KR20040082262A - Heater for airconditioning - Google Patents

Abstract

PURPOSE: A heater for air conditioning is provided to improve the responsiveness of temperature controlling by enlarging a range capable of controlling temperature. CONSTITUTION: A heater(10) for air conditioning comprises a lamp heater(12) and a metal heat sink(14). The heater is installed in a specific position of a duct(16A). The lamp heater comprises halogen lamps(18). The lamp heater is fixed on a support frame(20) facing the airflow of the duct. The metal heat sink is installed at the upper flow portion of the lamp heater, spacing apart from the lamp heater. The metal heat sink is heated by the radiant heat of the lamp heater and heats air with the lamp heater.

Description

Air Conditioning Heater {HEATER FOR AIRCONDITIONING}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioning heater, and more particularly to an air conditioning heater that controls the temperature of air supplied to an air conditioning chamber by heat generated when a light bulb is turned on.

In recent years, the precision environmental chamber of a clean room for semiconductor manufacturing has been strictly required to control indoor temperature due to the large scale integration of semiconductors.

In particular, it is required to suppress the fluctuation of room temperature to ± / 1000 DEG C or lower in order to increase the inspection analysis accuracy in the space for actually performing the inspection analysis work.

Therefore, high-precision temperature management is performed in the air conditioner for precision environmental chamber rooms.

In a conventional air conditioner, an air conditioner heater for controlling temperature of air supplied to an air conditioner with a halogen lamp heater has been proposed (for example, Patent Document 1).

According to the air conditioner heater, the temperature of the air passing through the halogen lamp heater is detected by a temperature sensor, and the output of the halogen lamp heater is feedback-controlled by the heater controller according to the detected temperature.

(Patent literature)

Japanese Patent Application Laid-Open No. 2001-194040

However, since the air conditioning heater described in Patent Document 1 controls the temperature of the air only by the surface temperature rise of the halogen lamp heater, there is a problem that it cannot cope with sudden temperature fluctuations.

In the case of halogen lamp heaters, the temperature fluctuations of ± 1000 ° C or less can be dealt with immediately by controlling the output.However, when cold or hot air is suddenly supplied to the halogen lamp heater, only the output is controlled. Was not able to respond immediately, there was a problem that the cool air or hot air is supplied directly to the air conditioning chamber.

In the air conditioner for the precision environment chamber chamber, a large-scale temperature control is performed by an air conditioner installed at the front end of the air conditioning heater, instead of temperature control of the incoming external air as it is by the halogen lamp heater. have.

Therefore, even if it is cold air or hot air mentioned above, since temperature control is performed by the air conditioner of a front end, when it supplies to a halogen lamp heater, it becomes irregular at about +/- 3/100 degreeC.

This invention is made | formed in view of such a situation, and an object of this invention is to provide the air conditioning heater which improved the instantaneous response to air temperature control.

The present invention provides an air conditioning heater in which a light bulb is installed in a duct and heat is supplied to the air conditioning chamber by heat generated when the light bulb is turned on to achieve the above object. A ventilated metal heat sink is provided in a nearby duct, and the air passing through the metal heat sink is heated by heating the metal heat sink by radiant heat from the bulb.

According to the present invention, in addition to transferring heat to the air from the lit bulb surface, heat is transferred from the metal heat sink heated by radiant heat from the bulb to the air.

As a result, the area in which temperature control is possible is enlarged, and an immediate response to air temperature control is improved.

According to the present invention, the light bulb and the metal heat dissipation plate are configured to be attached to a short duct that forms a part of the duct and is detachably attached to the duct.

Thus, in the present invention, when repairing or replacing a light bulb or a metal heat sink, the short duct may be removed from the main body of the duct. Therefore, replacement work and maintenance work become easy.

BRIEF DESCRIPTION OF THE DRAWINGS The perspective view which shows the air conditioning heater which concerns on embodiment of this invention.

2 is a cross-sectional view showing a state in which the air conditioning heater of Figure 1 is mounted on the duct of the air conditioning equipment.

3 is a block diagram of an air conditioning system using the air conditioning heater of FIG.

4 is a view showing a relationship between a voltage applied to a halogen lamp and air temperature rise.

5 is a graph comparing responsiveness of temperature fluctuations to a heater output signal.

