JP6090284B2 - Humidifier - Google Patents

Description

  The present invention relates to a humidifier.

  Conventionally, as a humidifier, there is one that is mounted on an outdoor unit and supplies humidified air that has absorbed moisture from the outside air to the indoor unit through a hose (Patent Document 1: Japanese Patent Application Laid-Open No. 2001-41511). Publication).

  The conventional humidifier includes a humidification rotor, a moisture absorption passage that passes through the moisture absorption region of the humidification rotor, a moisture absorption fan that sends outside air to the moisture absorption passage, a humidification passage that passes through the humidification region of the humidification rotor, and the humidification passage. It has a humidifying fan for sending air and a heater provided in a humidifying passage on the upstream side of the humidifying rotor. The conventional humidifier absorbs moisture from the outside air passing through the moisture absorption passage into the moisture absorption region of the humidification rotor, while moisture from the humidification region of the humidification rotor is heated by the heater passing through the humidification passage. To generate humidified air, and the humidified air is guided to the indoor unit through a hose connected to the humidifying passage so as to supply the humidified air into the room.

JP 2001-41511 A

  However, in the above conventional humidifier, the hose may be blocked due to poor construction of the hose or the like or the retention of condensed water in the hose after a long pause, but there is a problem that the hose cannot be detected. there were. When the hose is blocked, humidified air does not flow, so the humidification function is impaired, and the heater temperature may increase.

  Then, the subject of this invention is providing the humidification apparatus which can detect obstruction | occlusion of pipe lines, such as a hose.

In order to solve the above problems, the humidifying device of the present invention provides:
A humidification rotor,
A moisture absorption passage through a moisture absorption region of the humidification rotor;
A moisture absorption fan that allows air to flow through the moisture absorption passage,
A humidifying passage through a humidifying region of the humidifying rotor;
A humidifying fan that allows air to flow through the humidifying passage;
A heater provided upstream of the humidification region of the humidification rotor in the humidification passage;
A temperature sensor provided in the humidification passage and downstream of the humidification region of the humidification rotor;
After the heater and the humidifying fan are turned on and air flows through the humidifying passage, when a predetermined time has elapsed, the temperature of the air detected by the temperature sensor is below the predetermined temperature. Bei example and a determining blockage determination unit duct is closed continuous,
A heater output control unit is provided which controls the output of the heater based on the outside air temperature so as to decrease as the outside air temperature increases .

  The humidifier of the above configuration is a temperature sensor provided on the downstream side of the humidification rotor in the humidification passage, because the flow of air from the humidification passage to the pipeline side does not occur when the conduit is closed with dew condensation water or the like. Utilizing the fact that the temperature of the detected air does not rise, the blockage determination unit determines blockage of the pipeline.

  That is, the blockage determination unit turns on the heater and the humidifying fan and flows air through the humidifying passage, and then after the predetermined time has elapsed, in the humidifying passage and beyond the humidifying region of the humidifying rotor. When the temperature of the air detected by the temperature sensor provided on the downstream side is equal to or lower than the predetermined temperature, it is determined that the pipeline connected to the humidification passage is blocked. It can be detected reliably.

In particular, since the blockage of the pipeline can be detected without receiving a signal from a temperature sensor or the like on the indoor unit side, the apparatus configuration is simplified and the control is simplified.
According to the present invention, the heater output control unit controls the output of the heater to be lower as the outside air temperature is higher based on the outside air temperature, thereby reducing the influence of the outside air temperature. Further, it is possible to prevent erroneous detection of the blockage of the pipeline.

In one embodiment,
The blockage determination unit stops the determination of the blockage determination unit when the temperature of the air detected by the temperature sensor is equal to or higher than a predetermined set value.

  Thus, by setting the preset value of the temperature of the air to a temperature in a state where the heater is in the drooping control, for example, the temperature immediately before the drooping control of the heater is high. Sometimes, the determination of the blockage determination unit is stopped, so that erroneous detection of the presence or absence of blockage of the pipeline can be prevented.

In one embodiment,
The predetermined temperature is a temperature higher by a predetermined value than the outside air temperature.

  According to the embodiment, the predetermined temperature is a temperature higher by a predetermined value than the outside air temperature, so that it is possible to prevent erroneous detection of the blockage of the pipe line due to the temperature of the outside air.

In one embodiment,
The blockage determination unit determines whether or not the temperature of the air detected by the temperature sensor is equal to or lower than the predetermined temperature when the predetermined time has elapsed. Do when.

