KR102042771B1 - Ventilation control system - Google Patents

Abstract

The present invention provides a ventilation control system, which can independently control a ventilation condition of each room and adjust the ventilation condition along with a heating condition, thereby efficiently improving indoor environment and saving energy. The ventilation control system is installed indoors, and comprises: a heat exchanger; diffusers connected to the heat exchanger and installed in a plurality of rooms; room controllers installed in the plurality of rooms, setting ventilation conditions of the plurality of rooms, and connected to the diffusers installed in the corresponding rooms to control the diffusers in accordance with the ventilation conditions; and a main controller connected to the heat exchanger and the room controllers to control the heat exchanger. The ventilation conditions of the plurality of rooms can be independently controlled through the room controllers.

Description

Ventilation control system

The present invention relates to a ventilation control system for ventilating indoor air, and more particularly, to a ventilation control system for ventilating indoor air according to a user's setting.

Ventilation generally means exchanging indoor air with outdoor air to improve the carbon dioxide concentration or humidity of the indoor air. Ventilation is divided into natural ventilation using a window and forced ventilation using a blower or a fan. Among the forced ventilation, a total heat exchanger may be used to reduce heat loss.

The diffuser is installed on the ceiling of the room and installed to communicate with the room. Furthermore, the total heat exchanger and the diffuser are connected by the ventilation pipe to achieve ventilation. On the other hand, the total heat exchanger is provided with a blowing fan for intake and exhaust, it is possible to adjust the ventilation amount by controlling the output of the blowing fan with the main controller.

1 is a plan view illustrating a conventional ventilation control method. Referring to this, a diffuser is installed in each room, and a diffuser installed in each room is connected to the heat exchanger by a ventilation pipe, and the heat exchanger is connected to the main controller. It is electrically connected. Therefore, the diffuser in each room is always open, and the main controller ventilates each room at the same time by turning the heat exchanger on or off or adjusting the ventilation amount.

However, this conventional method is to control only the heat exchanger to the main controller, the ventilation of each room is made the same, there is a problem that can not independently control the ventilation conditions of each room.

On the other hand, Figure 2 is a plan view of a building illustrating a conventional heating control method, referring to this, each room is equipped with a controller, each controller is electrically connected to the valve controller, the valve controller controls the hot water distributor system . Although not shown, the hot water distributor system supplies hot water to each room through the boiler pipe. That is, in the case of heating, heating of each room is performed independently by a controller.

Therefore, heating and ventilation are controlled by separate systems. However, since heating and ventilation are mutually influential factors in relation to comfort environment environment and energy efficiency, conventional ventilation and heating control methods are inefficient.

The present invention is to solve the problems of the prior art as described above, specifically, an object of the present invention is to provide a ventilation control system that can independently control the ventilation conditions of each room.

In addition, an object of the present invention is to provide a ventilation control system that can efficiently improve the indoor environment and save energy by controlling the ventilation and heating conditions of each room in conjunction with each other.

Embodiment of the present invention, in order to solve the above problems, in the ventilation control system installed in the room, a total heat exchanger; A diffuser connected to the heat exchanger and installed in a plurality of rooms, respectively; A room controller installed in each of the plurality of rooms and configured to set respective ventilation conditions of the plurality of rooms and connected to the diffuser installed in the corresponding room to control the diffuser according to the ventilation conditions; A main controller connected to the total heat exchanger and the room controller to control the total heat exchanger; Including, characterized in that for controlling the ventilation conditions of the plurality of rooms independently through the room controller.

In another aspect, the present invention, the hot water distributor system is connected to each of the boiler pipe of the plurality of rooms to adjust the heating flow rate of the boiler pipe; The room controller may further set heating conditions of a corresponding room in which the room controller is installed, and the main controller is connected to the hot water distributor system to control the hot water distributor system according to the heating condition. The room controller is characterized in that to independently control the ventilation conditions and heating conditions of the plurality of rooms.

In another aspect, the present invention, the diffuser is formed with an opening communicating with the room, the diffuser includes a damper for opening or closing the opening, characterized in that the room controller controls the opening degree of the opening.

Furthermore, the room controller can control the diffuser automatically or manually.

