JP5699108B2 - Environmental test equipment - Google Patents

Description

  The present invention relates to an environmental test apparatus having a function of adjusting the temperature environment of a closed space, and more particularly to an environmental test apparatus including a blower that stirs air in the closed space.

  There is an environmental testing device as a device for testing the performance and durability of products and materials. This type of environmental test apparatus includes a test space on which a specimen to be tested is placed, and adjusts the temperature and humidity in the test space to a desired test environment. That is, this type of environmental test apparatus is a heater that heats air or a cooler that cools air (for example, an evaporator that forms part of a refrigeration cycle) in order to adjust the test space to a desired test environment. Furthermore, at least a blower for stirring the air in the test space is mounted.

  By the way, in Patent Literature 1, each of the above-described devices (heater, cooler, and blower) that contributes to the formation of a test space in which a sample body is placed and a test environment is formed in one constant temperature and humidity chamber by a partition wall. Etc.) is disclosed. This environmental test device starts the blower with the heater and cooler driven, and circulates air between the air conditioning space and the test space so that the temperature and humidity in the test space become almost uniform. It is something to control.

JP 2011-163585 A

  However, in an environmental test apparatus such as that disclosed in Patent Document 1, it may be difficult to form a desired test environment stably and with high accuracy, which may impair the reliability of test results. The reason will be specifically described below.

  The environmental test apparatus of Patent Document 1 has a basic configuration in which an air conditioner is arranged in the order of a cooler, a heater, and a blower from the upstream side in the air flow direction. That is, inside the air adjustment space, the circulating air passes in the order of the cooler and the heater, and is sent out into the test space via the blower.

  More specifically, in this type of environmental test apparatus, a cooler and a heater are selectively used in the air adjustment space according to the target temperature and target humidity in the test space. That is, when the sample body in the test space is exposed to a high temperature, a heater is mainly used. Specifically, in the high-temperature test operation, the heater is adjusted to a predetermined output (proportional control or on / off control), and circulating air is formed between the test space and the air adjustment space by a blower to The atmospheric temperature is controlled to be maintained at the target temperature. On the other hand, when the sample body in the test space is exposed to a low temperature, both a cooler and a heater are used. Specifically, in the low-temperature test operation, the heater is adjusted to a predetermined output (proportional control or on / off control) while the cooler is operated intermittently, and the test space and the air adjustment space are blown by the blower. Circulating air is formed in the test space so that the ambient temperature of the test space is maintained at the target temperature.

  However, in actuality, in any operation, as shown in FIG. 17, air can flow from a direction of 360 ° with reference to an inflow portion (hereinafter referred to as an intake port 102) through which air flows into the blower 100. The air taken into the blower 100 from the air inlet 102 may cause a large uneven distribution in temperature and humidity. This is largely due to the fact that the suction force in one direction decreases due to the widening of the intake range in the blower, and a stagnant region where air is stagnated is formed in the vicinity of the intake port 102. As shown in FIG. 17, this staying region is a position slightly separated from the intake port 102, and is likely to occur near the upper corner of the air adjustment space with respect to the intake port 102. That is, the staying area generated in the air adjustment space is a portion along the wall surface that mainly forms the outline of the apparatus. Further, in the vicinity of the wall surface in the air adjustment space, it is influenced by the outside air temperature. That is, in the conventional environmental test apparatus, the residence region is formed in the range where the influence of such disturbances is exerted. Therefore, the temperature adjusted by the cooler, the heater, etc. in the air adjustment space, even during the test. And air different from humidity is formed. And the air of the residence area | region where this temperature was not adjusted was suck | inhaled by the air blower 100, and the big distribution nonuniformity was produced in temperature and humidity.

  In addition, as another reason for causing a large distribution unevenness in the temperature and humidity of the air sucked into the blower, for example, the air flowing into the blower 100 passes through only the cooler (simply referred to as low temperature air), For example, air that has passed through the cooler and the heater 101 (simply referred to as adjustment air) or air that has passed through only the heater 101 (simply referred to as high-temperature air) enters the middle halfway and is mixed.

  For these reasons, the air taken into the blower 100 from the air inlet 102 does not have a uniform distribution of temperature and humidity, and large distribution unevenness occurs in the temperature and humidity. Further, the air discharged from the blower 100 is also in a state where large distribution unevenness occurs in temperature and humidity so as to follow it. That is, in the discharge air of the blower 100, uneven distribution of temperature and humidity is formed in a cross section in a direction crossing the discharge direction. The test space is adjusted to a desired environment by the air with uneven distribution.

  As described above, in the conventional environmental test apparatus, air having various temperatures and humidity is introduced into the blower from the intake port, and the test environment is formed using the air. It was difficult to maintain the test environment in a stable state. As a result, an environmental test is forced in an unstable environment, causing a decrease in test accuracy. That is, the distribution unevenness of the discharge air in the blower has been one of the causes that cause a decrease in test accuracy. In particular, a constant temperature device or a constant temperature and humidity device (environmental test device) suitable for tests that maintain high and low temperature conditions over the long term will have a greater impact on the test results, thus increasing the reliability of the environmental test. There was a possibility of lowering.

  Therefore, in the present invention, in view of the problems of the prior art, uneven distribution of temperature and humidity of the discharge air from the blower, in particular, uneven distribution in the rotation direction of the rotating fins of the blower is suppressed, thereby improving the accuracy of the environmental test. It is an object of the present invention to provide an environmental test apparatus capable of performing the above.

