JP2010181221A - Dew condensation testing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide dew condensation testing device capable of observing and controlling the dew condensation place and dew condensation amount of a sample becoming an inspection target. <P>SOLUTION: The dew condensation testing device which produces dew condensation on the sample becoming the test target set in a chamber includes at least one mist nozzle for ejecting mist to the sample, a cooler and a heater both of which change the temperature of the sample set in the chamber, a thermoviewer for measuring a change in the temperature of the sample from the outside of the chamber through the opening provided in the chamber, a blower for sending air to the sample and a control unit for controlling the cooler, the heater, the blower, the mist nozzle and the thermoviewer. An air curtain or a closure member comprising an infrared ray transmitting material is provided in the opening of the chamber and the temperature distribution and temperature change of the sample during testing dew condensation are measured by the thermoviewer, and the dew condensation distribution and dew condensation amount of the sample are calculated on the basis of the obtained measuring data by the control unit. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

The present invention relates to a dew condensation test apparatus used for a reliability evaluation test of an electronic device.

When an electronic device is used outdoors, there is an opportunity to be exposed to condensation, and there is a risk that the electronic device may corrode a short circuit between conductors or a part of the conductor due to condensation. For this reason, the electronic device is tested using a dew condensation test method which is one of the reliability evaluation tests of the electronic device.

As such a dew condensation test, a dew cycle test, a temperature / humidity cycle test, a method of alternately replacing test objects using two tanks of a low temperature and low humidity tank and a high temperature and high humidity tank are used. Condensation cycle test is based on dew condensation by, for example, using an environmental test device as shown in Patent Document 1 to rapidly change the humidity condition and repeat the generation and drying of dew condensation for a certain amount of time. This is a test method for advancing the change, and the environmental test apparatus places a test object in a test chamber kept in a dry state and blows damp air on the test object.

JP-A-5-164684

In any of the conventional dew tests, including the environmental test apparatus, it was difficult to confirm how much dew condensation occurred on which part of the sample. In addition, since the conventional dew condensation test uses an air conditioning control system, there is a problem that there is an upwind and a downwind, and the dew condensation part of the sample is likely to be biased.

In view of the above-described problems of the prior art, an object of the present invention is to provide a dew condensation test apparatus capable of controlling and observing a dew point and a dew amount.

A dew condensation test apparatus according to the present invention is a dew condensation test apparatus for generating dew condensation on a sample to be tested set in a chamber, and is set in the chamber with at least one mist nozzle for injecting mist onto the sample. A cooler and a heater for changing the temperature of the sample, a thermo viewer for measuring the temperature change of the sample from outside the chamber through an opening provided in the chamber, a blower for sending air to the sample, the cooler, A heater, the blower, the mist nozzle, and a control device for controlling the thermoviewer are provided, and the opening of the chamber is provided with a closing member made of an air curtain or an infrared transmitting material. Measure the temperature distribution and temperature change of the above sample, and based on the obtained measurement data In serial controller and obtains the condensation distribution and condensation of the sample.

Furthermore, the cooler, the heater, and the blower are controlled by the control device based on the dew distribution and the dew amount of the sample obtained by the control device by measuring the temperature distribution and temperature change of the sample by the thermo viewer. Then, the temperature of the sample is changed, and the mist nozzle is controlled to change the injection amount of the mist so that a predetermined condensation amount and a condensation distribution are obtained.

The mist nozzle is movable, the movement of the mist nozzle is controlled by the control device, and a predetermined amount of mist is injected to a predetermined location of the sample.

A dew condensation test apparatus according to the present invention is a dew condensation test apparatus for generating dew condensation on a sample to be tested set in a chamber, and is set in the chamber with at least one mist nozzle for injecting mist onto the sample. A cooler and a heater for changing the temperature of the sample, a thermo viewer for measuring the temperature change of the sample from outside the chamber through an opening provided in the chamber, a blower for sending air to the sample, the cooler, A heater, the blower, the mist nozzle, and a control device for controlling the thermoviewer are provided, and the opening of the chamber is provided with a closing member made of an air curtain or an infrared transmitting material. Measure the temperature distribution and temperature change of the above sample, and based on the obtained measurement data By obtaining the condensation distribution and condensation of the sample in the serial control device, upon condensation test, it is possible to check whether the condensation of much anywhere in the sample has occurred.

