KR101599461B1 - Air conditioner for preventing condensation of duct - Google Patents

Abstract

An air conditioning apparatus for preventing condensation of a duct is disclosed.
According to an embodiment of the present invention, there is provided an air conditioner comprising: an air conditioning unit for supplying cool air to an indoor space; a discharge duct for discharging a part of air in the indoor space to the outside; and a recirculation duct for recirculating part of the indoor space to the air conditioning unit A piezoelectric device installed in the recirculation duct and producing predetermined power by a pressure of air introduced into the recirculation duct; And a heating unit which is installed on an air movement path of the recirculating duct and generates heat using electric power generated by the piezoelectric unit and heats the air moving in the recirculating duct to prevent condensation on the surface of the recirculating duct An air conditioning apparatus for preventing condensation of a duct including means can be provided.

Description

TECHNICAL FIELD [0001] The present invention relates to an air conditioner for preventing duct condensation,

The present invention relates to an air conditioner for preventing condensation of a duct.

In an interior space such as a cabin, an air conditioner for adjusting the temperature and humidity may be installed for the health of the user or the operation of the device. Such an air conditioner can perform a cooling function so as to lower the temperature of the indoor space.

2. Description of the Related Art Generally, an air conditioning apparatus includes an air conditioning unit for supplying cold air to an indoor space to lower the temperature of the indoor space, a discharge duct for discharging some air in the indoor space to the outside for ventilation of the indoor space, And a recirculating duct for recirculating part of the air in the indoor space to the air conditioning unit for efficiency and then re-supplying the air to the indoor space.

The air conditioning unit mixes the air supplied from the recirculation duct and the outside air at an appropriate ratio to supply the air to the indoor space. The air in the indoor space is discharged to the outside through the discharge duct, And can be ventilated.

In order to increase the cooling efficiency of the indoor space and to reduce the load of the air conditioning unit to save energy, some air in the indoor space is recirculated to the air conditioning unit through the recirculation duct, Since the temperature of the air to be sent is lower than the outside air, the outer surface of the recirculating duct can also be cooled.

Since the recirculating duct extends to the air conditioning unit through the outside of the indoor space, the outer surface of the recirculating duct can be exposed to the outside air. Therefore, when the cooled recirculating duct comes into contact with the outside air at a relatively high temperature, condensation of water vapor may occur on the outer surface of the recirculating duct.

Condensation on the outer surface of the recirculation duct can flow down the recirculation duct in the form of moisture and fall to the floor, which can corrode other structures in the environment or corrode the recirculation duct itself.

Therefore, in order to prevent condensation from occurring on the outer surface of the recirculating duct, the outer surface of the recirculating duct is conventionally wrapped with a heat insulating material so that the recirculating duct is not directly exposed to the outside.

However, since the conventional method for preventing condensation of the recirculating duct as described above requires the entire recirculating duct to be enclosed by the heat insulating material, it is very troublesome to construct the heat insulating material, and a separate space for the heat insulating material section outside the recirculating duct in a limited space such as a ship So that the arrangement of other structures around the recirculation duct may be changed accordingly.

Also, in the conventional method for preventing condensation of the recirculating duct, even if the recirculating duct is tightly enclosed by the heat insulating material, a discontinuity or a gap of the heat insulating material is inevitably generated, and external air is brought into contact with the recirculating duct through the discontinuity surface or the gap, have. In this case, the condensation proceeds due to a gap between the heat insulating material and the recirculating duct, resulting in poor ventilation, resulting in mold and odor.

Korean Patent Publication No. 10-2013-0094946 (Mar.

Embodiments of the present invention provide an air conditioning apparatus for preventing condensation of a duct in which condensation does not occur on an outer surface of a recirculation duct by raising an air temperature of a recirculation duct for recycling a part of air in an indoor space.

According to an aspect of the present invention, there is provided an air conditioner comprising: an air conditioning unit for supplying cool air to an indoor space; a discharge duct for discharging part of the indoor space to the outside; and a recirculation duct for recirculating part of the indoor space to the air conditioning unit A piezoelectric device installed in the recirculation duct and generating predetermined power by a pressure of air introduced into the recirculation duct; And a heating unit which is installed on an air movement path of the recirculating duct and generates heat using electric power generated by the piezoelectric unit and heats the air moving in the recirculating duct to prevent condensation on the surface of the recirculating duct An air conditioning apparatus for preventing condensation of a duct including means can be provided.

The piezoelectric means may be a piezo element installed in at least one of the grill portion and the bending portion having a relatively high air pressure in the recirculating duct.

A cooling unit for cooling the air heated by the heating unit may be installed at the rear end of the recirculation duct.