  According to the embodiment, it is determined whether or not the temperature of the air detected by the temperature sensor is equal to or lower than the predetermined temperature when the predetermined time has elapsed. Since it is performed at the following time, the presence or absence of the blockage of the pipeline can be reliably identified without being affected by the temperature of the outside air, and erroneous detection of the blockage of the pipeline can be prevented.

One embodiment is:
When the blockage determination unit determines that the pipe line connected to the humidification passage is blocked, the blockage determination unit includes a notification unit that notifies the blockage.

  According to the embodiment, it is possible to notify the user of blockage of the pipeline.

In addition, this invention
A humidification rotor;
A moisture absorption passage through a moisture absorption region of the humidification rotor;
A moisture absorption fan that allows air to flow through the moisture absorption passage,
A humidifying passage through a humidifying region of the humidifying rotor;
A humidifying fan that allows air to flow through the humidifying passage;
A heater provided upstream of the humidification region of the humidification rotor in the humidification passage;
A temperature sensor provided in the humidification passage and downstream of the humidification region of the humidification rotor;
After the heater and the humidifying fan are turned on and air flows through the humidifying passage, when a predetermined time has elapsed, the temperature of the air detected by the temperature sensor is below the predetermined temperature. A blockage determining unit that determines that a continuous pipeline is blocked;
With
The heater output when the blockage determination unit determines whether or not the pipeline is blocked is such that the heater output increases as the length of the pipeline connected to the humidification passage increases. Set to.

According to the above invention , since the heater output is set to increase as the length of the pipeline becomes longer, erroneous detection of blockage of the pipeline can be prevented.

In addition, this invention
A humidification rotor;
A moisture absorption passage through a moisture absorption region of the humidification rotor;
A moisture absorption fan that allows air to flow through the moisture absorption passage,
A humidifying passage through a humidifying region of the humidifying rotor;
A humidifying fan that allows air to flow through the humidifying passage;
A heater provided upstream of the humidification region of the humidification rotor in the humidification passage;
A temperature sensor provided in the humidification passage and downstream of the humidification region of the humidification rotor;
After the heater and the humidifying fan are turned on and air flows through the humidifying passage, when a predetermined time has elapsed, the temperature of the air detected by the temperature sensor is below the predetermined temperature. A blockage determining unit that determines that a continuous pipeline is blocked;
With
Humidification for setting the rotational speed of the humidification fan when the blockage determination unit determines whether or not the pipeline is blocked based on the length of the pipeline connected to the humidification passage. A fan speed setting unit is provided.

According to the invention , the humidifying fan speed setting unit can set the rotation speed of the humidifying fan to be high or low based on the length of the pipe line, so that the length of the pipe line is hardly affected. It is possible to accurately detect the blockage of the pipeline.

The humidifier of this invention is
A humidification rotor,
A humidifying passage through the humidifying region of the humidifying rotor;
A humidifying fan that allows air to flow through the humidifying passage;
A heater provided upstream of the humidification region of the humidification rotor in the humidification passage;
A temperature sensor provided in the vicinity of the outlet of the pipe line connected to the humidifying passage;
After the heater and the humidifying fan are turned on and air flows through the humidifying passage, the temperature of the air detected by the temperature sensor when a predetermined time has elapsed,
A blockage determining unit that determines that the pipe line connected to the humidifying passage is blocked when the temperature is equal to or lower than a predetermined temperature.

  According to the above configuration, the blockage determination unit turns on the heater and the humidifying fan and flows air through the humidifying passage, and when a predetermined time elapses, the outlet of the pipe connected to the humidifying passage Since it is determined that the pipeline connected to the humidifying passage is blocked when the temperature of the air detected by the temperature sensor provided in the vicinity is equal to or lower than the predetermined temperature, the blockage of the pipeline is easily and reliably blocked. Can be detected.

  According to this invention, the blockage determination unit can detect blockage of a pipe such as a hose.

