JP4718437B2 - Environmental test equipment - Google Patents

Description

  The present invention relates to an environmental test apparatus that changes an ambient environment of a device under test when measuring an unnecessary radiation wave generated by the device under test such as an electronic device in an anechoic chamber.

  In Patent Document 1, a first support base on which a test object is placed, a cover surrounding the test object placed on the first support base, and an air conditioner and a cover arranged outside are communicated. An anechoic chamber having a duct is described. In this anechoic chamber, the duct is composed of an intake duct that sucks air from the air conditioning equipment into the cover and an exhaust duct that exhausts air from the cover to the air conditioning equipment. The ambient temperature of the device under test placed in the cover is exhausted from the exhaust duct while the air adjusted to a predetermined temperature by the air conditioning equipment is sucked into the cover through the intake duct. (Temperature in the cover) can be set to a predetermined temperature. Because the cover is made of expanded polystyrene that does not affect electromagnetic waves and has good heat insulation properties, measure the electromagnetic waves radiated or received by the DUT in the cover with an antenna in the anechoic chamber and outside the cover. Is possible. With this configuration, by measuring the electromagnetic wave with the antenna while setting the temperature inside the cover to a predetermined temperature, it is possible to measure the unwanted radiation wave of the device under test under the predetermined temperature condition.

JP-A-2005-347524 (FIG. 2)

  However, in the anechoic chamber described in Patent Document 1 described above, air from the air conditioning equipment is sent from the outside of the anechoic chamber through the duct into the cover. In this case, even if the duct is made of foamed polystyrene or resin having good heat insulating properties, the air passing through the duct is lower than the temperature set by the air conditioning equipment due to energy loss, so the temperature in the cover is set to a predetermined temperature. Takes time. If air conditioning equipment is installed in the anechoic chamber to shorten the duct and reduce energy loss, electromagnetic waves leak out from the air conditioning equipment when measuring the unwanted radiation of the device under test. It is difficult to measure high unwanted radiation.

  Accordingly, an object of the present invention is to provide an environmental test apparatus capable of measuring unnecessary radiation with high accuracy while reducing energy loss when the temperature and humidity around the device under test are set to a predetermined condition.

  The environmental test apparatus of the present invention is a temperature and humidity adjustment that changes the temperature and humidity of air in an environmental test apparatus that changes the ambient temperature and humidity conditions of the device under test to a predetermined condition in an anechoic chamber that is not affected by external electromagnetic waves. Means, and a metal casing constituting the air conditioning chamber provided with the temperature / humidity adjusting means, and the device under test adjacent to the air conditioning chamber is accommodated by being attached to the housing while covering the device under test And a cover constituting a test chamber. And, in the case, a communication hole is formed in which the air conditioning chamber and the test chamber communicate with each other, so that the case has an electromagnetic shielding structure in which electromagnetic waves do not leak out from the air conditioning chamber. The communication hole is covered with a metal mesh, and the cover has electromagnetic permeability capable of measuring an unnecessary radiation wave of the test object in the test chamber.

  According to this, since the test room and the air-conditioning room are adjacent and communicated with each other, air adjusted to a predetermined temperature and humidity condition in the air-conditioning room flows into the test room, and the ambient temperature and humidity of the DUT is set as the predetermined condition. It becomes possible to do. At this time, since the air conditioning room and the test room are adjacent to each other, the energy loss of the air whose temperature and humidity from the air conditioning room are adjusted is reduced. In addition, since the casing has an electromagnetic shielding structure, even if electromagnetic waves are generated from the temperature / humidity adjusting means, it is difficult to leak into the test chamber and the anechoic chamber. Therefore, it is possible to accurately measure unnecessary radiant waves of the device under test under predetermined temperature and humidity conditions through the cover.

