KR100707082B1 - Heater unit having heat insulator and air conditioning apparatus having the same - Google Patents

Abstract

The present invention relates to a heater unit for regenerating a desiccant unit of an air conditioner having a dehumidifying function. The heater unit of the air conditioner according to the present invention includes a heater case; Heating element built in the heater case; And a heat insulating member provided in the heater case to prevent heat generated from the heating element from being transferred to the outside through the heater case. According to this configuration, it is possible to reduce the energy loss of the air conditioner by providing a heat insulating member inside the heater case to reduce the heat generated from the heating element through the heater case.

Desiccant, Heater Unit, Insulation Member, Radiant Insulation Plate, Conductive Insulation Plate

Description

HEATER UNIT HAVING HEAT INSULATOR AND AIR CONDITIONING APPARATUS HAVING THE SAME}

1 is an exploded perspective view schematically showing an air conditioner according to an embodiment of the present invention;

FIG. 2 is a perspective view schematically illustrating the desiccant unit and the heater unit of FIG. 1; FIG.

3 is a cross-sectional view taken along line III-III of FIG. 2;

4 is a cross-sectional view taken along line IV-IV of FIG. 2;

5 is a conceptual view for explaining the operation of the air conditioner shown in FIG.

6 is a cross-sectional view for explaining the operation of the heat insulating member of the heater unit shown in FIG. 2.

<Description of the symbols for the main parts of the drawings>

120; Desiccant unit 140; Fan Motor Unit for External Air

180; Fan motor unit 200 for regenerative air; Heater unit

210; Heater case 220; Heating element

230; Insulation member 232; Radiant insulation

234; Conductive Insulation Plate RA: Regenerative Air

PA; Outside air

The present invention relates to an air conditioner, and more particularly, to a heater unit of an air conditioner for regenerating a desiccant unit that performs a dehumidifying function.

An air conditioner having a dehumidifying function may be classified into a cooling type and a non-cooling type according to a dehumidifying method.

The cooling dehumidification type air conditioner performs dehumidification by liquefying moisture contained in the outside air by cooling the outside air in contact with the evaporator below the dew point. Such a cooling dehumidification method has a problem in that it is not discharged to the room in a state where the outside air is cooled, so that the room temperature cannot be kept constant, and moisture is not liquefied when the difference between the evaporator and the room temperature is not large. In addition, since the evaporator must be kept cool below the dew point temperature of the outside air during operation, excessive energy is used to maintain the high maintenance cost. For this reason, an uncooled dehumidification method that does not cool outside air is used.

A general uncooled dehumidification type air conditioner includes a desiccant unit for removing moisture from introduced external air, a heater unit for removing moisture from the desiccant unit, and drying and regenerating the desiccant unit. And a fan motor unit for blowing regenerated air heated by the to the desiccant unit. The heater unit includes a heater case and a heating element built in the heater case.

Looking at the dehumidification process of the air conditioner having the configuration as described above, the outside air is deodorized due to the strong affinity for the moisture of the desiccant unit while passing through the desiccant unit. Deodorized water is present in the state adsorbed to the desiccant unit.

Therefore, in order for the desiccant unit to repeatedly perform a dehumidification operation, a regeneration process of removing moisture from the desiccant unit is required. This regeneration process is performed by the fan motor unit blowing the regeneration air heated by the heating element to the desiccant unit to dry regenerate the desiccant unit. When heated regeneration air passes through the desiccant unit, the moisture adsorbed on the desiccant unit is vaporized. The vaporized water is blown with the regeneration air. As such, the desiccant unit is dried and regenerated by the heater unit, and the desiccant unit can repeatedly perform a dehumidification process.

For the regeneration process as described above, the heater unit must heat the desiccant unit to a predetermined temperature or more.

However, part of the heat generated from the heating element is discharged to the outside through the heater case is lost. In particular, considering that most of the energy consumed by the uncooled air conditioner is consumed by the heater unit, the energy loss through the heater case described above is a fatal factor that increases the power consumption of the air conditioner.