It is a schematic sectional drawing of the humidification apparatus of 1st Embodiment of this invention. It is a schematic diagram explaining the humidification function of the humidification apparatus of the said 1st Embodiment. It is a functional block diagram of the control apparatus of the humidification apparatus of the said 1st Embodiment. It is a flowchart of the obstruction | occlusion determination part of the humidification apparatus of the said 1st Embodiment. It is a flowchart of the obstruction | occlusion determination part of the humidification apparatus of the said 1st Embodiment. It is a flowchart of the obstruction | occlusion determination part of the humidification apparatus of the said 1st Embodiment. It is a graph which shows the relationship between elapsed time and blowing temperature about the case where the temperature of external air is -5 degreeC, there is no obstruction | occlusion, and there exists obstruction | occlusion. It is a graph which shows the relationship between elapsed time and blowing temperature about the case where the temperature of external air is 24 degreeC, there is no obstruction | occlusion, and an obstruction | occlusion. It is a graph which shows the relationship between outside temperature and a heater output by using the length of a hose as a parameter.

  Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments.

(First embodiment)
In FIG. 1, 1 is an outdoor unit, 2 is a humidifying device mounted on the outdoor unit 1, and 3 is an indoor unit to which humidified air is supplied from the humidifying device 2.

  As shown in FIGS. 1 and 2, the humidifying device 2 has a disc-shaped humidifying rotor 21. The humidification rotor 21 is formed by forming a moisture absorbing material such as silica gel, zeolite, alumina, etc. into, for example, a honeycomb shape or a porous multi-grain shape. As schematically shown in FIG. 2, the humidification rotor 21 is rotated around the central axis in the direction of arrow R by a motor (not shown). H and heat recovery region T. A moisture absorption fan 23 is provided through the moisture absorption area A through the moisture absorption passage 22 to flow air through the moisture absorption path 22. Further, a humidifying fan 26 is provided in which the heat recovery region T and the humidifying region H are sequentially passed through a humidifying passage 25 in a substantially U shape, and air is supplied to the humidifying passage 25. A heater 27 is provided between the heat recovery area T and the humidification area H of the humidification passage 25. Heat is recovered from the heat recovery area T to preheat the relatively cold outside air ca, and the preheated air pa is further heated by the heater 27 to form the high temperature air hh. The moisture is absorbed from the humidification region H to generate the humidified air ha.

  Further, as shown in FIG. 1, the humidifying rotor 21 is arranged in a casing 30, and the inside of the casing 30 is partitioned by a partition plate (not shown), and a moisture absorption passage 22 passing through a moisture absorption region A shown in FIG. The humidification passage 25 that passes through the heat recovery region T and the humidification region H is formed.

  Further, a temperature sensor 31 composed of, for example, a thermistor for detecting the temperature of the humidified air ha is provided downstream of the humidification region H of the humidification rotor 21 in the humidification passage 25 and downstream of the humidification fan 26. A damper 32 that opens and closes is provided on the downstream end side of the humidifying passage 25.

  One end of a hose 35 bent in a U shape as an example of a pipe line is connected to the downstream end of the humidifying passage 25, and the other end of the hose 35 is connected to the duct 36 of the indoor unit 3. The duct 36 is provided with a temperature / humidity sensor 37 as an example of a temperature sensor.

  On the other hand, a temperature fuse 47 and a safety fuse 48 are provided on the upstream side of the heater 27 in the humidifying passage 25. The temperature fuse 47 is blown at a temperature lower than that of the safety fuse 48.

  The humidifying device 2 includes a control device 100 shown in the functional block diagram of FIG. 3, and the control device 100 includes a microcomputer and an input / output circuit. The control device 100 controls the notifying device 41 that notifies the blockage of the hose 35 with the humidifying rotor motor 210 that drives the humidifying rotor 21, the humidifying fan 26, the moisture absorbing fan 23, the heater 27, and the display lamp of the indoor unit 3, In addition, a temperature detection signal, a heater output setting signal, and a humidifying fan speed setting signal are received from the temperature sensor 31, the heater output setting unit 43, and the humidifying fan speed setting unit 44.

  The control device 100 includes a blockage determination unit 110, and the blockage determination unit 110 is configured by software. When the hose 35 is blocked with the dew condensation water 50 or the like, the blockage determination unit 110 does not cause an air flow from the humidification passage 25 to the hose 35 side, so the temperature of the air detected by the temperature sensor 31 increases. The determination operation shown in the flowcharts of FIGS.

  Further, as shown in FIG. 3, the blockage determination unit 110 includes a determination stop unit 111 based on air temperature (blow-out temperature), a determination stop unit 112 based on outside air temperature, and a heater output control unit 113.

