JP2019158172A - Humidifier control method and humidification system - Google Patents

Abstract

To provide a humidifier control method and a humidification system, capable of inhibiting silica and scale from being deposited in a humidification module, to maintain capacity of the humidification module over a long term.SOLUTION: A humidifier control method comprises: a detection step of detecting an air state value of air at an upstream side with respect to a humidification module unit 20; a number determination step of, based on saturation efficiency of the humidifying module unit 20 that varies depending on the number of humidifying modules 20a to be passed and the air state value of the air at the upstream side, determining the number of humidification modules 20a to be passed by feed-forward control; and a control step of controlling the opening/closing of an on/off valve in accordance with the humidification modules according to the determined number.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a humidifier control method and a humidification system, and more particularly to a humidifier control method and a humidification system according to a vaporization type humidifier.

As an air conditioner, a cold / hot water coil that adjusts the temperature of air by adjusting the amount of cooling or heating of air, and a drop pervaporation type humidifier that adjusts humidity by adjusting the amount of water vaporization, A humidifying system is known.
Patent Document 1 discloses a temperature change amount of a humidifying module (humidifier) that calculates a temperature change amount before and after humidification based on a distance between an arbitrary point of a saturated vapor line in an air diagram and a point before starting humidification. And a feedforward control method for controlling the heating amount is disclosed.
And in the same document, when the temperature of the heater is not uniform, in order to correctly estimate the amount of temperature change before and after humidification, for each control input break related to the opening degree of the valve corresponding to each humidification module, It describes the construction of different model formats.

JP 2002-323252 A

  However, in the technique disclosed in Patent Document 1, since the humidity is adjusted by finely adjusting the valve opening degree for supplying water to each humidifying module, the number of times that water is vaporized from the humidifying module may increase. there were. If the number of times is large, a large amount of silica and scale may be deposited on the humidifying module, and the precipitated silica and scale cause a reduction in the capacity of the humidifying module.

  This invention is made | formed in view of said subject, suppresses that silica and a scale precipitate on a humidification module, and the humidifier control method and humidification system which can maintain the capability of a humidification module over a long term are provided. The purpose is to provide.

  The humidifier control method of the present invention includes a humidifying module unit composed of a plurality of humidifying modules, a water supply unit that passes water for each of the plurality of humidifying modules, and an on-off valve that controls water flow for each of the plurality of humidifying modules. A humidifier control method for controlling a vaporizing humidifier, comprising: a detection step for detecting an air state value upstream of the humidifying module unit; and a flow of the humidifying module to be passed. A number determining step of determining the number of humidifying modules to be passed by feedforward control based on the saturation efficiency of the humidifying module unit that varies depending on the number and the air condition value of the air on the upstream side; And a control step of controlling opening / closing of the on / off valve in accordance with the humidifying modules according to the number of units.

  The humidification system of the present invention is a humidification system comprising a vaporization type humidifier and a control device that controls the vaporization type humidifier, wherein the vaporization type humidifier comprises a plurality of humidification modules. A unit, an air condition value sensor for detecting an air condition value upstream of the humidifying module unit, a water supply unit for supplying water to each of the plurality of humidifying modules, and a water supply for each of the plurality of humidifying modules. An on-off valve that controls the air flow rate, and the control device includes a saturation efficiency of the humidifying module unit that varies depending on the number of the humidifying modules that are passed through, and the air state value detected by the air state value sensor. , The number of the humidifying modules to be passed is determined by feedforward control, and the humidifying modules according to the determined number are determined. Characterized in that it controls the opening and closing of the said opening and closing valve according to Le.

  According to the humidifier control method and the humidification system of the present invention, it is possible to suppress the deposition of silica and scale on the humidification module, and it is possible to suppress a decrease in the capability of the humidifier.

It is a typical lineblock diagram showing the composition of the humidification system concerning this embodiment. It is a flowchart which shows the humidifier control method which concerns on this embodiment. It is a typical perspective view which shows the humidification module unit periphery. It is the figure which showed the air-conditioning target range and the indoor air setting range with the typical air diagram. It is the figure which showed the example of an air conditioning which can be included in a saturation efficiency line and an air-conditioning target range with a typical air diagram. It is a figure which shows the relationship between the wind speed of the air in the attachment surface of a humidifier, and saturation efficiency. It is a typical block diagram which shows the structure of the humidification system which concerns on a 1st modification. It is a flowchart which shows the humidifier control method which concerns on a 1st modification. It is a typical block diagram which shows the structure of the humidification system which concerns on a 2nd modification.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
The embodiment described below is merely an example for facilitating the understanding of the present invention, and does not limit the present invention. That is, the types, number, parameters, and the like of the devices described below can be changed and improved without departing from the spirit of the present invention, and the present invention naturally includes equivalents thereof.
Moreover, in all drawings, the same code | symbol is attached | subjected to the same component, and the overlapping description is abbreviate | omitted suitably.