In a first embodiment, in the case of manually controlling the room controller, the room controller receives the ventilation amount and controls the ventilation amount as a required ventilation amount of the diffuser, wherein the main controller is controlled by the room controller. A value obtained by adding all the necessary ventilation amounts of the diffuser may be a total required ventilation amount, and the output ventilation amount of the total heat exchanger may be calculated from the total required ventilation amount to control the total heat exchanger.

In a second embodiment, when automatically controlling the room controller, the room controller may control the diffuser to selectively open any of the diffusers set according to a time zone.

Further, in the case of automatically controlling the room controller, the main controller sets an arbitrary necessary ventilation amount set according to a time zone as a total required ventilation amount, and calculates an output ventilation amount of the total heat exchanger from the total required ventilation amount so as to calculate the output heat exchanger. Can be controlled.

That is, when automatically controlling the room controller, the room controller controls the diffuser to selectively open any of the diffusers set according to time zones, and the main controller controls the required ventilation amount of the diffusers opened among the diffusers. The sum of all the values is taken as the total required ventilation amount, and the output ventilation amount of the total heat exchanger is calculated from the total required ventilation amount to control the total heat exchanger.

In a third embodiment, in the case of automatically controlling the room controller, the room controller calculates a difference between the present temperature of the room and the set temperature set to the heating condition, and the room controller calculates a difference between the present temperature and the set temperature. The heating rate and the ventilation ratio is calculated according to the above, and the heating flow rate of the boiler pipe and the required ventilation amount of the diffuser are adjusted to be proportional to the heating ratio and the ventilation ratio, and the main controller adds all the necessary ventilation amounts of the diffuser. It may be characterized in that the total required ventilation amount, the output ventilation amount of the total heat exchanger is calculated from the total required ventilation amount to control the total heat exchanger.

As an example of the third embodiment, the present invention may be characterized in that as the difference between the present temperature and the set temperature decreases, the heating rate decreases, and the ventilation rate increases.

In another example of the third embodiment, when the present temperature is lower than the set temperature, the heating rate decreases as the difference between the present temperature and the set temperature decreases, the ventilation rate is 0, and the present temperature. Is equal to or higher than the set temperature, the heating rate is 0, and the ventilation rate may be increased as time increases.

In a fourth embodiment, the room controller may receive a ventilation time together with the ventilation amount from a user and open the diffuser when the ventilation time arrives.

In a fifth embodiment, when automatically controlling the room controller, the room controller stores the conventionally set ventilation conditions as data together with any one or more of the ventilation time, temperature, humidity, and whether the user is occupied. The control unit may control a required ventilation amount of the diffuser according to a ventilation condition when at least one of the current time, temperature, humidity, and whether the user is occupied in the data is matched, and the main controller may adjust the required ventilation amount of the diffuser. The sum of all values is used as the total required ventilation amount, and the output heat exchanger of the total heat exchanger is calculated from the total required ventilation amount to control the total heat exchanger.

In a sixth embodiment, the value of the total required ventilation amount may be divided into a plurality of ranges, and the output ventilation amount may be assigned to a specific value according to the range. That is, the main controller can control the total heat exchanger step by step.

In a seventh embodiment, the main controller, when the total required ventilation amount is less than the basic air flow for driving the ventilation control system, the basic air flow is controlled as the output ventilation of the heat exchanger to control the heat exchanger. You can do

In this case, the room controller calculates a ratio of the opening time (t ₁ ) and the closing time (t ₂ ) of the damper based on the basic airflow amount, the number of the diffusers to be opened, and the required ventilation amount of the diffuser. The damper may be periodically opened and closed according to the ratio of the opening time t ₁ and the closing time t ₂ .

More specifically, the ratio of the opening time t ₁ and the closing time t ₂ is

It can be calculated as.

According to the problem solving means of the present invention as described above it can be expected a variety of effects including the following matters. However, the present invention is not achieved by exerting all of the following effects.

According to the present invention, the ventilation of each room in the room can be controlled independently, and can be efficiently ventilated in consideration of the current state of each room. In addition, since the conventional equipment related to heating control can be used as it is, construction is easy, and installation costs are also very low. In addition, the degree of opening of the dampers installed in each room can be adjusted, so that the amount of ventilation in each room can be accurately adjusted in response to the set ventilation conditions.