  The determination stop unit 111 based on the air temperature (blow-out temperature) determines that the air temperature (blow-out temperature) detected by the temperature sensor 31 is equal to or higher than a preset value (for example, 58 ° C.). The determination operation of the unit 110 is stopped to prevent erroneous detection. For example, if the temperature of the air detected by the temperature sensor 31 is 58 ° C. or higher, the drooping control of the heater 27 is performed. Therefore, it is considered that the temperature of the air has increased. Because.

  The determination stop unit 112 based on the outside air temperature is to stop the determination operation of the blockage determination unit 110 when the outside air temperature exceeds a predetermined outside air set temperature. That is, the determination stop unit 112 based on the outside air temperature determines whether the air temperature detected by the temperature sensor 31 is equal to or lower than the predetermined temperature when the predetermined time has elapsed. It is performed when the outside air temperature is equal to or lower than a predetermined outside air set temperature (for example, 16 ° C.), and when the outside air is at a high temperature exceeding, for example, 16 ° C., the determination about the blockage is not performed. Is to prevent.

  This is based on the experimental results shown in FIGS. That is, as shown in FIG. 7, when the outside air temperature is −5 ° C., the temperature of the air detected by the temperature sensor 31, that is, the blowing temperature, is indicated by a broken line connecting square points when there is no blockage. On the other hand, in the case of clogging, since it does not rise so much as shown by the broken line connecting the triangular points, the presence or absence of clogging can be accurately determined at the above-mentioned high and low blowout temperature, as shown in FIG. Thus, when the outside air temperature is 24 ° C., the temperature of the air (blowout temperature) detected by the temperature sensor 31 is not blocked (a broken line connecting square points) and is blocked (a triangular point is This is because there is little difference between the connecting line and the blowout temperature, and the presence or absence of blockage cannot be accurately determined.

  The heater output control unit 113 controls the output of the heater 27 so as to decrease as the outside air temperature increases based on the outside air temperature. That is, the heater output control unit 113 reduces the output of the heater 27 when the outside air temperature is high while increasing the output when the outside air temperature is low to reduce the influence of the outside air temperature and prevent erroneous detection. ing.

  The outside air temperature is detected by an outside air temperature sensor (not shown) in the outdoor unit 1. Alternatively, an external air temperature sensor (not shown) may be separately provided in the humidifying device 2, and the outdoor air temperature may be detected by the external air temperature sensor.

  On the other hand, the heater output setting unit 43 determines the output of the heater 27 when the blockage determination unit 110 determines whether or not the hose 35 is blocked based on the length of the hose 35. The output of the heater 27 is set by inputting the length of the hose 35.

  Therefore, as shown in FIG. 9, the heater output control unit 113 and the heater output setting unit 43 output the heater 27 as the outside air temperature increases with the length of the hose 35 as a parameter. As the length of the hose 35 decreases and the length of the hose 35 increases, the output of the heater 27 increases.

  The humidifying fan speed setting unit 44 determines the rotational speed of the humidifying fan 26 when the blocking determination unit 110 determines whether the hose 35 is blocked based on the length of the hose 35. The rotational speed of the humidifying fan 26 is set by inputting the length of the hose 35. Thereby, even if the hose 35 is long, the blockage of the hose 35 can be accurately detected.

  Note that the heater output setting unit 43 and the humidifying fan speed setting unit 44 are integrated into a single unit, and by simply inputting the length of the hose 35, both the output of the heater 27 and the rotational speed of the humidifying fan 26 are obtained. May be set.

  The humidifying device 2 configured as described above operates as follows.

  In addition, since the startup operation, the drying operation, and the humidification operation of the humidifier 2 are conventionally well-known and have little relation to the gist of the present invention, the blockage detection operation (after the startup operation, This will be explained by focusing on (done before the drying operation).

  First, in step S1 of FIG. 4, the damper 32 is opened, and the humidification fan 26 and the heater 27 are driven with the humidification rotor 21 and the moisture absorption fan 23 stopped.

  At this time, the rotational speed of the humidifying fan 26 is the speed set by the humidifying fan speed setting unit 44 as described above, and the output of the heater 27 is determined by the heater output setting unit 43 and the heater output control unit 113. Output.

  As described above, the humidifying fan speed setting unit 44 sets the rotational speed of the humidifying fan 26 based on the length of the hose 35 so that the length of the hose 35 is almost affected. Therefore, the hose 35 can be accurately detected. Further, as shown in FIG. 9, the heater output control unit 113 and the heater output setting unit 43 output the heater 27 as the outside air temperature increases with the length of the hose 35 as a parameter. Since the output of the heater 27 is controlled to increase as the length of the hose 35 becomes smaller and the length of the hose 35 becomes longer, the influence of the outside air temperature and the length of the hose 35 is reduced to accurately Blockage can be detected.