<< Outline of the Invention >>
First, the outline of the present invention will be described with reference to FIGS. 1 and 2. FIG. 1 is a schematic configuration diagram illustrating a configuration of a humidification system 1 according to the present embodiment, and FIG. 2 is a flowchart illustrating a humidifier control method according to the present embodiment.
A humidifier control method according to an embodiment of the present invention from one aspect includes a humidifying module unit 20 configured by a plurality of humidifying modules 20a and a water supply unit 21 that passes water for each of the plurality of humidifying modules 20a illustrated in FIG. And the vaporizer-type humidifier 2 provided with the on-off valve 22 that controls water flow for each of the plurality of humidification modules.
As shown in FIGS. 1 and 2, the humidifier control method varies depending on the detection step S101 for detecting the air state value of the air upstream of the humidifying module unit 20 and the number of humidifying modules 20a to be passed. Based on the saturation efficiency of the humidifying module unit 20 and the air condition value of the air on the upstream side, the number determining step S102 for determining the number of humidifying modules 20a to be passed by feedforward control, and the determined number And a control step S103 for controlling opening / closing of the on-off valve 22 in accordance with the humidifying module 20a.

  Here, the “air condition value” is temperature or humidity or a numerical value that can be converted from these values, and may be any combination of absolute humidity, relative humidity, dry bulb temperature, dew point temperature, saturated absolute humidity, or enthalpy. Good. Based on the numerical value of temperature or humidity or a numerical value that can be converted from these values (a combination of absolute humidity, relative humidity, dry bulb temperature, dew point temperature, saturated absolute humidity, or enthalpy) Can be determined.

Moreover, the humidification system 1 which concerns on embodiment of this invention by another viewpoint is provided with the vaporization type humidifier 2 and the control apparatus 8 which controls the vaporization type humidifier 2. FIG. The vaporizing humidifier 2 includes a humidifying module unit 20 including a plurality of humidifying modules 20a, and an air condition value sensor (dry bulb thermometer) that detects an air condition value of air upstream from the humidifying module unit 20. 3 and a relative hygrometer 4 or a dew point meter 5) including these, a water supply unit 21 for passing water for each of the plurality of humidifying modules 20a, and an on-off valve 22 for controlling water flow for each of the plurality of humidifying modules 20a. .
The control device 8 determines the saturation efficiency of the humidifying module unit 20 depending on the number of humidifying modules 20a to be passed through and the air detected by the air condition value sensor (the dry bulb thermometer 3 and the relative hygrometer 4 or the dew point meter 5). Based on the state value, the number of humidifying modules 20a through which water passes is determined by feedforward control, and the opening / closing valve 22 is controlled to open / close in accordance with the humidifying modules 20a corresponding to the determined number.

  When the opening / closing of the valve is frequently switched by adjusting the amount of water flow to the humidification module 20a proportionally by the opening adjustment valve as in the conventional humidification system, the humidification module 20a is changed from the wet state to the dry state. The number of times of switching increases. In this case, silica and scale are likely to be deposited on the humidifying module 20a.

  On the other hand, the humidification system 1 according to the present embodiment opens and closes the on-off valve 22 by feedforward control based on at least the saturation efficiency of the humidification module 20a that varies depending on the number of water flow, and allows the water to flow for each humidification module 20a. Control. For this reason, the humidification system 1 can suppress the frequency | count that the humidification module 20a switches from a wet state to a dry state compared with the conventional one. Thereby, it can suppress that a silica and a scale precipitate on the humidification module 20a, and can suppress the capability fall of the humidifier 2. FIG.

  In addition, the humidifier control method of this invention should just control the vaporization type humidifier 2, and is not limited to what controls the humidification system 1 used with the cold / hot water coil 6 demonstrated below. Similarly, the humidification system of this invention should just be equipped with the vaporization type humidifier 2, and the cold / hot water coil 6 which has a cooling / heating function is effective as an air conditioning for making it comfortable environment. However, the cold / hot water coil 6 may not necessarily be provided.

