KR20060107243A - A ventilating apparatus and a driving method of the ventilating apparatus - Google Patents

Abstract

The present invention relates to a ventilator and a method of operating the ventilator, and the present invention relates to a suction passage formed between an outdoor suction port and an indoor discharge port, a discharge passage formed between the indoor suction port and the outdoor discharge port, the suction channel and the discharge path. An electrothermal heat exchange element disposed at an intersection point of the flow path to exchange heat between the air flowing along the suction flow path and the air flowing along the discharge flow path without mixing with each other, an air supply fan installed on the suction flow path, and installed on the discharge flow path When the ventilator including the exhaust fan is operated at low temperature, the air supply amount is adjusted to prevent condensation or freezing during low temperature operation.

Description

A ventilating apparatus and a driving method of the ventilating apparatus}

1 is a perspective view of a ventilation device according to an embodiment of the present invention.

Fig. 2 is a block diagram of the ventilator shown in Fig. 1.

3 to 5 are diagrams illustrating an operation mode of an air supply fan and an exhaust fan that vary according to outdoor temperature during low temperature operation.

6 is a flowchart illustrating a method of operating the ventilator shown in FIGS. 1 and 2.

* Description of the symbols for the main functions of the drawings *

11: Suction euro 12: Drain euro

13a: supply fan 13b: exhaust fan

15a: supply fan motor 15b: exhaust fan motor

30: microcomputer 31: outdoor temperature sensor

The present invention relates to a ventilator and a method of operating the ventilator, and more particularly, to a method of operating a ventilator and a ventilator that can prevent condensation or freezing by appropriately adjusting the air supply during operation at low temperatures. will be.

In general, air is muffled in a confined space such as a house or an office, and when a person stays in such a space for a long time, the content of carbon dioxide increases, thereby making the indoor air more turbid. Therefore, various ventilation devices have been developed for the ventilation of the enclosed space, for example, there is a total heat exchanger. The heat exchanger is a device designed to prevent energy loss by maintaining the maximum heat in the indoor space while ventilating. Indoor air and intakes are discharged in the process of exhausting indoor air to ventilate the building and sucking outdoor air into the room. The outdoor air is exchanged with each other to reduce heat loss in the ventilation process.

Conventional total heat exchanger is installed at the intersection of the intake flow path of the outdoor air and the discharge flow path of the indoor air, as disclosed in the Republic of Korea Patent Publication No. 2003-0063845, the heat exchange element for heat exchange between the outdoor air and the indoor air And an air supply fan provided on the suction passage and an exhaust fan provided on the discharge passage. In the conventional heat exchanger, when the air supply fan and the exhaust fan rotate, outdoor air is introduced into the room through the suction flow path, indoor air is discharged to the outside, and heat exchange occurs between the discharged indoor air and the introduced outdoor air.

On the other hand, the conventional heat exchanger described above had a problem in that the intake amount of air is reduced when condensation or freezing occurs on the suction flow path when the outdoor temperature is operated at a temperature below zero (for example, in winter). In order to solve this problem, conventionally, the operation of the total heat exchanger was stopped for a long time during low temperature operation, or the air introduced into the PTC heater was heated as disclosed in Korean Patent Application Publication No. 20-0359970.

However, if the former method is used to prevent dew condensation or freezing in the suction flow path, the indoor air quality is poor because the indoor air is not ventilated for a long time. If the latter method is used, the power consumption of the PTC heater increases. There was a problem.

The present invention is to solve the above-mentioned problems, an object of the present invention is to control the amount of air flowing into the room from the outdoor during low temperature operation to prevent condensation or freezing in the suction flow path and the operation of the ventilation device In providing a method.

In order to achieve the above object, the present invention provides a method of operating a ventilator for heat exchange without mixing the air introduced into the indoor and the air discharged from the indoor to the outdoor, the outdoor temperature is measured, the outdoor temperature Lower is characterized in that for reducing the amount of air flowing into the room from the outdoors.

In addition, in order to reduce the amount of air flowing into the indoor from the outdoor it is characterized in that for reducing the operating time of the air supply fan forced air blowing to the indoor.

