JP2013034944A - Energy-saving dehumidification system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve controllability and maintainability and reduce an initial cost in an energy-saving dehumidification system.SOLUTION: The energy-saving dehumidification system 20 stores previously a first relational expression of an energy balance value obtained by dividing, by the treatment air amount passing through a dehumidification section 22, the energy of difference between an energy acquired by a low-temperature air passing through a purge section 23 when the dew-point temperature of a treatment air at the outlet side of the section 22 is a prescribed value, and an energy lost from a high-temperature air passing through a regeneration section 24, with a regeneration air amount ratio obtained by dividing the amount of high-temperature air passing through the regeneration section 24 by the amount of the treatment air passing through the section 22. The system is provided with a controller for controlling the regeneration air amount ratio to conform to the first relational expression at the time when the dew-point temperature of the treatment air at the outlet side of the dehumidification section estimated by the actually-measured energy balance value and regeneration air amount ratio, and the first relational expression is a prescribed one.

Description

  The present invention relates to an energy saving dehumidification system that adsorbs moisture from process air passing through a rotatable dehumidification rotor impregnated with a dehumidifying agent to dehumidify the process air and provide a low humidity environment.

  In general, in factories such as lithium ion secondary batteries and electric double layer capacitors, moisture contained in the air affects the yield, performance, and reliability of the product, so the dew point temperature is -50 ° C DP or less. A very low humidity environment is needed.

  Therefore, conventionally, in the manufacturing factory, as shown in FIG. 5 or FIG. 6, for example, glass fiber paper or ceramic paper is impregnated with a dehumidifying agent such as silica gel or zeolite and formed into a cylindrical shape. Various dehumidification systems equipped with a rotor 1 are installed.

  In this case, the dehumidifying rotor 1 includes a dehumidifying section 2 that adsorbs moisture from the passing processing air and dehumidifies the processing air, a regeneration section 3 that is heated by the passing hot air and desorbs moisture, and a passing low temperature. A purge section 4 that is cooled by air is provided, and the sections 2, 3, and 4 are continuously dehumidified, regenerated, and purged while constantly rotating to supply low dew point air.

  As a specific dehumidifying system of this type, the system shown in FIG. 5 or FIG. 6 is usually adopted in many cases. In this type of dehumidification system, the outside air (OA) precooled and dehumidified by the precooler 5 and the return air (RA) from the manufacturing plant are supplied to the dehumidification rotor 1 by the supply fan 6 as process air, and the dehumidification rotor 1 is dehumidified. In section 2, moisture in the processing air is adsorbed and removed, cooled by the aftercooler 7, and then supplied into the environment of the manufacturing plant.

  On the other hand, the air that has passed through the purge section 4 of the dehumidifying rotor 1 is heated to a predetermined temperature (about 140 ° C.) by the regenerative heater 8 to become high-temperature air, and is then transported to the regenerating section 3 by the exhaust fan 9. 1 is heated to desorb moisture. Thereafter, the air that has passed through the regeneration section 3 is exhausted to the outside as shown in FIG. 5, or a part of the air returns to the upstream side of the regeneration heater 8 as shown in FIG. So that it is circulated.

  However, this type of dehumidification system does not control the operation according to the moisture load, and thus has a problem that the running cost increases. In such a dehumidification system, the energy consumption is the largest in the regeneration section 3 when it is desorbed the moisture adsorbed on the dehumidification rotor 1 (regenerative energy). 50 to 60% of the total. On the other hand, the required regenerative energy varies greatly depending on the moisture load. For example, during the winter or at night, the moisture load becomes small, so that the necessary regenerative energy is small. For this reason, various dehumidification systems that control the regenerative energy according to the moisture load have been proposed.

  For example, a dew point meter that measures the dew point temperature at the outlet of the dehumidifying section is installed, and the amount of air passing through the regeneration section (regenerative air amount) and regeneration so that the dew point temperature measured by this dew point meter becomes the predetermined dew point temperature. There is a dehumidification system that controls the temperature on the inlet side of a section (regeneration temperature) or the rotation speed of a dehumidification rotor (see Patent Document 1).

