pressure response method formed in a preferred embodiment of the present invention.
5 is a conceptual diagram of an air conditioner installed with a conventional airflow regulator.
Figure 6 is an experimental diagram showing the temperature tracking degree of the cooling state of the electronic pressure diffuser of the automatic pressure response method formed in a preferred embodiment of the present invention.
Figure 7 is an experimental diagram showing the temperature tracking degree of the heating state of the electronic pressure diffuser of the automatic pressure response method formed in a preferred embodiment of the present invention.

In the present invention, a cylindrical inlet tube 10 is formed, the discharge wing 20 is formed in communication with the inlet tube 10 to be inclined downward to the outer periphery, the inlet tube 10 of the In the general electric and electronic diffuser having an operating system 12 is fixed at the upper end and is operated by a motor, the flow control plate 30 is formed at the lower end of the operating system 12,

A damper 100 is formed at the rear of the inflow pipe 10 and connected to the communication pipe 40.

The damper 100 has a body 110 having an orifice portion 112 having an inner diameter thereof reduced therein, and two fixing stems 120 are formed across the inside of each of the fixing stems 120. A support rod 130 penetrates through the center, and a damper head 150 is formed at the end of the support rod 130 so as to be able to flow back and forth around the support rod 130 by a spring 140. A connector 160 is formed at the other end of the support rod 130 so as to transfer the support rod 130 back and forth, and a position adjusting tool 165 is formed at the end of the connector 160.

The flow control plate 30 is fixed to the end of the operating system 12, it is formed by dividing the fixed plate 31 and the trim plate (32).

The fixed plate 31 is fixed to the operating system 12 through the upper end, the intake air temperature sensor 31a and the carbon dioxide sensor 31b is formed at the bottom.

The bottom of the fixing plate 31 is formed with a trim plate 32 is fixed spaced apart at a predetermined interval, the trim plate 32 is formed with a hole in the center, the periphery is formed with a step 32a at the top, It is formed to be spaced apart from the fixed plate (31).

The upper end of the fixing plate 31, the operating system 12 is formed to extend to the upper end of the inlet pipe 10, the air supply temperature sensor 12a is formed on the upper end of the operating system (12).

An inlet pipe 10 is formed at the outer circumference of the operating system 12, and a discharge wing unit 20 is formed to be inclined downward to the lower end of the inlet pipe 10.

The communication tube 40 is formed by extending to the rear of the inlet tube 10, and the temper 100 is formed by extending to one side of the communication tube 40.

The damper 100 has a body 110 having an orifice portion 112 having an inner diameter thereof reduced therein, and two fixing stems 120 are formed across one side of the inside of the damper 100.

A hole is formed in the center of each fixing stem 120, and the support rod 130 is inserted and fixed in the hole.

One side of the support rod 130 is a support rod fixture 132 is formed, the support rod fixture 132 inside the spring 140 is formed.

A connector 160 is formed at the other side of the support rod 130, and a position adjuster 165 is formed at an upper end of the connector 160.

The support rod 130 is adjusted by the position adjuster 165 at the time of initial installation, and is fixed by the support rod fixture 132.

A damper head 150 is formed at an outer circumference of the support rod fixing part 132, and a fixture fixed to the connector 160 is formed inside the damper head 150.

The support rod fixture 132 is fixed by a fixture formed inside the damper head 150, by which the damper head 150 and the support rod fixture 132 move together.

Hereinafter, the operation of the electronic pressure diffuser of the automatic pressure response method formed by the preferred embodiment of the present invention will be described.

As shown in FIG. 4, a main duct 1 connected to an air conditioner AHU is installed, and a plurality of sub ducts 2 connected to the main duct 1 are installed, and a plurality of diffusers are provided in the sub duct 2. 200 is formed.

The diffuser 200 is all connected to the network, which is connected to the central system to control each.

When the air conditioner (AHU) is operated in the installed air conditioner formed as described above, the controlled inflow air is introduced into the subduct (2) from the main duct (1).