Wherein the cooling unit includes: an inflow passage branched from the rear end of the recirculation duct to introduce a part of the air of the recirculation duct; Compressed air supply means installed in at least one of the recirculation duct and the inflow passage and supplying compressed air to the inflow passage; A vortex cooler for separating the air introduced through the inflow passage into a cool air and a warm air by a vortex flow; A cool air supply pipe for sending the cool air separated from the vortex cooler to the recirculation duct or the air conditioning unit; And a warmth supply pipe for sending the warmth classified in the vortex cooler to the exhaust duct.

A guide vane for guiding air to the inflow passage may be provided at a point corresponding to the inlet of the inflow passage among the rear ends of the recirculation duct.

A damper for adjusting the amount of air supplied to the vortex cooler may be installed in the inflow passage.

An air temperature and humidity sensor installed in at least one of the inside and the outside of the indoor space for measuring temperature and humidity of air; And a control unit for selectively providing the electric power generated by the piezoelectric unit to the heating unit and controlling the heating unit based on a signal of the air temperature and humidity sensor.

The heating means may include at least two heating coils controlled by the control unit so that a heating amount of air moving in the recirculating duct is variable.

The heating coil may be arranged in series along the path of air in the recirculation duct.

According to the embodiment of the present invention, it is possible to increase the air temperature of the recirculating duct for recirculating part of the air in the indoor space, thereby preventing condensation from occurring on the outer surface of the recirculating duct.

In addition, according to the embodiment of the present invention, since the air inside the recirculation duct is heated by using the piezoelectric means capable of generating electric power by itself, the external power is not consumed and energy can be saved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram of an air conditioner for preventing condensation of a duct according to an embodiment of the present invention;
FIG. 2 is an enlarged view of the rear end of the recirculation duct and the structure of the cooling unit in FIG. 1,
3 is a block diagram illustrating a control relationship of an air conditioner for preventing condensation of a duct according to an embodiment of the present invention.
FIG. 4 is a schematic view showing a heating means of an air conditioning apparatus for preventing condensation of a duct according to an embodiment of the present invention; FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, configurations and operations according to embodiments of the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE INVENTION The following description is one of many aspects of the claimed invention and the following description may form part of the detailed description of the invention.

However, the detailed description of known configurations or functions in describing the present invention may be omitted for clarity.

While the invention is susceptible to various modifications and its various embodiments, it is intended to illustrate the specific embodiments and the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Terms including ordinals such as first, second, etc. may be used to describe various elements, but the elements are not limited by such terms. These terms are used only to distinguish one component from another.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, .

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise.

Hereinafter, an air conditioning apparatus for preventing condensation of a duct according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a block diagram of an air conditioner for preventing condensation of a duct according to an embodiment of the present invention. Referring to FIG. 1, an embodiment of the present invention includes an air conditioner unit A discharge duct 20 for discharging part of the air in the indoor space 1 to the outside and a recirculation duct 30 for recirculating part of the air in the indoor space 1 to the air conditioning unit 10, And further includes the piezoelectric means 100 and the heating means 200. The piezoelectric means 100 and the heating means 200 may be the same or different.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. However, the known technology may not be described in detail because the gist of the present invention may be overlooked.

At least one piezoelectric unit 100 can be installed in the recirculation duct 30 and the piezoelectric unit 100 can generate a predetermined electric power by the pressure of the air flowing into the recirculation duct 30. [ have.

The piezoelectric means 100 may be of various types that output a predetermined electric power when pressure is applied from the outside. For example, a piezo element may be used.

It is advantageous that the piezoelectric means 100 is installed at a position where the pressure of the air introduced into the recirculation duct 30 can be increased when the piezoelectric means 100 is installed in the recirculation duct 30. Therefore, Can be installed in at least one of the grill portion (2) and the bending portion (3) at a relatively higher air pressure than the other portions of the bending portion (30).

The grill part 2 may be installed on the ceiling of the indoor space 1 and the grill part 2 may be installed on the ceiling of the indoor space 1 so that some air of the indoor space 1 can be easily introduced into the recirculation duct 30. [ And the inner diameter gradually decreases from the lower part to the upper part.

Since the pressure of the air may locally increase in the grill part 2 according to the structure of the grill part 2, if the piezoelectric device 100 is installed in the grill part 2, the piezoelectric efficiency can be increased .

Since the bending portion 3 of the recirculating duct 30 is a bent portion of the path of the recirculation duct 30 and the bending portion 3 can also increase the pressure of the air locally, The piezoelectric efficiency can be increased.

The piezoelectric means 100 may be installed in any one of the grill portion 2 and the bending portion 3, but it may be installed appropriately in two or more places as required.