  In addition, an absolute hygrometer (dew point meter) that measures the absolute humidity (dew point temperature) on the inlet side of the dehumidifying section is installed, and the absolute humidity (dew point temperature) measured by the absolute hygrometer (dew point temperature) is There is a dehumidification system that predicts the dew point temperature on the outlet side and controls the regeneration air volume or the regeneration temperature so that the dew point temperature becomes a predetermined dew point temperature (see Patent Document 2).

Japanese Patent No. 3266326 JP 2007-260506 A

  However, the above-described dehumidification system of Patent Document 1 has the following problems.

  In other words, a capacitance type dew point meter or a mirror-cooled dew point meter is usually used as a dew point meter for measuring low dew point air. However, a capacitance type dew point meter has a large measurement error and a slow response speed. Therefore, the regeneration air volume or regeneration temperature is controlled at a dew point temperature different from the original dew point temperature, which may be significantly higher than the predetermined dew point temperature.

  On the other hand, in the case of a mirror-cooled dew point meter, the measurement error and response speed are faster and the response speed is faster than the capacitance type dew point meter. Maintenance is required. Further, the amount of the mirror-cooled dew point meter is about 5 to 10 times that of the capacitance type dew point meter, and there is a problem that the initial cost is increased.

  Moreover, in the case of the dehumidification system of patent document 2 mentioned above, in order to measure the absolute humidity (dew point temperature) of the entrance side of a dehumidification section, the absolute humidity meter (dew point meter) whose measurement range is higher than the dehumidification system of patent document 1 mentioned above However, since an absolute hygrometer (dew point meter) is still required, the measurement accuracy, responsiveness, maintainability, and initial cost are the same as in the case of the dehumidification system of Patent Document 1 described above. There is a problem.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a dehumidification system with good measurement accuracy, fast response speed, good controllability, excellent maintainability, and low initial cost. It is what.

  In order to achieve the above object, the present invention provides an energy saving dehumidification system including a rotatable dehumidification rotor impregnated with a dehumidifying agent, wherein the dehumidification rotor absorbs moisture from the processing air passing therethrough and performs the treatment. A dehumidifying section for dehumidifying the air; a regeneration section heated by the passing hot air to desorb moisture; and a purge section cooled by the passing cold air; and the processing air at the outlet side of the dehumidifying section When the dew point temperature is a predetermined value, the difference energy between the energy acquired by the cold air passing through the purge section and the energy lost by the hot air passing through the regeneration section passes through the dehumidification section. The energy balance value obtained by dividing by the air volume of the processing air and the high-temperature air passing through the regeneration section The first relational expression of the reproduction air volume ratio obtained by dividing the air volume by the air volume of the processing air passing through the dehumidifying section and the energy balance value and the regeneration air volume ratio obtained by actual measurement are stored in advance. And a control for controlling the regenerative air flow ratio so that the estimated dew point temperature of the processing air at the outlet side of the dehumidifying section estimated by the first relational expression and the first relational expression coincides with the first relational expression at a predetermined dew point temperature. A device is provided.

  The present invention is also an energy saving dehumidification system comprising a rotatable dehumidification rotor impregnated with a dehumidifying agent, wherein the dehumidification rotor adsorbs moisture from the process air passing therethrough and dehumidifies the process air. And a regeneration section that is heated by the passing hot air to desorb moisture, and a purge section that is cooled by the passing cold air, and the dew point temperature of the processing air at the outlet side of the dehumidifying section is a predetermined value The difference energy between the energy acquired by the low temperature air passing through the purge section and the energy lost by the high temperature air passing through the regeneration section at the time is divided by the air volume of the processing air passing through the dehumidification section. The energy balance value obtained in this way and the temperature of the hot air at the inlet side of the regeneration section The estimated dew point of the processing air at the outlet side of the dehumidifying section, preliminarily stored with the second relational expression of temperature, and estimated from the energy balance value and regeneration temperature obtained by actual measurement and the second relational expression A control device for controlling the regeneration temperature is provided so as to match the second relational expression when the temperature is a predetermined dew point temperature.