In addition, the operating time of the air supply fan is set differently for each of the plurality of steps classified according to the outdoor temperature, characterized in that for operating the air supply fan with the operation time of the step belonging to the measured outdoor temperature.

In addition, the amount of air generated by the air supply fan is reduced by reducing the number of revolutions per minute of the air supply fan forcibly blowing outdoor air into the room in order to reduce the amount of air introduced into the room.

In addition, the air volume is set differently for each of the plurality of steps classified according to the outdoor temperature, characterized in that for controlling the number of revolutions per minute of the air supply fan so that the air volume of the step to which the measured outdoor temperature belongs.

In addition, in order to reduce the amount of air flowing into the indoor from the outdoor is characterized in that the operating time of the air supply fan forced air blowing to the indoor and the amount of air generated by the air supply fan together.

In addition, the suction flow path formed between the outdoor suction port and the indoor discharge port, the discharge flow path formed between the indoor suction port and the outdoor discharge port, and the air flowing along the suction flow path and disposed at the intersection of the suction flow path and the discharge flow path and the discharge An electrothermal exchange element which allows air flowing along the flow path to exchange heat without mixing with each other, an air supply fan installed on the suction flow path, an exhaust fan installed on the discharge flow path, an outdoor temperature sensor measuring an outdoor temperature, and the outdoor temperature It includes a microcomputer to control the air supply fan so that the amount of air flowing into the suction flow path is reduced as the lower.

In addition, the microcomputer may reduce the operation time of the air supply fan or reduce the air volume generated by the air supply fan in order to reduce the amount of air introduced into the indoors from the outdoor.

In addition, the microcomputer may be configured to maintain the operation time of the exhaust fan or the air volume by the exhaust fan even when the outdoor temperature decreases.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. As shown in FIG. 1, the ventilator according to the exemplary embodiment of the present invention has an inlet flow passage 11 for guiding outdoor air to the inside of the main body 10 that is open to the bottom and forms an exterior, and indoor air to the outside. The discharge passage 12 for guiding is provided to be partitioned, and one side of the main body 10 is provided with an indoor suction port 12a through which indoor air is sucked, and an indoor discharge port 11b through which outdoor air is discharged into the room. ) The other side is provided with an outdoor inlet 11a through which outdoor air is sucked and an outdoor outlet 12b through which indoor air is discharged to the outside.

At this time, the outdoor suction port 11a and the indoor discharge port 11b are connected by the suction flow path 11 to suck the outdoor air into the room, and the indoor suction port 12a and the outdoor discharge port 12b are discharge paths ( 12) to allow indoor air to be discharged to the outside. In addition, the suction passage 11 and the discharge passage 12 are intersected with each other so that the outdoor air sucked into the indoor air and the indoor air discharged to the outside can exchange with each other, and the suction passage 11 and the discharge passage 11 At the intersection where (12) intersects, an electrothermal exchange unit (20) is arranged so that the air passing through the suction passage (11) and the air passing through the discharge passage (12) can be exchanged without being mixed with each other.

The total heat exchange unit 20 is alternately stacked such that the flow path through which the air sucked in and the discharged air pass passes at right angles to each other, thereby separating the air passing through the suction flow path 11 and the discharge flow path 12. The passing air is allowed to cross heat exchange without mixing with each other.

An air supply fan 13a and an exhaust fan 13b are respectively disposed in the suction passage 11 and the discharge passage 12 to generate a blowing force so that air can flow along the suction passage 11 and the discharge passage 12. Therefore, according to the operation of the air supply fan 13a and the exhaust fan 13b, the outdoor air and the indoor air flow along the suction flow passage 11 and the discharge flow passage 12, respectively, to allow ventilation. The air supply fan 13a and the exhaust fan 13b consist of a centrifugal fan that sucks air from the axial direction and discharges it in the radial direction, and indoors the air discharged radially from the air supply fan 13a and the exhaust fan 13b. It is installed in the fan casings 14a and 14b leading to the outlet 11b and the outdoor outlet 12b. On one side of each of the fan casings 14a and 14b, air supply fan motors and exhaust fan motors 15a and 15b which generate rotational forces to rotate the air supply fan 13a and the exhaust fan 13b are respectively provided.

