JP5402136B2 - Weather resistance test equipment - Google Patents

Description

  The present invention relates to a weather resistance test apparatus that performs a weather resistance test by irradiating a sample with light.

  2. Description of the Related Art Conventionally, a test apparatus that tests a weather resistance by placing a sample in a test tank in which a light source is arranged and irradiating ultraviolet rays is known. Such a test apparatus includes a blower that circulates the air inside the test chamber, a heater that heats the air inside the test chamber, and a cooler that cools the sample. The temperature and humidity are kept at the conditions set as test conditions (see, for example, Patent Document 1).

JP 2005-181028 A

In the conventional test apparatus described above, the temperature inside the test chamber is adjusted by a heater and a cooler, while the detected temperature of the black temperature detector used as an indicator of the sample surface temperature depends on the temperature inside the test chamber and the speed of the blower. Therefore, there is a problem that it takes time to stabilize both the temperature detected by the black temperature detector and the temperature in the test chamber at the set temperature.
The present invention has been made in view of the above-described circumstances, and provides a weather resistance test apparatus that can quickly adjust both the detection temperature of the black temperature detector and the temperature in the test tank in accordance with the set conditions. The purpose is to provide.

In order to achieve the above object, the present invention provides a sample temperature detector for detecting a temperature in the test chamber by disposing a sample and a black temperature detector in a test chamber having a light source, and the test chamber. A weather resistance test apparatus comprising: a blower that circulates and blows air of air; and a cooler and heater that adjusts the temperature of air blown by the blower, wherein the operation state of the cooler and the heater and the blower a control unit for controlling the rotational speed, the control unit, from the start of lighting the light source until a predetermined time elapses, the condenser and state Chi coercive stopping the said heater, said black said blower higher rotational speed than the rotational speed used to stabilize the temperature detected by the temperature detector to a target temperature, or maintained at the maximum rotational speed and blowing, after the predetermined time has elapsed, the rotational speed of the blower While lifting, based on the detected temperature of the tank temperature detector controls the cooler and the heater, to stabilize the detected temperature of the tank temperature sensor to a target temperature, the condenser and the control of the heater the detected temperature of the tank temperature sensor in a state that is stabilized at the target temperature, the detected temperature of the black temperature detector controls the rotational speed of the blower to be stable at the target temperature by, then weathering Until the end of the control, the control of the cooler and the heater based on the detection temperature of the in-tank temperature detector, and the control of the rotational speed of the blower based on the detection temperature of the black temperature detector, It is characterized in that the stability of the detected temperature of the in- tank temperature detector and the detected temperature of the black temperature detector is maintained .

  Further, the present invention provides the weather resistance test apparatus, wherein the cooler and the heater are arranged in an air passage for blowing air sucked from the upper part of the test tank to the lower part of the test tank by the blower, and A wind direction plate is provided to guide the air to be blown toward the black temperature detector.

  According to the present invention, after the lighting of the light source is started in the weather resistance test apparatus, the temperature in the test tank in which the sample is placed and the detection temperature of the black temperature detector representing the sample surface temperature are quickly adjusted. Can be stabilized in the target temperature range.

It is a partially broken front view which shows the structure of the weather resistance test apparatus which concerns on embodiment. It is a sectional side view which shows the structure of a weather resistance test apparatus. It is a flowchart which shows operation | movement of a weather resistance test apparatus. It is a graph which shows the operation example of a weather resistance test apparatus. It is a graph which shows the operation example of a weather resistance test apparatus.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a front view showing a configuration of a weather resistance test apparatus 1 according to an embodiment to which the present invention is applied, and shows an internal configuration excluding a part of the front surface of a housing 10. FIG. 2 is a side sectional view of the weather resistance test apparatus 1 as seen from the left side.
As shown in FIGS. 1 and 2, the weather resistance test apparatus 1 is provided with a test tank 3 in a substantially box-shaped housing 10, and a sample 4 is accommodated in the test tank 3 to perform a weather resistance test. It is. A sample 4 to be tested by the weather resistance test apparatus 1 is a synthetic resin plate or a plate-like object to be coated and is preliminarily adjusted to a predetermined size.

