JP2005189148A - Environment-testing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an environment-testing system which is reduced in the consumption of energy and easy to install. <P>SOLUTION: A heat exchanger 9 for performing the heat exchange between the high-temperature/high-humidity air discharged from a desorbing zone 4 of a dehumidifying rotor 1, and open air OA is provided and the open air OA which is raised in temperature by the heat exchanger 9 is heated by a heater 8, to be passed through the desorbing zone 4. Accordingly, the energy of the air discharged from the desorbing zone 4 is recovered efficiently, not only for suppressing the consumption of energy, but also for fully lowering the temperature of an exhaust gas EA; and the air discharged can be discharged into a room, and the exhaust equipment to the open air can be omitted. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an environmental test system that adjusts and maintains a test chamber interior space at constant temperature and humidity, and particularly relates to an environmental test system that consumes less energy and is easy to install.

  The environmental test room simulates various environmental conditions by changing the temperature and humidity of the interior space of the test room to measure and test the performance of the sample in various environments, and It is used in a wide range of industrial fields, such as used for finding.

  Such an environmental test chamber is operated as one system combined with a cooling device and a heating device for temperature control, and a dehumidifying device and a humidifying device for humidity control. In this environmental test room, it is required in some cases to keep the room at a very low dew point. Therefore, an adsorption type dehumidifier is used as the combined dehumidifying device.

A dehumidifying device used in combination with such an environmental test chamber is often operated for a long time, and a device that consumes less energy while maintaining a low dew point of supplied air is required. An example of a conventional dehumidifying device used with such an environmental test room is disclosed in Japanese Patent No. 2731499. In order to reduce energy consumption, this conventional dehumidifying device has an appropriate angular range such as a purge zone and each processing zone in a dehumidifying rotor, and air that has exited the regeneration processing zone by a heat exchanger, Heat is exchanged between the air exiting the purge zone and the mixed air of the air exiting the regeneration pretreatment zone to recover thermal energy.
Japanese Patent No. 2731499

  In the conventional dehumidifying device disclosed in Patent Document 1, the heated air after passing through the regeneration treatment zone is hot and humid, and the heat held by the heated air is recovered by a heat exchanger. The heat exchange target air passes through the regeneration pretreatment zone and the purge zone and rises in temperature compared to the outside air. Therefore, the heated air leaving the regeneration treatment zone is sufficient even after heat exchange in the heat exchanger. However, this heated air will not be discharged into the atmosphere but a duct as a discharge path that leads the exhaust from the equipment part to the outside must be provided. Has a problem of cost.

  In addition, since the heated air that is hot and humid is cooled with heat exchange, condensed water may be generated in the heat exchanger, so it is necessary to provide a conduit for discharging condensed water together with the heat exchanger. In addition, there is a problem that the structure of the apparatus becomes complicated and expensive.

  The present invention has been made to solve the above-mentioned problems. When the dehumidifying device and the test room are integrated and installed in a building, a duct leading to the outside of the building is not provided at all or a minimum of 1 An object of the present invention is to provide an environmental test system that can be completed simply by providing a book, is easy to install, and consumes less energy.

  The environmental test system according to the present invention is provided with a heat exchanger for exchanging heat between high-temperature and high-humidity air discharged from the desorption zone of the dehumidification rotor and the outside air, and allows the outside air whose temperature has been raised by heat exchange to pass through the heater through the desorption zone. As a result, the dehumidification efficiency is improved, and the temperature of the air that has left the desorption zone can be sufficiently lowered by heat exchange with the outside air, and this air can be discharged into the building.

  As described above, according to the present invention, the air exhausted from the system includes air that has sufficiently decreased in temperature by heat exchange with the external air after leaving the desorption zone, and low-humidity air that is partially exhausted from the test chamber. By having only two types, the temperature of the air exhausted from the system can be kept low, there is no problem even if it is exhausted inside the building, there is no need to provide an exhaust route to the outside of the building, and installation costs can be reduced There is an effect. Further, in the heat exchanger, heat is exchanged between the outside air, which is the air having the largest temperature difference, and the regenerative exhaust, so that the heat recovery rate is increased and the energy consumption in the entire system can be reduced. It has the effect.

  Further, according to the present invention, a blower is provided between the desorption zone outlet side and the heat exchanger, and the air from the blower passes through the heat exchanger and is then discharged out of the system. It is difficult to reach the outside, is excellent in quietness, and has an effect of preventing problems in terms of noise even when air is exhausted into the building.

  In addition, according to the present invention, a blower is provided immediately below the heat exchanger, and when condensed water is generated in the heat exchanger, the condensed water is caused to flow down to the blower, so that the condensed water is discharged to the blower. The drain pipe provided can be shared, and it is not necessary to provide a separate condensed water discharge pipe for the heat exchanger, so that the structure can be simplified and the entire system can be made compact.