<< System configuration >>
Next, in addition to FIG. 1, the details of the system configuration of the humidification system 1 will be described with reference to FIG. FIG. 3 is a schematic perspective view showing the surroundings of the humidifying module unit 20.
As described above, the humidifying system 1 includes the vaporizing humidifier 2 and the control device 8 that controls the humidifier 2, and further includes the cold / hot water coil 6 for controlling the temperature, and the humidifying system 1. A fan 7 for creating a flowing air flow and a housing 40 are provided.
The humidifier 2, the cold / hot water coil 6, and the fan 7 are accommodated in the housing 40. Further, inside the housing 40, there are an inlet duct P1 for taking outside air into the housing 40, and an outlet duct P2 for supplying air whose humidity and temperature are adjusted by the humidifier 2 and the cold / hot water coil 6 into the room. It is connected.

The humidifier 2 includes a humidifying module unit 20, a dew point meter 5 including a dry bulb thermometer 3 and a relative hygrometer 4, a water supply unit 21, and an on-off valve 22 that controls water flow for each of the plurality of humidifying modules 20a. Have
The humidification module unit 20 is for humidifying the air in the housing 40 by passing air so that the water comes into contact with the water being passed. In the present embodiment, four humidification modules are used. 20a. The humidification module 20a has a net-like humidifier and has a saturation efficiency of about 20% per sheet. That is, when all four sheets are allowed to function by water, the saturation efficiency is about 80%.

The dew point meter 5 includes a dry bulb thermometer 3 and a relative hygrometer 4, and displays dry bulb temperature, relative humidity, absolute humidity, dew point temperature, and saturated absolute humidity by detecting the dry bulb temperature and relative humidity. And it is comprised so that output to the control apparatus 8 is possible. The dry bulb thermometer 3 and the relative hygrometer 4 are connected to the inside of the inlet duct P1, and detect the dry bulb temperature and the relative humidity of the air in the inlet duct P1. In FIG. 1, the dry bulb thermometer 3 and the relative hygrometer 4 are connected to different positions of the inlet duct P1, but may be connected to the same position. The control device 8 described later uses the external dry bulb temperature T ₀ obtained by the dry bulb thermometer 3 when determining deterioration diagnosis, energy consumption prediction, and the number of humidification modules 20a used. In addition, the control device 8 uses the external dry bulb temperature T ₀ and the external relative humidity H ₀ obtained by the relative hygrometer 4 when calculating the external absolute humidity HA ₀ .
The water supply unit 21 is configured to be able to supply water to the humidification module unit 20 via the on-off valve 22 by a pump (not shown).
The on-off valve 22 is, for example, an electromagnetic valve or an electric ball valve, and is configured to be selectively selectable from full open / full close. That is, the open degree is not adjustable, and the valve open degree is not fully open / open. This is an on / off valve that can only be in the fully closed position.

The cold / hot water coil 6 adjusts the temperature of surrounding air when cold / hot water passes. A hot water supply pipe HS and a cold water supply pipe CS, and a hot water return pipe HR and a cold water return pipe CR for circulating cold / hot water are connected to the cold / hot water coil 6 through an on-off valve 62 and an opening degree adjusting valve 63. .
The fan 7 is for forming a flow of air from the outside toward the room through the inlet duct P1, the cold / hot water coil 6, the humidification module unit 20, and the outlet duct P2.
The control device 8 controls the humidifier 2, the cold / hot water coil 6 and the fan 7. The control device 8 is connected to a dry bulb thermometer 3, a relative hygrometer 4, a dew point meter 5, a fan 7, on-off valves 22, 62, an opening adjustment valve 63, and the like by a communication cable or wireless communication not shown in FIG. It is connected with the electric equipment of this, and is comprised so that communication is possible bidirectionally.

<< About the control method of the humidifier >>
Next, the control method of the humidifier 2 by the control device 8 will be described with reference mainly to FIGS. 4 to 6 in addition to FIGS. FIG. 4 is a schematic air diagram showing the air conditioning target range A1 and the indoor air setting range A2. FIG. 5 is a schematic air diagram showing examples of air conditioning that can be included in the saturation efficiency lines 11a, 11b, 11c, and 11d and the air conditioning target range A1. FIG. 6 is a diagram showing the relationship between the air velocity on the mounting surface of the humidifier 2 and the saturation efficiency.
The indoor air setting range A2 is a temperature / humidity range set by the user. The air conditioning target range A1 after being humidified by the humidifier 2 is determined by back calculation from the indoor air setting range A2. With respect to the air passing through the outlet duct P <b> 2 after being humidified by the humidifier 2, the air state value is slightly changed by the fan 7 such as a temperature rise. The air conditioning target range A1 is determined by calculating back the change in the air condition value.