The present invention has been made in view of the above point, and an object of the present invention is to provide a heater unit for an air conditioner which can reduce energy consumption.

Another object of the present invention is to provide an air conditioner that can reduce energy consumption.

The heater unit of the air conditioner according to the present invention for achieving the above object is provided with an inlet for regenerating air is introduced and an outlet for discharging the regenerated air to the desiccant unit that absorbs moisture from the outside air. Heater case; A heating element embedded in the heater case to heat the regeneration air introduced into the inlet; And a heat insulating member provided in the heater case to prevent heat generated from the heating element from being transferred to the outside through the heater case.

According to an embodiment of the present invention, the heat insulating member is interposed between the heating element and the heater case, the radiation insulation plate for reflecting the radiant heat generated from the heating element to the desiccant unit, the radiation insulation plate and the heater case It includes a conductive insulating plate interposed between.

The radiation insulation plate is made of at least one of stainless steel and mirror, the conductive insulation plate is made of at least one material of mica, asbestos, glass fiber. In addition, at least one heating coil is used as the heating element.

On the other hand, the object as described above, the desiccant unit for adsorbing moisture from the introduced outside air; A fan motor unit for external air for introducing external air into the desiccant unit and discharging the external air from which moisture is removed by the desiccant unit; A fan motor unit for regeneration air circulating regeneration air for regenerating the desiccant unit; A heater case provided with an inlet for regenerating air circulated by the fan motor unit for regenerating air and an outlet for discharging the regenerated air to the desiccant unit; A heating element embedded in the heater case to heat the regeneration air introduced into the inlet; And a heat insulating member provided on the heater case to prevent heat generated from the heating element from being transferred to the outside through the heater case.

Hereinafter, an air conditioner according to an embodiment of the present invention will be described in detail.

1 and 2, an air conditioner according to an embodiment of the present invention includes a frame 100, a desiccant unit 120, a fan motor unit 140 for an external air, a heat exchange unit 160, The fan motor unit 180 and the heater unit 200 for the regeneration air.

The frame 100 is provided with a receiving portion 102 to which the desiccant unit 120 is coupled to one surface thereof, and the fan motor unit 140 for the external air is coupled to the other surface thereof. In addition, the fan motor unit 180 and the heater unit 200 for the regenerative air are installed in the frame 100. The frame 100 is supported by a body frame, not shown.

The desiccant unit 120 includes a rotor case 122, a desiccant rotor 124 rotatably installed at the rotor case 122, and a driving motor for rotating the desiccant rotor 124. 130 and a power transmission member 132 for transmitting the power of the drive motor 130 to the desiccant rotor 124.

The rotor case 122 is coupled to the receiving portion 102 of the frame 100 by a screw or the like, and a shaft 123 to which the desiccant rotor 124 is coupled is formed at the center of the rotor case 122. do.

The desiccant rotor 124 includes an outer rim 125 having a gear 126 formed along an outer circumferential surface thereof, and a desiccant 127 coupled to the inside of the outer rim 125.

In general, the desiccant 127 is a material having a strong affinity for moisture and capable of absorbing moisture directly from the surrounding air. For example, the desiccant 127 has a cylindrical shape in which a flat paper and corrugated paper of ceramic fiber are alternately wound therein, and a silica gel is coated therein, and a plurality of fine holes are formed on the surface thereof. Can be. 2, the desiccant 127 may be classified into a dehumidifying region DHD for adsorbing moisture from the outside air and a regeneration region RD for removing moisture adsorbed from the outside air. The regeneration zone RD may be classified into a drying zone DD for drying the adsorbed moisture and a cooling zone CD for cooling the desiccant 127 heated by the drying zone DD. have.

Since the structure of the desiccant 127 described above is a known technique, a detailed description of the structure and function will be omitted. The desiccant 127 is coupled to a bearing 128 coupled to the shaft 123 of the rotor case 122 such that the desiccant rotor 124 is rotatably supported by the rotor case 122.

The drive motor 130 is supported as a driving source for rotating the desiccant rotor 124 and is not shown in the main body frame. The driving motor 130 is connected in signal communication with a controller (not shown) and driven by the controller at regular intervals or according to a predetermined data value.