A box-shaped test tank 3 is disposed at the top of the weather resistance test apparatus 1. The test chamber 3 includes a sample chamber 30 that accommodates the sample 4, an upper chamber 31 that is positioned above the sample chamber 30, and a lower chamber 32 that is positioned below the sample chamber 30 by two partition plates 33 and 34. It is divided into.
In the center of the sample chamber 30, a xenon lamp (xenon arc lamp) 40 as an ultraviolet light source for testing is fixed and installed vertically. The xenon lamp 40 is provided with a lamp jacket 41 provided with a cooling water channel through which cooling water flows and a filter (not shown) that allows light in a specific wavelength range to pass around the light emitting unit.
A sample holder 35 is disposed in the sample chamber 30 so as to surround the xenon lamp 40. As shown in FIG. 2, the sample holder 35 is a frame that supports the plurality of samples 4 so as to face the xenon lamp 40, and is configured to surround the xenon lamp 40 from the side and from above and below. The sample 4 is arranged inside the. Each sample 4 is attached to the sample holder 35 such that the surface to be exposed to light in the weather resistance test faces inward, and the surface is irradiated with light from the xenon lamp 40.
The sample holder 35 is supported by a rotating drum 36. The rotating drum 36 is rotatably supported by a rotation support part 37 installed below the test chamber 3, and the power of a motor (not shown) is transmitted to the rotation support part 37. The power of the motor rotates the sample holder 35. The drum 36 integrally rotates around the xenon lamp 40.

  As shown in FIG. 1, an equipment room is provided in the lower part of the weather resistance test apparatus 1, and a cooling water tank 43 and a heat exchange unit 44 are arranged in the equipment room. The cooling water tank 43 stores water used as cooling water for the xenon lamp 40, and the cooling water circuit that circulates the cooling water is supplied with water from the cooling water tank 43 as necessary. . Further, the heat exchange unit 44 cools the cooling water flowing through the lamp jacket 41. The heat exchange unit 44 includes, for example, a heat exchanger that is connected to a refrigerator provided inside or outside the weather resistance test apparatus 1 and that exchanges heat between the refrigerant or brine flowing from the refrigerator and the cooling water. ing.

  Further, as shown in FIG. 2, behind the test tank 3, each of a blower fan 50 (blower), a heater 52, a cooler 53, and a humidifier 57 for adjusting the temperature and humidity in the test tank 3. Equipment is installed. The cooler 53 is connected to a refrigerator 54 installed below the test tank 3 and includes a heat exchanger that evaporates the refrigerant supplied from the refrigerator 54 and cools the air. The refrigerator 54 is disposed in the lower part of the weather resistance test apparatus 1, and compresses the refrigerant (not shown), a water-cooled heat exchanger (not shown) that condenses the compressed high-pressure refrigerant, and the condensed refrigerant. A pressure reducing valve for reducing the pressure and supplying the same to the cooler 53 is provided.

The blower fan 50 sucks air from the upper chamber 31 of the test chamber 3 and blows it to the lower chamber 32 to circulate the air in the test chamber 3. The blower fan 50 is installed at the rear of the test chamber 3 and has a horizontal air passage 59 extending from the upper chamber 31 to the blower fan 50, a vertical air passage 51 through which air blown downward by the blower fan 50 passes, An air passage extending substantially horizontally from the lower portion of the passage 51 to the lower chamber 32 is provided.
The heater 52 and the cooler 53 are arranged inside the air passage 51, and the air blown out by the blower fan 50 is heated by the heater 52 or cooled by the cooler 53 and sent out to the lower chamber 32. The blower fan 50, the heater 52, and the cooler 53 adjust the internal temperature (internal temperature) of the test chamber 3 by heating and cooling while circulating the air in the test chamber 3.

As shown in FIG. 2, ventilation holes are formed around the rotation support portion 37 in the partition plate 34 that partitions the lower chamber 32 and the sample chamber 30. The air blown by the blower fan 50 flows into the sample chamber 30 from below the sample holder 35 through the ventilation holes provided in the partition plate 34 as indicated by arrows in the drawing. Here, an inverted conical wind direction plate 38 that disperses the wind flowing from the lower chamber 32 is disposed below the sample holder 35, so that the wind uniformly hits each sample 4 fixed to the sample holder 35. ing.
A ventilation hole of the partition plate 33 that partitions the sample chamber 30 and the upper chamber 31 is located immediately above the sample holder 35, and air in the sample chamber 30 is sucked out to the upper chamber 31 through this ventilation hole. Then, the air is sucked into the blower fan 50 through the air passage 59. In this way, the air in the test chamber 3 is largely circulated and sent by the blower fan 50.

