JP2017156120A5 - - Google Patents

Description

Environmental test equipment and air conditioner

The present invention relates to an environmental test apparatus capable of creating a specific environment in a test chamber and exposing a device under test to a desired environment.
The environmental test apparatus of the present invention is suitable as an environmental test apparatus in which a test room and an air conditioner are separate bodies and both are installed at a distance.
The present invention also relates to an air conditioner that creates a specific environment in a space such as a test room.

Environmental tests are known as tests for examining the performance and durability of products and parts. Environmental tests are performed using equipment called environmental test equipment. The environmental test apparatus artificially creates, for example, a high temperature environment, a low temperature environment, a high humidity environment, and the like.
Some environmental test apparatuses are divided into an air conditioner for adjusting temperature and humidity and a test room.
For example, the size of the DUT itself may be large, or the device that drives the DUT may be large, and the test room and the air conditioner are separated due to the balance with other devices and layout restrictions. Things may be adopted.
FIG. 5 is a conceptual diagram of a conventional environmental test apparatus 100 that can create a ventilation environment in a test chamber.

In the environmental test apparatus 100, the test chamber 2 and the air conditioner 3 are separate bodies as described above, and the circulation channel 5 connects between the two.
The test chamber 2 has a test space 6 in which a DUT is installed. The test space 6 is covered with a heat insulating wall 7.
The test chamber 2 is provided with a temperature sensor 30 for detecting the temperature of the space and a humidity sensor 31 for detecting the relative humidity of the space in a space in which equipment or parts to be a sample are arranged when performing an environmental test. It has been. The temperature sensor 30 is a temperature sensor such as a conventionally known resistance temperature detector, for example. On the other hand, the humidity sensor 31 is, for example, a conventionally known humidity sensor. A wind speed sensor 8 is provided in the test chamber 2.
The test chamber 2 has an air inlet 10 and an air outlet 11.

The air conditioner 3 has a ventilation space (not shown) inside, and an air conditioner 18 is incorporated therein. The air conditioner 18 includes the evaporator 12, the humidifier 13, and the heater 15 of the cooling device 32.
The cooling device 32 is an evaporator of a refrigeration device (not shown). The cooling device 32 realizes a refrigeration cycle using a phase-change refrigerant, and includes a compressor 33, a condenser 35, an expansion means 36, an evaporator 12, and a refrigerant pipe 25 that connects these in an annular shape. The refrigeration circuit 23 is provided.
Therefore, the air conditioner 3 includes an evaporator 12, a humidifier 13, a heater 15, and a blower 16. The motor of the blower 16 is controlled by an inverter, and the rotation speed can be changed.
The air conditioner 3 has an air supply port 20 that blows air toward the test chamber 2 and an air return port 21 that introduces air returned from the test chamber 2 into the air conditioner 3.
The air conditioner 3 introduces air from the air return port 21 to the ventilation space (not shown), adjusts the temperature and humidity of the air while passing through the ventilation space, and blows air from the air supply port 20 by the blower 16. have.

In the environmental test apparatus 100, the test chamber 2 and the air conditioner 3 are separate bodies as described above, and both are connected by the circulation flow path 5.
That is, the air supply port 20 of the air conditioner 3 and the air supply inlet 10 of the test chamber 2 are connected by the forward air passage 22. Further, a return side air passage 25 connects between the air discharge port 11 of the test chamber 2 and the air return port 21 of the air conditioner 3. Both the forward-side air passage 22 and the return-side air passage 25 are ducts.

In the environmental test apparatus 100, the target environment of the test room 2 is set by an input device (not shown). In the environmental test apparatus 100, the set temperature, the set humidity, and the set wind speed are input.
In the environmental test apparatus 100, the wind speed sensor 8 in the test chamber 2 detects the wind speed of the wind hitting the test object, and the wind speed is fed back to the blower 16 so that the wind speed in the test chamber 2 is adjusted to the set wind speed. Is done.
That is, when the wind speed detected by the wind speed sensor 8 is lower than the set wind speed, the rotational speed of the blower 16 is increased. Conversely, when the wind speed detected by the wind speed sensor 8 exceeds the set wind speed, the rotational speed of the blower 16 is reduced.