The power transmission member 132 includes a drive gear 133 provided at one end of the drive shaft 131 of the drive motor 130 and a driven gear 134 geared to the drive gear 133. The driven gear 134 is coupled to the gear 126 formed on the outer rim 125.

Therefore, when the driving motor 130 is driven, the driven gear 134 is rotated by the rotation of the drive gear 133, the driven gear 134 rotates the outer rim 125. Although the driving gear 133 and the driven gear 134 are illustrated as the power transmission member 132 in this embodiment, various power transmission devices such as pulleys and driving belts may be used.

The fan motor unit 140 for external air includes a duct 142 for inducing the discharge of external air and a blowing fan 144 installed in the duct 142. The duct 142 is coupled to the other surface of the frame 100 by screws or the like. When the fan motor unit 140 for external air having such a structure is driven, the external air to be dehumidified is introduced into the inlet formed in the main body frame (not shown), and the introduced external air is exchanged to the heat exchange unit 160 and the desiccant ( 127 and the receiving portion 102 of the frame 100 in order to flow into the duct 142, the air introduced into the duct 142 is discharged to the outside through the discharge port formed by the body frame not shown .

The heat exchange unit 160 includes first and second heat exchangers 162 and 172 that are supported by a body frame, not shown, and communicate with each other. The first heat exchanger 162 is provided with a first inlet 164 at an upper end thereof, and a first outlet 166 for discharging the regenerated air introduced into the first inlet 164 at the lower end thereof. Meanwhile, a plurality of internal flow paths are formed in the first heat exchanger 162, and slits S through which external air passes are formed between the internal flow paths.

The second heat exchanger 172 is provided with a second inlet 174 communicating with the first outlet 166 at a lower end thereof, and a second outlet for regenerating air introduced into the second inlet 174 at an upper end thereof. Outlet 176 is formed. A plurality of flow paths are formed in the second heat exchanger 172, and slits S are formed between the respective internal flow paths.

In such a structure, the regenerated air heated through the heater unit 200 by the fan motor unit 180 for the regenerated air passes through the desiccant 127 and due to the moisture removed from the desiccant 127. Inflow to the first inlet 164 in a state of high temperature and high humidity. The regenerated air introduced into the first inlet 164 passes through the internal flow path of the first heat exchanger 162 and is discharged through the first outlet 166 and is discharged through the first outlet 166. Air enters the second inlet 174 of the second heat exchanger 172. The regenerated air introduced into the second heat exchanger 172 passes through the plurality of internal flow paths and is discharged to the second outlet 176. The regeneration air discharged to the second outlet 176 passes through the regeneration air duct 178 which communicates the second outlet 176 and the fan motor unit 180 for regeneration air to the regeneration air fan motor unit 180. Flows into.

As described above, the regeneration air is heat-exchanged with the outside air passing through the slit S between the inner passages while passing through the plurality of inner passages of the first and second heat exchangers 162 and 172. The regeneration air of is cooled to below the dew point temperature, whereby water in the form of water vapor contained in the regeneration air is liquefied. Liquefied water is discharged through a drain 165 into a container, not shown. Therefore, the regenerated air passing through the heat exchange unit 160 is in a dry state in which moisture is removed.

The fan motor unit 180 for regeneration air is for circulating regeneration air, and is supported by the frame 100, and an inlet thereof is connected to the regeneration air duct 178, and an outlet thereof is a heater unit ( And the inlet 218 of the 200. That is, the fan motor unit 180 for regenerative air forcibly blows dry low temperature regenerative air that has passed through the heat exchange unit 160 to the inlet 218 of the heater unit 200.

2 to 4, the heater unit 200 includes a heater case 210, a heating element 220, and a heat insulating member 230.