The heating means 200 is installed on an air movement path of the recirculation duct 30 so that the heating means 200 can generate heat using the electric power generated by the piezoelectric means 100 .

The heating means 200 heats the moving air in the recirculation duct 30 to generate a difference between the temperature inside the recirculation duct 30 and the temperature outside the recirculation duct 30, Condensation on the surface can be prevented.

Here, a cooling unit 300 for cooling the air heated by the heating unit 200 may be additionally provided at the rear end of the recirculation duct 30. [

When the air whose temperature has risen relatively through the heating means 200 is supplied directly to the air conditioning unit 10, not only the load of the air conditioning unit 10 increases, but also the overall cooling efficiency may be lowered. The air heated by the heating means 200 can be cooled by the cooling unit 300 before being supplied to the air conditioning unit 10. [

The cooling unit 300 may be a conventional cooler, such as the air conditioning unit 10, which requires separate power and refrigerant, but may include the following configuration using a vortex cooling principle for energy saving have.

2, the cooling unit 300 includes an inflow passage 310, a compressed air supply unit 320, a vortex cooler 330, a cold air supply pipe 340, and a warm air supply pipe 350 can do.

2 is an enlarged view showing in detail the structure of the rear end of the recirculation duct 30 and the structure of the cooling unit 300 in FIG. 1. Referring to FIG. 2, the inlet passage 310 is connected to the rear end of the recirculation duct 30, So that some air of the recirculation duct 30 can be introduced. At this time, a part of the air heated by the heating means 200 may be introduced into the inflow passage 310.

A portion of the rear end of the recirculation duct 30 corresponding to the inlet of the recirculation duct 310 may be provided at a position corresponding to the inlet of the recirculation duct 310 so that some air of the rear end of the recirculation duct 30 can be smoothly introduced into the recirculation duct 310. [ A guide vane 400 for guiding the air of the recirculation duct 30 to the exhaust duct 310 may be installed.

The guide vane 400 is installed at the rear end of the recirculation duct 30 so that its end is directed toward the inlet side of the inlet passage 310 so that part of the air flowing along the recirculation duct 30 is naturally And may enter the inflow passage 310 side.

The compressed air supply means 320 is for supplying compressed air to the inflow passage 310. The compressed air supply means 320 is connected to at least one of the recirculation duct 30 and the inflow passage 310 Can be installed.

The compressed air supply means 320 may be any means capable of compressing the air so that the compressed air can be introduced into the inflow passage 310. For example, This possible compression fan can be used.

2, the compressed air supply means 320 is installed at the rear end of the recirculation duct 30 before the inflow passage 310 to compress the air of the recirculation duct 30 to the inflow passage 310 But it is possible to compress only the air that is directly installed in the inflow path 310 and flows into the inflow path 310, as needed.

In addition, the vortex cooler 330 can separate the compressed air introduced through the inflow passage 310 into cold air and warm air by the vortical flow therein. The vortex cooler 330 separates the supplied compressed air into a cool air and a warm air by means of a vortex flow without using electricity and a refrigerant at all. In this embodiment, only the separated cool air is used and the warm air is sent to the exhaust duct 20 It can be discharged to the outside.

The cool air supply pipe 340 sends the cool air separated from the vortex cooler 330 to the recirculation duct 30 or the air conditioning unit 10 and the warm air supply pipe 350 is separated from the vortex cooler 330 To the outside through the exhaust duct (20). 2, the cool air supply pipe 340 is connected to the rear end of the recirculation duct 30. However, the cool air supply pipe 340 may be connected to the air conditioning unit 10 And may be mixed with the air of the recirculation duct in the air conditioning unit 10 and then supplied to the indoor space 1.

Here, the cooling principle of the vortex cooler 330 will be briefly described. When the compressed air is supplied through the inflow passage 310, the compressed air is introduced into the vortex rotating chamber in the vortex cooler 330, Can be generated. At this time, the number of revolutions per minute of the whirlpool is about 1,000,000 rpm, which is close to the speed of sound, and the whirlpool is directed toward the warm supply pipe 350, a part of which is discharged through the warm supply pipe 350, And may be discharged to the cool air supply pipe 340 while forming the car bolt. Since such a vortex cooler 330 belongs to a generally known technique, further detailed description and illustration of the vortex cooler 330 structure is omitted.

Meanwhile, a damper 500 for controlling the amount of air supplied to the vortex cooler 330 may be installed in the inflow passage 310. The damper 500 can control the amount of air supplied to the air conditioning unit 10 by adjusting the amount of air supplied to the vortex cooler 330. The damper 500 can be manually moved And can be automatically moved by a separate control unit. For example, the damper 500 may be implemented as a throttle valve installed in an intake pipe of an automobile to control the amount of air.