In the environmental test apparatus 100, the temperature and humidity in the test chamber 2 are fed back to the air conditioner 3, and air adjusted to a desired temperature and humidity by the air conditioner 3 is sent to the test chamber 2 side.
That is, in the environmental test apparatus 100, the temperature and humidity in the test chamber 2 are detected by the temperature sensor 30 and the humidity sensor 31 in the test chamber 2, and the air conditioner 18 of the air conditioner 3 is controlled based on the detection information.
More specifically, when the temperature in the test chamber 2 is detected by the temperature sensor 30 and the detected temperature is lower than the set temperature, the heater 15 of the air conditioner 18 of the air conditioner 3 located at a remote position is detected. The output is increased and the output of the cooling device 32 is decreased. As a result, the temperature of the air blown from the air conditioner 3 rises, and the heated air is sent to the test chamber 2 at a remote location.
Conversely, when the temperature in the test chamber 2 is higher than the set temperature, the output of the cooling device 32 is increased and the output of the heater 15 is decreased. As a result, the temperature of the air blown from the air conditioner 3 is lowered, and the air whose temperature has dropped is sent to the test chamber 2 at a remote position.

Further, the humidity in the test chamber 2 is detected by the humidity sensor 31, and when the detected humidity is lower than the set humidity, the output of the humidifying device 13 of the air conditioner 18 at a remote position is increased. As a result, the humidity of the air blown from the air conditioner 3 increases, and the humidified air is sent to the test chamber 2 at a remote position.
Conversely, when the humidity in the test chamber 2 is higher than the set humidity, the cooling device 32 is operated to condense water vapor in the air on the surface of the evaporator 12 and dehumidify it. As a result, the humidity of the air blown from the air conditioner 3 decreases, and the dehumidified air is sent to the test chamber 2 at a remote position.

As described above, the air conditioner 18 includes the evaporator 12, the humidifier 13, and the heater 15 of the cooling device 32. The cooling device 32 reduces the temperature of the air and reduces the humidity of the air. It is used for purposes. However, it is difficult to accurately control the cooling amount and dehumidifying amount of the cooling device 32. Therefore, in the actual environmental test apparatus 100, the temperature of the air is slightly reduced by the cooling device 32, and the air is heated by the heater 15 to finely adjust the air temperature to the set temperature.
The same applies to the humidity adjustment. The air humidity is slightly reduced by the cooling device 32, and the air is humidified by the humidifying device 13 to finely adjust the air humidity to the set humidity.

Japanese Patent Laid-Open No. 2016-3980

As described above, in the environmental test apparatus 100, the test chamber 2 and the air conditioner 3 are separate bodies, and air is heated, cooled, humidified, and dehumidified by the air conditioner 18 in the air conditioner 3. Sent to test room 2
In the prior art, detection signals from the temperature sensor 30 and the humidity sensor 31 in the test chamber 2 are fed back to the air conditioner 18 in the air conditioner 3. Therefore, if the temperature of the test chamber 2 is higher than the set temperature, the air cooled by the air conditioner 18 is blown into the test chamber 2. If the temperature of the test chamber 2 is lower than the set temperature, the temperature of the air sent from the air conditioner 18 is increased.
Further, if the humidity in the test chamber 2 is higher than the set humidity, the air is dehumidified in the air conditioner 18 and blown to the test chamber 2. Is humidified and blown to the test chamber 2 at a position away from the air conditioner 18.

  As described above, in the environmental test apparatus 100, the test chamber 2 and the air conditioner 3 are separate bodies, and both are installed at different positions. However, depending on the layout of the laboratory or the like, the two are considerably separated from each other. In some cases, the length of the forward air passage 22 and the return air passage 25 connecting the both may exceed 10 m. If the length of the forward air passage 22 and the return air passage 25 is long, the environmental change in the test chamber 2 may be delayed with respect to the heating and humidification of the air applied by the air conditioner 3. A similar problem may occur when the volume of the test chamber 2 is too large compared to the volume of the air conditioner 3, and the environment in the test chamber 2 against the heating and humidification of air performed in the air conditioner 3. Changes may be delayed.