  In FIG. 9, the relationship between the outside air temperature and the heater output is a right-downward straight line relationship, but may be, for example, a hyperbola, another curve, or a broken line as long as it is a right-downward relationship.

  Next, the process proceeds to step S2, waits for a predetermined time, for example, 10 minutes to elapse after starting the blockage detection operation, and proceeds to step S3 when 10 minutes elapses.

  In step S3, it is determined whether or not the blowing temperature detected by the temperature sensor 31 has become equal to or higher than a set value until a predetermined time elapses. If YES, the process proceeds to step S4, and the determination operation of the blockage determination unit 110 is performed. Is stopped and the process proceeds to the drying operation in step S6. On the other hand, if it is determined NO in step S3, the process proceeds to step S5.

  More specifically, when the air temperature (blowout temperature) detected by the temperature sensor 31 is equal to or higher than a predetermined set value (for example, 58 ° C.), the determination stop unit 111 based on the air temperature determines the blockage. The determination operation of the unit 110 is stopped. This is a state where the drooping control of the heater 27 is carried out when the blowout temperature detected by the temperature sensor 31 is, for example, 58 ° C. or higher, and therefore the blowout temperature is high regardless of the presence or absence of blockage. It is thought that it became.

  On the other hand, in step S5, it is determined whether or not the air temperature (blowing temperature) detected by the temperature sensor 31 is equal to or lower than a predetermined temperature that is a predetermined value higher than the outside air temperature.

  As described above, since the predetermined temperature is a temperature higher by a predetermined value than the outside air temperature, it is possible to prevent erroneous detection of the blockage of the hose 35 due to the outside air temperature.

  Specifically, as shown in FIG. 7, assuming that the temperature of the outside air is −5 ° C., the temperature of the air (blowout temperature) detected by the temperature sensor 31 is more predetermined than the outside air temperature (−5 ° C.). It is determined whether or not the value (35 ° C.) is not higher than a predetermined temperature (30 ° C.), and it is determined whether or not the hose 35 is clogged with condensed water 50 or the like. When the hose 35 is blocked with the dew condensation water 50 or the like, air does not flow toward the hose 35 side toward the humidifying passage 25, so the blowing temperature detected by the temperature sensor 31 is 30 ° C. or lower as shown in FIG. It becomes.

  If it is determined NO in step S5 and the blowing temperature detected by the temperature sensor 31 exceeds the predetermined temperature, it is determined that the hose 35 is not blocked, and the process proceeds to step S6 to shift to a drying operation.

  On the other hand, if YES is determined in step S5, the process proceeds to step S7 in FIG. 5 to determine whether it is the second time. If it is determined NO (first time) in step S7, the process proceeds to step S9 in FIG. 6 to stop the driving of the moisture absorption fan 23, the humidification rotor 21, the humidification fan 26, and the heater 27, and the process proceeds to step S10. After waiting for a certain period of time, the process returns to step S1 to repeat the determinations of steps S2 to S5.

  On the other hand, if it is determined to be good in step S7, that is, if it is determined to be the second time, the process proceeds to step S8 to output a signal notifying the blockage of the hose 35 to the notification device 41, so that the user can The image indicates that the hose 35 is blocked.

  In this way, since it is determined that the hose 35 is closed only after it is determined in step S7 that it is the second time, the possibility of erroneous detection becomes extremely low.

  As described above, since the blockage of the hose 35 due to the condensed water 50 or the like can be reliably detected and notified to the user, there is little possibility of operating the heater 27 for a long time in the blockage state.

  If the heater 27 is operated for a long time with the hose 35 closed, as shown in FIG. 1, there is a possibility that the hot air rhh will flow backward through the humidifying passage 25 and the temperature fuse 47 may melt.

  However, according to the humidifying device of the first embodiment, it is possible to reliably detect the blockage of the hose 35 and notify the user, so that such melting of the thermal fuse 47 can be prevented.

  Further, the humidifying device 2 of the first embodiment is provided with the temperature sensor 31 in the humidifying passage 25 and completes the control within the humidifying device 2, in other words, exchanges signals with the indoor unit 3. Even if it is not, since the blockage of the hose 35 can be detected, the structure is simple and the control is simplified.