6 is a graph showing a temperature control situation by the air conditioning heater of the embodiment;

7 is a graph showing a temperature control situation by a conventional air conditioning heater.

(Explanation of symbols for the main parts of the drawing)

10: air conditioner heater 12: lamp heater

14 metal heat sink 16 duct

18: halogen lamp 24: short cut duct

42: precision environment chamber room (air conditioning room) 54: cooler

56 heater 58 air conditioner

76: cold water production apparatus

EMBODIMENT OF THE INVENTION Hereinafter, preferred embodiment of the air conditioning heater which concerns on this invention according to an accompanying drawing is described in detail.

As shown in FIG. 1, FIG. 2, the air conditioning heater 10 of embodiment is comprised from the lamp heater 12 and the metal heat sink 14, and is attached to the predetermined position of the duct 16. As shown in FIG.

The lamp heaters 12 are 15 halogen lamps (bulbs) 18, 18... Arranged in a row of 5 rows and 3 columns as shown in FIG. 1. It is comprised by the square frame-shaped support frame 20 so that the surface part may face with respect to the air which flows into the duct 16, and is fixed.

These halogen lamps 18, 18... Is connected to the thyristor 70 of FIG. 3 via the cable 22, and the voltage (output) applied by the thyristor 70 is controlled, and the light emission amount is controlled.

As shown in FIGS. 1 and 2, the metal heat sink 14 is provided at a position separated by a predetermined amount from the upstream side of the air stream with respect to the lamp heater 12.

The heat sink 14 made of metal is a honeycomb structure having a plurality of air passage holes, and is made of aluminum having a small heat capacity in order to efficiently transfer heat to the air passing through the air passage holes.

In addition, the material of the metal heat sink 14 is not limited to aluminum, It is applicable if it is a metal with a small heat capacity. Moreover, as long as the rigidity with respect to airflow can be ensured, you may produce a heat sink with paper instead of metal.

Moreover, the metal heat sink 14 has taken large contact area with air so that the heat of the metal heat sink 14 may fully be transmitted to air.

Specifically, the width B of the metal heat sink 14 is formed long.

In addition, the lamp heater 12 and the metal heat sink 14 are attached to the short duct 24, and are unitized.

The short duct 24 constitutes a part of the duct 16, and is detachably attached to the ends of the upstream duct 16A and the downstream duct 16B by the fastener 26.

Therefore, the air supplied from the upstream duct 16A flows to the downstream duct 16B after the heat from the air conditioning heater 10 is transferred.

The inner walls and outer walls of the ducts 16A and 16B are bonded with heat insulating materials 28 and 30 used for blocking and keeping heat.

4 is a graph showing the relationship between the voltage applied to the halogen lamp 18 of the lamp heater 12 and the air temperature rise. In addition, the horizontal axis | shaft of the said graph has shown the voltage and the vertical axis | shaft rose.

In addition, the said graph is obtained by actually measuring by duct diameter 650x650mm and wind speed 2.5m / s. As the halogen lamp 18, 15 of 85 watts made by Ushio Electric Co., Ltd. were used.

As shown in the graph, since the voltage applied to the halogen lamp 18 and the air temperature rise are in a linear relationship, it has been found that temperature control can be sufficiently performed by controlling the voltage applied to the halogen lamp 18.

5 is an immediate response of the conventional air conditioning heater which is only a lamp heater, and the air conditioning heater 10 of the embodiment which has the lamp heater 12 and the metal heat sink 14 with respect to the waveform output signal. Is a graph comparing the outlet temperature of the heater for air conditioning.

According to the figure, the horizontal axis represents the elapsed time, the left horizontal side represents the outlet temperature of the air conditioning heater, and the right horizontal axis represents the heater output signal (%).

Moreover, the temperature fluctuation by the conventional air conditioning heater with respect to the heater output signal C is shown by the waveform A, and the temperature fluctuation by the air conditioning heater 10 of embodiment is shown by the waveform B. FIG. .

As shown in the figure, the conventional air conditioning heater only reacts slightly to the heater output signal C as in the waveform A, and the temperature fluctuation is small and the response is poor.

On the other hand, the air conditioning heater 10 of the embodiment reacts sensitively to the heater output signal C as in the waveform B, and the temperature fluctuation is large and the response is good.