  Furthermore, the present invention is an energy saving dehumidification system comprising a rotatable dehumidification rotor impregnated with a dehumidifying agent, wherein the dehumidification rotor adsorbs moisture from the process air passing therethrough and dehumidifies the process air. And a regeneration section that is heated by the passing hot air to desorb moisture, and a purge section that is cooled by the passing cold air, and the dew point temperature of the processing air at the outlet side of the dehumidifying section is a predetermined value The difference energy between the energy acquired by the low temperature air passing through the purge section and the energy lost by the high temperature air passing through the regeneration section at the time is divided by the air volume of the processing air passing through the dehumidification section. And the air flow rate of the high-temperature air passing through the regeneration section. The first relational expression of the reproduction air volume ratio obtained by dividing by the air volume of the processing air passing through the storage is stored in advance, and the regeneration air volume ratio is controlled so as to match the first relational expression, A second relational expression between the energy balance value when the dew point temperature of the processing air on the outlet side of the dehumidifying section is a predetermined value and the regeneration temperature that is the temperature of the hot air on the inlet side of the regeneration section Is stored in advance, and the control device controls the regeneration temperature so as to match the second relational expression, and the control apparatus controls the regeneration air flow ratio based on the first relational expression in the second relational expression. Dehumidification estimated by the first relational expression and the energy balance value and the regeneration air flow ratio obtained by actual measurement even if the regeneration air flow ratio control is performed in preference to the regeneration temperature control based on the equation On the exit side of the section When it is determined that the estimated dew point temperature of the processing air does not match the first relational expression at the predetermined dew point temperature, the energy balance value and the regeneration temperature obtained by actual measurement and the second relation The regeneration temperature is controlled so that the estimated dew point temperature of the processing air at the outlet side of the dehumidifying section estimated by the equation matches the second relational expression at the predetermined dew point temperature.

  According to the present invention, various excellent effects can be obtained, such as providing an energy saving dehumidification system with good measurement accuracy, fast response speed, good controllability, excellent maintainability, and low initial cost. Can do.

It is explanatory drawing which shows the energy-saving dehumidification system which concerns on embodiment of this invention. In the energy saving dehumidification system which concerns on embodiment of this invention, it is a figure which shows the relationship between an energy balance value and a reproduction | regeneration air volume ratio. In the energy-saving dehumidification system which concerns on embodiment of this invention, it is a figure which shows the relationship between an energy balance value and regeneration temperature. In the energy-saving dehumidification system which concerns on embodiment of this invention, it is a figure which shows the relationship between the temperature of the air on the exit side of a regeneration section, and the dew point temperature of the air on the exit side of a dehumidification section. It is explanatory drawing which shows the conventional energy-saving dehumidification system. It is explanatory drawing which shows another conventional energy saving dehumidification system.

  Hereinafter, an energy-saving dehumidification system according to an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is an explanatory diagram showing an energy saving dehumidification system according to an embodiment of the present invention. The dehumidification system 20 includes a dehumidification rotor 21 that is formed into a cylindrical shape by impregnating glass fiber paper or ceramic paper with a dehumidifying agent such as silica gel or zeolite, and the dehumidification rotor 21 includes driving means (illustrated) such as a motor. Omitted) to rotate at a predetermined speed.

  The dehumidification rotor 21 includes a dehumidifying section 22 that desorbs the processing air by adsorbing moisture from the processing air that passes by a partition plate, a regeneration section 24 that is heated by the passing high-temperature air and desorbs moisture, and passes through And a purge section 23 cooled by low-temperature air.

  The outside and the inlet side portion of the dehumidifying section 22 of the dehumidifying rotor 21 are connected by a first duct 25, and the first air volume adjusting damper (in order from the outside side in the direction of air flow) VD) 26, a precooler 27, and an air supply fan 28 are provided. A second duct 29 is branched from the first duct 25 to the downstream side of the air supply fan 28, and the second duct 29 is connected to an inlet side portion of the purge section 23 of the dehumidifying rotor 21. A first thermometer 30 for measuring the temperature of the air on the inlet side of the purge section 23 is provided in the vicinity of the purge section 23 of the second duct 29. The first thermometer 30 includes a thermocouple, A platinum resistance thermometer or the like is used.

  The outlet side of the dehumidifying section 22 of the dehumidifying rotor 21 and a space (for example, a dry room) where a low humidity environment is required are connected by a third duct 31, and an after cooler 32 is provided in the third duct 31. ing.