Furthermore, the present invention can prevent unnecessary ventilation by setting different ventilation conditions for each room according to time zones when the control is performed automatically. In addition, the present invention, since the ventilation control in conjunction with the heating control in accordance with the difference between the current temperature and the set temperature, it is possible to prevent the heat accumulated by the heating is lost to the ventilation. In addition, in conjunction with the heating and ventilation, the heating is ensured after the ventilation is set to be further maximized the heat loss prevention effect. Therefore, the present invention has the advantageous effect of saving energy.

In addition, the present invention, since it is possible to control the output ventilation amount of the total heat exchanger step by step, it is possible to reliably implement the ventilation control system in a simple manner to adjust the output ventilation amount by using a DC motor and adjusting the voltage value.

In addition, the present invention, by calculating the ratio of the opening time and the closing time of the damper to open the damper periodically, even if the basic air flow amount is supplied more than the total required ventilation amount can be ventilated only by the ventilation amount required in each room.

1 is a plan view showing a conventional ventilation control system,
2 is a plan view showing a conventional heating control method,
3 is a plan view schematically showing the present invention,
4 is a cross-sectional view schematically showing the present invention,
5 is a flow chart of the ventilation control method of the present invention,
6 is a flow chart of a control method of interlocking heating and ventilation when calculating the required ventilation amount of FIG. 5;
7 is a flowchart illustrating a method of calculating a heating rate and a ventilation rate of FIG. 6;
FIG. 8 is a flowchart illustrating a control method considering a basic airflow amount when calculating the output ventilation amount and controlling the damper and the total heat exchanger of FIG. 5.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings.

3 is a plan view schematically showing the present invention, FIG. 4 is a cross-sectional view schematically showing the present invention, and FIG. 5 is a flowchart of the ventilation control method of the present invention.

As shown in these figures, the present invention, the heat exchanger 10 for ventilating the indoor air and outdoor air, the diffuser connected to the heat exchanger 10 by the ventilation pipe 11 and installed in each room of the room ( 20, 21, 22, 23, 24, hot water distributor system 52 for supplying hot water for heating of each room. Furthermore, the present invention provides room controllers 40, 41, 42, 43, 44 and room controllers 40 installed in each room to control the heat exchanger 10, the diffuser 20, the hot water distributor system 52. It is connected to the main controller 30.

The room controller 40 may set heating and ventilation conditions of the room, and includes a sensor 26 capable of sensing a current temperature, and transmits the input heating and ventilation conditions to the main controller 30. , According to the heating conditions to control the diffuser 20 installed in the room.

The main controller 30 is driven by the power source 31 and is connected to the room controller 40 of each room to control the hot water distributor system 52 and the total heat exchanger 10 according to the heating and ventilation conditions received. .

First, the present invention will be described with reference to the heating control, the boiler 50 is the hot water pipe 51 is connected to each room to heat each room, the hot water pipe 51 connected to each room is a hot water distributor system 52 Is connected to the boiler (50). In FIG. 4, for convenience, each room and the boiler 50 and the hot water distributor system 52 are connected by one hot water pipe 51, but may be actually connected by a pair of supply pipe and a recovery pipe. In the present invention, the hot water distributor system 52 is connected to the hot water pipe 51 of each room, the hot water distributor for controlling the flow rate of each hot water pipe 51 and the valve for controlling the total flow rate to be supplied from the hot water distributor Include.

In the heating control, when the user inputs the set temperature to the heating condition using the room controller 40 installed in each room, whether the set temperature received by the main controller 30 from each room controller 40 is higher than the current temperature sensed. By judging, the hot water distributor and the valve of the hot water distributor system 52 is made by supplying hot water to the room.

Furthermore, when describing the present invention with respect to the ventilation control, the total heat exchanger 10 is connected to the diffuser 20 and the ventilation pipe 11 respectively installed in each room. In FIG. 4, the heat exchanger 10 and the diffuser 20 are connected by one ventilation pipe 11 for convenience, but may be actually connected by a pair of intake pipes and exhaust pipes. The total heat exchanger (10) includes a blower fan for forced ventilation and a motor for driving the blower fan. The diffuser 20 also has an opening in communication with the room, and includes a damper 25 for opening or closing the opening. The damper 25 can adjust the opening degree of the opening and is driven by a motor.