In the detection step S101 of FIG. 2, the dry bulb thermometer 3, the relative hygrometer 4, and the dew point meter 5 are the air state values in the inlet duct P1, and the external dry bulb temperature T ₀ and the external relative humidity H shown in FIG. ₀ or external absolute humidity HA ₀ is detected or calculated. These values detected or calculated from the dry bulb thermometer 3, the relative hygrometer 4, and the dew point meter 5 are transmitted, and the control device 8 receives them.

  In the number determination step S102 of FIG. 2, the control device 8 determines the saturation efficiency of the humidifying module unit 20 that varies depending on the number of humidifying modules 20a to be passed, and the air state value of the upstream air detected or calculated. Based on the above, the number of humidification modules 20a through which water passes is determined by feedforward control.

Specifically, in the air diagram, an isoenthalpy line starting from the air condition values of the upstream air (external dry bulb temperature T ₀ , external relative humidity H ₀ and external absolute humidity HA ₀ ), and water flow Based on saturation efficiency lines 11a, 11b, 11c, and 11d related to the saturation efficiency determined for each number of humidifying modules 20a, the air state value after passing through the humidifying module 20a falls within a target range. The number of humidification modules 20a through which water passes can be determined by feedforward control.

Note that “in the air diagram” according to the present embodiment is not limited to the method of actually using the air diagram, but includes those using a conversion formula or a table for deriving a value converted by the air diagram. To do. In other words, the control unit 8 reads and controls a conversion formula or table corresponding to an air diagram stored in a storage unit (not shown).
In addition, the “air state value of the air on the upstream side” means the upstream side of the humidifying module unit 20, and the air state value expected after heating or cooling by the cold / hot water coil 6 (in this embodiment) Includes inlet-side dry bulb temperature T ₁ , T ₄ inlet-side relative temperatures H ₁ , H ₄ ).

  Saturation efficiency lines 11a, 11b, 11c, and 11d are air condition values after humidification determined by saturation efficiency changing in a predetermined temperature range at a predetermined absolute humidity for each number of humidifying modules 20a that pass water in the air diagram. It is a connected line. When one humidification module 20a is passed, the saturation efficiency line 11a is used. When two are used, the saturation efficiency line 11b is used. When three are used, the saturation efficiency line 11c is used. When four are used, the saturation efficiency line 11d is used.

As shown in FIG. 6, the saturation efficiency varies depending on the wind speed of the air passing through the humidification module 20a (the mounting surface of the humidifier 2). In this embodiment, the wind speed of the air passing through the humidification module 20a generated by the fan 7 is 2.5 m / s, and the saturation efficiency when water is passed through the four humidification modules 20a at this time is 80%. And saturation efficiency changes proportionally with the number of humidification modules 20a which let water flow.
Specifically, the control device 8 calculates the air volume from the wind speed of air obtained from an anemometer (not shown) provided in the outlet duct P2 and the cross-sectional area of the outlet duct P2. The control device 8 divides the calculated air volume by the passage area of the humidifying module 20a to calculate the above wind speed (2.5 m / s) of the air passing through the humidifying module 20a. And the control apparatus 8 controls various apparatuses using the numerical value of the exact saturation efficiency calculated based on the said wind speed value.

  In the air diagram, the air in an arbitrary state humidified by the humidifying module 20a changes its state toward the saturated vapor line SV along the isoenthalpy line, and depending on the number of water passing through the humidifying module 20a, respectively. Air conditioning is performed up to the point where the saturation efficiency lines 11a, 11b, 11c, and 11 intersect.

For example, when there are a plurality of cases that fall within the target air conditioning target range A1, a method for suppressing the amount of power consumption may be selected and set to fall within the target range.
Specifically, when the power consumption is kept small, the control device 8 gives priority to the case where the number of humidifying modules 20a through which water passes is small when there is a process of heating the air using the cold / hot water coil 6. Just decide. And when there exists the process of cooling air using the cold / hot water coil 6, you may preferentially determine the case where there are many numbers of the humidification modules 20a which let water flow. In this way, the heating amount and the cooling amount can be suppressed, and the energy consumption can be suppressed.