  In addition, according to the present invention, the amount of air returning from the test chamber internal space is less than the amount of air sent to the test chamber internal space, so that the test chamber internal space becomes positive pressure and is externally connected to the test chamber internal space. Therefore, the air in the test chamber space can be reliably maintained at a low dew point. Furthermore, because the air sent to the test room interior space is the air recirculated from the test room interior space and the outside air to compensate for the shortage, a part of the air in the test room interior space is always ventilated, It has the effect that the oxygen supply to the worker in the test chamber interior space can be secured.

  In addition, according to the present invention, the air recirculated from the test chamber is also introduced into the purge zone of the dehumidification rotor, and the humidity of the air passing through the purge zone is reduced, thereby further promoting the purge action in the purge zone and dehumidifying. The performance of the rotor can be further exerted, and the air supplied to the test chamber through the adsorption zone can be reliably maintained at a low humidity.

  The invention according to claim 1 of the present invention is provided with a heat exchanger that divides the dehumidification rotor into an adsorption zone, a desorption zone, and a purge zone, and exchanges heat between the high-temperature / humidity air that has come out of the desorption zone and the outside air, The outside air whose temperature has been raised by heat exchange is passed through the heater to the desorption zone, so that heat can be reliably recovered and the temperature of the air leaving the desorption zone can be sufficiently lowered and released.

  Hereinafter, an embodiment of the environmental test system of the present invention will be described in detail with reference to FIG. 1 and FIG. FIG. 1 is a block diagram of the environmental test system of the present invention, and FIG. 2 is a cross-sectional view of the main part of the environmental test system of the present invention. A dehumidifying rotor 1 constituting a dry dehumidifying device is formed as a rotating body in which ceramic paper or the like is arranged in a honeycomb (honeycomb) shape and allows air to flow substantially parallel to the rotation axis direction. An adsorbent is supported.

  The dehumidifying rotor 1 is slowly rotated at a speed of about 25 rph by a geared motor (not shown), and is divided into a moisture adsorption zone 2 for the circulating air, a purge zone 3, and a desorption zone 4.

  The outside air OA is guided to the suction side of the processing blower 6 through the outside air duct 5 and is sent to the purge zone 3 and the adsorption zone 2 by the processing blower 6. Dry air that has exited the adsorption zone 2 is supplied to the internal space of the test chamber 7 as supply air SA.

The air inside the test chamber 7 is returned to the suction side of the processing blower 6 as return air RA. For example, if the amount of supply air SA is 750 m ³ / h, the amount of return air RA is adjusted to be 740 m ³ / h, and the amount of air of this difference is exhausted from the test chamber 7 by 10 m ³ / h. It is discharged through a hole (not shown). Since the return air RA from the test chamber 7 is sent again to the adsorption zone 2 of the dehumidification rotor 1, the dew point of the air in the test chamber 7 can be made extremely low.

  Air from the processing blower 6 is also sent to the purge zone 3. The air flowing through the purge zone 3 cools the portion of the dehumidifying rotor 1 that has been at a high temperature immediately after the desorption of moisture, and conversely, the temperature of the air that has passed through the purge zone 3 rises. The air whose temperature has risen is heated by the heater 8 and enters the desorption zone 4. Since part of the return air RA from the test chamber 7 is also directed to the purge zone 3, it is possible to introduce air with increased dryness, and the purge effect in the purge zone 3 can be increased, and further the desorption zone 4 on the downstream side. This also improves the playback effect.

  On the other hand, the outside air that has passed through the outside air duct 5 passes through the heat exchanger 9 and is raised in temperature, and then mixed with the air that has passed through the purge zone 3 and heated by the heater 8 and enters the desorption zone 4. In the desorption zone 4, the adsorbent is regenerated with heated air, while the air takes in moisture and becomes humid.

  The hot and humid air leaving the desorption zone 4 is sent to the upper heat exchanger 9 by the desorption blower 10 for delivery. The heat exchanger 9 performs sensible heat exchange between two airs. That is, the heat exchanger 9 exchanges heat between the hot and humid air exiting the desorption zone 4 and the outside air OA. As a result, the temperature of the outside air OA increases, and conversely, the temperature of the hot and humid air that has left the desorption zone 4 decreases. The desorption blower 10 is provided directly under the heat exchanger 9 as shown in FIG. A drain pipe 13 for discharging drain generated in the blower to the outside is attached to the desorption blower 10.

  In this environmental test system, the air having the highest temperature is the air immediately after leaving the heater 8, the air passing through the desorption zone 4 has the second highest temperature, and the outside air OA has the lowest temperature. Therefore, the energy recovery efficiency by the heat exchanger 9 is high.