  In the present invention, the temperature / humidity adjusting unit includes a cooling / dehumidifying unit that cools and dehumidifies air, a heating unit that heats air, and a humidifying unit that humidifies air. It is preferable that it is composed of a pipe and a Peltier element. Thereby, since the heat pipe and the Peltier element constituting the cooling and dehumidifying means hardly emit electromagnetic waves when driven, the electromagnetic waves are more difficult to leak from the air-conditioned room to the outside at the time of measurement.

  Moreover, in this invention, it is preferable that the said air conditioned room is provided with the air blower which sends the air of the said air conditioned room into the said test chamber. Thereby, air can be forced to flow from the air-conditioned room to the test room. Therefore, the test chamber can be quickly brought to a predetermined temperature and humidity condition.

  At this time, the blower may be driven by an air motor driven by compressed air. Thereby, electromagnetic waves are not generated even when the blower is driven. Therefore, even when the blower is driven at the time of measurement, the measurement accuracy of the unnecessary radiant wave of the DUT is not lowered.

  Further, in the present invention, the casing has a metal stage on which a device under test is placed, the stage has a circular planar shape, and the stage is located at the center of the stage. It is preferable that a shaft that traverses the air-conditioning chamber is connected in a direction orthogonal to the surface direction, and the housing is provided with an air motor that applies a rotational force to the shaft. Thereby, an unnecessary radiation wave can be measured while changing the angle of the device under test. Further, since the electromagnetic wave is not generated from the air motor even if the angle of the test object is changed, the measurement accuracy of the unnecessary radiation wave of the test object does not decrease.

  At this time, a sensor for detecting the rotation angle of the stage may be provided in the air conditioning chamber. Thereby, the unnecessary radiation wave in the predetermined angle of a to-be-tested body can be measured.

  At this time, an air tank for storing compressed air in the anechoic chamber may be further provided, and the air motor may be driven by the compressed air from the air tank. Thereby, the air motor can be driven without driving the air compressor at the time of measurement. For this reason, the accuracy of measurement of unnecessary radiation of the device under test does not decrease.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a schematic configuration diagram when an environmental test apparatus 1 according to an embodiment of the present invention is disposed in an anechoic chamber 100. An anechoic chamber 100 shown in FIG. 1 has an electromagnetic shield chamber 101 shielded from the outside. The electromagnetic shield chamber 101 is externally provided by a floor 102 having electromagnetic shielding properties, four electromagnetic shielding walls 103 on the front, rear, left and right in FIG. 1 and a ceiling 104 having electromagnetic shielding properties disposed on the upper surface of each electromagnetic shielding wall 103. It is a shielded space. A radio wave absorber 105 is disposed on the inner surface of the electromagnetic shield chamber 101, that is, on the inner surfaces of the floor 102, the ceiling 104, and each electromagnetic shield wall 103. Thereby, electromagnetic waves do not enter the electromagnetic shield room 101 from the outside of the anechoic chamber 100.

  A communication hole 110 that connects the electromagnetic shield chamber 101 and the outside is formed in the electromagnetic shield wall 103 on the left side in FIG. An electromagnetic wave absorber 105 on the floor 102 accommodates the device under test 9 and sets the ambient temperature and humidity of the device under test 9 to predetermined conditions, an air tank 2 for storing compressed air, and a measurement A support base 122 for supporting the antenna 121 is provided. The device under test 9 is supported by the environmental test apparatus 1 and the antenna 121 is supported by the support stand 122 at a predetermined position and posture. The position of the antenna 121 in the vertical direction can be variably set along the support base 122, and unnecessary radiation waves radiated from the device under test 9 can be measured at various height positions.

  As shown in FIG. 1, the antenna 121 is connected to the flexible cable 123. The flexible cable 123 hangs down from the connecting portion 121a at the rear end of the antenna 121 (left end in FIG. 1) toward the floor 102 in the electromagnetic shield chamber 101 behind the antenna 121 and extends over the radio wave absorber 105. However, it is drawn out of the anechoic chamber 100 through the communication hole 110. A flexible cable 123 is connected to a measuring instrument 125 arranged adjacent to the left side of the anechoic chamber 100. In the present embodiment, the flexible cable 123 is a coaxial cable, but may be other types of cables.