Further, for example, when there are a plurality of cases that fall within the target air conditioning target range A1, a case where the number of the humidifying modules 20a to pass through is small may be selected for water saving.
Specifically, in the air diagram, a point that is within the air conditioning target range A1 at the intersection of the isoenthalpy lines 10a and 10b starting from the upstream air condition value and the saturation efficiency lines 11a, 11b, 11c, and 11d. Among them, the air conditioning method is preferentially selected in the order of the intersections with the saturation efficiency lines 11a, 11b, 11c, and 11d. For example, in FIG. 5, the air condition after humidification is not an air conditioning method in which the outlet-side dry bulb temperature T ₅ and the outlet-side relative temperature H ₅ are the intersections with the saturation efficiency line 11d, but the saturation efficiency line 11c. An air-conditioning method is selected so that the outlet-side dry bulb temperature T ₂ and the outlet-side relative temperature H ₂ are the intersections. That is, the control device 8 selects an air-conditioning method for passing water to the three humidification modules 20a related to the saturation efficiency line 11c including the points that become the outlet-side dry bulb temperature T ₂ and the outlet-side relative temperature H ₂ in the air diagram. To do.

In the control step S103, the control device 8 controls opening / closing of the on-off valve 22 in accordance with the humidifying modules 20a relating to the determined number.
When heating or cooling is required before passing air through the humidifying module unit 20, the control device 8 opens the on-off valve 62 and adjusts the opening of the opening adjusting valve 63.
Specifically, the control device 8 is connected to the cold / hot water coil 6 and opens the open / close valve 62 connected to the hot water supply pipe HS and the hot water return pipe HR, or the open / close valve 62 connected to the cold water supply pipe CS and the cold water return pipe CR. The opening degree of the opening degree adjustment valve 63 is adjusted according to the adjustment temperature. For example, FIG. 6 shows a state in which the humidification module unit 20 humidifies the external dry bulb temperature T _{0 from} the state of the external dry bulb temperature T _{0 to} the state of the inlet side dry bulb temperature T ₁ and the inlet side dry bulb temperature T _4. .

In the above description, the method of obtaining the number of water passing through the humidifying module 20a, the inlet-side dry bulb temperature T ₁ and the inlet-side dry bulb temperature T ₄ after heating or cooling by the cold / hot water coil 6 from the air diagram has been described. It is not limited to such a method, You may make it obtain | require these based on required humidification amount dHA until it reaches air-conditioning target range A1.

Specifically, the controller 8 calculates the saturation efficiency based on the wind speed of the air passing through the humidifying module 20a in the same manner as described above, and then obtains the external dry bulb temperature T ₀ obtained from the dry bulb thermometer 3 (this embodiment). In this embodiment, the external absolute humidity HA ₀ (50 g / kg in this embodiment) is calculated from the external relative humidity H ₀ obtained from the relative hygrometer 4.
Furthermore, when the absolute humidity HA ₁ (70 g / kg in the present embodiment) at the lower limit of the air conditioning target range A1 is greater than the external absolute humidity HA ₀ , the control device 8 changes the absolute humidity HA ₁ to the external absolute humidity HA. _The required humidification amount dHA is calculated by subtracting ₀ .

The control apparatus 8 calculates | requires the saturation absolute humidity for every number of the humidification modules 20a which let water flow. Specifically, the saturated absolute humidity of each number of the humidifying module 20a for passing water, in dividing the saturation efficiency of each number from required humidification amount dHA, a value obtained by adding the external absolute humidity HA _0.
For example, when three water passes in the present embodiment, the saturation absolute humidity HA ₃ is 80 g / kg as shown in FIG. The control device 8 obtains the inlet-side dry bulb temperature and the outlet-side dry bulb temperature from the enthalpy determined by the saturation efficiency and the saturation absolute humidity. For example, when three waters are passed in the present embodiment, as shown in FIG. 5, the inlet side dry bulb temperature T _{1 is} 18 ° C., and the outlet side dry bulb temperature T ₂ is 13 ° C.
Control device 8, optimize the conditioning method outlet dry bulb temperature T ₂ enters the dry-bulb temperature range of the air conditioning target range A1 (heating and cooling degree by cold and hot water coil 6, the number of water flow to the humidifying module 20a) Decide as a thing. Then, the control unit 8, the inlet-side dry bulb temperature T ₁ of the opening controls the opening and closing valve 62 and opening regulating valve 63 so as to control the opening and closing valve 22 to water flow only to the humidifying module 20a determined number To do.

In addition, since the air state after humidification should just enter air-conditioning target range A1, not only based on the lower limit of absolute humidity of A1 as mentioned above but on the basis of the numerical value enclosed by air-conditioning target range A1. Also good. That is, even if the absolute humidity at the intersection of the isenthalpy lines 10a and 10b and the saturation efficiency lines 11a, 11b, 11c and 11d is not the absolute humidity HA ₁ , it is equal to or higher than the absolute humidity HA ₁ , and the intersection is the air conditioning target range A1. As long as it falls within the dry bulb temperature range for.