The heater case 210 is divided into a heating part 214 in which the heating element 220 is installed and a purge part 216 for blowing unheated regenerated air to the desiccant 127 by the separating wall 212. do. A connection hole 213 is formed in the separation wall 212, and the heating part 214 and the purge part 216 communicate with each other by the connection hole 213. In addition, the purge part 216 of the heater case 210 is provided with an inlet 218 communicating with the outlet of the fan motor unit 180 for regeneration air, and the desiccant 127 of the purge part 216. A plurality of outlet holes 217 are formed on the surface facing the discharge port 218 for discharging the air introduced into the inlet 218 into the cooling region CD of the desiccant 127 without being heated.

On the other hand, the outlet facing the desiccant 127 of the heating unit 214 is provided with an outlet 215 for discharging the regeneration air to the desiccant 127.

With the structure as described above, the regeneration air blown by the fan motor unit 180 for the regeneration air is first introduced into the purge unit 216 through the inlet 218, a part of the regenerated air flows out It is discharged to the cooling area CD of the desiccant 127 through the through hole 217, and the remaining part of the regeneration air flows into the heating part 214 through the connection hole 213. The regenerated air introduced into the heating unit 214 is discharged to the drying region DD of the desiccant 127 through the outlet 215 of the heating unit 214.

The heating element 220 heats the regeneration air for discharging the drying region DD of the desiccant 127 and transmits radiant heat to the drying region DD of the desiccant 127. Heating coil 220 is included. The heating coil 220 may be manufactured by various methods such as winding the nichrome wire wound on the mica plate. In addition, unlike the present embodiment, the heating element 220 may use various heating elements such as a thermoelectric element.

The heat insulating member 230 is interposed between the heating element 220 and the heater case 210 to prevent the heat generated by the heating element 220 from being lost through the heater case 210. And a radiation insulating plate 232 and a conductive insulating plate 234.

The radiation insulating plate 232 reflects the radiant heat generated from the heating element 220 to the dry region DD of the desiccant 127 so that the heat generated from the heating element 220 is transferred to the heater case 210. Minimizing and maximizing heat transferred to the drying region DD of the desiccant 127 is interposed between the heating element 220 and the conductive insulating plate 234. The radiation insulation plate 232 may be made of stainless steel or mirror having excellent reflectance of radiant heat.

The conductive insulation plate 234 is to prevent heat generated from the heating element 220 from being transferred to the radiation insulation plate 232 and the heater case 210 and released to the outside. The radiation insulation plate 232 and the heater It is interposed between the cases 210. The conductive insulation plate 234 may be made of a material having a small heat transfer coefficient such as mica, asbestos, and glass fiber.

As such, the radiant heat insulating plate 232 and the conductive heat insulating plate 234 minimize the radiant heat and the conductive heat generated from the heat generating element 220 to the outside of the heater case 210, and the dry region of the desiccant 127 ( By maximizing the heat transferred to DD), it is possible to reduce the energy consumption of the air conditioner by maximizing the thermal efficiency.

Hereinafter, the operation of the air conditioner according to an embodiment of the present invention will be described with reference to FIGS. 5 and 6.

5 and 6, by driving the fan motor unit 140 for external air, the external air PA passes through the slit S of the first and second heat exchangers 162 and 172. As a result, the dehumidifier 127 is introduced into the dehumidifying region DHD. The outside air introduced into the dehumidifying area DHD of the desiccant 127 is deodorized by the desiccant 127. In more detail, the vapor pressure of the surface of the desiccant 127 is lower than the partial pressure of the external air PA so that the moisture of the external air PA is adsorbed to the desiccant 127. The external air PA from which moisture is removed by the desiccant 127 is discharged to the outside by the fan motor unit 140 for external air.

Meanwhile, in order to repeatedly use the desiccant 127, the moisture adsorbed on the desiccant 127 should be removed. To remove this, the desiccant 127 may be rotated to move the dehumidifying region DHD in which moisture is adsorbed to the drying region DD. To this end, the control unit not shown drives the driving motor 130. When the driving motor 130 is driven, the drive gear 133 rotates to rotate the driven gear 134. When the driven gear 134 rotates, power is transmitted to the gear 126 formed along the outer circumference of the rim 125 so that the desiccant rotor 124 rotates in the A direction to absorb moisture from the desiccant 127. Reaches the dry region DD. The controller may not only rotate the driving motor 130 continuously but also control the rotation of the driving motor 130 according to the amount of moisture adsorbed by the desiccant 127.