  For example, when the humidity of the test chamber 2 is lower than the set humidity, the environmental test apparatus 100 feeds back the humidity of the test chamber 2 to the air conditioner 3 and humidifies the air passing through the air conditioner 3. The humidified air is sent to the test chamber 2, but when the distance between the test chamber 2 and the air conditioner 3 is large, the humidified air blown from the air conditioner 3 reaches the test chamber 2. It may take time to complete. In addition, in order for the air in the test chamber 2 to be completely replaced, the air may need to circulate several tens of times between the test chamber 2 and the air conditioner 3. The environmental change in the test chamber 2 may be delayed with respect to heating or humidification of the air.

While the air circulates between the air conditioner 3 and the test chamber 2, the environment of the test chamber 2 gradually approaches the target environment, but the air until the environment in the test chamber 2 reaches the target environment. There is a case where the inside of the air conditioner 3 on the side that heats and humidifies is greatly deviated from the original setting environment.
In particular, when the inside of the test chamber 3 is set to an environment with a higher humidity than in the atmosphere, the situation described below may occur.

FIG. 6 is a graph showing a humidity change in the test chamber 2 and a humidity change in the air conditioner 3 of the environmental test apparatus 100 according to the prior art.
The humidity (relative humidity) of the room where the environmental test apparatus 100 is placed is, for example, 40 percent. On the other hand, the set humidity is 70%, for example, which is higher than the humidity of the outside air.
When the environmental test apparatus 100 is activated under this condition, the humidity in the test chamber 2 at the start of the test and the humidity in the air conditioner 3 are 40 percent, which is the same as the outside air.
In the environmental testing apparatus 100 of the prior art, the humidity in the test chamber 2 is fed back to the air conditioner 3 and humidified with an output corresponding to the deviation between the set humidity (70 percent) and the current humidity in the test chamber 2 (40 percent). The apparatus 13 is operated, and the humidity in the air conditioner 3 is rapidly increased.

In contrast, the increase in humidity in the test chamber 2 is slow, and the humidity increases slowly in the test chamber 2.
Therefore, the test chamber 2 does not readily reach the set humidity, and the actual humidity of the test chamber 2 continues to be lower than the set humidity. Conversely, the humidity in the air conditioner 3 greatly exceeds the set humidity.
Finally, the humidity in the air conditioner 3 exceeds 100%, and the water vapor in the air in the air conditioner 3 becomes supersaturated. As a result, a large amount of condensation may occur in the air conditioner 3. If it demonstrates with the graph of FIG. 6, when t1 time passes after a driving | operation start, the humidity in the air conditioner 3 will reach 100 percent, and after that, a large amount of dew condensation may occur in the air conditioner 3.
Therefore, in the air conditioner 3, it is necessary to dehumidify the inside of the air conditioner 3, the cooling device 32 is operated, the surface temperature of the evaporator 12 is lowered, and the dehumidified air is sent to the test chamber 2.

  On the other hand, the humidity change in the test chamber 2 appears behind the humidity change in the air conditioner 3. Therefore, as shown in FIG. 6, the humidity in the test chamber 2 increases with the passage of time, reaches the set humidity at time t2, and further increases. There is a possibility that the humidity in the test chamber 2 will greatly overshoot and greatly exceed the set humidity.

As described above, in the environmental test apparatus 100 of the prior art, a large amount of condensed water may be generated from the start of operation until the humidity in the test chamber 2 falls to the set humidity. Moreover, since the environmental test apparatus 100 needs to send air to the test chamber 2 in a remote position, the air conditioner 3 may be equipped with a large blower with high generated pressure. Therefore, the negative pressure tendency in the air conditioner 3 becomes strong, and it may be difficult to discharge condensed water from the air conditioner 3.
Furthermore, in the environmental test apparatus 100 of the prior art, the humidity in the test chamber 2 may greatly overshoot, and the humidity in the test chamber 2 may finally stabilize at time t3. For this reason, the conventional environmental test apparatus 100 may take a long time from the start of operation until the humidity in the test chamber 2 falls to the set humidity. Moreover, there is dissatisfaction that the power consumption in the meantime is high.

  The present invention focuses on the above-described problems of the prior art, and an object of the present invention is to develop an environmental test apparatus that generates less condensation before the humidity in the test chamber falls to the set humidity.