  The outlet side portion of the purge section 23 of the dehumidifying rotor 21 and the inlet side portion of the regeneration section 24 of the dehumidifying rotor 21 are connected by a fourth duct 33, and the purge section 23 is adjacent to the purge section 23 of the fourth duct 33. A second thermometer 34 is provided for measuring the temperature of the air on the outlet side, and a thermocouple, a platinum resistance thermometer, or the like is used for the second thermometer 34. In addition, a regeneration heater 35 is provided in the fourth duct 33, and a third thermometer 36 for measuring the temperature of the air on the inlet side of the regeneration section 24 is provided in the vicinity of the regeneration section 24 of the fourth duct 33. For the third thermometer 36, a thermocouple, a platinum temperature measuring resistor, or the like is used.

  The outlet side portion of the regeneration section 24 of the dehumidifying rotor 21 and the outside are connected by a fifth duct 37, and the temperature of the air on the outlet side of the regeneration section 24 is measured in the vicinity of the regeneration section 24 of the fifth duct 37. A fourth thermometer 38 is provided, and a thermocouple, a platinum resistance thermometer, or the like is used for the fourth thermometer 38. The fifth duct 37 is provided with an exhaust fan 39 and a second air volume adjustment damper (VD) 40.

  The fourth duct 33 on the upstream side of the regenerative heater 35 and the fifth duct 37 on the downstream side of the exhaust fan 39 are connected by a sixth duct 41 to form a circulation line, and a circulation damper is connected to the sixth duct 41. 42 is provided.

  In the dehumidifying system 20 having such a configuration, the outside air (OA) introduced from the outside as the processing air through the first duct 25 is precooled and dehumidified by the precooler 27 and then rotated by the air supply fan 28. Is supplied to the dehumidifying rotor 21. Of the processing air supplied to the dehumidifying rotor 21, processing air of a predetermined air volume passes through the dehumidifying section 22 via the first duct 25, and the remaining processing air of air volume is purged via the second duct 29. Pass through section 23.

  The dehumidification rotor 21 adsorbs moisture from the process air passing through the dehumidification section 22 to dehumidify the process air. The dehumidified process air is cooled by the aftercooler 32 and then is supplied as the low supply air (SA). It is supplied to a space where a humidity environment is required.

  On the other hand, the process air that has passed through the purge section 23 is cooled to the dehumidification rotor 21 as low-temperature air, and then merged with the air flowing through the sixth duct 41 (circulation line). The combined air is heated by the regeneration heater 35 and then passes through the regeneration section 24 of the dehumidifying rotor 21 as high-temperature air, passes through the fifth duct 37, and is exhausted to the outside as exhaust (EA) by the exhaust fan 39. Discharged. At this time, a part of the air flowing through the fifth duct 37 passes through the sixth duct 41 (circulation line) and is returned to the upstream side of the regeneration section 24 of the dehumidifying rotor 21, and as described above, the fourth duct. 33 is merged with the air flowing through 33.

  Next, control of the dehumidification system 20 which concerns on embodiment of this invention is demonstrated.

  As shown in FIG. 1, the dehumidifying system 20 is provided with a control device 43, which includes first to fourth thermometers 30, 34, 36, 38, a regenerative heater 35, an exhaust fan 39, and The circulation dampers 42 are electrically connected to the control device 43, respectively.

  The control device 43 is provided with a storage unit (not shown). In this storage unit, as shown in FIG. 2, the dew point temperature of the processing air on the outlet side of the dehumidifying section 22 is a predetermined value. (In FIG. 2, −50 ° C. DP, −55 ° C. DP, −60 ° C. DP) The energy acquired by the cold air passing through the purge section 23 and the hot air passing through the regeneration section 24 are lost. The energy balance value obtained by dividing the energy difference from the energy by the air volume Q1 of the processing air that passes through the dehumidifying section 22 and the air volume Q3 of the high-temperature air that passes through the regeneration section 24 that pass through the dehumidifying section 22 The first relational expression of the reproduction air volume ratio obtained by dividing by the air volume Q1 is stored in advance.