In the above description, it has been described that the number of humidification modules 20a through which water passes is determined by the control method of the humidifier 2. When the water flow is biased to only a part of the humidifying module unit 20 in the humidifying module unit 20, silica and scale deposits accumulate on only a part of the humidifying module unit 20, thereby increasing the service life of the humidifier 2 as a whole. It can be shortened.
Therefore, in the control process, based on the water flow history of the plurality of humidifying module units 20 shown in Table 1, the opening / closing of the on-off valve 22 provided in each of the humidifying modules 20a may be controlled.

For example, regarding the number of times of water passing shown in Table 1, a case is assumed in which the first humidification module is three times, the second humidification module is three times, the third humidification module is two times, and the fourth humidification module is one time. At this time, the control device 8 performs water passage with priority in the order of the fourth humidification module, the third humidification module, and optionally the first humidification module or the second humidification module.
The water flow history is formed by a counter (not shown) counting the number of on / off times of the valve, specifically on / off, and the number of times is recorded by a logger (recorder) not shown. That's fine. And the control apparatus 8 reads the water flow log | history recorded by the logger, and it can control to preferentially water the thing with little water flow among the humidification modules 20a.

  Regardless of the water flow history, the control device 8 may control the humidification module 20a in the water flow so as to continue the water flow. If it does in this way, the frequency | count that the humidification module 20a switches from a wet state to a dry state can be suppressed, and precipitation of a silica or a scale can be suppressed.

<First Modification>
Next, the humidification system 1X which concerns on a 1st modification is demonstrated with reference mainly to FIG.7 and FIG.8. FIG. 7 is a schematic configuration diagram showing a configuration of a humidification system 1X according to the first modification, and FIG. 8 is a flowchart showing a humidifier control method according to the first modification.
As described above, the dew point meter 5 including the dry bulb thermometer 3 and the relative hygrometer 4 that are inserted into the inlet duct P1 on the upstream side of the humidifying module 20a and measures the air state value is provided. . In addition to this, in the humidification system 1X according to the present modification, as shown in FIG. 7, the dry bulb temperature that is inserted into the outlet duct P2 on the upstream side of the humidification module 20a and measures the air state value. A dew point meter 15 including a meter 13 and a relative hygrometer 14 is provided. A dew point indicating controller 16 electrically connected to the dew point meter 15 and the opening adjustment valve 63 of the cold / hot water coil 6 is provided.
The dew point indicating controller 16 adjusts the opening of the opening adjustment valve 63 of the cold / hot water coil 6 according to the dew point temperature measured by the dew point meter 15 to finely adjust the dew point temperature of the air supplied to the room. .

  As shown in FIG. 8, the humidifier control method according to the first modification further includes a deterioration diagnosis step S204 for performing a deterioration diagnosis of the humidifier 2 after the detection step S201, the number determination step S202, and the control step S203. Each of the detection step S201, the number determination step S202, and the control step S203 is the same as the detection step S101, the number determination step S102, and the control step S103. In the deterioration diagnosis step S204, the air condition value inside the inlet duct P1 upstream of the humidifying module 20a in the humidifier 2 and inside the outlet duct P2 downstream is measured, and the measured actual value and air line measured. The deterioration diagnosis of the humidifier 2 is performed by comparing with the calculated value calculated by the figure.

  In this way, it is diagnosed that any of the humidifier 2 (humidification module unit 20 and on-off valve 22 etc.), the cold / hot water coil 6 and the fan 7 which are mutually related with respect to the dry bulb temperature and relative humidity is deteriorated. be able to. In particular, when it is desired to diagnose which one of the devices has deteriorated, dry bulb thermometers 3, 13 and relative hygrometers 4, 14, etc. are arranged on the upstream side and the downstream side across each device. What should I do?

  In particular, the air condition value is a dew point temperature measured by the dew point meters 5 and 15, and it is preferable to perform a deterioration diagnosis of the humidification module 20 a among those built in the humidifier 2 in the deterioration diagnosis step. According to such a configuration, by comparing the dew point temperatures that can be easily measured by the control device 8, it is possible to perform the deterioration diagnosis of the humidification module 20a that is likely to be deteriorated due to deposition of silica or scale.