Reference numeral 16 denotes a lower panel 16 covering the opening of the main body 10 which is opened downward, and a through hole 16a is provided at the center thereof to separate and clean the heat exchange unit 20 to the outside.

As shown in FIG. 2, the ventilator of FIG. 1 drives the outdoor temperature sensor 31, the air supply fan motor 15a, and the exhaust fan motor 15b to measure the outdoor temperature in addition to the components shown in FIG. The motor drive part 32 and the microcomputer 30 which control the air supply fan motor 15a and the exhaust fan motor 15b are included.

The microcomputer 30 stores low temperature operation data used for controlling the ventilation device when the outdoor temperature falls below zero. As shown in FIG. 3, the low temperature operation data sets the operation mode of the air supply fan 13a and the exhaust fan 13b which vary depending on the outdoor temperature T. As shown in FIG. That is, in the low temperature operation data, the outdoor temperature is divided into four ranges, and operation modes (first step to fourth step) of the air supply fan 13a and the exhaust fan 13b applied in each range are set.

For example, when the measured outdoor temperature belongs to -5T0 (° C), the operation of driving the air supply fan 13a for 80 minutes and stopping for 10 minutes is repeated, and the exhaust fan 13b is set to operate continuously. In addition, when the measured outdoor temperature belongs to -10T-5 (° C), the operation of operating the air supply fan 13a for 50 minutes and stopping for 10 minutes is repeated, and the exhaust fan 13b is set to operate continuously. .

Meanwhile, the low temperature operation data stored in the microcomputer 30 may be set as shown in FIG. 4 different from FIG. 3. In FIG. 4, as the outdoor temperature decreases, the air volume by the air supply fan 13a decreases, and the air volume of the exhaust fan 13b is maintained to be 'strong'. The air flow rate by the air supply fan 13a can be changed by adjusting the RPM per minute of the air supply fan motor 15a, and as the air speed of the air supply fan motor 15a decreases, the air flow rate of the air supply fan 13a is also reduced. Changes in order of strong, medium and weak.

In addition, the low temperature operation data may be set as shown in FIG. 5. In FIG. 5, as the outdoor temperature decreases, the operation time of the air supply fan 13a and the air volume by the air supply fan 13a are reduced together, and the exhaust fan 13b. ) Is set to run continuously while the airflow is kept in 'river'.

The low temperature operation data illustrated in this embodiment divides the outdoor temperature into four ranges and sets the operation mode in each range from the first step to the fourth step. It may be set differently from FIGS. 3 to 5 in consideration.

Referring to Figure 6 will be described the operation method of the ventilation device according to an embodiment of the present invention. When the operation of the ventilation device starts, the microcomputer 30 receives the measured value from the outdoor temperature sensor 31 and checks the outdoor temperature. And it is determined whether the outdoor temperature is less than 0 ℃ (40). If the outdoor temperature is greater than or equal to 0 ° C., the microcomputer 30 operates in the first step by referring to the low temperature operation data (46). As shown in Figs. 3 to 5, the first step is an operation mode in which the air supply fan 13a and the exhaust fan 13b are continuously operated at a constant air volume.

However, if the outdoor temperature is less than 0 ℃ again determines whether the outdoor temperature is less than -5 ℃ (42). If the outdoor temperature is greater than or equal to -5 ° C, operation is performed in the second step of the low temperature operation data (44).

In the second step, the air supply fan 13a is stopped for 80 minutes or 10 minutes while the exhaust fan 13b is continuously operated as shown in FIGS. 3 to 5, or the exhaust fan 13b is operated 'strong'. While driving the air supply fan (13a) in the middle, or continuously running the exhaust fan (13b) to the 'strong' to let the air supply fan (13a) 120 minutes driving-10 minutes to stop.