When the moisture adsorption portion of the desiccant 127 reaches the dry region DD, the regenerated air RA heated by the heating element 220 and the radiant heat of the heating element 220 are heated and adsorbed to the desiccant 127. Moisture is vaporized. More specifically, the surface of the desiccant 127 of the drying region DD is heated so that the vapor pressure of the surface thereof becomes higher than the vapor pressure of the regeneration air RA, whereby the moisture of the desiccant 127 becomes desiccant ( 127) from the surface.

The desiccant 127 from which moisture is removed from the drying region DD continues to rotate to reach the cooling region CD. When reaching the cooling zone CD, unheated regeneration air RA is blown to the desiccant 127 through the outflow hole 217 of the purge part 216. By this, the desiccant 127 is cooled, and the vapor pressure of the surface becomes low. Therefore, the dehumidification capacity of the desiccant 127 which has passed through the cooling region CD is restored and raised again, and the moisture can be adsorbed from the outside air by moving to the dehumidification region DHD. By repeating the series of processes as described above, the desiccant 127 may repeatedly remove moisture from the outside air PA.

On the other hand, looking at the circulation process of the regeneration air (RA), the regeneration air (RA) is introduced into the inlet 218 of the heater case 210 by the drive of the fan motor unit 180 for the regeneration air. A part of the regenerated air RA introduced is blown to the cooling area CD through the outflow hole 217 of the purge part 216, and the other part passes through the heating part 214. The regeneration air RA passing through the heating part 214 is heated by the heating element 220 to become the high temperature regeneration air RA. The high temperature regeneration air RA is blown to the drying area DD through the outlet 215 of the heater case 210 to remove moisture of the desiccant 127 located in the drying area DD. The heat in the heating unit 214 is blocked from being transferred to the outside of the heater case 210 by the conductive insulating plate 234. Therefore, the heat generated by the heating element 220 is used as heat for heating the regeneration air RA without being discharged to the outside of the heater case 210, so that the regeneration air RA can be heated more efficiently. .

Meanwhile, radiant heat generated from the heating element 220 is also transferred to the desiccant 127 located in the drying area DD to heat the desiccant 127. At this time, as shown in Figure 6, the radiant heat emitted to the rear of the heating element 220 is reflected back to the desiccant 127 by the radiation insulating plate 232 is used as heat for heating the desiccant 127. Therefore, the radiant heat can be transmitted to the desiccant 127 more efficiently. As a result, by installing the radiation insulation plate 232 and the conductive insulation plate 234 inside the heater case 210, it is possible to use energy more efficiently.

The high temperature and high humidity regeneration air RA including the water removed from the desiccant 127 passes through the first and second heat exchangers 162 and 172. While passing through the first and second heat exchangers 162 and 172, as described above, the high temperature and high humidity regeneration air RA heat exchanges with the incoming external air PA so that the temperature falls below the dew point. As a result, the gaseous water contained in the regeneration air RA is liquefied and discharged through the drain 165 (see FIG. 1) provided under the first and second heat exchangers 162 and 172. Moisture discharged through the drain 165 is collected in a container not shown.

As described above, an experiment was performed to measure the amount of dehumidification discharged through the drain 165 of the air conditioner when and without the radiant insulation plate 232 in the heater unit 200. The conditions and results of the test are shown in [Table 1].