  Invention of Claim 1 for solving an above-mentioned subject is a test room which installs a to-be-tested object, an air-conditioning device which has a humidity adjustment function, and blows the air in which humidity was adjusted, The test room, It has a circulation channel that circulates air between the air conditioner and the test chamber by connecting the air conditioner in a ring shape, and a test chamber side humidity sensor that detects the humidity in the test chamber. The humidity of the air discharged from the air conditioner or from the air conditioner is detected in an environmental test apparatus in which general air conditioning control is performed in which the humidity in the test room is fed back to the air conditioner and the humidity in the test room is adjusted to the set humidity. When the humidity in the air conditioning unit rises and exceeds a certain rising side threshold humidity, the air conditioning unit is controlled based on the detected humidity of the air conditioning unit side humidity sensor from the general air conditioning control. Sky to control Be switched in part priority control is an environment test apparatus according to claim.

The environmental test apparatus of the present invention can implement “general air conditioning control” and “air conditioning unit priority control” as control methods. The general air conditioning control is a control method similar to the conventional one, and is a control method for adjusting the humidity in the test chamber to the set humidity by feeding back the humidity in the test chamber detected by the test chamber side humidity sensor to the air conditioner.
On the other hand, the air conditioning unit priority control is a control method for controlling the air conditioner based on the detected humidity of the air conditioning unit side humidity sensor.
In the environmental test apparatus of the present invention, when the humidity in the air conditioner rises and becomes equal to or higher than a certain rising threshold humidity, the general air conditioning control is switched to the air conditioning unit priority control. Therefore, the air in the air conditioner is prevented from reaching a water vapor supersaturated state, and condensation in the air conditioner is reduced.

  The invention according to claim 2 is characterized in that when the humidity in the air conditioner drops and becomes equal to or lower than a certain lowering threshold humidity, the air conditioning unit priority control returns to the general air conditioning control. Item 2. The environmental test device according to Item 1.

  According to the present invention, when there is no longer a concern that the air conditioner is in a water vapor supersaturated state, the control returns to the normal general air conditioning control.

  The invention according to claim 3 is capable of setting the wind speed in the test chamber, the rising side threshold humidity and / or the falling side threshold humidity is changed according to the set wind speed, and when the set wind speed is slow, The environmental test apparatus according to claim 1, wherein the rising-side threshold humidity and / or the falling-side threshold humidity is lower than when the set wind speed is high.

The delay in the environmental change in the test chamber correlates with the wind speed in the test chamber. When the wind speed in the test chamber is slow, the delay in the environmental change is large. When the wind speed in the test chamber is high, the delay in the environmental change is small. .
That is, the delay in the environmental change in the test chamber correlates with the time during which the air in the test chamber is replaced. The time for which the air in the test chamber is replaced correlates with the amount of air introduced from the air conditioner into the test chamber, and the air amount further correlates with the wind speed in the test chamber.
The present invention pays attention to this correlation, and when there is a high possibility that the delay of the environmental change in the test chamber becomes large, the rising-side threshold humidity is set to a low humidity.

  The invention described in claim 4 has air blowing information detecting means for detecting information related to the air blowing environment in the test chamber, and is easily replaced when the air blowing environment in the test chamber is an environment in which the air in the test chamber is difficult to be replaced. 4. The environmental test apparatus according to claim 1, wherein the rising-side threshold humidity and / or the falling-side threshold humidity is lower than the case.

  Also in the present invention, when there is a high possibility that the delay in the environmental change in the test chamber is large, the rising threshold humidity is set to a low humidity.

  According to a fifth aspect of the present invention, the rising-side threshold humidity and / or the falling-side threshold humidity is changed according to the amount of air sent from the air conditioner to the test chamber and / or the amount of air introduced into the test chamber, 5. The environmental test apparatus according to claim 1, wherein when the air volume is small, the rising-side threshold humidity and / or the falling-side threshold humidity is lower than when the air volume is large. is there.

  Also in the present invention, when there is a high possibility that the delay in the environmental change in the test chamber is large, the rising threshold humidity is set to a low humidity.

  According to the sixth aspect of the present invention, the rising threshold humidity and / or the falling threshold humidity is changed according to the response delay to the humidity change of the air discharged from the air conditioner of the humidity change in the test chamber, and the response delay is large. 6. The environmental test apparatus according to claim 1, wherein the rising threshold humidity and / or the falling threshold humidity is lower than when the response delay is small.

  Also in the present invention, when there is a high possibility that the delay in the environmental change in the test chamber is large, the rising threshold humidity is set to a low humidity.