In the ventilation control, when the user sets the ventilation condition using the room controller 40 installed in each room, the room controller 40 controls the damper 25 of the diffuser 20 according to the set ventilation condition. Furthermore, the main controller 30 controls the heat exchanger 10 by collecting the ventilation conditions received from each room controller 40.

Therefore, the present invention can independently control the ventilation conditions and heating conditions of each room through the room controller 40. Installing the room controller 40 in each room, and connecting the room controller 40 and the main controller 30 has a lot of problems because the construction cost is greatly increased due to the difficult wiring. However, the present invention utilizes the conventional valve controller as the main controller 30 using the valve controller and the room controller 40 controlling the conventional hot water distributor system 52, and the room controller 40 to control the ventilation conditions of each room. It is possible to set, and by controlling the diffuser 20 with the room controller 40, it is possible to independently control the ventilation conditions of each room only by connecting the room controller 40 and the diffuser 20. Therefore, it can be implemented reliably at low cost.

5 is a flow chart of the ventilation control method using the present invention, referring to this, the ventilation control is the heating condition and the ventilation condition setting (S10), the required ventilation amount calculation (S20), the total required ventilation amount calculation (S30), the output ventilation amount calculation ( S40), diffuser 20 and the total heat exchanger control (S50) step.

In order to explain this again in detail, the step of setting the heating condition and the ventilation condition (S10) is a step of setting the heating condition and the ventilation condition of each room manually or automatically. This step is implemented by the room controller 40, The following steps are performed based on the set ventilation conditions.

The required ventilation amount calculation step (S20) is a step of calculating the required ventilation amount required by each diffuser 20 installed in each room, that is, the ventilation amount controlled by each room controller 40. In other words, the necessary ventilation amount means the ventilation amount ventilated in each diffuser 20. As shown in the table below, the hourly ventilation amount can be determined for each diffuser 20 installed in each room in consideration of the area and purpose of each room, and the required ventilation amount means the hourly ventilation amount of the corresponding room or based on the hourly ventilation amount of the corresponding room. It may mean a calculated value.

Room type room 1 room 2 room 3 living room Hourly ventilation 80 80 30 120

The total output ventilation amount calculation step S30 is calculated by the required ventilation amount, and is a step of calculating the total necessary ventilation amount to be controlled by the main controller 30. That is, the total required ventilation amount is a value obtained by adding up each required ventilation amount, and is calculated by the main controller 30. The output ventilation amount calculation (S40) step is calculated from the total required ventilation amount, and the main controller 30 is the total heat exchanger. It is the step of calculating the output ventilation amount of. That is, the output ventilation amount means the ventilation amount required in the total heat exchanger. The output ventilation amount may be the same value as the total required ventilation amount, and as described below, it may be determined step by step based on the total required ventilation amount or may be the same value as the basic airflow amount. In the diffuser 20 and the total heat exchanger control (S50), the room controller 40 controls the damper 25 of the diffuser 20 to the required ventilation amount, and the main controller 30 controls the blower fan of the total heat exchanger as the output ventilation amount. To control. Although the damper 25 and the heat exchanger are simultaneously controlled in the drawing, the room controller 40 may control the damper 25 even before the output ventilation amount calculation S40, after the required ventilation amount calculation step S20. .

The ventilation control system of the present invention controls the ventilation of each room by the control method, but the ventilation control method can be largely divided into manual control and automatic control, and in detail, can be divided into the first to seventh embodiments. have.

The first embodiment is a method for manual control, the second embodiment is a method for automatic control according to time zone, the third embodiment is a method for automatic control in conjunction with a heating state, and the fourth embodiment is controlled according to a user's reservation setting. Method, the fifth embodiment is a method for automatic control according to the conventional ventilation pattern, the sixth embodiment is a method for controlling the output ventilation amount of the total heat exchanger step by step during manual or automatic control, the seventh embodiment is manual or automatic control It is a method to control the output ventilation of the total heat exchanger in consideration of the basic air flow rate. Hereinafter, a description will be given of a ventilation control system for implementing each embodiment in order.