Further, the humidifier 57 adjusts the humidity of the sample chamber 30 by heating the humidifying water stored therein by the humidifying heater 58. Between the sample chamber 30 and the humidifier 57, a suction air passage of a different system from the air passage 59 is provided, and the humidifier 57 is supplied to the air sucked from the suction air passage of this different system by a humidifying heater 58. The generated water vapor is mixed and sent to the sample chamber 30 to adjust the humidity in the sample chamber 30.
Further, as shown in FIG. 2, an injection unit 39 for injecting water toward the sample holder 35 is disposed between the xenon lamp 40 and the sample holder 35. It is possible to inject water onto the surface on the xenon lamp 40 side.

In addition, the weather resistance test apparatus 1 includes a black standard temperature measuring body 21 (black temperature detector), an ultraviolet radiation intensity detector 22, and a bath temperature detector 23.
The black standard temperature sensor 21 serving as an index of the sample surface temperature is installed together with the sample 4 on the sample holder 35 (the upper portion of the sample holder 35 in the example of FIG. 2) with the black panel portion facing the xenon lamp 40. The black standard temperature detector 21 is attached to a part of the space for attaching the sample 4 in the sample holder 35, and the sample 4 is not arranged at the attachment position of the black standard temperature detector 21.
Further, the ultraviolet radiation intensity detector 22 for measuring the ultraviolet radiation intensity from the xenon lamp 40 is suspended from the xenon lamp 40 at a predetermined distance inside the sample holder 35.
Further, the in-tank temperature detector 23 for detecting the temperature inside the sample chamber 30 is provided in the vicinity of the entrance of the air passage 59 through which the blower fan 50 sucks air from the upper chamber 31. The tank temperature detector 23 is specifically configured as a temperature / humidity converter, and detects the temperature and humidity of the air sucked from the air passage 59. The temperature and humidity detected by the bath temperature detector 23 can be used for adjusting the bath temperature by the heater 52 and the cooler 53 and for adjusting the humidity by the humidifier 57.
The in-tank temperature detector 23 only needs to be able to detect the in-tank temperature of the test tank 3, and the in-tank temperature detector 23 may be configured with a simple temperature sensor. In this case, a humidity sensor that can be used for humidity control by the humidifier 57 may be provided separately.

  As shown in FIG. 1, a door 13 of a sample chamber 30 is provided on the front surface of the weather resistance test apparatus 1 so that the sample 4 can be set in the sample chamber 30 from the front surface. An operation panel 14 having a touch panel 15 is provided on the front surface at a position aligned with the door 13. The touch panel 15 has a display screen for displaying various information related to the operating state of the weather resistance test apparatus 1 and an operation screen, and has a function of detecting a contact operation on the display screen. And inside the housing | casing 10, the control part 20 is accommodated in the position corresponding to the operation panel 14. FIG.

Above the control unit 20, a ballast 42 that incorporates a transformer, a choke, and the like and lights the xenon lamp 40 is disposed. The ballast 42 is connected to the control unit 20 and turns on and off the xenon lamp 40 according to the control of the control unit 20.
Further, the control unit 20 controls a pump (not shown) and a heat exchange unit 44 provided in a cooling water circuit for circulating the cooling water through the lamp jacket 41, and timing in accordance with lighting and extinguishing of the xenon lamp 40. Then, the pump is driven and stopped, and the heat exchange unit 44 is driven and stopped so that the temperature of the cooling water is kept below a predetermined temperature.