  In addition, a communication hole 115 for communicating the electromagnetic shield chamber 101 with the outside is formed in the lower part of the electromagnetic shield wall 103 on the right side in FIG. 1 and the radio wave absorber 105 on the inner surface thereof. An air hose 4 that connects the air compressor 3 and the air tank 2 disposed adjacent to the right side of the anechoic chamber 100 is passed through the communication hole 115. Since the air compressor 3 is disposed outside the anechoic chamber 100, electromagnetic waves generated when the air compressor 3 is driven do not enter the electromagnetic shield chamber 101. In addition to the air hose 4, two air hoses 5 and 6 are connected to the air tank 2, and these air hoses 5 and 6 are connected to two air motors 41 and 42 included in the environmental test apparatus 1, respectively. . Electromagnetic valves (not shown) are respectively arranged at connection points between the air hoses 5 and 6 and the air tank 2. These electromagnetic valves are only opened and closed, and are opened from the closed state before measuring the unnecessary radiation wave of the device under test 9, and are closed when the measurement of the unnecessary radiation wave is completed. Therefore, the influence of the electromagnetic wave generated during the opening / closing operation of the electromagnetic valve does not affect the measurement of the unnecessary radiation wave of the device under test 9.

  FIG. 2 is a schematic cross-sectional view of an environmental test apparatus according to an embodiment of the present invention. FIG. 3 is a plan view of the environmental test apparatus according to the embodiment of the present invention with the cover 15 removed. As shown in FIG. 2, the environmental test apparatus 1 has a metal housing 12 having an air conditioning chamber 25 (described later) inside, and an upper surface 13 of the housing 12 so as to cover the upper surface 13 of the housing 12. And an attached cover 15.

  The cover 15 has a cylindrical shape with the upper part closed, and forms a test chamber 14 that surrounds the device under test 9 together with the housing 12 when attached to the housing 12. The cover 15 in this embodiment is made of foamed styrene having radio wave permeability and excellent heat insulation properties, but may be made of any material as long as it has radio wave transmissivity such as resin.

  The housing 12 includes a cylindrical side wall 21, and a ceiling 22 and a floor 23 provided on the upper and lower surfaces of the side wall 21. The housing 12 is provided with a heater 33 and a humidifier 34 in a space 25 surrounded by the side wall 21, the ceiling 22 and the floor 23. In addition, the housing 12 is provided with a heat pipe 31 and a Peltier element 32 serving as dehumidifying and cooling means. The heat pipe 31, the Peltier element 32, the heater 33, and the humidifier 34 constitute temperature / humidity adjusting means for adjusting the temperature / humidity of the air in the space 25 to a predetermined temperature / humidity. That is, the space 25 is an air conditioning room 25.

  In addition, four support members 17 that support the cover 15 when the cover 15 is attached are provided on the upper outer peripheral side surface of the housing 12. These four support members 17 are formed so as to protrude upward from the upper surface 13, and are arranged so that the center of the ceiling 22 is point-symmetric.

  The heat pipe 31 passes through the side wall 21 and is fixed to the side wall 21, and one end portion is disposed in the air conditioning chamber 25 and the other end portion is disposed outside the air conditioning chamber 25. A heat absorbing fin 71 is fixed to one end of the heat pipe 31 and inside the air conditioning chamber 25. Thereby, the air in the air-conditioning room 25 can be effectively absorbed and dehumidified. On the other hand, a Peltier element 32 is fixed to the other end of the heat pipe 31.