Radiation Insulation Board Desiccant size Air flow Power applied to heating element [W] Desiccant Rotor Speed [RPH] Dehumidification amount [liter / day] Outside air [CMM] Regenerative Air [CMM] Without radiant insulation Diameter: 270 mm Thickness: 17 mm 2.7 0.4 700 35 8.5 If you have radiant insulation Diameter: 270 mm Thickness: 17 mm 2.7 0.4 700 35 9.3

As shown in Table 1, the experiment includes the size of the desiccant, the flow rate (CMM, Cubic Meter per Minute) of the outside air (PA) and the regeneration air (RA), the power applied to the heating element 220, and The rotation speed (RPH, Revolution Per Hour) of the desiccant rotor 124 was set in the same state. And the radiation insulation plate 232 was used stainless steel. As a result of the experiment, the dehumidification amount of the air conditioner is 8.5 liters per day when there is no radiation insulation plate 232, while the dehumidification amount of the air conditioner is 9.3 liters when the radiation insulation plate 232 is present. That is, when the radiation insulation plate 232 is used, the amount of dehumidification increased by 0.8 liters. The experiment is a case where only the radiation insulation plate 232 is used, the dehumidification amount will be further improved when the conductive insulation plate 234 is used together.

While passing through the first and second heat exchangers 162 and 172, the regeneration air RA from which moisture is removed is introduced into the regeneration air fan motor unit 180 through the regeneration air duct 178.

As described above, through the circulation process of the regeneration air (RA) and the outside air (PA), it is possible to repeatedly perform the dehumidification of the outside air (PA).

According to the present invention as described above, by installing a heat insulating member inside the heater case it is possible to reduce the energy loss of the air conditioner by reducing the heat generated from the heating element through the heater case.

In particular, the conductive heat insulating plate is conducted to the outside through the heater case to reduce the heat lost and the radiant heat insulating plate reflects the radiant heat generated from the heating element back to the desiccant dry area, thereby more efficiently using the heat generated from the heating element. Will be.

While the invention has been shown and described in connection with preferred embodiments for illustrating the principles of the invention, the invention is not limited to the construction and operation as shown and described. That is, those skilled in the art to which the present invention pertains will appreciate that many changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims. Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

Claims (13)

A heater case having an inlet for regenerating air introduced therein and an outlet for discharging the regenerated air into the desiccant unit which absorbs moisture from the outside air; A heating element embedded in the heater case to heat the regeneration air introduced into the inlet; And And a heat insulating member provided in the heater case to prevent heat generated from the heat generator from being transferred to the outside through the heater case. The method of claim 1, wherein the heat insulating member, And a heater unit interposed between the heating element and the heater case. The method of claim 2, wherein the heat insulating member, And a radiant heat insulating plate for reflecting radiant heat generated from the heating element to the desiccant unit. The method of claim 3, wherein the heat insulating member, And a conductive heat insulating plate interposed between the radiant heat insulating plate and the heater case. The radiation insulating plate of claim 4, Heater unit of the air conditioner, characterized in that at least one of stainless steel and mirror. The method of claim 5, wherein the conductive insulating plate, Heater unit of the air conditioner, characterized in that made of at least one of mica, asbestos, glass fiber. 8. The heater unit according to any one of claims 1 to 7, wherein the heating element is at least one heating coil. A desiccant unit for adsorbing moisture from the introduced external air; A fan motor unit for external air for introducing external air into the desiccant unit and discharging the external air from which moisture is removed by the desiccant unit; A fan motor unit for regeneration air circulating regeneration air for regenerating the desiccant unit; A heater case provided with an inlet for regenerating air circulated by the fan motor unit for regenerating air and an outlet for discharging the regenerated air to the desiccant unit; A heating element embedded in the heater case to heat the regeneration air introduced into the inlet; And And a heat insulating member provided in the heater case to prevent heat generated from the heat generator from being transferred to the outside through the heater case. The method of claim 8, wherein the heat insulating member, And an air conditioner interposed between the heating element and the heater case. The method of claim 9, wherein the heat insulating member, A radiation insulating plate for reflecting radiant heat generated from the heating element to the desiccant unit; And And a conductive heat insulating plate interposed between the radiant heat insulating plate and the heater case. The method of claim 10, wherein the radiation insulating plate, Air conditioning apparatus, characterized in that at least one of stainless steel and mirror. The method of claim 11, wherein the conductive insulating plate, Air conditioning apparatus, characterized in that made of at least one of mica, asbestos, glass fiber. The air conditioner according to any one of claims 8 to 12, wherein the heating element is at least one heating coil.

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