However, if the outdoor temperature is less than -5 ℃ it is determined whether the outdoor temperature is less than -10 ℃ (48). If the outdoor temperature is greater than or equal to −10 ° C., operation is performed in the third step of the low temperature operation data (50). If the outdoor temperature is less than −10 ° C., operation is performed in the fourth step of the low temperature operation data (52).

In the third step, as shown in FIGS. 3 to 5, the air supply fan 13a is stopped for 50 minutes and 10 minutes while the exhaust fan 13b is continuously operated, or the exhaust fan 13b is operated in a 'strong' state. While driving the air supply fan 13a to 'weak' or continuously operating the exhaust fan 13b to 'strong', the air supply fan 13a is allowed to stop for about 10 minutes to 'weak' for 100 minutes. In the fourth step, as shown in FIG. 4 or FIG. 5, the air supply fan 13a is driven to 'weak' while the exhaust fan 13b is driven 'strong', or the air supply fan is continuously operated to the 'strong' exhaust fan 13b. Allow the fan 13a to stop for approximately 50 minutes of operation-10 minutes.

Next, the microcomputer 30 determines whether the operation of the ventilation device is continuing, and returns to step 40 if the operation is continued, and ends the cycle if the operation is not continued.

As described in detail above, the present invention can prevent the condensation or freezing in the suction flow path by appropriately adjusting the operation mode of the air supply fan during low temperature (especially winter) operation.

In addition, since the operation of the air supply fan is not stopped for a long time during low temperature operation, it is possible to prevent the air quality of the indoor space from dropping.

In addition, in order to prevent condensation and freezing during low temperature operation, it is not necessary to separately provide a freezing prevention means such as a heater, thereby reducing power consumption.

Claims (9)

In the operating method of the ventilator to heat exchange without mixing the air introduced into the indoors and the air discharged from the indoors to the outside, Measure the outdoor temperature, Operating method of the ventilator, characterized in that as the outdoor temperature is lowered the amount of air introduced into the room from the outdoor decreases The method of claim 1, Operating method of the ventilator characterized in that to reduce the operation time of the air supply fan forcibly blowing the outdoor air to the indoor to reduce the amount of air introduced into the indoor The method of claim 2, The operation time of the air supply fan is set differently for each of the plurality of steps classified according to the outdoor temperature, and the operation method of the ventilation device according to claim 1, wherein the air supply fan is operated by the operation time of the step to which the measured outdoor temperature belongs. The method of claim 1, Operating method of the ventilation device, characterized in that for reducing the amount of air flowing into the indoor air to reduce the amount of air generated by the air supply fan by reducing the number of revolutions per minute of the air supply fan forced air blowing into the room The method of claim 4, wherein The air flow rate is set differently for each of the plurality of steps classified according to the outdoor temperature, and the operating method of the ventilator, characterized in that for controlling the number of revolutions per minute of the air supply fan to the air flow of the step belonging to the measured outdoor temperature The method of claim 1, Operating method of the ventilation device characterized in that for reducing the amount of air flowing into the indoor from the outdoor air supply fan forced air blowing to the indoor and the amount of air generated by the air supply fan together An inlet flow path formed between an outdoor inlet port and an indoor outlet port, an outlet channel formed between the indoor inlet port and the outdoor outlet port, and air flowing along the inlet path and the outlet channel disposed at an intersection point of the inlet path and the outlet channel; A heat exchange element for allowing the air flowing along the air to exchange heat without mixing with each other, an air supply fan installed on the suction passage, an exhaust fan installed on the discharge passage, an outdoor temperature sensor measuring an outdoor temperature, and the outdoor temperature Ventilator including a microcomputer to control the air supply fan so that the lower the amount of air flowing into the suction flow path The method of claim 7, wherein The microcomputer is a ventilation device, characterized in that to reduce the amount of air flowing into the indoor from the air supply fan to reduce the operating time, or the amount of air generated by the air supply fan The method of claim 7, wherein The microcomputer ventilator, characterized in that to control the operation time of the exhaust fan or the air volume by the exhaust fan is maintained even if the outdoor temperature is lowered

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