<Second Modification>
Next, a humidification system 1Y according to a second modification will be described mainly with reference to FIG. FIG. 9 is a schematic configuration diagram illustrating a configuration of a humidification system 1Y according to the second modification.
In the housing 40 of the humidification system 1Y according to the second modification, the cold / hot water coil 6 is provided on the upstream side of the humidification module unit 20, and the cold / hot water coil 36 is provided on the downstream side.
Thus, by providing the cold / hot water coil 36 on the downstream side of the cold / hot water coil 6, the control device 8 controls the temperature of the air after humidification by the humidifier 2 to be within the air conditioning target range A <b> 1. It becomes easy to adjust to be included in.
Specifically, the control device 8 is connected to the cold / hot water coil 36 and opens the open / close valve 62a connected to the hot water supply pipe HS and the hot water return pipe HR, or the open / close valve 62a connected to the cold water supply pipe CS and the cold water return pipe CR, The opening degree of the opening degree adjusting valve 63a is adjusted according to the adjustment temperature.
In addition, the temperature indication controller 30 adjusts the opening of the opening adjustment valve 63a of the cold / hot water coil 36 according to the dry bulb temperature measured by the dry bulb thermometer 13, and the temperature of the air supplied to the room Tweak the.

In other words, the present modification further includes a temperature adjustment step of heating or cooling the air downstream of the humidifying module unit 20 in the humidifier 2. In this temperature adjustment step, the control device 8 heats or cools the air so that the air state value downstream of the humidifier 2 is included in the target range (air conditioning target range A1).
By further providing such a temperature adjustment step, the air temperature is adjusted so that the air condition value downstream of the humidifier 2 is included in the air conditioning target range A1, and finally the indoor air setting range in the outlet duct P2. A2 can be entered. For this reason, the variation of the number of the humidification modules 20a through which water flows so as to be included in the air conditioning target range A1 increases, and water flow control is facilitated.

This embodiment includes the following technical ideas.
(1) Vaporization comprising a humidifying module unit composed of a plurality of humidifying modules, a water supply unit for passing water for each of the plurality of humidifying modules, and an on-off valve for controlling water passing for each of the plurality of humidifying modules. A humidifier control method for controlling a type humidifier,
A detection step of detecting an air state value of air upstream from the humidifying module unit;
Based on the saturation efficiency of the humidifying module unit that varies depending on the number of humidifying modules that are passed through and the air state value of the air on the upstream side, the number of humidifying modules that are passed through is controlled by feedforward control. A number determining step to be determined;
And a control step of controlling opening and closing of the on-off valve according to the humidifying modules relating to the determined number.
(2) In the number determination step, in the air diagram, a saturation efficiency related to a saturation efficiency determined for each number of the humidifying modules that pass through an isoenthalpy line starting from the air state value of the air on the upstream side. The humidifier control according to (1), wherein the number of the humidifying modules that pass water is determined based on the line so that the air state value of the air that has passed through the humidifying module falls within a target range. Method.
(3) It further includes a temperature adjustment step of heating or cooling the air downstream of the humidifying module in the vaporizing humidifier,
The humidification according to (1) or (2), wherein in the temperature adjustment step, the air is heated or cooled so that the air state value of the air downstream from the vaporizing humidifier is included in a target range. Control method.
(4) In the control step, on / off control of the on-off valve provided in the humidification module is controlled based on the water flow history of each of the plurality of humidification modules. The humidifier control method described in 1.
(5) further comprising a deterioration diagnosis step of performing a deterioration diagnosis of the vaporizing humidifier;
In the deterioration diagnosis step, the air condition value upstream and downstream of the humidification module in the vaporizing humidifier is measured, and the measured actual value is compared with the calculated value calculated by the air diagram. The humidifier control method according to any one of (1) to (4), wherein deterioration diagnosis of the vaporizing humidifier is performed.
(6) The humidifier control method according to any one of (1) to (5), wherein the air condition value is a temperature or humidity or a numerical value that can be converted into these values.
(7) The air condition value is a dew point temperature;
The humidifier control method according to (5), wherein the deterioration diagnosis of the humidification module is performed in the deterioration diagnosis step.
(8) A humidifying system comprising a vaporizing humidifier and a control device that controls the vaporizing humidifier,
The vaporizing humidifier includes a humidifying module unit composed of a plurality of humidifying modules, an air condition value sensor for detecting an air condition value of air upstream of the humidifying module unit, and the plurality of humidifying modules. A water supply unit that passes water, and an on-off valve that controls water flow for each of the plurality of humidification modules,
The control device allows the humidification module to pass water based on the saturation efficiency of the humidification module unit that varies depending on the number of the humidification modules to be passed and the air condition value detected by the air condition value sensor. The humidification system is characterized in that the number of is determined by feedforward control, and the on / off valve is controlled to open / close in accordance with the humidification module relating to the determined number.