  In addition, as shown in FIG. 3, the dew point temperature of the processing air on the outlet side of the dehumidifying section 22 is stored in the storage unit at a predetermined value (in FIG. 3, −50 ° C. DP, −55 ° C. DP, − The second relational expression of the energy balance value at the time of 60 ° C. DP) and the regeneration temperature T3 that is the temperature of the hot air on the inlet side of the regeneration section 24 is stored in advance.

  For example, when the predetermined dew point temperature of the processing air at the outlet side of the dehumidifying section 22 is −50 ° C. DP, first, the control device 43 performs the following operation according to the following equation (1) while the dehumidifying rotor 21 is in operation. The temperature T1 of the air on the inlet side of the purge section 23 actually measured by the first thermometer 30, the temperature T2 of the air on the outlet side of the purge section 23 actually measured by the second thermometer 34, and the purge section 23 The air flow rate Q2 passing through the purge section 23 calculated by actually measuring the differential pressure between the inlet side and the outlet side of the gas by a micro differential pressure gauge (not shown), the loss energy of the purge section 23 calculated from the The temperature T3 of the air on the inlet side of the regeneration section 24 actually measured by the thermometer 36, and the output of the regeneration section 24 actually measured by the fourth thermometer 38. Calculated from the temperature T4 of the side air and the air volume Q3 passing through the regeneration section 24, which is calculated by actually measuring the differential pressure between the inlet side and the outlet side of the regeneration section 24 with a fine differential pressure gauge (not shown). The amount of air Q1 passing through the dehumidification section 22 calculated by actually measuring the difference energy between the acquired energy of the regeneration section and the differential pressure between the inlet side and the outlet side of the dehumidification section 22 by a micro differential pressure gauge (not shown). Divide by to calculate the energy balance.

Energy balance value (kJ / m ³ ) = {(T3−T4) ° C.) × Q3m ³ / h × ρkg / m ³ × CpkJ / ° C · kg} − {(T2−T1) ° C. × Q2m ³ / h × ρkg / M ³ × CpkJ / ° C · kg} ÷ Q1m ³ / h (1)
In the above equation (1), T1 is the temperature of the air on the inlet side of the purge section 23, T2 is the temperature of the air on the outlet side of the purge section 23, T3 is the temperature of the air on the inlet side of the regeneration section 24, T4 Is the temperature of the air on the outlet side of the regeneration section 24, ρ is the air density, and Cp is the constant pressure specific heat.

  Further, the control device 43 actually operates the air volume Q3 passing through the regeneration section 24 actually measured and calculated as described above according to the following equation (2) while the dehumidifying rotor 21 is in operation as described above. The regenerated air volume ratio is calculated by dividing by the air volume Q1 passing through the dehumidifying section 22 calculated by the above.

Play air volume ratio ^{= Q3m 3 / h ÷ Q1m 3} / h ······ (2)
Next, the control device 43 calculates the energy balance value and the regeneration air volume ratio calculated in this way and the outlet side of the dehumidifying section 22 estimated from the first relational expression when the dew point temperature is −50 ° C. DP shown in FIG. The regenerative air volume ratio is controlled by controlling the opening degree of the circulation damper 42 and / or the inverter frequency of the exhaust fan 39 so that the estimated dew point temperature of the processing air matches the first relational expression when the predetermined dew point temperature is −50 ° C. DP. To control.

  Next, even if the control device 43 controls the regeneration air flow ratio in this way, if the estimated dew point temperature of the processing air does not match the first relational expression when the predetermined dew point temperature is −50 ° C. DP, the control device If the controller 43 determines, the controller 43 determines whether the calculated energy balance value and regeneration temperature and the outlet of the dehumidifying section 22 estimated from the second relational expression at the time of the dew point temperature −50 ° C. DP shown in FIG. The output of the regeneration heater 35 is controlled so that the estimated dew point temperature of the processing air on the side coincides with the second relational expression when the dew point temperature is −50 ° C. DP shown in FIG. The regeneration temperature of the hot air is controlled.

  More specifically, for example, the control device 43 is configured so that the air volume Q2 passing through the purge section 23 and the air volume Q3 passing through the regeneration section 24 are equal, and even if the regeneration air volume ratio is minimized, When it is determined that the estimated dew point temperature is lower than the dew point temperature −50 ° C. DP, the output of the regeneration heater 35 is controlled so as to lower the regeneration temperature of the hot air passing through the regeneration section 24.