The inflow air introduced into the sub duct 2 passes through the damper 100 and flows out between the flow control plate 30 and the discharge wing 20 to be introduced into the room.

When the inlet air is introduced, the temperature is measured by the air supply temperature sensor 12a.

At this time, the indoor air flows into the groove of the center of the trim plate 32 installed at the bottom spaced apart from the fixed plate 31 of the flow control plate 30, which is fixed to the fixed plate 31 by the inflow of air. It flows in by sucking in air which was between the trim plates 32.

When the indoor air is introduced as described above, the temperature of the indoor air is checked by the intake air temperature sensor 31a, and the control room monitors the temperature to determine the temperature difference between the indoor air and the inlet air, thereby determining the position of the flow regulating plate 30. Adjust the flow rate of inlet air discharged by moving up and down.

As shown in FIG. 6 and FIG. 7, the operation as described above can be confirmed that the room temperature is maintained close to the set temperature during heating and cooling.

In addition, the quality of the indoor air introduced by the carbon dioxide sensor 31b can be confirmed, and the outside air is introduced in the control room.

If installed in another layer or when the flow rate of the inlet air suddenly changes due to a change in the temperature load of the adjacent diffuser 200, the damper 100 operates.

When the pressure of the inlet air is increased, the damper head 150 is pushed backward, and the side of the damper head 150 is close to the inner wall of the orifice portion 112 to change the flow rate, thereby alleviating the impact.

When installing the damper 100 for shock mitigation as described above by changing the position of the adjusting device 160 in the position adjusting device 165 to set the position of the first support rod 130.

According to the present invention, since the temperature is immediately measured by the intake air temperature sensor and the air supply temperature sensor, and the flow rate is adjusted in the central system, the tracking is smoothly performed according to the set temperature, and the damper is directly installed in the diffuser, so that the separate air flow rate Since there is no need to install a regulator, and each device for measuring the amount of carbon dioxide is formed, there is an effect such as not having to install a corresponding system for measuring the amount of carbon dioxide separately.

Although the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that various modifications may be made therein without departing from the scope of the invention, which is covered by the following claims.

1: Main duct 2: Sub duct
10: inlet tube 12: operating system
20: discharge wing portion 30: flow control plate
31: fixed plate 31a: intake air temperature sense
31b: CO2 sensor 32: Trim plate
32a: step 40: communication tube
100: damper 110: body
112: orifice portion 120: fixed stem
130: support rod 132: support rod fixture
140: spring 150: damper head
160: connector 165: position adjustment
200: diffuser

Claims (4)

delete A cylindrical inlet tube 10 is formed, the discharge wing 20 is formed in communication with the inlet tube 10 to be inclined downward to the outer periphery is formed, in the upper middle of the inlet tube 10 In the general electric and electronic diffuser is fixed and the operating system 12 is formed by the motor, the flow control plate 30 is formed at the lower end of the operating system 12,
A damper 100 is formed at the rear of the inflow pipe 10 and connected to the communication pipe 40.
The damper 100 has a body 110 having an orifice portion 112 having an inner diameter thereof reduced therein, and two fixing stems 120 are formed across the inside of each of the fixing stems 120. A support rod 130 penetrates through the center, and a damper head 150 is formed at the end of the support rod 130 so as to be able to flow back and forth around the support rod 130 by a spring 140. A connector 160 is formed at the other end of the support rod 130 so as to transfer the support rod 130 back and forth, and a position adjusting tool 165 is formed at the end of the connector 160.
The flow rate control plate 30 is fixed to the end of the operating system 12, the electric pressure electronic diffuser of the automatic pressure response method, characterized in that formed by divided into a fixed plate 31 and a trim plate (32). The method of claim 2,
The fixed plate (31) is an electromechanical diffuser of the automatic pressure response type, characterized in that the operating system 12 is fixed through the upper end, the intake air temperature sensor (31a) and carbon dioxide sensor (31b) is formed at the bottom. delete

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