The first embodiment is a method of manually controlling the ventilation conditions of each room. The user can set the ventilation conditions of each room through the room controller (related to S10). That is, it is possible to set whether to ventilate the room and how much ventilation to ventilate. If only the ventilation is set, the amount of ventilation per hour determined for each room is the required ventilation amount, and if the ventilation amount is set, the ventilation amount is the required ventilation amount (related to S20). The main controller calculates the sum of the required ventilation amounts in each room as the total required ventilation amount (related to S30), and calculates the total required ventilation amount as the output ventilation amount of the total heat exchanger (related to S40), and controls the total heat exchanger (related to S50). . The room controller controls the diffuser to the required ventilation amount (associated with S50).

The second embodiment is a method for automatically controlling the ventilation condition of each room to a value set according to the time zone and the actual use state. Ventilation conditions are automatically set (related to S10), in which case it is possible to utilize the above-mentioned ventilation amount per hour. For example, if you set the air volume per hour as shown in the table below,

Room type room 1 room 2 room 3 living room Hourly ventilation 80 80 30 120

The room controller controls the diffuser to selectively open any diffuser according to the time zone in consideration of the time zone and the actual use state. At this time, the required ventilation amount of the open diffuser is the amount of ventilation per hour in the table, and the required ventilation amount of the unopened diffuser is 0 (related to S20).

The total required ventilation amount is the sum of the required ventilation amounts of each diffuser, and the total required ventilation amount considering the time zone and the actual use state can be calculated as follows (S30 related). Explain the table below,

slot 06 ~ 08 o'clock 08 ~ 19 o'clock 19-22 o'clock 22 ~ 06 h Actual state of use All room living room All room room 1, 2 Total required ventilation 310
(80 + 80 + 30 + 120) 120 310
(80 + 80 + 30 + 120) 160
(80 + 80)

06-08 is a time to prepare for work or school after the weather, and all the space in the house is used. Therefore, all rooms need to be ventilated, in which case the required ventilation amount is set to 310 by the hourly ventilation amount.

08-19 o'clock is generally the time when there are few people in the house. Therefore, in this case, only the living room can be determined to be ventilated, in which case the required ventilation amount is 120.

19 to 22 o'clock is a time when school is usually closed after work and before bedtime, when all the space in the house is used. Therefore, all rooms need to be ventilated and the required ventilation amount is set at 310.

It is usually bedtime from 22 to 06 o'clock, and only bedroom needs to be ventilated. Assuming room3 is a clothes room, only room 1 and 2 can be set to be ventilated, and the required ventilation amount is 160.

The main controller calculates the total required ventilation amount by the above-described method, and can control the total heat exchanger by using the calculated total required ventilation amount as the output ventilation amount of the total heat exchanger (S40 and S50 related).

The third embodiment is a method for automatically controlling the ventilation condition in conjunction with the heating state. 5 is a flowchart of a ventilation control method using a heating state, and FIG. 6 is a flowchart of a control method of interlocking heating and ventilation when calculating a required ventilation amount of FIG. 5. Referring to this, the ventilation condition is automatically set (related to S10), and the required ventilation amount is calculated in association with the heating state (related to S20). Subsequent steps are performed in the same manner as in the manual control of the first embodiment (related to S30 to S50).

The required ventilation amount is calculated in conjunction with the temperature difference as shown in FIG. 5, and thus may include a temperature sensor. First, the current temperature is sensed using the sensor of the room controller (S21). Thereafter, the room controller calculates a temperature difference Δt between the set temperature and the present temperature (S22), and calculates a heating ratio and a ventilation ratio according to the temperature difference (S23). Then, the heating flow rate and the required ventilation amount is calculated (S24) so as to be proportional to the calculated heating rate and ventilation rate.

The third embodiment can be controlled in the normal mode or the economy mode. In the general mode, when the temperature difference is 1 to 5 ° C., the heating rate is proportional to the temperature difference, and the ventilation rate is controlled in inverse proportion to the temperature difference. On the other hand, in the saving mode, only heating is performed when the set temperature is higher than the present temperature, and only ventilation is performed when the set temperature is lower than or equal to the present temperature. The normal mode and the saving mode are intended to reduce the heat loss due to ventilation, and especially in the saving mode to minimize the heat loss.