The invention according to claim 1, which is provided to solve the above problem, includes an air conditioning space having a heat source and a blower, and a test space in which a sample body is arranged. It is an environmental test device that circulates air between them to form the test space in a desired environment, and in the air adjustment space, it is arranged in the order of the heat source and the blower from the upstream side in the air flow direction. The passage direction of the air sucked into the blower intersects with the passage direction of the air passing through the heat source, and a blocking wall is provided to restrict the flow of air from the air adjustment space to the test space. The blower has a discharge port for discharging air, the blocking wall has an opening, and the opening is in communication with the discharge port of the blower, between the heat source and the blower. The air whose temperature is adjusted mainly by the heat source An air introduction guide leading to the blower is provided, the blower has an intake port, and air is sucked from the intake port, and the air introduction guide has the heat source around the intake port. It is an environmental test apparatus characterized by having an enclosing wall that encloses a part other than a certain direction, and an inflow opening that guides air into the enclosing wall.

That is, the present invention has an air conditioning space having a heat source and a blower, and a test space in which a sample body is arranged, and circulates air between the air conditioning space and the test space, An environmental test apparatus formed in a desired environment, in the air conditioning space, arranged in the order of the heat source and the blower from the upstream side of the air flow direction, and the blower has a passage direction of the air sucked into the blower. The air introduction guide is installed between the heat source and the blower to guide the air whose temperature is mainly adjusted by the heat source to the blower. it shall be the feature of the you are.
The “heat source” mentioned here includes the concept of a cold heat source and a heating source.

As described above, this type of environmental test apparatus adjusts the heater to a predetermined output (proportional control or on / off control) in a high-temperature test operation, and the air blower blows the space between the test space and the air adjustment space. Circulating air is formed and controlled so that the ambient temperature of the test space is maintained at the target temperature. On the other hand, in the low-temperature test operation, the heater is adjusted to a predetermined output (proportional control or on / off control) while the cooler is operated intermittently, and the circulating air is blown between the test space and the air adjustment space by the blower. And control so that the ambient temperature of the test space is maintained at the target temperature.
That is, in this type of environmental test apparatus, the heater is driven in both the high temperature test operation and the low temperature test operation.

  Therefore, the environmental test apparatus described in claim 1 is configured such that an air introduction guide is provided between the blower and the heat source, and the air that has passed through the heat source is guided to the blower. As a result, in any environmental test apparatus, air in a substantially uniform state after adjusting the temperature and humidity in the vicinity of the downstream of the heat source is mainly flowed into the blower of the environmental test apparatus, regardless of which test is performed. Therefore, the distribution unevenness of the temperature and humidity of the inflowing air can be made substantially uniform. Further, as described above, even in the case where the stay region is formed in the air adjustment space and above the air intake portion of the blower, in the present invention, the air introduction guide Since the air can be regulated so as not to be sucked in, the occurrence of uneven distribution of the temperature and humidity of the air flowing into the blower can be prevented more reliably. That is, in the present invention, since the uneven distribution of the temperature and humidity of the discharged air in the blower can be made substantially uniform, the test environment in the test space can be easily adjusted. As a result, it is possible to maintain the test environment in a stable state for a long time. As a result, even when the environmental test device of the present invention is employed in a constant temperature device or a constant temperature and humidity device that maintains a high temperature state or a low temperature state for a long period of time, high test accuracy can be ensured. There is no risk of reducing reliability.

Furthermore, in the present invention, since the blower is installed so that the passage direction of the air sucked into the blower intersects the passage direction of the air passing through the heat source, the air introduction guide is provided. The environmental test equipment is not increased in size.
The reason for this will be briefly described.
In the environmental test apparatus, a motor is used as a drive source for the blower. In general, a motor may be defective due to exposure to a high temperature or a sudden temperature change. Therefore, in the environmental test apparatus, it is avoided to arrange the motor in the test space or the air adjustment space. Therefore, in general, a centrifugal blower is used more frequently than the axial flow type in the environmental test apparatus. The centrifugal blower has a structure that sucks air from the axial direction and discharges it in the rotational direction. That is, the centrifugal blower has a structure in which the air suction direction and the discharge direction intersect. And the motor which is a drive source of an air blower is generally arrange | positioned in the axial center direction. In view of such circumstances, conventionally, a blower has been installed such that a motor is disposed outside the air conditioning space, and the direction of the air sucked into the blower intersects the direction of the air passing through the heat source. ing. In addition, when installed in this posture, it is possible to prevent the occurrence of motor problems due to heat and to prevent the environmental test apparatus from becoming larger than necessary.
Therefore, in the present invention, since the air introduction guide is provided while the installation posture of the blower is the same as that of the conventional one, it is possible to expect a new effect while maintaining the same size as the conventional environmental test apparatus. it can.

  According to a second aspect of the present invention, the air introduction guide has an inflow opening on the upstream side with respect to the air flow direction, and the inflow opening is formed to open toward the heat source. The environmental test apparatus according to claim 1, wherein:

  According to this configuration, since the inflow opening of the air introduction guide is disposed so as to open toward the heat source, the air after passing through the heat source can be taken into the blower more effectively. In other words, since the inflow opening of the air introduction guide is located on the extension of the portion (intake part) through which air flows into the blower, the inflow opening can be regarded as the intake part of the blower, and the air in the vicinity of the downstream of the heat source Can be reliably taken into the blower.