Furthermore, the cooler, the heater, and the blower are controlled by the control device based on the dew distribution and the dew amount of the sample obtained by the control device by measuring the temperature distribution and temperature change of the sample by the thermo viewer. Then, the temperature of the sample is changed, and the mist nozzle is controlled to change the mist injection amount so as to obtain a predetermined dew condensation amount and dew distribution. It is possible to generate a necessary amount of condensation at a required place, and a more accurate condensation test can be performed.

Further, the mist nozzle is movable, the movement of the mist nozzle is controlled by the control device, and a predetermined amount of mist is injected to a predetermined location of the sample, thereby obtaining a finer condensation distribution and amount of condensation. It becomes possible.

It is a schematic sectional drawing of the dew condensation test apparatus of the 1st Embodiment of this invention. It is a schematic sectional drawing of the dew condensation test apparatus of 2nd Embodiment. It is a schematic sectional drawing of the dew condensation test apparatus of 3rd Embodiment.

Hereinafter, the dew condensation test apparatus 1 according to the first embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is a schematic sectional view of a dew condensation test apparatus 1 according to the first embodiment.

The dew condensation test apparatus 1 according to the first embodiment includes a chamber 2 in which a sample 10 to be tested is placed, a mist nozzle 3 that injects mist onto the sample 10, a cooler 4 that changes the temperature of the sample 10, and a heater 5. A blower 6, a thermo viewer 9 for measuring the temperature distribution and temperature change of the sample 10 from outside the chamber 2, the cooler 4, the heater 5, the blower 6, the mist nozzle 3, and the thermo viewer 9. A control device 7 for controlling is provided.

In the upper part of the chamber 2, an opening 18 having an air curtain 8 is provided in order to measure the sample 10 set in the chamber 2 by the thermo viewer 9. Sometimes the inside of the chamber 2 is not affected by outside air. A plurality of the mist nozzles 3 are arranged, and each mist nozzle 3 is movable and can change the mist injection direction. The mist nozzle 3 can perform continuous injection and pulse injection, and can change the amount of mist and the injection speed.

The blower 6 is used for controlling the temperature in the chamber 2 and for operating the air curtain 8. The wind generated by the blower 6 flows from the side wall to the upper surface of the chamber 2 as shown by an arrow in FIG. 1, and flows into the air curtain 8 of the opening 18, and the sample 10 provided in the chamber 2. The air blower 6 operates in conjunction with the cooler 4 and the heater 5, and the temperature of the sample 10 is increased. To change.

The thermo viewer 9 measures the temperature distribution and temperature change of the sample 10 using infrared rays, and continuously measures the temperature distribution of the sample 10 during the dew condensation test. The thermo-viewer 9 is movable and can be moved so that a predetermined portion of the sample 10 can be measured when the sample 10 is large or when dew condensation is locally confirmed.

The dew condensation test apparatus 1 includes a control device 7 for controlling the mist nozzle 3, the cooler 4, the heater 5, the blower 6, the air curtain 8, and the thermo viewer 9. The control device 7 includes a mist control unit 13 that controls the mist nozzle 3, the cooler 4, the heater 5, a chamber control unit 11 that controls the blower 6, an air curtain control unit 12 that controls the air curtain 8, A thermo-viewer control unit 14 for controlling the thermo-viewer 9, a measurement result of the thermo-viewer 9 is analyzed, a current dew distribution and dew amount are obtained, and control necessary for obtaining a predetermined dew amount is performed by the mist control unit 13. And a dew condensation control unit 15 for transmitting to the chamber control unit 11.

The chamber controller 11 controls the temperature of the sample 10 by controlling the cooler 4, the heater 5, and the blower 6. The air curtain control unit 12 controls the blower 6 to open and close the air curtain 8.

The mist control unit 13 controls the mist injection location and the injection amount of the mist nozzle 3 and can control each of the plurality of mist nozzles 3. Further, by controlling the mist injection method (continuous injection / pulse injection) and the injection speed, a predetermined amount of mist is injected to a predetermined portion of the sample 10 to cause condensation.