The control unit 20 controls a motor (not shown) that rotates the rotating drum 36, and rotates and stops the motor at a timing that matches the lighting and extinction of the xenon lamp 40. The control unit 20 is connected to a black standard temperature measuring body 21, an ultraviolet radiation intensity detector 22, and a bath temperature detector 23. The black standard temperature measuring element 21 detects the temperature of the black panel according to the control of the control unit 20 and outputs information indicating the detected temperature (black standard temperature: BST temperature) to the control unit 20. Further, the ultraviolet radiation intensity detector 22 detects the received light intensity of ultraviolet rays according to the control of the control unit 20, and outputs information indicating the detection amount to the control unit 20. The bath temperature detector 23 detects the temperature and humidity of the air flowing into the air passage 59 according to the control of the control unit 20 (that is, the bath temperature and the bath humidity of the test bath 3), and the detected temperature and humidity are detected. The information shown is output to the control unit 20. The control unit 20 acquires and stores the black standard temperature input from the black standard temperature sensor 21 and the detection amount of the ultraviolet radiation intensity detector 22, and the tank temperature and the tank detected by the tank temperature detector 23. Acquire and store the internal humidity.
The control unit 20 is connected to the blower fan 50, the heater 52, the cooler 53, the refrigerator 54, and the humidifying heater 58, and controls each of these units.

  That is, the control unit 20 controls the rotation speed (the number of rotations) of the blower fan 50 so that the black standard temperature falls within a preset temperature range. Specifically, when the black standard temperature exceeds the set temperature range, the rotational speed of the blower fan 50 is increased. As a result, the amount of air blown to each part of the sample holder 35 including the black standard temperature sensor 21 is increased, the heat generated by the irradiation of the xenon lamp 40 is radiated, and the detected temperature of the black standard temperature sensor 21 is lowered. When the black standard temperature falls below the set temperature range, the rotational speed of the blower fan 50 is reduced.

Further, the control unit 20 controls the operating states of the heater 52 and the cooler 53 based on the in-tank temperature detected by the in-tank temperature detector 23.
Here, the control of the operating state of the heater 52, that is, the control of heating, is performed by turning on / off the energization of the heater 52. The control of the operating state of the cooler 53, that is, the control of the cooling is performed by, for example, opening and closing of a valve provided in a refrigerant pipe for supplying a refrigerant from the refrigerator 54 to the cooler 53 and / or a compressor provided in the refrigerator 54 This is done by controlling the operation. When the refrigerator 54 is a variable output type refrigerator, the controller 20 may control the increase / decrease in the output of the refrigerator 54.
The controller 20 heats the air passing through the air passage 51 with the heater 52 so that the temperature in the tank falls within a preset temperature range, or operates the cooler 53 and the refrigerator 54 to cause the air to flow. Allow to cool.
Furthermore, the control unit 20 switches on / off the humidifying heater 58 so that the in-tank humidity detected by the in-tank temperature detector 23 falls within a preset humidity range.
The control unit 20 includes a non-volatile storage unit (not shown) configured using a magnetic recording medium or a semiconductor storage device. The rotation speed of the blower fan 50 set in advance and xenon are set in the non-volatile storage unit. Stores various data such as the target temperature of the bath temperature detected by the bath temperature detector 23, the target temperature of the black standard temperature detected by the black standard temperature measuring body 21 for a predetermined time after the lamp 40 is turned on. Yes. These data may be input by operating the touch panel 15, for example.

Next, the operation of the weather resistance test apparatus 1 will be described.
FIG. 3 is a flowchart showing the operation when the weather resistance test is performed by the weather resistance test apparatus 1.
First, the control unit 20 sets the rotation speed of the blower fan 50 to a preset speed, stops the heater 52 and the cooler 53, turns on the xenon lamp 40, and starts a weather resistance test (step S1). S1). In this step S1, control such as operating a pump (not shown) to flow cooling water through the lamp jacket 41 prior to lighting of the xenon lamp 40 is also performed.
The rotational speed (preset speed) of the blower fan 50 set in step S1 is, for example, the maximum speed in the rated operating speed range of the blower fan 50.

Subsequently, the control unit 20 continuously rotates the blower fan 50 at a set speed from the start of lighting of the xenon lamp 40 until a predetermined time set in advance (step S2). If it passes (step S2; Yes), control of the temperature in a tank will be started (step S3).
In step S3, the control unit 20 controls heating and cooling of the air in the air passage 51 so that the temperature in the tank falls within a preset target temperature range.