  An invention of an air conditioner that solves the same problem is an air conditioner that has a humidity adjustment function and blows air with adjusted humidity, and is connected to a space in which humidity is to be adjusted, and the humidity in the space is controlled. In an air conditioning apparatus that performs general air conditioning control that feeds back and adjusts the humidity in the space to a set humidity, it has an air conditioning unit-side humidity sensor that detects the humidity of air discharged from the air conditioning apparatus or the air conditioning apparatus, and When the humidity in the device rises and exceeds a certain rising threshold humidity, the general air conditioning control can be switched to the air conditioning unit priority control that controls the air conditioning device based on the detected humidity of the air conditioning unit side humidity sensor. It is characterized by.

  The air conditioner employed in the present invention is connected to a space such as a test room and adjusts the humidity of the space. And when the humidity in an air conditioner rises and becomes more than a fixed rising threshold humidity, it is switched from general air conditioning control to air conditioning unit priority control. Therefore, the air in the air conditioner is prevented from reaching a water vapor supersaturated state, and condensation in the air conditioner is reduced.

According to the present invention, condensation that occurs before the humidity in the test chamber falls to the set humidity is reduced.

It is a principle figure of the environmental test apparatus of embodiment of this invention. It is the graph which compared the humidity change in the test chamber of the environmental test apparatus of FIG. 1, and the humidity change in an air conditioner. It is a graph which shows the relationship between the wind speed in a test chamber, and the delay of a humidity change. It is a principle figure of the environmental test apparatus of other embodiment of this invention. It is a principle figure of the environmental test apparatus of a prior art. It is the graph which compared the humidity change in the test chamber of the environmental test apparatus of a prior art, and the humidity change in an air conditioner.

Embodiments of the present invention will be further described below.
The main components of the environmental test apparatus 1 of this embodiment are substantially the same as those of the environmental test apparatus 100 of the prior art. The same members as those in the prior art are denoted by the same reference numerals. Also in this embodiment, the test chamber 2 and the air conditioner 3 are separate bodies, and both are connected by the circulation flow path 5. The circulation channel 5 is a duct and has a length of 10 m or more. The blower 16 employed in the present embodiment desirably generates a considerable air volume and pressure, and for example, a fan that can generate a static pressure of 1000 pa or more, preferably about 2000 pa is recommended.

The difference between the environmental test apparatus 1 of this embodiment and the environmental test apparatus 100 of the prior art is that the air conditioner 3 is also provided with a temperature sensor 40 and a humidity sensor 41.
In the environmental test apparatus 1 of the present embodiment, since the temperature sensor 30 and the humidity sensor 31 are also provided in the test chamber 2 as in the prior art, the sensors in the test chamber 2 are connected to the test chamber side in order to distinguish between them. The temperature sensor 30 and the test chamber side humidity sensor 31 are referred to, and the sensors in the air conditioner 3 are referred to as the air conditioner side temperature sensor 40 and the air conditioner side humidity sensor 41.

The environmental test apparatus 1 of the present embodiment is different from the prior art in the control method for adjusting the humidity of the test chamber 2. This will be described below.
That is, the environmental test apparatus 1 of the present embodiment includes general air conditioning control and air conditioning unit priority control as the control method of the air conditioning equipment 18, and both are automatically switched when specific conditions are met.

Here, the general air conditioning control is a control method similar to the conventional one, and feeds back the detection signal of the test room side humidity sensor 31 provided in the test room 2 to the air conditioner 18 of the air conditioner 3. In the general air conditioning control, the humidifier 13 and the cooling device 32 in the air conditioner 18 are operated so that the humidity in the test chamber 2 becomes the set humidity.
On the other hand, the air conditioning unit priority control is a control method in which the detection signal of the air conditioning unit side humidity sensor 41 provided in the air conditioner 3 is fed back to the air conditioning equipment 18. In the air conditioning unit priority control, the humidifier 13 and the cooling device 32 in the air conditioner 18 are operated so that the humidity of the air blown from the air conditioner 3 becomes the set humidity.