In the first aspect of the present invention, the air blower has an air inlet, and air is sucked from the air inlet, and the air introduction guide has a direction other than the direction where the heat source is located around the air inlet. a surrounding wall surrounding the portion, it characterized as having an inlet opening for introducing air into the surrounding wall.

  According to such a configuration, the air introduction guide that guides air to the intake port is formed by the surrounding wall that surrounds the portion other than the direction in which the heat source is present around the intake port of the blower, and through the inflow opening, Since air can be guided into the surrounding wall, the air that has passed through the inflow opening can be reliably taken into the blower. In other words, according to the present invention, since air can be prevented from flowing into the surrounding wall from a place other than the inflow opening, the uneven distribution of the temperature and humidity of the air taken into the blower is more reliably suppressed. be able to.

Generally, in an environmental test apparatus, a heater having a smaller size (outer shape) than a cooler size (outer shape) is employed. Further, a general fluid tries to follow a path with a small resistance in accordance with the relationship of flow path resistance. Therefore, the air that has passed through the cooler flows so as to avoid the heater, which has been one of the causes of uneven distribution of air temperature and humidity in the blower.
Therefore, the invention of claim 3 is provided, in the air conditioning space, the area occupied in the direction in which the heat source is perpendicular to the flow direction of air, the air conditioning space is orthogonal to the flow direction of the air an environmental test apparatus according to claim 1 or 2, characterized in that less than an area occupied by the direction.

  According to such a configuration, even if it is a configuration that can flow into the blower along a path that avoids the heat source, the air in the vicinity of the heat source can be taken into the blower by the air introduction guide. That is, the air near the downstream of the heat source can be sucked into the blower without changing the design of the equipment configuration or the air conditioning space in the existing environmental test apparatus. According to this, there is no fear that manufacturing cost will increase significantly.

The invention according to claim 4, wherein the inlet opening is any one of claims 1 to 3, characterized in that the heat source is disposed so as to be located in a projection plane obtained by projecting toward the inlet opening It is an environmental test apparatus as described in above.

  According to such a configuration, since the inflow opening of the air introduction guide is arranged so as to be located in the projection plane projected toward the inflow opening, the heat source passes more effectively with respect to the blower. Later air can be taken in.

The invention described in claim 5 is characterized in that the blower has a discharge port for discharging air, and a resistor serving as air flow resistance is provided in the vicinity of the discharge port. It is an environmental test apparatus in any one of 1-4 .

  According to such a configuration, the flow of air discharged from the discharge port can be limited by the resistor, and the deviation of the discharge flow rate that can be generated by the rotating fins of the blower can be adjusted. Thereby, since the flow rate discharged from the blower and directed into the test space can be dispersed almost uniformly, the test space can be efficiently brought to a desired test environment without time difference. As a result, the test accuracy can be improved.

The invention according to claim 6 is the environmental test according to claim 5 , wherein the blower is a multi-blade type fan, and the resistor is provided on a rotation direction side of the fan. Device.

  According to this structure, since the resistor is provided on the rotation direction side of the blower, the flow rate of the blower can be dispersed. Thereby, the air discharged from the blower can be more evenly dispersed.

The invention according to claim 7 has a second heat source in the air adjustment space, and in the air adjustment space, the second heat source, the heat source, and the blower are arranged in this order from the upstream side in the air flow direction. aligned, the area occupied in the direction in which the heat source is perpendicular to the flow direction of the air, according to claim 1, wherein the second heat source is equal to or smaller than the area occupied in a direction orthogonal to the flow direction of the air 6. The environmental test apparatus according to any one of 6 above.

  According to such a configuration, even if the air that has passed through the second heat source can flow into the blower along a path that avoids the heat source, the air in the vicinity of the downstream of the heat source is moved into the blower by the air introduction guide. Can be imported.

In the environmental test apparatus of the present invention, it is desirable that the heat source is a heater and the second heat source is a cooler. (Claim 8 )

  In the environmental test apparatus of the present invention, an air introduction guide is provided between the blower and the heater, and the air that has passed through the heater can be guided to the blower by the air introduction guide. It is possible to suppress humidity distribution unevenness. Thereby, since the test environment in the test space can be maintained stably and with high accuracy, a highly reliable test result can be obtained.

It is a conceptual diagram which shows the environmental test apparatus which concerns on embodiment of this invention. It is a perspective view which shows the substance of the principal part inside the environmental test apparatus of FIG. It is a perspective view which shows an introduction flow path formation member. It is a front view which shows an introduction flow path formation member. It is explanatory drawing which shows the positional relationship of the air blower in the environmental test apparatus, its peripheral device, and a member. It is a conceptual diagram which shows the flow of the air in an environmental test apparatus. It is the conceptual diagram which paid its attention to the flow of the air upstream and downstream of an air blower. It is a conceptual diagram paying attention to the flow of the air in the downstream of an air blower. It is a perspective view which shows the modification of an introduction flow path formation member. (Curved shape) It is a perspective view which shows the modification of an introduction flow path formation member. (Triangle shape) It is a perspective view which shows another modification of an introduction flow path formation member. (Inflow opening expansion) It is a perspective view which shows another modification of the introduction flow path formation member. It is a perspective view which shows the modification of a resistance board. (Tilt) It is explanatory drawing which shows the modification of a resistance board. (Hanging) It is explanatory drawing which shows the modification of a resistance board. (Curved) It is explanatory drawing which shows the modification of a resistor. (Slit shape) It is the conceptual diagram which paid its attention to the flow of the air upstream and downstream of the air blower in the conventional environmental test apparatus. (Shaded area: staying area)

Below, the environmental test apparatus 1 which concerns on embodiment of this invention is demonstrated.
First, the basic configuration of the environmental test apparatus 1 of the present embodiment will be described.
An environmental test apparatus 1 shown in FIG. 1 is a so-called constant temperature and humidity apparatus having a casing 2 whose periphery is covered with a heat insulating material 3. That is, the housing 2 constitutes a constant temperature and humidity chamber 5, and the interior is divided into a test chamber (test space) 6 and an air conditioning passage (air conditioning space) 7 by the partition wall 4. Openings 9 and 19 for communicating the test chamber 6 and the air conditioning passage 7 are provided on the upper side and the lower side in the constant temperature and humidity chamber 5.