Specifically, when the temperature inside the tank is lower than the target temperature as shown in the following formula (1), the control unit 20 switches on the heater 52 to perform heating, and the inside of the tank as shown in the following formula (2) When the temperature is within the range of the target temperature to the target temperature + 1 ° C., neither heating by the heater 52 nor cooling by the cooler 53 is performed, and the bath temperature exceeds the target temperature + 1 ° C. as shown in the following formula (3). In the case of cooling, cooling by the cooler 53 is performed.
Tank temperature <target temperature (1)
Target temperature ≤ temperature in the tank ≤ target temperature + 1 ° C (2)
Target temperature + 1 ° C <In-tank temperature (3)
Here, if the weather resistance test apparatus 1 includes a plurality of heaters 52 and coolers 53, the control unit 20 is based on the temperature difference between the temperature detected by the in-tank temperature detector 23 and the target temperature. Control for changing the number of heaters 52 and coolers 53 to be used may be performed.

The control unit 20 continues to control the temperature in the tank until the temperature in the tank reaches the target temperature range (step S4). When the temperature in the tank reaches the target temperature range (step S4; Yes), the blower fan 50 is controlled. Is set (step S5), and the rotation speed control of the blower fan 50 based on the black standard temperature is started (step S6).
In the rotation speed control in step S6, the control unit 20 changes the rotation speed of the blower fan 50 so that the black standard temperature falls within a preset target temperature range. Specifically, the control unit 20 reduces the rotational speed of the blower fan 50 when the black standard temperature is lower than the target temperature by 2 ° C. as shown in the following formula (4), and the following formula (5) When the black standard temperature is within the range of the target temperature ± 2 ° C. (target temperature range), the rotation speed of the blower fan 50 is maintained, and the black standard temperature is 2 from the target temperature as shown in the following formula (6). When the temperature is higher than ° C., the rotational speed of the blower fan 50 is increased. The rotation speed of the blower fan 50 is changed, for example, in units of 5 Hz (5 rotations / second).
Black standard temperature <target temperature -2 ° C (4)
Target temperature-2 ° C. ≦ Black standard temperature ≦ Target temperature + 2 ° C. (5)
Target temperature + 2 ° C <Black standard temperature (6)

In step S4, not only when the in-tank temperature detected by the in-tank temperature detector 23 reaches the target temperature range, for example, when the temperature within the target temperature range is maintained for a set time. Alternatively, it may be determined that the temperature in the tank is stable, and the process may proceed to step S5.
By the operation of the above steps S1 to S6, the temperature inside the tank reaches the target temperature range and stabilizes from the start of lighting of the xenon lamp 40, and then the black standard temperature stabilizes within the target temperature range. The weather resistance test can be performed while maintaining
Thereafter, the control unit 20 continues the control of the heater 52 and the cooler 53 based on the temperature inside the tank and the rotational speed control of the blower fan 50 based on the black standard temperature until the weather resistance test is completed (step S7). .

  4 and 5 are tables showing an example of the operation of the weather resistance test apparatus 1. The example shown in FIG. 4 is an operation example at the beginning of the life of the xenon lamp 40, and the example shown in FIG. 5 is an operation example at the end of the life of the xenon lamp 40. 4 and 5 show the black standard temperature (a) detected by the black standard temperature sensor 21, the tank temperature (b) detected by the tank temperature detector 23, and the rotation speed (c) of the blower fan 50. ). Here, the horizontal axis represents the elapsed time from the start of lighting of the xenon lamp 40. The broken line T1 in FIGS. 4 and 5 indicates the target temperature of the black standard temperature, and the broken line T2 indicates the target temperature of the bath temperature. 4, 5, R <b> 1, R <b> 2, and R <b> 3 indicate the rotation speed of the blower fan 50.

As the conditions of the weather resistance test performed by the weather resistance test apparatus 1, the illuminance on the sample is set in addition to the above-described temperature in the tank and the black standard temperature. On the other hand, the luminous efficiency of the test light source including the xenon lamp 40 decreases with time. For this reason, if the power consumption of the xenon lamp 40 remains constant, the illuminance varies from the beginning to the end of the lamp life. Therefore, in the weather resistance test apparatus 1, the control unit 20 controls the ballast 42 to adjust the power consumption of the xenon lamp 40, so that the illuminance in the sample 4 is within the set range regardless of the period of use of the xenon lamp 40. It is stabilized with.
Since the example shown in FIG. 4 is the initial life of the xenon lamp 40, the power consumption of the xenon lamp 40 is, for example, 4.0 kW. On the other hand, since the example shown in FIG. 5 is the end of life of the xenon lamp 40, the power for obtaining the required illuminance is increasing, and the power consumption is, for example, 5.0 kW.