(Second Embodiment)
About the humidification apparatus of this 2nd Embodiment, FIGS. 1-2 of 1st Embodiment is used.

  The humidifying device of the second embodiment uses a temperature sensor 37 provided in the duct 36 of the indoor unit 3 instead of the temperature sensor 31 provided in the humidifying passage 25 used in the first embodiment in FIG. Only differs from the humidifying device 2 of the first embodiment.

  Also in the humidifier of the second embodiment, the output of the temperature sensor 37 provided in the duct 36 of the indoor unit 3, that is, the temperature sensor provided in the vicinity of the outlet of the hose 35 as an example of a pipe line connected to the humidifying passage 25. Based on the output of 37, the blockage of the hose 35 can be detected.

  A blockage determination unit (not shown) turns on the heater 27 and the humidifying fan 26 and flows air through the humidifying passage 25, and then the air detected by the temperature sensor 37 on the indoor unit 3 side when a predetermined time has passed. It is determined that the hose 35 is blocked when the temperature is equal to or lower than the predetermined temperature.

  In this way, it is possible to easily detect the blockage of the hose 35 due to the condensed water 50 or the like.

  In this case, it is necessary to transmit a signal representing the detected temperature from the temperature sensor 37 of the indoor unit 3 to the humidifier.

  Of course, the constituent elements described in the first and second embodiments and modifications may be combined as appropriate, and may be selected, replaced, or deleted as appropriate.

DESCRIPTION OF SYMBOLS 1 Outdoor unit 2 Humidifier 3 Indoor unit 21 Humidification rotor 22 Hygroscopic passage 23 Hygroscopic fan 25 Humidification passage 27 Heater 35 Hose 31, 37 Temperature sensor 41 Notification device 43 Heater output setting part 44 Humidity fan speed setting part 50 Condensation water 100 Control device 110 Blockage Determination Unit 111 Determination Stop Unit Based on Blowing Temperature 112 Determination Stop Unit Based on Outside Air Temperature 113 Heater Output Control Unit

Claims (9)