Referring to the mechanism, the air conditioning heater 10 transmits heat to the air from the surface of the lit halogen lamp 18, and radiates heat radiated from the halogen lamp 18 (in the direction of arrow A in FIG. 1). The heat dissipation plate 14, which is heated by radiant heat), also transfers heat to the air.

As a result, the area in which temperature control is possible is enlarged, and an immediate response to air temperature control is improved. This is the mechanism by which an instant response becomes good.

In addition, the air conditioning heater 10 is mounted on the short duct 24 in which the lamp heater 12 and the metal heat sink 14 constitute a part of the duct 16 and are detachably mounted to the duct 16. Since the halogen lamp 18 and the metal heat sink 14 are repaired and replaced, the short duct 24 may be removed from the duct 16. Therefore, replacement work and maintenance work become easy.

Next, an air conditioner using the air conditioner heater 10 will be described.

3 is a block diagram showing the configuration of an air conditioner 40 for a precision environment chamber chamber (air conditioner). The precision environment chamber chamber 42 shown in this figure is isolated from the outside by the partition wall 44, and the manufacturing line of a precision machine, an inspection analysis apparatus, etc. are installed indoors.

In this precision chamber chamber 42, it is required to maintain a constant temperature within an order of tolerance ± 1/1000 占 폚.

In FIG. 3 of the wall surface of the partition wall 44, the air supply panel 46 is provided in the right wall surface, and the air intake panel 48 is provided in the left wall surface. These panels 46 and 48 use punching metals which allow air to pass and also have a rectifying action.

A duct 50 is connected to the intake panel 48. The duct 50 is connected to the air conditioner 58 which consists of the blower 52, the cooler 54, and the heater 56. As shown in FIG.

Moreover, the duct 16A is connected to the air outlet of this air conditioner 58, the air conditioning heater 10 is connected to this, and the supply panel 46 is connected through the duct 16B. By this duct piping, the air conditioner 40 of FIG. 4 has the structure which circulates the air in the precision environment chamber chamber 42. As shown in FIG.

When the blower 52 is operated, air in the precision chamber chamber 42 is sucked from the intake panel 48 to the air conditioner 58 through the duct 50. The sucked air is cooled to a predetermined temperature by the cooler 54. A cooling coil (not shown) is provided inside the cooler 54, and the sucked air comes into contact with the cooling coil to cool it.

The heater 56 is a lamp heater having a halogen lamp inside, and immediately after the heater 56, a temperature sensor 60 is installed in the duct 16A, and immediately after exiting the heater 56, 16A. Is detecting the temperature inside.

The temperature sensor 60 is connected to the digital controller 62, the digital controller 62 controls the thyristor 64 in accordance with the temperature information of the temperature sensor 60, the power supply unit (not shown) by the thyristor 64 Is supplied to the heater 56 at a predetermined voltage.

The performance of the resolution in the digital controller 62 is ± 1/100 deg. By the heater 56 of such a structure, the air cooled by the cooler 54 is heated to near the required temperature.

For example, when the required temperature is 23.2 degrees Celsius, the air is heated and controlled by the heater 56 to be 22.9 degrees Celsius.

The temperature sensor 66 which detects the temperature in the precision environment chamber 42 is provided in the precision environment chamber chamber 42.

The temperature sensor 66 is connected to the digital controller 68, the digital controller 68 controls the thyristor 70 in accordance with the temperature information of the temperature sensor 66, the power supply unit (not shown) by the thyristor 70 ), The electric power of a predetermined voltage is supplied to the lamp heater 12 (refer FIG. 1) of the heater 10 for air conditioning.

Here, the resolution in the digital control system 68 is higher than the digital control system 62, and the one capable of up to ± 1/1000 ° C of the temperature in the precision environment chamber chamber 42 is used.

By the air conditioning system 40 of this structure, the conditioned air blown out from the supply panel 46 is sucked out from the intake panel 48, and a side flow (horizontal laminar flow) in the precision environment chamber chamber 42 is obtained. ) Flows.

In the precision environment chamber chamber 42, the temperature is strictly controlled, and the precision environment chamber chamber 42 is maintained at a temperature within a tolerance of ± 1/1000 ° C at 23.2 ° C. In particular, due to the side flow in the precision chamber chamber 42, air does not stay in the precision chamber chamber 42, and the temperature distribution in the chamber chamber 42 is equalized, resulting in turbulence and the like. The temperature controllability is improved because it can be prevented.