In the example shown in FIG. 4, at the start of lighting of the xenon lamp 40, (a) the black standard temperature is lower than the target temperature T1, and (b) the tank temperature is lower than the target temperature T2. After the lighting of the xenon lamp 40 starts, the blower fan 50 rotates at a predetermined constant rotation speed R1, and (a) the black standard temperature and (b) the temperature in the tank gradually increase due to the heat generated by the xenon lamp 40. To rise.
After a predetermined time (in this example, 10 minutes) has elapsed since the xenon lamp 40 was turned on, (c) the temperature control in the tank is started while the rotation speed of the blower fan 50 is kept constant. In this tank temperature control, the heater 52 is switched ON by the control unit 20, heating by the heater 52 is performed, and (b) the temperature in the tank rises.
(B) When the tank temperature approaches the target temperature T2, (c) the setting of the rotational speed of the blower fan 50 is released from the set speed R1, and the speed decreases. This is because the controller 20 determines that the temperature in the tank is stable, and (a) the rotational speed of the blower fan 50 is reduced to increase the black standard temperature. Then, (a) when the black standard temperature is stabilized near the target temperature T1, the rotational speed of the blower fan 50 is maintained at a relatively low rotational speed R2. In the example of FIG. 4, (b) the temperature inside the tank and (a) the black standard temperature are stable when 20 minutes have elapsed since the start of lighting of the xenon lamp 40.

In the example shown in FIG. 5, (a) the black standard temperature is lower than the target temperature T1 and (b) the in-bath temperature is lower than the target temperature T2 at the start of lighting of the xenon lamp 40. After the lighting of the xenon lamp 40 is started, the heat of the xenon lamp 40 gradually increases (a) the black standard temperature and (b) the temperature in the tank. (C) The rotational speed of the blower fan 50 is maintained at a preset rotational speed R1 from the start of lighting of the xenon lamp 40.
Thereafter, after a predetermined time (in this example, 10 minutes) elapses, (c) tank temperature control is started while the rotation speed of the blower fan 50 is kept constant. In this tank temperature control, the heater 52 is switched ON by the control unit 20, heating by the heater 52 is performed, and (b) the temperature in the tank rises.
(B) When the tank temperature approaches the target temperature T2, (c) the setting of the rotational speed of the blower fan 50 is released from the set speed R1, and the rotational speed of the blower fan 50 is controlled based on the black standard temperature. Thus, the rotational speed of the blower fan 50 increases and decreases with the speed R3 as the minimum speed.

In the example of FIG. 5, (b) the black standard temperature continues to rise after the temperature in the tank is stabilized, and a slight overshoot occurs over the target temperature T1, which is as described above. In addition, since the power consumption of the xenon lamp 40 is increased as compared with the example of FIG. 4, the heat generated by the xenon lamp 40 is large and the black standard temperature is likely to rise. However, in the example of FIG. 5, (a) the rotation speed of the blower fan 50 is increased in response to the change in the black standard temperature, and the black standard temperature is stable near the target temperature T1. As described above, after (b) the temperature in the tank is stabilized, the black standard temperature is controlled by increasing / decreasing the rotational speed of the blower fan 50, and approximately 20 minutes have elapsed since the start of lighting of the xenon lamp 40. Thus, (b) the temperature in the tank and (a) the black standard temperature are stable.
Even after (b) the temperature inside the tank and (a) the black standard temperature is stabilized near the target temperatures T2 and T1, respectively, the rotational speed of the blower fan 50 is increased and decreased to stabilize the black standard temperature. Has been. In the example of FIG. 5, (a) the black standard temperature is likely to rise because the heat generated by the xenon lamp 40 has increased, but (c) 20 minutes from the start of lighting by changing the rotational speed of the blower fan 50 finely. Even after the lapse of time, the black standard temperature has been successfully stabilized within the target temperature range.