In this embodiment, when the humidity in the test chamber 2 is low, general air conditioning control is performed, and the humidity in the test chamber 2 is high, and there is a concern that a large amount of dew condensation may occur when the humidity rises as it is. The air conditioning unit priority control is performed.
That is, when the humidity in the test chamber 2 before the start of the test is lower than the set humidity, the air conditioner 3 is controlled in general air conditioning, and the humidifier 13 of the air conditioner 3 is operated to increase the humidity in the test chamber 2. . At the stage of general air conditioning control, the detection signal of the test chamber side humidity sensor 31 provided in the test chamber 2 is fed back to the air conditioner 18 and inside the air conditioner 3 (strictly, near the air supply port 20 of the air conditioner 3). Humidity rises. That is, the air in the air conditioner 3 is humidified by the humidifier 13 so that the humidity in the test chamber 2 becomes the set humidity. In this embodiment, the humidity in the air conditioner 3 at that time is monitored by the air conditioning unit side humidity sensor 41.

When the humidity in the air conditioner 3 continues to rise, and the detected humidity of the air conditioning unit side humidity sensor 41 becomes equal to or higher than a certain rising threshold humidity A1, the control method changes from the general air conditioning control to the air conditioning unit. Switch to priority control. Thereafter, the detection signal of the air conditioning unit side humidity sensor 41 is fed back to the air conditioner 18, and the humidifier 13 is operated so that the humidity in the air conditioner 3 becomes the set humidity.
As a result, the humidity in the air conditioner 18 gradually decreases. When the detected humidity becomes equal to or lower than the certain lowering threshold humidity A2 and leaves the dangerous water area where condensation occurs, the control method is returned from the air conditioning unit priority control to the original general air conditioning control.

Next, the rising side threshold humidity A1 and the falling side threshold humidity A2 will be described.
In the present embodiment, when the humidity in the air conditioner 3 tends to increase, and the humidity in the air conditioner 3 becomes equal to or higher than the rising threshold humidity A1, the control method is automatically switched from the general air conditioning control to the air conditioning unit priority control. Further, if the humidity in the air conditioner 3 tends to decrease and the humidity in the air conditioner 3 becomes lower than the lower threshold humidity A2, the control method is automatically returned from the air conditioning unit priority control to the general air conditioning control.

The rising-side threshold humidity A1 is a humidity in anticipation of an overshoot of humidity, and there is a concern that if the humidity continues to increase beyond this, the temperature may reach a temperature region where a large amount of condensation occurs.
In the present embodiment, the rising side threshold humidity A1 is automatically changed according to a response delay to the humidity change of the air discharged from the air conditioner 3 of the humidity change in the test chamber 2.
In this embodiment, the magnitude of the response delay is predicted according to the wind speed of the test chamber 2, and the predicted value is stored in a control device (not shown).
That is, the relationship between the wind speed in the test chamber 2 and the humidity delay is as shown in the graph of FIG. 3, where the delay is small when the wind speed is fast, and the delay is large when the wind speed is slow.

  Here, the vertical axis of the graph of FIG. 3 is the difference between the humidity in the test chamber 2 and the humidity in the air conditioner 3 after a certain period of time has elapsed since the start of the test when the air conditioner 3 is controlled in general air conditioning. Is “relative humidity (percent)”.

In the present embodiment, the humidity delay amount (relative humidity (percentage)) expected from the set wind speed is determined based on the graph of FIG. 3, and the value obtained by subtracting the delay amount from 100% humidity at which condensation occurs is increased. The side threshold humidity A1 is set.
For example, if the humidity delay amount determined from the set wind speed is 20%, a value obtained by subtracting the delay amount (20%) from 100% (relative humidity 80%) is the rising threshold humidity A1. Then, an increase in humidity in the air conditioner 3 is monitored by the air conditioning unit side humidity sensor 41, and if the relative humidity in the air conditioner 3 becomes 80% or more, the control method is switched from the general air conditioning control to the air conditioning unit priority control.

  The lowering threshold humidity A2 serving as a reference for returning the control method is the same as or close to the increasing threshold humidity A1. In the present embodiment, the lower threshold humidity A2 is somewhat lower than the upper threshold humidity A1. For example, the humidity obtained by subtracting a certain value (for example, 5%) from the rising threshold humidity A1 is the falling threshold humidity A2. If applied to the above-described example, the lower-side threshold humidity A2 is 75% relative humidity. If the relative humidity in the air conditioner 3 is 75% or less, the control method is switched from the air conditioning unit priority control to the general air conditioning control.