The thermoviewer control unit 14 controls the movement of the thermoviewer 9 and further stores and manages measurement data from the thermoviewer 9. The dew condensation control unit 15 analyzes the measurement data of the thermo viewer 9 obtained by the thermo viewer control unit 14, reads the temperature distribution and temperature change of the sample 10, and determines the dew distribution and dew amount of the sample 10. Ask.

Further, the dew condensation control unit 15 compares the obtained dew distribution and dew amount with the dew distribution and dew amount required for the dew test of the sample 10 so that a predetermined dew amount can be obtained at a predetermined place. The required temperature of the sample 10 is sent to the chamber controller 11, and the mist injection amount and injection location from the mist nozzle 3 are sent as data to the mist controller 13.

Based on the data sent from the dew condensation control unit 15, the chamber control unit 11 controls the cooler 4, the heater 5, and the blower 6 to change the sample 10 to a predetermined temperature. The mist control unit 13 operates the mist nozzle 3 to inject a predetermined amount of mist to a predetermined portion of the sample 10. Thereby, the condensation distribution and the amount of condensation required for the sample 10 can be generated.

Furthermore, the method of the dew condensation test using the said dew condensation test apparatus 1 is demonstrated in detail. First, the sample 10 is set on the stage 19 in the chamber 2. At this time, the condensation distribution and the amount of condensation necessary for the sample 10 are input to the condensation controller 15.

Next, the air curtain control unit 12 operates the blower 6 to close the opening 18 of the chamber 2 with the air curtain 8. The dew condensation test is started from this state. The chamber controller 11 controls the cooler 4, the heater 5, and the blower 6 to bring the sample 10 to a predetermined temperature. At this time, the temperature of the sample 10 is measured using the thermo viewer 9 to confirm that the sample 10 has reached a predetermined temperature.

When the sample 10 reaches a predetermined temperature, the mist control unit 13 operates the mist nozzle 3 to inject mist onto the sample 10. At this time, depending on the conditions of the dew condensation test, a method of spraying mist uniformly on the entire sample 10 and a method of spraying mist locally on the sample 10 where condensation is necessary can be selected. When the amount of dew condensation is changed partially, it is also possible to spray locally after spraying uniformly.

Simultaneously with the mist injection by the mist nozzle 3, the temperature distribution and temperature change of the sample 10 are measured by the thermo viewer 9. When the mist is sprayed onto the sample 10 by the mist nozzle 3 and dew condensation occurs, a temperature change occurs in the sample 10. By measuring the temperature change with the thermo viewer 9 and analyzing the measurement data of the temperature change with the dew condensation control unit 15, the amount of dew condensation on the sample 10 can be obtained. Since the temperature distribution is measured simultaneously with the temperature change, the condensation distribution can be obtained by analyzing the temperature distribution measurement data.

In the dew condensation control unit 15, the dew distribution and dew amount thus obtained are required for the sample 10 in comparison with the dew distribution and dew amount required for the sample 10 during the dew condensation test. If there is a portion that has not reached the amount of dew condensation, the temperature of the sample 10 required for the chamber controller 11 is sent as data, and the mist injection amount from the mist nozzle 3 is further sent to the mist controller 13. And the injection point is sent as data.

Based on each data sent from the dew condensation control unit 15, the chamber control unit 11 operates the cooler 4, the heater 5, and the blower 6 so that the sample 10 reaches a predetermined temperature. At the same time, the mist control unit 13 operates the mist nozzle 3 to inject a predetermined amount of mist to a predetermined portion of the sample 10. In this way, it is possible to cause a predetermined amount of condensation at a predetermined location of the sample 10.

Conventionally, it was impossible to control such a fine condensation distribution and condensation amount. However, the condensation test apparatus 1 of the present invention is confirming the condensation distribution and condensation amount generated in the sample 10. A dew condensation test can be performed, and further, the necessary dew condensation can be generated in the required place of the sample 10. Thereby, a more accurate dew condensation test can be performed.

In addition, it is possible to provide a means for energizing the sample 10 in case the sample 10 needs to be energized during the dew condensation test. In the present embodiment, the amount of air blown to the air curtain 8 and the sample 10 is controlled by one air blower 6, but these can also be performed using two different air blowers.