  The Peltier element 32 is disposed outside the air conditioning chamber 25, the heat pipe 31 is fixed to one surface 32a, and the heat radiating fins 72 are fixed to the other surface 32b. The Peltier element 32 is cooled and dehumidified through the heat pipe 31 and the heat-absorbing fins 71 through cooling of the one surface 32a when a current is passed by control from a control device (not shown). At this time, the other surface 32b of the Peltier element 32 generates heat, but since the heat radiating fins 72 and the heat absorption fan (not shown) are fixed to the other surface 32b, heat generation from the Peltier element 32 is effectively performed. Heat can be dissipated. Thereby, the air conditioning chamber 25 can be effectively cooled and dehumidified. When the Peltier element 32 is not operating, the heat transfer of the heat pipe 31 is stopped and heat insulation is maintained. On the other hand, the heater 33 heats the air in the air conditioning chamber 25 under the control of a control device (not shown). Further, the humidifier 34 humidifies the air in the air conditioning chamber 25 under the control of a control device (not shown).

  As shown in FIG. 3, the ceiling 22 has a circular planar turntable 26 and a guide member 24 that guides the turntable 26. The guide member 24 extends from the side peripheral surface of the turntable 26 to the upper surface of the side wall 21. The turntable 26 is arranged at a position where the center of the turntable 26 overlaps the center of the ceiling 22, and is a stage on which the device under test 9 is placed. A shaft 27 extending in the vertical direction (a direction perpendicular to the upper surface 13) across the air conditioning chamber 25 is fixed to the center of the turntable 26. The floor 23 of the housing 12 is provided with an air motor 41 that rotatably supports one end of the shaft 27. The air motor 41 is connected to one end of the air hose 5 and is driven when air is supplied from the air tank 2 to rotate the shaft 27. Further, a rotary encoder (sensor) 28 through which a shaft 27 is inserted is disposed in the air conditioning chamber 25. Thereby, it is possible to detect how many angles of the DUT 9 with respect to the antenna 121 are. Therefore, it is possible to measure the unnecessary radiation wave of the device under test 9 when the device under test 9 is at a predetermined angle with respect to the antenna 121.

  The guide member 24 is formed with two through holes 51 and 52 that allow the air conditioning chamber 25 and the test chamber 14 to communicate with each other. These through holes 51 and 52 are arranged so that the center of the turntable 26 is point-symmetric, and both extend along the outer periphery of the turntable 26. The two through holes 51 and 52 are provided with metal meshes 53 and 54 covering the respective openings. As shown in FIG. 3, the metal meshes 53 and 54 are formed by crossing a plurality of metal wires so as to have a plurality of mesh-like openings. These metal meshes 53 and 54 suppress electromagnetic waves generated mainly from the heater 33 and the humidifier 34 from entering the test chamber 14 through the through holes 51 and 52. That is, the housing 12 is made of metal and has an electromagnetic shield structure in which the openings of the through holes 51 and 52 are closed with the metal meshes 53 and 54.

  The air conditioner 25 is provided with a blower 19. The blower 19 has an air motor 42. When the air motor 42 is driven, the air in the air conditioning chamber 25 is sucked and discharged toward the test chamber 14. The air motor 42 is connected to one end of the air hose 6 and is driven when air is supplied from the air tank 2. In the blower 19, the discharge port 18 that discharges air from the air conditioning chamber 25 is formed at a position facing the through hole 51. Therefore, the air in the air conditioning chamber 25 adjusted to a predetermined temperature and humidity by the heat pipe 31, the Peltier element 32, the heater 33, and the humidifier 34 can be effectively supplied to the test chamber 14. In addition, air is forcibly sent into the test chamber 14 by the blower 19, so that the air in the test chamber 14 flows into the air conditioning chamber 25 through the through hole 52, and the airflow circulating between the air conditioning chamber 25 and the test chamber 14 is generated. Arise. In this way, the air conditioning room 25 and the test room 14 are kept at substantially the same temperature and humidity.