Next, the behavior of the humidity in the test chamber 2 of the environmental test apparatus 1 and the humidity in the air conditioner 3 will be described with reference to FIG.
It is assumed that the humidity (relative humidity) of the room where the environmental test apparatus 1 is placed is, for example, 20 percent. On the other hand, assuming that the set humidity (relative humidity) is, for example, 50%, the set humidity is higher than the humidity of the outside air.
When the environmental test apparatus 1 is started under this condition, the relative humidity in the test chamber 2 and the relative humidity in the air conditioner 3 at the start of the test are 20 percent, which is the same as the outside air.
Also in the environmental test apparatus 1 of the present embodiment, the air conditioner 3 is subjected to general air conditioning control in the initial operation. Specifically, the humidity in the test chamber 2 is monitored by the test chamber side humidity sensor 31, and the detected value of the test chamber side humidity sensor 31 is fed back to the air conditioner 3, so that the set humidity (50 percent) and the current test chamber 2 The humidifier 13 is operated with an output corresponding to the deviation of the humidity (20 percent) in the inside, and the humidity in the air conditioner 3 rises rapidly.
In contrast, the increase in humidity in the test chamber 2 is slow, and the humidity increases slowly in the test chamber 2.

The humidity in the air conditioner 3 exceeds the set humidity (50%) when the time T1 has elapsed, and the humidity in the air conditioner 3 continues to increase. On the other hand, the humidity in the test chamber 2 is less than the set humidity.
The humidity in the air conditioner 3 continues to rise, and reaches the rising threshold humidity A1 (80%) when the time T2 has elapsed. As a result, the control method of the air conditioner 3 is switched from the general air conditioning control to the air conditioning unit priority control. Specifically, the detected value of the air conditioning unit side humidity sensor 41 provided in the air conditioner 3 is fed back to the air conditioner 18 so that the humidity in the air conditioner 18 is controlled to be the set humidity (50%). At the stage of switching from the general air conditioning control to the air conditioning unit priority control, the humidity in the air conditioning device 18 detected by the air conditioning unit side humidity sensor 41 has already exceeded the set humidity, so the humidifier 13 is stopped or weak. Operated with output.

As a result, as shown in the graph of FIG. 2, the humidity increase in the air conditioner 3 slows down, and when the time further elapses, the humidity in the air conditioner 3 tends to decrease. That is, the humidity in the air conditioner 3 decreases toward the set humidity. Therefore, the humidity in the air conditioner 3 does not reach 100%, and the water vapor is not supersaturated. Therefore, excessive condensation does not occur in the air conditioner 3.
After the time T3, the humidity in the air conditioner 3 becomes equal to or lower than the lower threshold humidity A2. As a result, the control method of the air conditioner 3 returns from the air conditioning unit priority control to the general air conditioning control.

On the other hand, while the air conditioner 3 is controlled by the air-conditioning unit priority control, the humidity in the test chamber 2 is gradually decreasing, but air exceeding the set humidity is continuously supplied from the air conditioner 3 to the test chamber 2. ing. Therefore, the humidity in the test chamber 2 still maintains an upward trend while the air conditioner 3 is operated with the air conditioning unit priority control, and the control method of the air conditioner 3 has returned from the air conditioning unit priority control to the general air conditioning control. In some cases, the humidity in the test chamber 2 is close to the set humidity.
When the control method of the air conditioner 3 returns from the air conditioning unit priority control to the general air conditioning control, the detected value of the test chamber side humidity sensor 31 is fed back to the air conditioner 3 as usual, but as described above, the humidity in the test chamber 2 Since the humidity is close to the set humidity, the deviation between the set humidity (50 percent) and the current humidity in the test chamber 2 (20 percent) is small, and the humidifier 13 is stopped or operated with a weak output. Is done.

As described above, in the environmental test apparatus 1 of the present embodiment, the control method is switched to the air conditioning unit priority control before the humidity in the air conditioner 3 becomes excessively high, and the humidity in the air conditioner 3 changes toward the set humidity. To do. Therefore, before the water vapor in the air conditioner 3 becomes supersaturated, the humidity in the air conditioner 3 can be lowered, and the occurrence of condensation is small.
Even if the air conditioner 3 is controlled by the air conditioning unit priority control, the humidity in the test chamber 2 approaches the set humidity, so there is little concern that the time for the test chamber 2 to reach the set humidity will be longer than before. . Furthermore, the amount of humidity overshoot in the test chamber 2 can be reduced.
Therefore, the environmental test apparatus 1 of the present embodiment can shorten the time required for the test chamber 2 to reach the set humidity, and also consumes less power.