Next, a dew condensation test apparatus 1 'according to the second embodiment using the two blowers 6 and 6' as described above will be described. In the dew condensation test apparatus 1 ′ of the second embodiment, the blower 6 of the dew condensation test apparatus 1 of the first embodiment is changed to two blowers 6, 6 ′, and is related to the blowers 6, 6 ′. Since other than that is the same as in the first embodiment, detailed description of the same content portion is omitted.

As shown in FIG. 2, the dew condensation test apparatus 1 ′ of the present embodiment controls the blower 6 in combination with the cooler 4 and the heater 5 by the chamber control unit 11. 2 is used to change the temperature of the sample 10, and the blower 6 ′ blows a flow of air as indicated by arrows in FIG. 2 in order to operate the air curtain 8. As described above, the air curtain control unit 12 controls the air curtain.

In this way, by using the two blowers 6 and 6 ′ separately, the operation of the air curtain 8 is performed independently of the temperature control in the chamber 2, so that the air curtain 8 can be stably operated. become able to.

Further, since the blower 6 can be operated independently of the air curtain 8, the blower 6 can be controlled more finely. Thereby, the amount of mist applied to the sample 10 can be controlled more finely by combining the air volume (wind speed) by the blower 6 with the mist injection amount from the mist nozzle 3.

Next, how the state of the sample 10 changes depending on the combination of the specific wind speed by the blower 6 and the amount of mist from the mist nozzle 3 will be described with reference to Table 1 below.

As shown in Table 1, when the wind speed by the blower 6 and the mist injection amount from the mist nozzle 3 are combined, for example, if the wind speed is increased and the mist amount is increased, the temperature change increases, and the dew condensation state Becomes wet. Further, when the wind speed is decreased and the mist amount is decreased, the temperature change is small and the dew condensation state becomes dry. Such a sample state can be obtained by a combination of the wind speed by the blower 6 and the amount of mist injected from the mist nozzle 3, so that this can be used for control by the dew condensation control unit 15, and the cooler 4 and By combining with the control of the heater 5, a more ideal dew distribution and dew amount can be generated in the sample.

Next, a dew condensation test apparatus 1 '' according to a third embodiment will be described with reference to FIG. In the dew condensation test apparatus 1 '' of this embodiment, instead of the air curtain 8 in the dew condensation test apparatus 1 of the first embodiment, a silicon filter is used as the closing member 17 made of an infrared transmitting material in the opening 18 of the chamber 2. It is provided. Accordingly, the arrangement of the mist nozzle 3 is also changed.

As shown in FIG. 3, the dew condensation test apparatus 1 ″ of the third embodiment includes a chamber 2 in which a sample 10 to be tested is placed, a mist nozzle 3 that injects mist onto the sample 10, and the sample 10. A cooler 4, a heater 5, and a blower 6 that change the temperature, a thermo viewer 9 that measures the dew condensation state of the sample 10 from outside the chamber 2, the cooler 4, the heater 5, the blower 6, and the mist nozzle 3 And a control device 7 for controlling the thermo viewer 9.

The upper part of the chamber 2 can be opened and closed to set the sample 10 in the chamber 2, and the opening 18 provided in the upper part is provided with a silicon filter as a closing member 17 made of an infrared transmitting material. It has been. Since the silicon filter transmits infrared rays, the thermo viewer 9 can measure the temperature change and temperature distribution of the sample 10 set in the chamber 2 through the silicon filter.

A plurality of the mist nozzles 3 are arranged in the chamber 2, and each mist nozzle 3 is movable and can change the injection location. The blower 6 blows air to the sample 10 from the side surface of the stage 19 in the chamber 2 and operates in conjunction with the cooler 4 and the heater 5 to change the temperature of the sample 10. Further, the blower 6 can control the mist sprayed on the sample 10 by interlocking with the mist nozzle 3. The details of the linkage between the blower 6 and the mist nozzle 3 have already been described in the second embodiment, and are therefore omitted here.

The control device 7 includes a mist control unit 13 that controls the mist nozzle 3, a cooler 4, the heater 5, a chamber control unit 11 that controls the blower 6, a thermoviewer control unit 14 that controls a thermoviewer 9, The measurement result of the thermo viewer 9 is analyzed, and the dew condensation control part 15 for performing control required in order to obtain a predetermined dew condensation amount is provided.