1, 1X, 1Y Humidification system 2 Humidifier 20 Humidification module unit 20a Humidification module 21 Water supply unit 22 On-off valve 3 Dry bulb thermometer (air condition value sensor)
4 Relative hygrometer (air condition value sensor)
5 Dew point meter (air condition value sensor)
6, 36 Chilled / hot water coils 62, 62a Open / close valve 63, 63a Opening adjustment valve 7 Fan 8 Control device (deterioration diagnosis unit)
10a, 10b Equal enthalpy line 11a, 11b, 11c, 11d Saturation efficiency line 13 Dry bulb thermometer 14 Relative hygrometer 15 Dew point meter 16 Dew point indicator controller 30 Temperature indicator controller 40 Housing A1 Air conditioning target range A2 Indoor air setting range CR Cold water reflux pipe CS Cold water supply pipe H ₀ External relative humidity H ₁ , H ₄ Inlet side relative temperature H ₂ , H ₅ Outlet side relative temperature HA ₀ External absolute humidity HA ₁ Absolute humidity HA ₃ Saturated absolute humidity HR Hot water return pipe HS hot water supply pipe P1 inlet duct P2 outlet duct SV saturated vapor line _{T 0} external dry-bulb temperature _T 1, _{T 4} inlet side dry bulb temperature _T 2, _{T 5} outlet dry bulb temperature dHA required humidification amount

Claims (8)

A vaporizing humidifier comprising: a humidifying module unit composed of a plurality of humidifying modules; a water supply unit for passing water for each of the plurality of humidifying modules; and an on-off valve for controlling water passing for each of the plurality of humidifying modules. A humidifier control method for controlling
A detection step of detecting an air state value of air upstream from the humidifying module unit;
Based on the saturation efficiency of the humidifying module unit that varies depending on the number of humidifying modules that are passed through and the air state value of the air on the upstream side, the number of humidifying modules that are passed through is controlled by feedforward control. A number determining step to be determined;
And a control step of controlling opening and closing of the on-off valve according to the humidifying modules relating to the determined number.   In the number determination step, in the air diagram, an isoenthalpy line starting from the air state value of the air on the upstream side and a saturation efficiency line related to a saturation efficiency determined for each number of the humidifying modules that pass water are used. 2. The humidifier control method according to claim 1, wherein the number of the humidifying modules to be passed is determined so that the air state value of the air after passing through the humidifying module falls within a target range. A temperature adjusting step of heating or cooling the air downstream of the humidifying module in the vaporizing humidifier;
The humidifier control according to claim 1 or 2, wherein in the temperature adjustment step, the air is heated or cooled so that the air state value of the air downstream of the vaporizing humidifier is included in a target range. Method.   The humidifier according to any one of claims 1 to 3, wherein in the control step, opening and closing of the on-off valve provided in the humidification module is controlled based on a water flow history of each of the plurality of humidification modules. Control method. Further comprising a deterioration diagnosis step of performing a deterioration diagnosis of the vaporizing humidifier,
In the deterioration diagnosis step, the air condition value upstream and downstream of the humidification module in the vaporizing humidifier is measured, and the measured actual value is compared with the calculated value calculated by the air diagram. The humidifier control method according to any one of claims 1 to 4, wherein the deterioration diagnosis of the vaporizing humidifier is performed.   The humidifier control method according to any one of claims 1 to 5, wherein the air condition value is temperature, humidity, or a numerical value that can be converted into these values. The air condition value is a dew point temperature;
The humidifier control method according to claim 5, wherein in the deterioration diagnosis step, deterioration diagnosis of the humidifying module is performed. A humidifying system comprising a vaporizing humidifier and a control device that controls the vaporizing humidifier,
The vaporizing humidifier includes a humidifying module unit composed of a plurality of humidifying modules, an air condition value sensor for detecting an air condition value of air upstream of the humidifying module unit, and the plurality of humidifying modules. A water supply unit that passes water, and an on-off valve that controls water flow for each of the plurality of humidification modules,
The control device allows the humidification module to pass water based on the saturation efficiency of the humidification module unit that varies depending on the number of the humidification modules to be passed and the air condition value detected by the air condition value sensor. The humidification system is characterized in that the number of is determined by feedforward control, and the on / off valve is controlled to open / close in accordance with the humidification module relating to the determined number.

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