Using the table below to describe the normal mode,

Current temperature (℃) Set temperature (℃) Temperature difference (△ t, ℃) Heating rate (%) Ventilation rate (%) 20 or less 25 5 or more 100 0 21 25 4 80 20 22 25 3 60 40 23 25 2 40 60 24 25 One 20 80 25 or more 25 0 or less 0 100

If the temperature difference is 5 ° C or more, only heating is operated at maximum output to ensure heating temperature quickly. That is, the heating rate is 100% and the ventilation rate is 0%. When the temperature difference is 1 to 5 ° C, the heating rate is proportional to the temperature difference, and the ventilation rate is set in inverse proportion to the temperature difference. That is, the heating rate and the ventilation rate are set in inverse proportion. If the temperature difference is less than 0 ℃, the heating temperature is assumed to be secured, and the heating rate is set to 0% and the ventilation rate is set to 100%.

Next, use the table below to describe the Economy Mode.

Current temperature (℃) Set temperature (℃) Temperature difference (△ t, ℃) Heating rate (%) Ventilation rate (%) 20 or less 25 5 or more 100 0 21 25 4 80 0 22 25 3 60 0 23 25 2 40 0 24 25 One 20 0 25 or more 25 0 or less 0 0 10 minutes after heating temperature is secured 0 30 20 minutes after heating 0 70 30 minutes after heating temperature is secured 0 100

When the temperature difference is 5 ° C or more, the heating is operated at the maximum output in order to secure the heating temperature quickly. If the temperature difference is more than 0 ~ 5 ℃, the heating rate is proportional to the temperature difference, the ventilation rate is set to 0%. If the temperature difference is less than 0 ° C, the heating temperature is assumed to be secured, and the heating rate is 0%, and the ventilation rate is set in proportion to the time after the heating temperature is secured. 30 minutes after the heating temperature has been ensured, the ventilation is switched on at maximum power. That is, based on whether the heating temperature is secured, only heating before securing and only ventilation after securing are operated.

Referring to FIG. 7 again, the present embodiment is sensed using the sensor of the room controller (S21), the difference between the set temperature and the present temperature (Δt) is calculated (S22), and the temperature difference (Δ). It is determined whether t) is 5 ° C. or more (S234), and when abnormal, the heating rate is calculated as 100% and the ventilation rate is 0% (S23a).

If the temperature difference Δt is less than or equal to 5 ° C., it is determined whether it is the normal mode or the saving mode (S235). If it is within this range, the heating rate is proportional to the temperature difference, and the ventilation rate is calculated to be inversely proportional to the temperature difference (S23b). At this time, the heating rate and the ventilation rate is in the range of 0 to 100%. If the temperature difference is 0 ° C or less, the heating rate is 0%, the ventilation rate is calculated as 100% (S23c).

In the saving mode, it is determined whether or not the temperature difference exceeds 0 ° C. (S237). If the temperature difference is exceeded, the heating rate is calculated to be proportional to the temperature difference, and the ventilation ratio is calculated to 0% (S23d). When the temperature difference is 0 ° C. or less, it is considered that the heating temperature is secured, and it is determined whether the temperature difference is maintained below 0 ° C. for a predetermined time (s) (S238). If not maintained, the heating rate and the ventilation rate are calculated again according to the temperature difference, and if maintained, the heating rate is calculated as 0% (S23e). Thereafter, the ventilation ratio is calculated to be proportional to the time s until the time s at which the heating temperature is maintained is 30 minutes, and when 30 minutes have elapsed, the ventilation ratio is calculated at 100%.

The heating flow rate and the required ventilation amount are calculated (S24) so as to be proportional to the heating rate and the ventilation rate calculated by the above-described method. The heating flow rate is determined by multiplying the heating rate by the maximum amount of hot water that can be supplied by the hot water pipe, and the required ventilation amount can be determined by multiplying the ventilation rate by the ventilation rate per hour.

In the fourth embodiment, when a user sets a ventilation condition and a user manually inputs a ventilation amount and a ventilation start time of a room through a room controller, when the set time arrives, the room controller automatically controls the ventilation amount as much as the set ventilation amount. to be. The user can input the desired ventilation amount by setting the ventilation intensity and the ventilation duration. The room controller calculates the input ventilation amount as the required ventilation amount (S20), and when the input ventilation start time comes, the damper 25 of the diffuser 20 is opened. The other steps are the same as in the case of manual control.