  The test chamber 6 has an indoor temperature detection means 23 for detecting the temperature of the space and an indoor humidity detection device for detecting the relative humidity of the space in the space in which equipment, parts, and the like serving as samples are arranged when performing an environmental test. Means 24 are provided. The room temperature detecting means 23 is a temperature sensor such as a conventionally known thermocouple or thermistor, for example. On the other hand, the indoor humidity detection means 24 is, for example, a conventionally known humidity sensor.

The air-conditioning passage 7 is a portion that generates air having a desired temperature and humidity. The humidifier 14, the evaporator (second heat source) 15, and the heater are sequentially arranged from the lower side (upstream side in the air flow direction). A (heat source) 26 and a blower 27 are arranged.
The humidifier 14 has an evaporating dish 30 and a conventionally known electric heater 31, and evaporates hot water stored in the evaporating dish 30 by the electric heater 31.
The evaporator (cooler) 15 is a part of the known cooling device 10 and functions to take part of the refrigeration cycle. That is, the evaporator 15 is capable of changing the cooling capacity and the surface temperature through which the phase-change refrigerant flows.
The heater 26 is a conventionally known electric heater, and heats air passing through the air conditioning passage 7.

  The blower 27 is a conventionally known centrifugal blower, and includes a rotating fin 28 and an outer member 33 incorporating the rotating fin 28. The blower 27 sucks air from the axial center direction of the rotating fin 28 and discharges air in the rotating direction. is there. That is, the blower 27 has an intake port 35 and a discharge port 36 in the outer member 33, and the intake port 35 is the outer member 33 and is formed on a side surface orthogonal to the rotation axis of the rotary fin 28. The outlet 36 is formed on the circumferential surface along the rotation direction of the rotary fin 28.

  The air conditioning passage 7 is provided with a blocking wall 16 on the upper side (downstream side in the air flow direction) of the blower 27. The blocking wall 16 is an air flow restriction member that has an opening 17 formed in a predetermined position and penetrating in the thickness direction of the member, and allows the passage of air only from the opening 17. That is, the closed wall 16 can send the air discharged from the blower 27 to the test chamber 6 side by connecting the discharge port 36 of the blower 27 to the opening 17. In the present embodiment, the opening shape of the opening 17 of the blocking wall 16 is substantially rectangular, and the opening size of the opening 17 is substantially the same as the opening size of the discharge port 36 of the blower 27.

Then, the characteristic structure of the environmental test apparatus 1 of this embodiment is demonstrated.
In the environmental test apparatus 1 of the present embodiment, the air introduction guide 8 is provided upstream of the air inlet 35 of the blower 27 in the air flow direction in order to suppress uneven distribution of the temperature and humidity of the air discharged from the blower 27. Further, the resistance plate 11 is provided downstream of the discharge port 36 of the blower 27 in the air flow direction in order to suppress uneven temperature and humidity distribution in the test chamber 6 and facilitate adjustment of temperature and humidity. It has been.

  As shown in FIG. 1, the air introduction guide 8 is provided between the heater 26 and the blower 27, and restricts the air flowing into the blower 27. That is, the air introduction guide 8 is a member that functions as an auxiliary flow path for introducing mainly air that has passed through the heater 26 into the blower 27. The air introduction guide 8 is formed by an introduction flow path forming member 12 attached to the blower 27 as shown in FIG.

  As shown in FIGS. 3 and 4, the introduction flow path forming member 12 has a substantially trapezoidal appearance, and includes a flow path forming portion 21 and an attachment portion 22. As shown in FIG. 2, the flow path forming portion 21 is a portion surrounding the air inlet 35 of the blower 27 and is formed by bending a metal member having a predetermined width (length in the depth direction in FIG. 3). It is a thing. That is, the flow path forming unit 21 includes two inclined walls (enclosure walls) 37 and 38 and a connecting wall (enclosure wall) 40 that connects the two inclined walls 37 and 38. In the flow path forming portion 21, two inclined walls 37 and 38 are arranged at the end portions of the connecting wall 40, and the inclined walls 37 and 38 are connected to the connecting wall 40 from the end portion of the connecting wall 40. The inclined walls 37 and 38 are arranged in an inclined direction so as to extend away from the surface of the connecting wall 40 and extend away from each other. That is, the flow path forming unit 21 forms the surrounding space 32 by the inclined walls 37 and 38 and the connecting wall 40 and is the side facing the surface of the connecting wall 40, and the inclined walls 37 and 38 are the most separated. This is a portion having an open portion (inflow opening) 25 formed between the end portions.