  Further, a temperature / humidity sensor 61 is provided in the vicinity of the through hole 51 in the test chamber 14. By providing the temperature / humidity sensor 61 in this manner, the temperature / humidity of the air in the test chamber 14 can be measured. Therefore, the measurement temperature and measurement humidity of the temperature / humidity sensor 61 are recognized by the control device, and the heat pipe 31, the Peltier element 32, the heater 33, and the humidifier 34 are controlled so that the temperature / humidity of the test chamber 14 becomes a predetermined condition. It becomes possible to do. Therefore, the temperature and humidity of the test chamber 14 can be reliably set to a predetermined condition.

  Next, the operation of the environmental test apparatus 1 when measuring an unnecessary radiation wave of the device under test 9 under a predetermined temperature and humidity condition in the anechoic chamber 100 will be described below. FIG. 4 is a diagram showing an operation flow of the environmental test apparatus. As shown in FIG. 4, first, in step 1 (S <b> 1), the cover 15 of the environmental test apparatus 1 placed in the electromagnetic shield chamber 101 is removed, and the device under test 9 is placed on the turntable 26. At this time, the device under test 9 is adjusted to the direction (here, the front surface) to be measured with respect to the antenna 121. And the cover 15 is attached to the housing | casing 12, and the environmental test apparatus 1 is made into the state shown in FIG. At this time, the temperature / humidity of the test chamber 14 is measured by the temperature / humidity sensor 61 in advance. At this time, the air compressor 3 is operated to fill the air tank 2 with compressed air.

  Next, in step 2 (S2), when the temperature and humidity measured by the temperature and humidity sensor 61 is lower than a predetermined temperature and humidity condition, the heater 33 and humidification are performed so that the temperature and humidity of the air-conditioning room 25 become the predetermined condition. The device 34 is controlled. On the other hand, when the measured temperature is higher than the predetermined condition, the Peltier element 32 is controlled so that the temperature and humidity of the air-conditioned room 25 become the predetermined condition. Then, the electromagnetic valve is opened, and the air in the air tank 2 filled with compressed air by the air compressor 3 is supplied to the air motor 42 via the air hose 6 to drive the blower 19. As a result, air in the air conditioning chamber 25 flows into the test chamber 14 forcibly through the through hole 51, and air in the test chamber 14 flows into the air conditioning chamber 25 through the through hole 52. Thus, the air in the air-conditioning room 25 and the test room 14 can be quickly set to a predetermined temperature and humidity condition.

  Next, in step 3 (S3), the rotational position of the shaft 27 is detected by the rotary encoder 28, and the DUT 9 is positioned using the position as a reference value. In step 4 (S4), when the temperature / humidity sensor 61 indicates a predetermined temperature / humidity condition, the air compressor 3 is stopped and the electromagnetic valve is closed to stop driving the blower 19. In this embodiment, although the drive of the air blower 19 is stopped in step 4, you may continue driving as it is. In this case, the test chamber 14 and the air-conditioning chamber 25 are kept at substantially the same temperature and humidity, and the ambient temperature and humidity of the device under test 9 are surely in a predetermined condition even when measuring an unnecessary radiation wave described later. Further, since the blower 19 is driven by the air motor 42, electromagnetic waves are not generated, and therefore, electromagnetic waves are not leaked from the air conditioning chamber 25 to the outside even when measuring unnecessary radiation waves, and measurement accuracy is not lowered.

  Next, in step 5 (S5), the unnecessary radiant wave in the predetermined temperature and humidity conditions of the device under test 9 is measured by the antenna 121 of the anechoic chamber 100. That is, unnecessary radiation waves radiated from the device under test 9 in the environmental test apparatus 1 are received by the antenna 121 as, for example, horizontal / vertically polarized waves and measured by the measuring instrument 125. At this time, since the operation of the air compressor 3 and the electromagnetic valve is not performed, the measurement accuracy of unnecessary radiant waves does not deteriorate. At this time, the temperature / humidity adjusting means including the Peltier element 32, the heater 33, and the humidifier 34 is controlled so as to maintain the temperature / humidity of the air conditioning room 25 under a predetermined condition, but immediately before measuring the unnecessary radiation wave. In addition, the control may be stopped. As a result, the measurement accuracy of unwanted radiation is further improved.