  As described above, according to the dehumidification system 20 according to the embodiment of the present invention, the relational expression between the energy balance value and the regeneration condition (that is, the regeneration air volume ratio or the regeneration temperature) is obtained in advance and estimated dehumidification section 22. The regenerative energy is increased when the estimated dew point temperature of the processing air at the outlet side is higher than the predetermined dew point temperature, and the regenerative energy is decreased when the estimated dew point temperature is lower than the predetermined dew point temperature. The dehumidification rotor 21 can be regenerated with energy.

  Further, when the control of the regeneration air volume ratio by the control device 43 and the control of the regeneration temperature are compared, the effect of reducing the energy consumption is the control of the regeneration air volume ratio. By giving priority over the control of the regeneration temperature, it is possible to reduce regeneration energy by 40% or more compared to the known prior art (see FIG. 5 or FIG. 6). Therefore, according to the dehumidification system 20 according to the above-described embodiment of the present invention, a significant reduction in running cost can be achieved.

  Furthermore, according to the dehumidifying system 20 according to the embodiment of the present invention, the control device 43 calculates the energy balance value and the regeneration air flow ratio from the measured values of the thermometer and the differential pressure gauge, and the measurement accuracy is good and the response speed is high. Therefore, controllability can be improved, and air having a low dew point temperature can be reliably supplied into a predetermined environment without deviating from the predetermined dew point temperature.

  Furthermore, according to the dehumidification system 20 according to the above-described embodiment of the present invention, the initial cost can be reduced and the maintainability can be improved as compared with a dehumidification system using a conventional dew point meter.

  As described above, in the above-described embodiment of the present invention, the control device 43 determines whether the outlet of the dehumidifying section 22 is based on the energy balance value and the regeneration air flow ratio or the regeneration temperature and the first relational expression or the second relational expression. Although the dew point temperature of the air on the side is estimated, it is difficult to estimate the dew point temperature of the air on the outlet side of the dehumidifying section 22 only by the energy lost by the high temperature air passing through the regeneration section 24. This is because the temperature of the air on the outlet side of the regeneration section 24 becomes substantially constant regardless of the dew point temperature of the air on the outlet side of the dehumidifying section 22 depending on the regeneration air volume ratio, as shown in FIG. For the same reason, it is also difficult to estimate the dew point temperature of the air on the outlet side of the dehumidifying section 22 using only the energy acquired by the low temperature air passing through the purge section 23.

  In the above-described embodiment of the present invention, the difference energy between the energy acquired by the low-temperature air passing through the purge section 23 and the energy lost by the high-temperature air passing through the regeneration section 24 is passed through the dehumidifying section 22. The energy balance value obtained by dividing the air volume Q1 of the processing air to be performed and the air volume Q3 of the high-temperature air passing through the regeneration section 24 by the air volume Q1 of the processing air passing through the dehumidifying section 22 The relational expression is defined as the first relational expression because it can cope with the change in the size of the dehumidifying rotor 21, for example, the processing air passing through the dehumidifying section 22. The energy acquired by the low-temperature air passing through the purge section 23 and the regeneration section 24 without being divided by the air volume Q1 of The difference energy with respect to the energy lost by the high temperature air is defined as the energy balance value, and the relational expression between the energy balance value and the air volume Q3 of the high temperature air passing through the regeneration section 24 is a first relational expression. May be defined.

  Similarly, the energy balance value calculated without being divided by the air volume Q1 of the processing air passing through the dehumidifying section 22 and the regeneration temperature T3 that is the temperature of the high-temperature air on the inlet side of the regeneration section 24. The relational expression may be defined as the second relational expression.

  Furthermore, since the above description of the embodiment of the present invention describes a preferred embodiment of the dehumidification system according to the present invention, there may be various technically preferable limitations. The technical scope of the present invention is not limited to these embodiments unless specifically described to limit the present invention. Furthermore, the components in the embodiment of the present invention described above can be appropriately replaced with existing components and the like, and various variations including combinations with other existing components are possible. The description of the embodiment of the present invention described above does not limit the contents of the invention described in the claims.