  The attachment portion 22 is a portion that contributes to attachment to the blower 27 and is arranged on the outer side with respect to the trapezoidal shape of the introduction flow path forming member 12 so as to straddle the two inclined walls 37 and 38 and the connection wall 40. It is a provided part. Specifically, the attachment portion 22 includes a plate portion main body 41 disposed so as to be substantially orthogonal to the flow path forming portion 21, and the plate portion main body 41 includes two inclined walls 37 and 38 and a connection wall 40. It is arranged to straddle. In the present embodiment, the plate portion main body 41 is disposed so as to straddle a part of the two inclined walls 37 and 38 and the entire connecting wall 40. The plate portion main body 41 has a contour side 42 at a position away from the flow path forming portion 21, and the contour side 42 is formed in a curved shape. Specifically, the contour side 42 is a circular arc that is a part of a circle having a radius r (for example, a length equal to or slightly longer than the length of the connecting wall 40). The plate portion main body 41 is provided with three through holes 43 through which fastening means such as screws penetrating in the member thickness direction are inserted.

  As shown in FIG. 2, the resistance plate 11 is a rectangular plate having a predetermined size, and equalizes the deviation of the flow distribution of the air discharged from the blower 27. That is, the resistance plate 11 includes a resistance portion 45 and a fixing portion 46 bent in a direction substantially perpendicular to the end portion of the resistance portion 45.

Next, the positional relationship between devices and members in the environmental test apparatus 1 will be described.
As described above, the environmental test apparatus 1 according to the present embodiment is divided into the test chamber 6 and the air conditioning passage 7 by the partition wall 4 provided in the constant temperature and humidity chamber 5. That is, the test chamber 6 and the air conditioning passage 7 are in a relationship adjacent to each other with the partition wall 4 as a boundary. In addition, the test chamber 6 and the air conditioning passage 7 are also in communication with each other through openings 9 and 19 provided above and below the partition wall 4.

  And in the air-conditioning channel | path 7, the humidifier 14, the evaporator 15, the heater 26, and the air blower 27 are installed in order from the air flow direction upstream (lower side of FIG. 1). The devices are arranged in series in the air-conditioning passage 7 at regular intervals. More specifically, the humidifier 14 is fixed so as to be positioned substantially at the center of the bottom of the air conditioning passage 7, and the evaporator 15 is formed in a projection area formed when the humidifier 14 is projected vertically upward. Almost all are fixed, and the heater 26 is formed when almost all belongs to the projection area formed when the humidifier 14 is projected vertically upward, and the evaporator 15 is projected vertically upward. The remaining part of the blower 27 deviates from the projection area of the evaporator 15, and the blower 27 is a projection area formed when the outer member 33 projects the humidifier 14 vertically upward. Almost all belong to the projection area formed when the evaporator 15 is projected vertically upward, and it is the same as the projection area formed when the heater 26 is projected vertically upward. Part belongs and the rest is the area It is fixed so as to al deviate.

Further, in order to clarify the positional relationship among the humidifier 14, the evaporator 15, the heater 26, and the blower 27, based on the size of the projection area in the vertical direction in the installation posture, the relative of each device in the present embodiment. In addition, the humidifier 14 is the largest, and the outer member 33 of the evaporator 15, the heater 26, and the blower 27 is made smaller in order. In other words, the gap P between the inner wall of the air conditioning passage 7 and each device is the smallest at the position of the evaporator 15 (gap P1), the position of the heater 26 (gap P2), and the position of the outer member 33 of the blower 27. It is large in the order of (gap P3). And in this embodiment, the clearance gap P1 is formed between the evaporator 15 and the partition wall 4, the clearance gap P2 is formed between the heater 26 and the housing | casing 2, and the outer member 33 and the partition wall of the air blower 27 are formed. Each device is arranged so that a gap P3 is formed between the two. Therefore, in the air conditioning passage 7, there is a portion where the evaporator 15 does not cover the humidifier 14, there is a portion where the heater 26 does not cover the evaporator 15, and a portion where the blower 27 does not cover the heater 26. There is. For this reason, in this embodiment, the guide plate 34 is provided so that the air which passed the evaporator 15 cannot flow in into the clearance gap P2. That is, as shown in FIG. 1, the guide plate 34 is disposed from the housing 2 side end of the evaporator 15 to the lower end of the heater 26.
In the present embodiment, the gap P3 is used as a main flow path that guides air to the blower 27. That is, the blower 27 is installed in a posture in which the intake port 35 is opened toward the gap P3.

  An air introduction guide 8 is provided so as to surround the air inlet 35 of the blower 27. That is, as shown in FIG. 1, the introduction flow path forming member 12 is arranged in a gap P <b> 3 formed between the outer member 33 of the blower 27 and the partition wall 4, and is connected to the blower 27 via the attachment portion 22. It is fixed. More specifically, the introduction flow path forming member 12 has an end portion (hereinafter also simply referred to as a projecting end side end) facing the end portion of the flow path forming portion 21 where the mounting portion 22 is located in the partition wall 4. It is fixed to the blower 27 in a posture arranged to face each other. At this time, a constant gap is formed between the protruding end side end portion of the flow path forming portion 21 and the partition wall 4. That is, the surrounding space 32 of the flow path forming portion 21 is also surrounded by the outer wall member 33 of the blower 27 in addition to the inclined walls 37 and 38 and the connecting wall 40.