In the embodiment described above, the configuration in which the wind speed in the test chamber 2 is changed by simply controlling the rotational speed of the blower 16 is used. However, the damper is used to control the opening degree of the damper to control the opening in the test chamber 2. The wind speed may be controlled. Moreover, both the opening degree of a damper and the rotation speed of the air blower 16 may be controlled.
The environmental test apparatus 50 of FIG. 4 is provided with a bypass flow path 51 in the middle of the circulation flow path 5 and further provided with a circulation opening degree adjusting means (damper) 52 closer to the test chamber 2 than the bypass flow path 51. . The bypass passage 51 is provided with a bypass opening adjusting means (damper) 54. In the environmental test apparatus 50, there is also a circulation opening degree adjusting means (damper) 53 on the return side air passage 25, which is closer to the test chamber 2 than the bypass passage 51.
Also in the environmental test apparatus 50 of the present embodiment, the wind speed in the test chamber 2 can be set. Then, the rising side threshold humidity and the falling side threshold humidity are determined according to the set wind speed.

In the above description, it is assumed that there is a considerable distance between the test chamber 2 and the air conditioner 3, but the distance between the test chamber 2 and the air conditioner 3 is not limited, and both are installed adjacent to each other. May be.
For example, when the volume of the test chamber 2 is large and the volume of the air conditioner 3 is small, a large amount of dew condensation may occur in the air conditioner 3 according to the configuration of the prior art, and the present invention can be adopted as a countermeasure.

In the embodiment described above, the rising-side threshold humidity A1 and the falling-side threshold humidity A2 are determined according to the set wind speed. However, the rising-side threshold humidity A1 and the falling-side threshold humidity A2 are determined according to the air volume supplied to the test chamber 2. May be determined.
For example, the rising side threshold humidity A1 and the falling side threshold humidity A2 may be determined according to the amount of air blown by the blower 16 and the opening of the damper.

In the embodiment described above, the rising side threshold humidity A1 and the falling side threshold humidity A2 are determined based on the set wind speed. However, the rising side threshold humidity A1 and the falling side threshold humidity A2 are determined using measured values such as wind speed. May be.
For example, a wind speed sensor 8 or a sensor for detecting the air volume is adopted as the air blowing information detecting means for detecting information related to the air blowing environment of the test chamber 2, and the rising side threshold humidity A1 and the lowering side are selected according to the air blowing environment in the test chamber 2. The threshold humidity A2 may be determined.
And when it is the environment where the air in the test chamber 2 is hard to be replaced, the rising side threshold humidity and the falling side threshold humidity are set lower than in the case where the air is easily replaced.

  The air conditioning unit side humidity sensor 41 is sufficient if it can substantially measure the humidity in the air conditioner 3, and may be provided, for example, in the outgoing air passage 22.

  The blower 16 employed in the embodiment described above is inverter-controlled, can change the number of rotations, and the amount of blown air is variable. However, the present invention is not limited to this configuration, and it may not be possible to change the air flow rate.

The air conditioner 3 described in the embodiment may be sold alone. In that case, the humidity of the space such as the test chamber 2 is adjusted by a control device (not shown) attached to the air conditioner 3. Therefore, it is desirable that the air conditioner 3 includes a sensor signal input terminal for inputting a signal from an external humidity sensor.
For example, when the air conditioner 3 is connected to an existing test room, the signal of the test room side humidity sensor 31 attached to the existing test room is connected to the sensor signal input terminal.

1.50 Environmental test device 2 Test chamber 3 Air conditioning device 5 Circulating flow path 8 Wind speed sensor (fan information detection means)
DESCRIPTION OF SYMBOLS 12 Evaporator 13 Humidifier 15 Heater 16 Blower 18 Air conditioner 32 Cooling device 22 Outgoing side air passage 25 Return side air passage 30 Test room side temperature sensor 31 Test room side humidity sensor 40 Air conditioner side temperature sensor 41 Air conditioner side humidity sensor