A humidification rotor (21);
A moisture absorption passage (22) passing through a moisture absorption region of the humidification rotor (21);
A moisture absorption fan (23) for flowing air through the moisture absorption passage (22);
A humidification passage (25) passing through a humidification region of the humidification rotor (21);
A humidifying fan (26) for flowing air through the humidifying passage (25);
A heater (27) provided upstream of the humidification region of the humidification rotor (21) in the humidification passage (25);
A temperature sensor (31) provided in the humidification passage (25) and downstream of the humidification region of the humidification rotor (21);
The temperature of the air detected by the temperature sensor (31) when a predetermined time has elapsed after the heater (27) and the humidifying fan (26) are turned on and air flows through the humidifying passage (25). but example Bei and the determining blockage determination unit conduit leading to the humidification passage (25) when a predetermined temperature or lower (35) is closed (110),
A humidifying device comprising: a heater output control unit (113) that controls the output of the heater (27) so as to be lower as the outside air temperature is higher based on the outside air temperature . A humidification rotor (21);
A moisture absorption passage (22) passing through a moisture absorption region of the humidification rotor (21);
A moisture absorption fan (23) for flowing air through the moisture absorption passage (22);
A humidification passage (25) passing through a humidification region of the humidification rotor (21);
A humidifying fan (26) for flowing air through the humidifying passage (25);
A heater (27) provided upstream of the humidification region of the humidification rotor (21) in the humidification passage (25);
A temperature sensor (31) provided in the humidification passage (25) and downstream of the humidification region of the humidification rotor (21);
The temperature of the air detected by the temperature sensor (31) when a predetermined time has elapsed after the heater (27) and the humidifying fan (26) are turned on and air flows through the humidifying passage (25). A blockage determination unit (110) that determines that the pipe line (35) connected to the humidification passageway (25) is closed when the temperature is equal to or lower than a predetermined temperature.
With
The output of the heater (27) when the blockage determination unit (110) determines whether the pipeline (35) is blocked or not is the pipeline (35) connected to the humidification passage (25). A humidifier comprising a heater output setting unit (43) for setting the height based on the length of the heater . A humidification rotor (21);
A moisture absorption passage (22) passing through a moisture absorption region of the humidification rotor (21);
A moisture absorption fan (23) for flowing air through the moisture absorption passage (22);
A humidification passage (25) passing through a humidification region of the humidification rotor (21);
A humidifying fan (26) for flowing air through the humidifying passage (25);
A heater (27) provided upstream of the humidification region of the humidification rotor (21) in the humidification passage (25);
A temperature sensor (31) provided in the humidification passage (25) and downstream of the humidification region of the humidification rotor (21);
The temperature of the air detected by the temperature sensor (31) when a predetermined time has elapsed after the heater (27) and the humidifying fan (26) are turned on and air flows through the humidifying passage (25). A blockage determination unit (110) that determines that the pipe line (35) connected to the humidification passageway (25) is closed when the temperature is equal to or lower than a predetermined temperature.
With
When the blockage determination unit (110) determines whether or not the pipeline (35) is blocked, the rotational speed of the humidification fan (26) is determined by the pipeline (25) connected to the humidification passage (25). 35) A humidifying device comprising a humidifying fan speed setting unit (44) for setting the height based on the length of 35) . A humidification rotor (21);
A humidifying passage (25) passing through a humidifying region of the humidifying rotor (21);
A humidifying fan (26) for flowing air through the humidifying passage (25);
A heater (27) provided upstream of the humidification region of the humidification rotor (21) in the humidification passage (25);
A temperature sensor (37) provided in the vicinity of the outlet of the conduit (35) connected to the humidifying passage (25);
The temperature of the air detected by the temperature sensor (37) when a predetermined time has elapsed after the heater (27) and the humidifying fan (26) are turned on and air flows through the humidifying passage (25). Is a blockage determination unit that determines that the pipe line (35) connected to the humidification passageway (25) is closed when the temperature is equal to or lower than a predetermined temperature.
With
A humidifying device comprising: a heater output control unit (113) that controls the output of the heater (27) so as to be lower as the outside air temperature is higher based on the outside air temperature . A humidification rotor (21);
A humidifying passage (25) passing through a humidifying region of the humidifying rotor (21);
A humidifying fan (26) for flowing air through the humidifying passage (25);
A heater (27) provided upstream of the humidification region of the humidification rotor (21) in the humidification passage (25);
A temperature sensor (37) provided in the vicinity of the outlet of the conduit (35) connected to the humidifying passage (25);
The temperature of the air detected by the temperature sensor (37) when a predetermined time has elapsed after the heater (27) and the humidifying fan (26) are turned on and air flows through the humidifying passage (25). Is a blockage determination unit that determines that the pipe line (35) connected to the humidification passageway (25) is closed when the temperature is equal to or lower than a predetermined temperature.
With
The output of the heater (27) when the blockage determination unit determines whether or not the pipeline (35) is blocked is the length of the pipeline (35) connected to the humidification passage (25). A humidifier comprising a heater output setting section (43) for setting the height based on the length of the heater . A humidification rotor (21);
A humidifying passage (25) passing through a humidifying region of the humidifying rotor (21);
A humidifying fan (26) for flowing air through the humidifying passage (25);
A heater (27) provided upstream of the humidification region of the humidification rotor (21) in the humidification passage (25);
A temperature sensor (37) provided in the vicinity of the outlet of the conduit (35) connected to the humidifying passage (25);
The temperature of the air detected by the temperature sensor (37) when a predetermined time has elapsed after the heater (27) and the humidifying fan (26) are turned on and air flows through the humidifying passage (25). Is a blockage determination unit that determines that the pipe line (35) connected to the humidification passageway (25) is closed when the temperature is equal to or lower than a predetermined temperature.
With
The blockage determining unit determines the rotational speed of the humidifying fan (26) when determining whether or not the conduit (35) is blocked, in the conduit (35) connected to the humidifying passage (25). A humidifying device comprising a humidifying fan speed setting unit (44) for setting the height based on the length . In the humidification device according to any one of claims 1 to 6 ,
The blockage determination unit (110) stops the determination of the blockage determination unit (110) when the temperature of the air detected by the temperature sensor (31) is equal to or higher than a predetermined set value. Humidifying device. In the humidification device according to any one of claims 1 to 7 ,
The humidifying apparatus, wherein the predetermined temperature is a temperature higher by a predetermined value than the outside air temperature. The humidifying device according to any one of claims 1 to 8 ,
The blockage determining unit (110) determines in advance whether or not the temperature of the air detected by the temperature sensor (31) is equal to or lower than the predetermined temperature when the predetermined time has elapsed. A humidifying device, which is performed when the temperature is equal to or lower than a set outdoor air temperature.

Images