The method of the dew condensation test using the dew condensation test apparatus 1 ″ of the present embodiment is almost the same as the dew condensation test of the embodiments described so far. First, the sample 10 is set on the stage 19 in the chamber 2 and the chamber 2 is closed. At this time, the condensation distribution and the amount of condensation necessary for the sample 10 are input to the condensation controller 5.

Next, the chamber controller 11 controls the cooler 4, the heater 5, and the blower 6 to change the temperature in the chamber 2 to bring the sample 10 to a predetermined temperature. At this time, it is confirmed whether the sample 10 has reached a predetermined temperature using the thermo viewer 9.

When the sample 10 reaches a predetermined temperature, the mist control unit 14 operates the mist nozzle 3 to inject mist onto the sample 10. At the same time, the temperature distribution and temperature change of the sample 10 are measured by the thermo viewer 9 and the obtained data is analyzed by the dew condensation control unit 15 to obtain the dew condensation distribution and dew amount in the sample 10.

By comparing the condensation distribution and the condensation amount obtained in the condensation control unit 15 with the required condensation distribution and the condensation amount, data relating to the control for obtaining the necessary condensation distribution and the condensation amount is obtained by the chamber control. Is sent to the unit 11 and the mist control unit 13, and is controlled by the chamber control unit 11 and the mist control unit 13. At this time, by considering the combination of the air volume (wind speed) by the blower 6 described in the second embodiment and the mist injection amount from the mist nozzle 3, finer control is possible. Furthermore, if the position, direction, and injection amount of the nozzle 3 are finely adjusted according to changes in the wind speed, the amount of condensation can be kept optimal.

The chamber controller 11 operates the cooler 4, the heater 5, and the blower 6 to change the sample 10 to a predetermined temperature. At the same time, the mist controller 13 operates the mist nozzle 3. Then, a predetermined amount of mist is injected to a predetermined location.

The confirmation of the condensation distribution and the amount of condensation can be performed any number of times, and the control by the condensation control unit 15 is repeatedly performed until a predetermined condensation distribution and the amount of condensation are obtained. In this manner, the sample 10 can generate a dew amount necessary for the dew condensation test at a predetermined location, and a more accurate dew condensation test can be performed. In this embodiment, a silicon filter is used as the closing member made of an infrared transmitting material. However, other materials that transmit infrared light may be used as the filter. In addition to the filter configured as glass, a filter having an appropriate configuration such as a film can be used. Furthermore, it is good also as a structure which uses the member which controls an inverter, a wind direction, or the member which controls the opening rate of a blower outlet for control of a wind direction and an air quantity.

1, 1 ', 1''Condensation test device 2 Chamber 3 Mist nozzle 4 Cooler 5 Heater 6 and 6' Blower 7 Controller 8 Air curtain 9 Thermo viewer 10 Sample 11 Chamber controller 12 Air curtain controller 13 Mist controller 14 Thermo viewer control unit 15 Condensation control unit 17 Closing member 18 Opening 19 Stage

Claims (3)

A dew condensation test apparatus that causes dew condensation on a sample to be tested set in a chamber,
Temperature change of the sample through at least one mist nozzle for injecting mist to the sample, a cooler and a heater for changing the temperature of the sample set in the chamber, and an opening provided in the chamber from outside the chamber A thermo-viewer that measures air, a blower that sends air to the sample, the cooler, the heater, the blower, the mist nozzle, and a control device that controls the thermo-viewer,
The opening of the chamber is provided with a closing member made of an air curtain or an infrared transmitting material,
Condensation test characterized in that the thermo-viewer measures the temperature distribution and temperature change of the sample during the dew condensation test, and determines the dew distribution and dew amount of the sample with the control device based on the obtained measurement data apparatus. Based on the dew distribution and dew amount of the sample obtained by the control device by measuring the temperature distribution and temperature change of the sample with the thermo viewer, the cooler, heater and blower are controlled by the control device. 2. The control according to claim 1, wherein the temperature of the sample is changed, and further, the mist nozzle is controlled to change the injection amount of the mist so as to obtain a predetermined condensation amount and condensation distribution. Condensation test equipment. 3. The dew condensation test according to claim 1, wherein the mist nozzle is movable, the movement of the mist nozzle is controlled by the control device, and a predetermined amount of mist is injected to a predetermined location of the sample. apparatus.