20 Dehumidification system 21 Dehumidification rotor 22 Dehumidification section 23 Purge section 24 Regeneration section

Claims (3)

An energy saving dehumidification system comprising a rotatable dehumidifying rotor impregnated with a dehumidifying agent,
The dehumidification rotor is dehumidified by adsorbing moisture from the passing processing air to dehumidify the processing air, a regeneration section heated by the passing high temperature air and desorbed by moisture, and cooled by the passing low temperature air A purge section, and
The difference between the energy acquired by the cold air passing through the purge section and the energy lost by the hot air passing through the regeneration section when the dew point of the processing air at the outlet side of the dehumidifying section is a predetermined value The energy balance value obtained by dividing the energy of the process air by the air volume of the processing air passing through the dehumidification section and the air volume of the hot air passing through the regeneration section are divided by the air volume of the processing air passing through the dehumidification section. The first relational expression of the regenerative air volume ratio obtained in this manner is stored in advance, and the outlet side of the dehumidifying section estimated from the energy balance value and the regenerative air volume ratio obtained by actual measurement and the first relational expression The control device for controlling the regenerative air volume ratio so that the estimated dew point temperature of the processing air in the case matches the first relational expression at the time of a predetermined dew point temperature Energy-saving dehumidification system, characterized in that it comprises. An energy saving dehumidification system comprising a rotatable dehumidifying rotor impregnated with a dehumidifying agent,
The dehumidification rotor is dehumidified by adsorbing moisture from the passing processing air to dehumidify the processing air, a regeneration section heated by the passing high temperature air and desorbed by moisture, and cooled by the passing low temperature air A purge section, and
The difference between the energy acquired by the cold air passing through the purge section and the energy lost by the hot air passing through the regeneration section when the dew point of the processing air at the outlet side of the dehumidifying section is a predetermined value A second relational expression of the energy balance value obtained by dividing the energy of the air by the air volume of the processing air passing through the dehumidifying section and the regeneration temperature, which is the temperature of the hot air at the inlet side of the regeneration section, When the estimated dew point temperature of the treated air at the outlet side of the dehumidifying section estimated by the energy balance value and regeneration temperature obtained by actual measurement and the second relational expression and the second relational expression is a predetermined dew point temperature, An energy-saving dehumidification system comprising a control device for controlling the regeneration temperature so as to coincide with the relational expression (2). An energy saving dehumidification system comprising a rotatable dehumidifying rotor impregnated with a dehumidifying agent,
The dehumidification rotor is dehumidified by adsorbing moisture from the passing processing air to dehumidify the processing air, a regeneration section heated by the passing high temperature air and desorbed by moisture, and cooled by the passing low temperature air A purge section, and
The difference between the energy acquired by the cold air passing through the purge section and the energy lost by the hot air passing through the regeneration section when the dew point of the processing air at the outlet side of the dehumidifying section is a predetermined value The energy balance value obtained by dividing the energy of the process air by the air volume of the processing air passing through the dehumidification section and the air volume of the hot air passing through the regeneration section are divided by the air volume of the processing air passing through the dehumidification section. The first relational expression of the regeneration air volume ratio obtained in this way is stored in advance, the regeneration air volume ratio is controlled so as to match the first relational expression, and the processing air at the outlet side of the dehumidifying section is controlled. When the dew point temperature is a predetermined value, the energy balance value, and the regeneration temperature, which is the temperature of the hot air at the inlet side of the regeneration section, The second relational expression stored in advance, and a control device for controlling the regeneration temperature to match to the second relational expression,
The control device performs the control of the regeneration air volume ratio based on the first relational expression over the control of the regeneration temperature based on the second relational expression, and even if the control of the regeneration air volume ratio is performed, The first relationship when the estimated dew point temperature of the processing air on the outlet side of the dehumidifying section estimated by the energy balance value and the regeneration air flow ratio obtained by the measurement and the first relational expression is the predetermined dew point temperature When it is determined that they do not match the equation, the estimated dew point temperature of the processing air at the outlet side of the dehumidifying section estimated from the energy balance value and regeneration temperature obtained by actual measurement and the second relational expression is the predetermined value. The regeneration temperature is controlled so as to coincide with the second relational expression at the time of the dew point temperature.