  In addition, as shown in FIGS. 1, 2, and 5, the flow path forming unit 21 is disposed at a position vertically above the heater 26 with the connecting wall 40 in a posture substantially parallel to the bottom surface of the air conditioning passage 7. In addition, the entire inflow opening 25 of the flow path forming portion 21 is disposed immediately above the heater 26. Specifically, the flow path forming portion 21 has a predetermined range 1 in which the total length extending in the longitudinal direction of the inflow opening 25 extends in the longitudinal direction of the heater 26 (in this embodiment, the total length L including the center in the longitudinal direction). About 1/2 to 2/3 times the vertical projection area).

  Therefore, in this embodiment, the air introduction guide 8 guides the air above the heater 26 from the inflow opening 25 into the surrounding space 32, and the air travels along the flow path forming unit 21 and the outer member 33 of the blower 27. Therefore, the arrangement can guide to the air inlet 35 of the blower 27.

  In addition, a blocking wall 16 is disposed on the top of the blower 27. That is, the blocking wall 16 is arranged so that the opening 17 penetrating in the member thickness direction communicates with the air conditioning passage 7 in the vertical direction, and the opening 17 communicates with the discharge port 36 of the blower 27. .

  A resistance plate 11 serving as air flow resistance is attached on the upper surface side of the blocking wall 16 and in the vicinity of the opening 17. The resistance plate 11 is in an upright posture with respect to the blocking wall 16, and is fixed with a fixing portion 46 along the edge of the opening 17. Specifically, the resistance plate 11 is attached to a position where the discharge flow rate of air discharged from the blower 27 is large and which blocks the discharge direction of part of the air. More specifically, in the present embodiment, the resistance plate 11 has a length in which the protruding end in the height direction is in contact with the ceiling of the air conditioning passage 7 and extends along the edge of the opening 17 in the mounting posture. The (width) extends from a position slightly separated from the partition wall 4 until it reaches a part of the discharge port 36. That is, the resistance plate 11 reflects the air dispersed in the height direction from the blocking wall 16 to the ceiling surface of the air conditioning passage 7, and the depth direction of the air conditioning passage 7 from the partition wall 4 to the wall surface of the housing 2 ( In this arrangement, a part of the air dispersed in the horizontal direction in FIG. 1 can be reflected.

Next, the basic operation of the environmental test apparatus 1 of the present embodiment will be described.
In the environmental test apparatus 1 of the present embodiment, a desired environment is created in the test chamber 6 by circulating the air in the constant temperature and humidity chamber 5 by the blower 27. That is, the air in the constant temperature and humidity chamber 5 is sucked by the blower 27 from the opening 9 on the lower side of the partition wall 4 to the air conditioning passage 7 side, passes through the air conditioning passage 7 vertically upward, and the partition wall. 4 is discharged from the opening 19 on the upper side to the test chamber 6 side.

More specifically, when the blower 27 is activated, as shown in FIG. 6, the air in the air conditioning passage 7 is sucked into the intake port 35 of the blower 27 and discharged from the discharge port 36. And the air discharged from the air blower 27 is sent out from the opening 19 of the upper part side of the partition wall 4 to the test chamber 6 side. Thereby, an air flow is formed along the wall surface in the test chamber 6. Then, the air that has reached the opening 9 on the lower side of the partition wall 4 is again introduced into the air conditioning passage 7. As described above, the humidifier 14, the evaporator 15, and the heater 26 are arranged in order along the air flow direction in the air conditioning passage 7, so that the air introduced into the air conditioning passage 7 is The humidifier 14 is humidified as necessary, passes through the evaporator 15, and then flows to the heater 26 side.
The environmental test apparatus 1 monitors the current temperature (current temperature) and the current relative humidity (current relative humidity) in the test chamber 6 by the indoor temperature detection means 23 and the indoor humidity detection means 24, and has a predetermined setting. Based on the conditions, each device (humidifier 14, evaporator 15, heater 26, blower 27, etc.) is controlled.

Then, the characteristic function in the environmental test apparatus 1 of this embodiment is demonstrated.
The environmental test apparatus 1 according to the present embodiment facilitates temperature and humidity adjustment in the test chamber 6 by suppressing uneven distribution of the temperature and humidity of the air discharged from the blower 27 during the basic operation. Furthermore, it has a function of suppressing uneven distribution of temperature and humidity in the test chamber 6.

  The environmental test apparatus 1 of the present embodiment provides the air introduction guide 8 on the upstream side of the blower 27 to restrict the air flowing into the blower 27. In other words, in the present embodiment, the air introduction guide 8 prevents the flow of air from the stagnant region where the air is stagnant to the blower 27, and guides the desired temperature-adjusted air to the blower 27. As a result, since the air inlet 35 of the blower 27 approaches the heater 26 side in a pseudo manner, the air near the heater 26 can be guided into the blower 27. Specifically, as shown in FIG. 7, the distance H from the air inlet 35 to the heater 26 is reduced to the pseudo distance h by providing the air introduction guide 8. More specifically, the inflow opening 25 of the introduction flow path forming member 12 is brought close to the heater 26, and the inflow opening 25 is directed downward so as to open toward the heater 26. Thereby, the air suck | inhaled by the inlet port 35 of the air blower 27 turns into the air which passed the inflow opening 25 substantially, and the distance of the air inlet 35 of the air blower 27 and the heater 26 is shrunk | reduced pseudo. As a result, the air introduction guide 8 can concentrate the air suction force in the blower 27 downward. That is, when the blower 27 is started, as shown in FIG. 7, in order to suck the air in the vicinity of the heater 26, that is, the air just above the heater 26, the air passes through the heater 26 and the gap P2. Then, the air that reaches the vicinity of the downstream side of the heater 26 flows so as to be sucked into the surrounding space 32 in the air introduction guide 8. In particular, in the present embodiment, the proportion of air that has passed through the heater 26 can be increased. Thereby, uneven distribution of the temperature and humidity of the air taken into the blower 27 can be greatly reduced.