Since the temperature of the high-temperature and high-humidity air that has left the desorption zone 4 is lowered by the heat exchanger 9, condensation (condensed water) may occur inside the heat exchanger 9. Therefore, it is desirable to provide a drain pipe (not shown) in the heat exchanger 9, but since the desorption blower 10 is disposed immediately below the heat exchanger 9, as shown in FIG. The drain pipe 13 of the desorption blower 10 can be shared by flowing down to the desorption blower 10 side as it is, and even if condensed water is generated in the heat exchanger 9, it can be discharged without any problem. Further, when such condensed water is generated, the heat exchanger 9 can recover up to the condensation heat, and the heat recovery efficiency is further increased.
The constituent elements described above are integrated together to form an environmental test system 11, which is installed in the building 12.

Here, an example of the amount of air passing through each part will be described. The outside air OA passes through the outside air duct 5 at 220 m ³ / h. Among these, 155 m ³ / h flows to the heat exchanger 9, 65 m ³ / h outside air and 740 m ³ / h return air RA are mixed, and a total of 805 m ³ / h air passes through the processing blower 6. .

Of the air that has passed through the processing blower 6, 55 m ³ / h of air passes through the purge zone 3, and 750 m ³ / h of air passes through the processing zone 2 and is sent to the environmental test chamber 7. The 55 m ³ / h air that has passed through the purge zone 3 is mixed with the 155 m ³ / h air that has passed through the heat exchanger 9 to become 210 m ³ / h air and passes through the heater 8.

From the above, the amount of hot and humid air passing through the heat exchanger 9 is 210 m ³ / h, and heat exchange is performed with 155 m ³ / h outside air OA. That is, the amount of hot and humid air to be discharged to the outside is larger than the amount of air sent to the desorption zone 4, so that sufficient heat recovery can be performed and the temperature of the air sent to the desorption zone 4 is increased as much as possible. Energy consumption can be suppressed.

  On the other hand, since the temperature of the exhausted hot and humid air can be sufficiently lowered by the heat exchanger 9, even if the air exhausted from the environmental test system 11 is exhausted into the building 12, problems are unlikely to occur. When installing, only the outside air duct 5 for introducing outside air may be installed from outside the building 12.

  In the above embodiment, the outside air is introduced from the outside of the building 12 to the environmental testing system 11 by the outside air duct 5, but the air in the building 12 is guided to the environmental testing system 11 without using the duct 5. Also good. In this case, no duct work is required for installation work.

  INDUSTRIAL APPLICABILITY The present invention is an environmental test system that adjusts the inside of a test room to constant temperature and humidity, and can provide a system that consumes less energy and can be easily installed.

It is a block diagram of the environmental test system of this invention. It is principal part sectional drawing of the environmental test system of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Dehumidification rotor 2 Adsorption zone 3 Purge zone 4 Desorption zone 5 Outside air duct 6 Process blower 7 Test chamber 8 Heater 9 Heat exchanger 10 Desorption blower 11 Environmental test system 12 Building 13 Drain pipe

Claims (5)

A dehumidification rotor composed of a rotating body capable of air circulation substantially parallel to the rotation axis direction with respect to the inside, and an air circulation portion of the dehumidification rotor includes a moisture adsorption zone and a desorption zone for the circulating air; and In an environmental test system that uses a dry dehumidifier divided into a purge zone to dehumidify the air to be treated and then continuously supply it to a predetermined test chamber space.
After desorbing moisture in the desorption zone, a high-temperature and high-humidity air that has flowed out of the desorption zone and a heat exchanger that exchanges heat with outside air that has been separately taken in from outside are provided, and the high-temperature and high-humidity air after heat exchange is discharged. An environmental test system characterized in that the outside air whose temperature has been increased through the heat exchange is once increased in temperature by a heater together with the air that has passed through the purge zone and then passed to the desorption zone. The environmental test system according to claim 1, wherein a blower for sending out the high-temperature and high-humidity air is provided between the desorption zone outlet side and the heat exchanger. The environmental test system according to claim 2, wherein the blower is disposed immediately below the heat exchanger and includes a drain pipe for draining. While most of the air supplied to the interior space of the test chamber is refluxed from the test chamber to the upstream side of the dehumidification rotor and mixed with the outside air taken in from the outside, it is led to at least the adsorption zone of the dehumidification rotor, while the test chamber The remaining proportion of the air supplied to the internal space is discharged outside the test room without recirculation, and a predetermined amount of new supply based on the outside air is always secured in the air supplied to the test room space. The environmental test system according to any one of claims 1 to 3. The environment according to claim 4, wherein the air that has been refluxed from the test chamber to the upstream side of the dehumidifying rotor and mixed with the outside air taken in from the outside is also introduced into the purge zone of the dehumidifying rotor. Test system.