  Next, in step 6 (S6), after the measurement of the unwanted radiation wave in step 5 is completed, when the unwanted radiation wave from the side surface of the device under test 9 is measured, the electromagnetic valve is opened and the air tank 2 is opened. The air inside is supplied to the air motor 41 via the air hose 5 to rotate the turntable 26 by 90 °. At this time, control is performed based on the measurement angle by the rotary encoder 28. When the measured value by the rotary encoder 28 becomes 90 ° with respect to the reference value, the electromagnetic valve is closed. Thus, positioning is performed with the side surface of the device under test 9 facing the antenna 121. In addition, various directions (angles) of the device under test 9 with respect to the antenna 121 can be positioned by the same method as in Step 6.

  Next, when the predetermined temperature / humidity condition of the device under test 9 is changed, in step 7 (S7), the Peltier element 32, the heater 33, and the humidifier are set so that the temperature / humidity of the air conditioning chamber 25 becomes a new predetermined condition. 34 is controlled. Also in this case, the blower 19 is driven as in step 2. At this time, when the compressed air in the air tank 2 has decreased so that the blower 19 cannot be driven, the air compressor 3 is operated. In step 8 (S8), when the temperature / humidity sensor 61 indicates a predetermined temperature / humidity condition, the electromagnetic valve is closed to stop driving the blower 19. At this time, if the air compressor 3 is operating, it is stopped.

  Next, in step 9 (S9), as in step 5, unnecessary radiation waves under a new predetermined temperature and humidity condition of the device under test 9 are measured. Further, when measuring the unnecessary radiation wave of the device under test 9 again by setting the predetermined conditions, the steps 6 to 9 are repeated, and various temperature and humidity conditions of the device under test 9 and the device under test 9 are measured. Unwanted radiation waves at various angles can be measured. And in step 10 (S10), control of the Peltier device 32, the heater 33, and the humidifier 34 is stopped, and a measurement test is complete | finished.

  According to the environmental test apparatus 1 according to the present embodiment as described above, since the test chamber 14 and the air conditioning chamber 25 are adjacent and communicated with each other, the air adjusted to a predetermined temperature and humidity condition in the air conditioning chamber 25 is the test chamber. 14, the ambient temperature and humidity of the DUT 9 can be set to a predetermined condition. At this time, since the air conditioning room 25 and the test room 14 are adjacent to each other, the energy loss of air whose temperature and humidity from the air conditioning room 25 are adjusted is reduced. In addition, since the casing 12 has an electromagnetic shield structure, even if electromagnetic waves are generated from the temperature / humidity adjusting means, it is difficult for the casing 12 to leak into the test chamber 14 and the anechoic chamber 100. Therefore, the unnecessary radiation wave of the device under test 9 can be accurately measured through the cover 15 under a predetermined temperature and humidity condition.

  Further, since the cooling and dehumidifying means is composed of the heat pipe 31 and the Peltier element 32 that hardly emit electromagnetic waves during driving, electromagnetic waves are more externally transmitted from the air conditioning chamber 25 during measurement of unnecessary radiation waves of the device under test 9. It becomes difficult to leak. Therefore, it is possible to measure unnecessary radiation waves with higher accuracy.

  Further, since the turntable 26 is provided, it is possible to measure unnecessary radiation waves while changing the angle of the device under test 9. Furthermore, since the turntable 26 is rotated by the air motor 41, no electromagnetic waves are generated even if the turntable 26 is rotating when measuring the unnecessary radiation wave. Therefore, the measurement accuracy of the unnecessary radiation wave of the device under test 9 does not decrease.