  The air thus taken into the blower 27 is discharged from the discharge port 36 to the outside of the blower 27. That is, the air is discharged from the blower 27 through the opening 17 of the blocking wall 16 at a flow rate that is mainly biased in the rotational direction (winding direction) of the rotary fin 28. Specifically, the discharge flow rate of the blower 27 is large in the right direction (the rotational direction of the rotary fin 28) and small in the left direction (the counter-rotating direction of the rotary fin 28) with reference to FIG. However, in this embodiment, since the resistance plate 11 is provided in the vicinity of the opening 17, a part of the air flowing in the rotation direction of the rotary fin 28 collides with the resistance plate 11 as shown in FIGS. Thus, the air is rebounded in the direction opposite to the rotational direction of the rotary fin 28 and only the remaining air passes between the resistance plate 11 and the housing 2 and flows in the rotational direction. Thereby, the air discharged from the blower 27 spreads almost evenly in the width direction of the air conditioning passage 7 (left and right direction in FIG. 8), and is sent into the test chamber 6. That is, air with almost no uneven distribution of temperature and humidity can be sent into the test chamber 6 with a substantially uniform flow rate distribution.

  As described above, in the present embodiment, the air introduction guide 8 is provided, the air reaching the downstream vicinity of the heater 26 is limited to be sucked from the intake port 35 of the blower 27, and the temperature of the air passing through the intake port 35 is limited. Since the uneven distribution of humidity and humidity can be reduced, the uneven distribution of temperature and humidity of the air discharged from the blower 27 can be suppressed within a predetermined range. That is, as shown in Table 1 below, in the case of the environmental test apparatus 1 having the above-described configuration (Example), the temperature distribution unevenness of the air discharged from the discharge port 36 of the blower 27 is within 1.0 degree Celsius. (Actually 0.3 degrees Celsius), but in the case of a conventional environmental test apparatus that does not have the air introduction guide 8 (comparative example), the temperature distribution unevenness of the air discharged from the discharge port of the blower Exceeded 3.0 degrees Celsius (actually 3.2 degrees Celsius).

  Moreover, in this embodiment, since the resistance plate 11 is provided and the uneven distribution of the flow rate discharged from the blower 27 can be made substantially uniform, uneven distribution of temperature and humidity in the test chamber 6 can be suppressed. As a result, the temperature and humidity in the test chamber 6 can be easily adjusted, and the test environment can be maintained more stably. Thereby, according to this embodiment, test accuracy can improve and the reliability of a test result can be improved.

In the above embodiment, the configuration in which the introduction flow path forming member 12 has a trapezoidal shape is shown. However, the present invention is not limited to this, and other shapes of the introduction flow path forming member may be adopted. Absent. For example, as shown in FIG. 9, the introduction flow path forming member 38 is a “mountain” shape having a curved surface by bending a member having a certain width into a curved shape, or a triangular shape as shown in FIG. 10. The introduced flow path forming member 39 may be used.
Further, the contour side of the mounting portion of the introduction flow path forming member is not limited to the arc shape, and may be trapezoidal, curved, or triangular according to the shape of the introduction flow path forming member.

Moreover, in the said embodiment, although the width | variety of the inflow opening 25 of the flow-path formation part 21 showed only the member width (length from the partition wall 4 to the outer member 33 of the air blower 27), the structure which showed this invention was shown. However, the present invention is not limited to this, and a configuration in which the width of the inflow opening is wider than that in the above embodiment may be used. For example, as shown in FIG. 11, a flow path forming portion 47 having a flow path opening 50 expanded to the same width as the heater 26 can be mentioned.
Furthermore, in the present invention, as shown in FIG. 12, a case-shaped introduction flow path forming member 48 having a communication opening 49 communicating with the inlet opening 25 and the air inlet 35 of the blower 27 may be adopted.

In the above-described embodiment, the configuration in which the resistance plate 11 is fixed so as to stand on the blocking wall 16 is shown, but the present invention is not limited to this, and the resistance plate 11 is suspended from the top surface of the housing 2. It may be configured to be fixed. Moreover, as shown in FIG. 13, you may fix to the obstruction | occlusion wall 16 so that it may incline at a fixed angle using the inclination resistance board 51. As shown in FIG. Similarly, the resistance plate 51 may be fixed to the ceiling surface of the housing 2.
As another configuration, as shown in FIG. 14, a suspension member 53 is attached to the ceiling surface of the housing 2, and the resistance plate 52 is suspended from the suspension member 53 so as to exhibit a certain inclination. It doesn't matter.

  In the above embodiment, the configuration using the rectangular resistor plate 11 is shown. However, the present invention is not limited to this, and as shown in FIG. 15, the configuration using the resistor plate 55 having a curved cross-sectional shape. It does not matter.

  In the above embodiment, the configuration in which the planar resistance plate 11 having a uniform thickness is employed is shown. However, the present invention is not limited to this, and a predetermined number of slits 57 are formed as shown in FIG. The resistor 56 may be used.