As described above, in the weather resistance test apparatus 1 according to the embodiment to which the present invention is applied, the sample 4 and the black standard temperature measuring body 21 are arranged in the test tank 3 provided with the xenon lamp 40, and the test tank 3 A temperature detector 23 for detecting the temperature of the air, a blower fan 50 for circulating and blowing the air in the test chamber 3, a heater 52 and a cooler 53 for adjusting the temperature of the air blown by the blower fan 50, and a heater 52 and a control unit 20 that controls the operating state of the cooler 53 and the rotational speed of the blower fan 50. The control unit 20 includes the cooler 53 and the cooler 53 until a predetermined time elapses from the start of lighting of the xenon lamp 40. While maintaining the state where the heater 52 is stopped, the blower fan 50 is rotated at a predetermined speed and blown. After a predetermined time has elapsed, the blower fan 50 is turned on. While the speed was set to the predetermined speed, and controls the cooler 53 and the heater 52 based on the temperature detected by the chamber temperature detector 23, since the detected temperature of the vessel temperature detector 23 reaches the target temperature range, The setting of the rotational speed of the blower fan 50 is canceled, and the rotational speed of the blower fan 50 is controlled based on the temperature detected by the black standard temperature measuring body 21.
For this reason, after the lighting of the xenon lamp 40 is started, the temperature in the test chamber 3 and the black standard temperature detected by the black standard temperature measuring body 21 can be quickly stabilized in the target temperature range.

  Usually, since the temperature inside the tank before the xenon lamp 40 is turned on is lower than the target temperature, when the adjustment of the temperature inside the tank is started at the start of lighting, the heater 52 is heated at the maximum output, and the temperature inside the tank rapidly increases. It may rise and overshoot beyond the target temperature range, and the black standard temperature may overshoot accordingly. Here, when the blower fan 50 is rotated at a predetermined speed without operating the heater 52 and the cooler 53 until a predetermined time elapses as in the weather resistance test apparatus 1 of the present embodiment, the temperature in the tank suddenly increases. Rise and overshoot associated therewith can be reliably prevented, and the temperature in the tank is controlled within the target temperature range by controlling the temperature in the tank by the heater 52 and the cooler 53 after a predetermined time has elapsed. It can be quickly stabilized. In addition, after starting the lighting of the xenon lamp 40, it is possible to wait until the output of the xenon lamp 40 is stabilized. The internal temperature can be stabilized.

  Further, if the speed of the blower fan 50 is changed based on the black standard temperature before the temperature inside the tank is stabilized, both the temperature of the air blown to the black standard temperature measuring body 21 and the wind speed are changed. Hunting may continue to be unstable. This is a configuration in which the air in the test chamber 3 is circulated and blown by the blower fan 50 as in the weather resistance test apparatus 1, and when the heater 52 and the cooler 53 are operated, the temperature in the chamber changes quickly in response. This is because the response of the black standard temperature sensor 21 to the detected temperature is slow. In other words, the tank temperature changes quickly according to the operating state of the heater 52 and the cooler 53, whereas the black standard temperature is the heat generated by the xenon lamp 40, the tank temperature, and the rotational speed of the blower fan 50. Therefore, even if the operating states of the heater 52 and the cooler 53 are changed, it takes time to be reflected in the black standard temperature. Due to this difference in responsiveness, it is difficult to control and stabilize both the bath temperature and the black standard temperature at the same time. Here, as in the weather resistance test apparatus 1 of the present embodiment, the rotation speed of the blower fan 50 is kept constant until the temperature in the tank is stabilized, and the rotation speed of the blower fan 50 is stabilized after the temperature in the tank is stabilized. If the black standard is controlled by changing the temperature, the black standard temperature can be quickly stabilized within the target temperature range while the temperature in the tank is reliably stabilized.

  Further, as described with reference to FIGS. 4 and 5, the rotation speed of the blower fan 50 set at the start of lighting of the xenon lamp 40 is changed by the control of the control unit 20 after the temperature in the tank is stabilized. The rotational speed of the blower fan 50 is higher. For this reason, the blower fan 50 rotates at high speed from the start of lighting of the xenon lamp 40 until the temperature in the tank is stabilized, and a state where the amount of air blown to the test tank 3 is kept large. Thereby, when the heater 52 and the cooler 53 are operated after that, the rapid increase in the temperature in the tank after the start of the lighting of the xenon lamp 40 can be suppressed. Furthermore, since the amount of air blown to the black standard temperature sensor 21 is large until the temperature in the tank is stabilized, an increase in the black standard temperature during this period can be suppressed, and the black standard temperature can be controlled quickly. An excessive rise in black standard temperature can be prevented.