The air conditioning apparatus for preventing condensation of a duct according to an embodiment of the present invention further includes an air temperature and humidity sensor 600 and a controller 700 to control the heating means 200 in consideration of temperature and humidity of air can do.

3 is a block diagram showing a control relationship of an air conditioner for preventing condensation of a duct according to an embodiment of the present invention. 3, the air / temperature and humidity sensor 600 may be installed in at least one of the inside and the outside of the indoor space 1, and may transmit a signal indicating the temperature and humidity of the air to the controller 700 can send.

The control unit 700 selectively supplies the electric power supplied from the piezoelectric means 100 to the heating means 200. The control unit 700 controls the heating means 200 based on a signal from the air / 200 can be controlled.

Specifically, the control unit 700 can control the operation of the heating unit 200 by providing the electric power supplied from the piezoelectric unit 100 to the heating unit 200 as needed, The means (200) can generate heat only when necessary to heat the air.

The controller 700 can control the amount of heating of the heating unit 200 based on a signal from the air / temperature / humidity sensor 600, even when supplying power to the heating unit 200. For example, when the temperature difference between the inside and the outside of the recirculation duct 30 is large, the heating amount of the heating means 200 can be increased. When the temperature difference is small, the heating means 200 Can be reduced.

The heating unit 200 may include at least two heating coils controlled by the controller 700 so that the heating amount of the air moving in the recirculating duct 30 varies according to a signal of the air temperature and humidity sensor 600, (210).

4, the heating coil 210 may be disposed in series along the path of the air in the recirculation duct 30. Since the temperature of the indoor space 1 is very low, the temperature of the recirculation duct 30 The control unit 700 may operate all the two or more heating coils 210 to equalize the air temperature of the recirculation duct 30 to the external temperature.

When the temperature difference between the inside and the outside of the recirculating duct 30 is not large, the controller 700 appropriately activates only a part of the two or more heating coils 210 to save energy, Can be adjusted to the same as the external temperature.

While the present invention has been described in connection with what is presently considered to be preferred embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention is not limited thereto.

1: indoor space 10: air conditioning unit
20: exhaust duct 30: recirculation duct
100: Piezoelectric means 200: Heating means
210: Heating coil 300: Cooling unit
310: inlet passage 320: compressed air supply means
330: vortex cooler 340: cool air supply pipe
350: warming supply pipe 400: guide vane
500: Damper 600: Air temperature and humidity sensor
700:

Claims (8)

1. An air conditioning system comprising: an air conditioning unit for supplying cold air to an indoor space; a discharge duct for discharging part of the indoor space to the outside; and a recirculation duct for recirculating part of the indoor space to the air conditioning unit,
A piezoelectric means installed in the recirculation duct for producing predetermined power by the pressure of the air introduced into the recirculation duct;
A heating means installed on an air movement path of the recirculating duct and generating heat using electric power generated by the piezoelectric means and heating air moving in the recirculating duct to prevent condensation on the surface of the recirculating duct; ; And
And a cooling unit installed at a rear end of the recirculation duct for cooling the air heated by the heating unit. The method according to claim 1,
The piezoelectric device includes:
And a piezo element installed in at least one of a grill portion and a bending portion having relatively higher air pressure than other portions in the recirculating duct. delete The method according to claim 1,
The cooling unit includes:
An inflow passage branched from the rear end of the recirculation duct to introduce a part of the air of the recirculation duct;
Compressed air supply means installed in at least one of the recirculation duct and the inflow passage and supplying compressed air to the inflow passage;
A vortex cooler for separating the air introduced through the inflow passage into a cool air and a warm air by a vortex flow;
A cool air supply pipe for sending the cool air separated from the vortex cooler to the recirculation duct or the air conditioning unit; And
And a warming supply pipe for sending the warmth classified by the vortex cooler to the discharge duct. 5. The method of claim 4,
Wherein a guide vane for guiding air to the inflow passage is provided at a point corresponding to an inlet of the inflow passage from a rear end portion of the recirculation duct. 5. The method of claim 4,
Wherein the inflow passage is provided with a damper for controlling an amount of air supplied to the vortex cooler. The method according to claim 1,
An air temperature and humidity sensor installed in at least one of the inside and the outside of the indoor space for measuring temperature and humidity of air; And
And a control unit for selectively supplying the electric power generated by the piezoelectric unit to the heating unit and controlling the heating unit based on a signal from the air temperature and humidity sensor. 8. The method of claim 7,
The heating means,
And at least two heating coils controlled by the control unit such that a heating amount of air moving inside the recirculation duct is variable.

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