In addition, by installing an air conditioner 58 and an air conditioner heater 10 and attaching a temperature sensor for controlling them, the air can be controlled in two stages with different temperature resolution, thereby providing excellent air control. The conditioner 40 can be provided.

In particular, the temperature is kept close to the temperature required by the heater 56 of the air conditioner 58 and maintained at the required temperature by the air conditioning heater 10. The fluctuation in the amount of control heat is reduced, so that the room temperature of the precision environment chamber chamber 42 can be easily controlled, and the room temperature can be stabilized.

On the other hand, a cooling coil (not shown) is provided inside the cooler 54, and the air sucked in the air conditioner 58 contacts and cools the cooling coil. The cold water pipe 72 is connected to the cooling coil.

The cold water pipe 72 is connected to the cushion tank 74, the cold water manufacturing apparatus 76, the heater 78, etc., and the pump P circulates the cold water in the cushion tank 74. As shown in FIG.

The cushion tank 74 is composed of two sets of cold water tanks 74A and 74B partitioned, and the cold water discharged from the cooler 54 is stored in the cold water tank 78A, and then the cold water production apparatus through the pipe 80. Return to (76).

In addition, the cold water produced by the cold water manufacturing apparatus 76 is stored in the cold water tank 74B through the pipe 82, and is supplied to the cooler 54 by the pump P. As shown in FIG.

The heater 78 is a coil wound around the heat transfer wire, and heats the heat transfer wire by energizing the heat transfer wire in a power supply section (not shown), and the desired temperature by contacting the heat transfer wire with cold water conveyed by the pump P. Heat cold water until

The temperature sensor 84 is provided in the cold water pipe 64 just behind this heater 78, and the temperature of the cold water just behind the heater 78 is detected. The temperature sensor 84 is connected to the digital controller 86. The digital controller 86 outputs a temperature signal to the thyristor 88 according to the temperature information of the temperature sensor 84, and feeds back the thyristor 88. The control signal by the control is output, and electric power of a predetermined voltage is supplied from the power supply unit (not shown) to the heater 82.

By the cooler 54 of such a structure, cold water can be cooled to the error range about 1/100 degreeC rather than the minimum required temperature.

(Example)

FIG. 6 is a graph showing the temperature control situation by the air conditioning heater 10 in the air conditioner 40 shown in FIG. 7 is a graph showing the temperature control situation when a conventional air conditioning heater, which is only a lamp heater, is used instead of the air conditioning heater 10.

Since the temperature control status confirmation test shown in FIG. 6, FIG. 7 was performed in substantially the same external air environment, the superiority of the control precision can be understood by comparing both.

According to the air conditioner heater 10 of the embodiment shown in FIG. 6, the control of +/- 2/1000 degreeC is possible with respect to 22.152 degreeC which is a target value, On the other hand, the conventional air conditioning heater shown in FIG. 7 is 22.152 which is a target value. The control up to ± 7/1000 ° C is limited.

Therefore, the air conditioning heater 10 of the embodiment provided with the lamp heater 12 and the metal heat dissipation plate 14 has improved the temperature control accuracy compared with the conventional air conditioning heater which is only the lamp heater.

As described above, according to the air conditioning heater according to the present invention, the air passing through the metal heat sink is heated by providing a ventilated metal heat sink in a duct near the bulb and heating the metal heat sink by radiant heat from the light bulb. As a result, the temperature controllable area is enlarged to improve the immediate response to the air temperature control.

In addition, according to the present invention, since the bulb and the metal heat sink are part of the duct and attached to the short duct that is detachably mounted on the duct, the duct can be shortened when repairing or replacing the light bulb or the metal heat sink. Just remove from the body. Therefore, replacement work and maintenance work become easy.

Claims (2)

In the air-conditioning heater which installs a light bulb in a duct, and heats the air supplied in the said duct and supplies it to an air conditioning room by the heat which generate | occur | produces when this light is turned on, An air conditioning heater, comprising: providing a breathable metal heat sink in a duct near the light bulb, and heating the metal heat sink by radiant heat from the light bulb, thereby heating the air passing through the metal heat sink. The air conditioner heater according to claim 1, wherein the electric bulb and the metal heat sink are mounted on a short duct that forms a part of the duct and is detachably mounted to the duct. .