  The weather resistance test apparatus 1 also includes a cooler 53 and a heater 52 in an air passage 51 that blows air sucked from the upper part of the test tank 3 to the lower part of the test tank 3 by the blower fan 50. Is provided with a wind direction plate 38 for guiding the air blown by the black standard temperature measuring body 21. In this configuration, when heating or cooling is performed by the heater 52 and the cooler 53 in order to adjust the temperature in the tank, the heated or cooled air is blown to the black standard temperature measuring body 21, so that the black standard temperature is equal to the heater 52. Although it is extremely susceptible to the effects of the operation of the cooler 53, as described above, the black standard temperature is suddenly changed or hunted by keeping the rotation speed of the blower fan 50 constant until the temperature in the tank is stabilized. It is possible to quickly stabilize both the bath temperature and the black standard temperature.

The above-described embodiment is merely an aspect of the present invention, and can be arbitrarily modified and applied within the scope of the present invention.
For example, in the above-described embodiment, the black standard temperature sensor 21 is arranged in the sample holder 35 and the black standard temperature is measured, but a black panel temperature sensor is provided instead of the black standard temperature sensor 21. The control may be performed based on the black panel temperature. In addition, the configuration using the xenon lamp 40 including the water-cooled lamp jacket 41 as the light source has been described as an example. However, the light source is not limited to the xenon lamp, and a metal halide lamp may be used. Of course, it can also be used. Furthermore, the blower fan 50 may be composed of a plurality of fans arranged in parallel. In this case, the rotational speeds of the fans may be the same or different. Further, in the above embodiment, the control unit 20 acquires the detection values of the black standard temperature measuring body 21, the ultraviolet radiation intensity detector 22, and the in-bath temperature detector 23, the rotational speed of the blower fan 50, the heater 52, the operation state of the cooler 53, the turning on / off of the xenon lamp 40, and the like are controlled. However, the present invention is not limited to this, and a plurality of functional units having a control function are used to control each unit. A configuration in which control is performed in a distributed manner may be employed.

DESCRIPTION OF SYMBOLS 1 Weather resistance test device 3 Test tank 4 Sample 20 Control part 21 Black standard temperature sensor (black temperature detector)
23 Temperature sensor in the tank 30 Sample chamber 35 Sample holder 38 Wind direction plate 40 Xenon lamp (light source)
50 Blower fan (blower)
51 Air passage 52 Heater 53 Cooler 54 Refrigerator

Claims (2)

A sample and a black temperature detector are arranged in a test tank equipped with a light source, a tank temperature detector for detecting the temperature in the test tank, a blower for circulating and blowing air in the test tank, and the blower A weather resistance test device comprising a cooler and a heater for adjusting the temperature of the air to be blown,
A control unit for controlling the operating state of the cooler and the heater and the rotational speed of the blower;
The controller is
Until a predetermined time elapses from the start of lighting of the light source, the rotational speed of the cooler and conditions the heater was stopped Chi coercive, using the blower in order to stabilize the detected temperature of the black temperature detector to the target temperature To maintain a higher rotational speed or maximum rotational speed
After the predetermined time has elapsed, while maintaining the rotation speed of the blower, the cooler and the heater are controlled based on the detected temperature of the in- tank temperature detector, and the detected temperature of the in-tank temperature detector is set. Stabilize to the target temperature,
The rotation speed of the blower is adjusted so that the detected temperature of the black temperature detector is stabilized at the target temperature in a state where the detected temperature of the in-tank temperature detector is stabilized at the target temperature by the control of the cooler and the heater. Control
Thereafter, control of the cooler and the heater based on the detected temperature of the in-tank temperature detector and control of the rotational speed of the blower based on the detected temperature of the black temperature detector until the weather resistance test is completed. Continuously maintaining the stability of each of the temperature detected by the in- tank temperature detector and the temperature detected by the black temperature detector . The weather resistance test apparatus according to claim 1 ,
The cooler and the heater are disposed in an air passage for blowing air sucked from the upper part of the test tank by the blower to the lower part of the test tank, and the air blown by the blower is directed toward the black temperature detector. A weather resistance test apparatus provided with a wind direction plate for guiding.

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