  In the above embodiment, the configuration of the environmental test apparatus 1 adopted as a constant temperature and humidity apparatus has been described as an example. However, the present invention is not limited to this, and is similarly applied to a constant temperature apparatus that does not include the humidifier 14. it can. The present invention can also be applied to an environmental test apparatus having other functions, such as a thermal shock test apparatus.

  In the above embodiment, the air conditioning passage 7 is arranged on the side of the test chamber 6 and the air flows in the height direction. However, the present invention is not limited to this, and the air conditioning passage 7 is connected to the test chamber 6. It may be arranged above or below the air so that air flows in the horizontal direction.

  In the said embodiment, although the structure arrange | positioned in order of the humidifier 14, the evaporator 15, and the heater 26 from the air flow direction upstream in the air-conditioning channel | path 7 was shown, this invention is not limited to this, For example, The heater 26, the humidifier 14, the evaporator 15 or the evaporator 15, the humidifier 14, the heater 26, etc. may be arranged in any order from the upstream side.

In the above-described embodiment, the configuration in which the humidifier 14 is the largest in the vertical projection area, and the device that decreases in the order of the evaporator 15 and the heater 26 has been employed. There is no limitation, and the size of each device may be any size. That is, each device arranged in the air conditioning passage 7 can be expected to have the same effect as that of the above embodiment regardless of the positional relationship and size thereof.
However, when the size of each device is changed, a configuration in which the device having the smallest vertical projection area is disposed at the position closest to the air introduction guide 8 in the air conditioning passage 7 (the most downstream side) is preferable. In that case, a particularly high effect can be obtained.

  In the said embodiment, although the structure provided with the two heat sources of the evaporator 15 and the heater 26 in the air-conditioning channel | path 7 was shown, this invention is not limited to this, It is a structure provided only with one of the heat sources. It does not matter.

  In the said embodiment, although the structure which the protrusion side edge part of the introduction flow path formation member 12 of the air introduction guide 8 does not contact | abut to the partition wall 4 was shown, this invention is not limited to this, The introduction flow path formation member 12 The projecting side end may be in contact with the partition wall 4. As a result, the stay region that can be formed above the intake port 35 of the blower 27 and the surrounding space 32 that guides the adjusted air to the intake port 35 of the blower 27 have a structure that is further blocked. The uneven distribution of the temperature and humidity of the air flowing into the air can be further uniformized.

  In the above embodiment, the configuration in which the guide plate 34 is provided between the heater 26 and the evaporator 15 in order to block the air passing between the heater 26 and the housing 2 has been described. However, the present invention is not limited to this, and the guide plate 34 may not be provided.

1 Environmental test equipment 4 Partition wall 6 Test room (test space)
7 Air conditioning passage (air conditioning space)
8 Air introduction guide 11, 51, 52, 55 Resistance plate (resistor)
12 Introducing flow path forming member 14 Humidifier 15 Evaporator (cooler, second heat source)
16 Blocking wall 17 Openings 21, 47 Flow path forming portions 25, 50 Inflow opening 26 Heater (heat source)
27 Blower 28 Rotating fin 32 Enclosure space 33 Outer member 35 Inlet port 36 Outlet port 56 Resistor

Claims (8)

It has an air conditioning space having a heat source and a blower, and a test space in which a sample body is arranged, and air is circulated between the air conditioning space and the test space to form a desired environment in the test space. An environmental testing device,
In the air conditioning space, the heat source and the blower are arranged in this order from the upstream side of the air flow direction, and the blower is arranged such that the passage direction of the air sucked into the blower intersects the passage direction of the air passing through the heat source. Installed in the
A blocking wall is provided to restrict the flow of air from the air conditioning space to the test space;
The blower has a discharge port for discharging air,
The blocking wall has an opening;
The opening communicates with a discharge port of the blower,
Between the heat source and the blower, an air introduction guide that guides the air whose temperature is mainly adjusted by the heat source to the blower is provided ,
The blower has an air inlet, and air is sucked from the air inlet,
The environmental test apparatus characterized in that the air introduction guide has an enclosure wall surrounding a portion of the periphery of the intake port other than the direction in which the heat source is located, and an inflow opening for introducing air into the enclosure wall .   The air introduction guide has an inflow opening on an upstream side with respect to a flow direction of air, and the inflow opening is formed to open toward the heat source. The environmental test apparatus described. In the air conditioning space, the area occupied in the direction in which the heat source is perpendicular to the flow direction of the air, according to claim wherein said air adjusting space is equal to or smaller than the area occupied in a direction orthogonal to the flow direction of the air The environmental test apparatus according to 1 or 2 . It said inlet opening, environmental testing apparatus according to any one of claims 1 to 3, characterized in that the heat source is disposed so as to be located in a projection plane obtained by projecting toward the inlet opening. The blower has a discharge port for discharging the air in the vicinity of the discharge ports, according to claim 1-4, characterized in that the resistor which is a flow resistance of air is provided according to any one Environmental test equipment. The blower is a multi-wing fan,
The environmental test apparatus according to claim 5 , wherein the resistor is provided on a rotation direction side of the fan. A second heat source in the air conditioning space;
In the air adjustment space, the second heat source, the heat source, and the blower are arranged in this order from the upstream side in the air flow direction.
Area occupied in the direction in which the heat source is perpendicular to the flow direction of the air, any claim 1-6, wherein the second heat source is equal to or smaller than the area occupied in a direction orthogonal to the flow direction of the air The environmental test apparatus according to the above. The environmental test apparatus according to claim 7 , wherein the heat source is a heater, and the second heat source is a cooler.

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