  Further, since the air tank 2 is provided, the air motors 41 and 42 can be driven without driving the air compressor 3 during measurement. Therefore, the accuracy of measurement of the unnecessary radiation wave of the device under test 9 does not decrease.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and various modifications can be made as long as they are described in the claims. For example, in the above-described embodiment, the cooling and dehumidifying means is composed of the heat pipe 31 and the Peltier element 32. However, since the casing 12 has an electromagnetic shield structure, the cooling and dehumidifying means is used by a device that easily generates electromagnetic waves. May be configured. Further, the air blower 19 may not be provided in the air conditioning room 25. Alternatively, a blower may be provided in the test chamber 14. In this case, it is preferable to provide the air in the test chamber 14 so as to forcibly flow into the air conditioning chamber 25. Moreover, when measuring the unnecessary radiant wave of the DUT 9 with the drive of the blower 19 stopped, the blower may be driven by a motor other than the air motor. Further, the turntable 26 and the rotary encoder 28 may not be provided. Further, the air tank 2 may not be provided. In this case, compressed air may be supplied directly to the air motors 41 and 42 from the air compressor 3 disposed outside the anechoic chamber 100.

  In the above-described embodiment, the test chamber 14 of the environmental test apparatus 1 is disposed above the air conditioning chamber 25. However, the test chamber may be disposed below the air conditioning chamber. Furthermore, an environmental test apparatus in which a test room and an air-conditioning room are arranged side by side may be used.

It is a schematic block diagram when the environmental testing apparatus by one Embodiment of this invention is arrange | positioned in an anechoic chamber. It is a schematic sectional drawing of the environmental test apparatus by one Embodiment of this invention. It is a top view in the state where the cover of the environmental testing device by one embodiment of the present invention was removed. It is a figure which shows the operation | movement flow of an environmental test apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Environmental test apparatus 2 Air tank 9 Specimen 12 Case 14 Test room 15 Cover 19 Blower 25 Air-conditioning room 26 Turntable (stage)
27 axis 28 rotary encoder (sensor)
31 Heat pipe 32 Peltier element 41, 42 Air motor 51, 52 Through hole 53, 54 Metal mesh 100 Anechoic chamber

Claims (7)

In an environmental test device that changes the ambient temperature and humidity conditions of the device under test to a specified condition in an anechoic chamber that is not affected by external electromagnetic waves,
Temperature and humidity adjustment means for changing the temperature and humidity of the air;
A metal casing constituting an air-conditioning room provided with the temperature and humidity adjusting means;
A cover that constitutes a test chamber that houses a device under test adjacent to the air-conditioning chamber is provided by being attached to the housing while covering the device under test,
The casing is formed with a communication hole for communication between the air conditioning chamber and the test chamber,
The communication hole is covered with a metal mesh so that the housing has an electromagnetic shielding structure in which electromagnetic waves do not leak out from the air conditioning chamber,
An environmental test apparatus characterized in that the cover has electromagnetic permeability capable of measuring an unnecessary radiation wave of a test object in the test chamber. The temperature and humidity adjusting means is
Cooling and dehumidifying means for cooling and dehumidifying the air;
Heating means for heating air;
A humidifying means for humidifying the air,
The environmental test apparatus according to claim 1, wherein the cooling and dehumidifying means includes a heat pipe and a Peltier element.   The environmental test apparatus according to claim 1, wherein the air-conditioning chamber is provided with a blower that sends air from the air-conditioning chamber to the test chamber.   The environmental test apparatus according to claim 3, wherein the blower is driven by an air motor driven by compressed air. The housing has a metal stage on which the device under test is placed;
The stage has a circular planar shape;
At the center of the stage, an axis that crosses the air-conditioning chamber with respect to a direction orthogonal to the surface direction of the stage is connected,
The annular test apparatus according to claim 1, wherein an air motor that applies a rotational force to the shaft is provided in the housing.   The environmental test apparatus according to claim 5, wherein a sensor for detecting a rotation angle of the stage is provided in the air conditioning chamber. An air tank for storing compressed air in the anechoic chamber is further provided;
The environmental test apparatus according to claim 4, wherein the air motor is driven by compressed air from the air tank.

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