The fifth embodiment is a method for automatically controlling the ventilation conditions (related to S10) according to the ventilation pattern of the occupants and the occupancy schedule. Here, the ventilation condition set by the user according to the first embodiment and the ventilation condition set automatically by the second to fourth embodiments may be accumulated as data to form a ventilation pattern. Ventilation conditions may likewise include venting, hourly ventilation, and duration of ventilation.

Accordingly, the room controller 40 stores a sensor for sensing whether a user is occupied, a temperature and humidity sensor, a ventilation condition, and a required ventilation amount calculation data together with variables such as time, occupancy, temperature and humidity, and stored data. The control unit may further include a control unit configured to calculate a ventilation pattern, set a ventilation condition using the calculated ventilation pattern, and calculate a required ventilation amount.

The control unit may derive a matching ventilation condition by comparing the current time, temperature, humidity, occupancy status, etc. with previously stored data, and determine the ventilation condition as an optimal condition, set the ventilation condition, and calculate the required ventilation amount. can do. When deriving a matching ventilation condition, data should be derived when as many variables as possible are matched, and it is preferable that the ventilation condition most frequently used by a user is derived first. At this time, it is also possible to consider the control method preferred by the user.

For example, when the user mainly inputs the ventilation condition according to the first embodiment or the fourth embodiment, the ventilation condition desired by the user by the accumulated data in consideration of the temperature and humidity at the time of the input ventilation amount and the ventilation time. Can be predicted and controlled. In addition, when the user mainly sets the ventilation conditions according to the second embodiment, it is possible to adjust the time zone and the room to be ventilated based on whether the user is in the room based on the second embodiment. In addition, in the case of mainly setting the ventilation conditions according to the third embodiment, the ventilation conditions may be set in consideration of whether the user prefers the general mode / saving mode, the indoor / outdoor temperature difference, or the like. On the other hand, when setting the ventilation conditions according to the fifth embodiment, the room controller is controlled by one of the second to third embodiments that control the ventilation conditions by the collected data, but automatically control when the data is not sufficient It is preferable to set in advance to work.

The sixth embodiment corresponds to both the manual and automatic setting of the ventilation conditions (S10 related), and is a method of controlling the output ventilation amount of the total heat exchanger step by step. This is related to the output ventilation amount calculation S40 of the total heat exchanger, and the steps S20, 30, and 50 are the same as in the case of manual control.

The output ventilation amount is calculated from the total required ventilation amount, the total required ventilation amount is divided into a plurality of ranges according to the value, and the output ventilation amount is assigned to a specific value according to the range of the total required ventilation amount. In more detail,

Room type room 1 room 2 room 3 living room Hourly ventilation 80 80 30 120

When the hourly ventilation in each room is as shown in the table above and the required ventilation in each diffuser is equal to the ventilation per hour, the possible combinations of the total required ventilation are as follows. Furthermore, the total required ventilation amount is divided into a plurality of ranges, and the output ventilation amount is assigned to any one of values within the corresponding range of the total required ventilation amount.

step Room ventilated Total required ventilation Output ventilation amount One none 0 100 2 room 3 30 3 room 1 (or 2) 80 4 room 1 (or 2), 3 110 5 living room 120 6 living room, room 3 150 180 7 room 1, 2 160 8 room 1, 2, 3 190 9 living room, room 1 (or 2) 200 10 living room, room 1 (or 2), 3 230 260 11 living room, room 1, 2 280 12 All room 310

That is, in the sixth embodiment, the output ventilation amount may be adjusted to weak, medium, or strong according to the range of the total required ventilation amount, in addition to controlling the output ventilation amount in correspondence with the total required ventilation amount in 1 to 12 steps. This requires a large number of components and circuits such as a static pressure sensor in the control unit of the motor for driving the blower fan to accurately control the air flow, in order to easily control the output ventilation amount by controlling the voltage value of the DC motor.

The seventh embodiment is applicable to the case of manually and automatically setting the ventilation conditions (related to S10), and the calculation of S20 and 30 is the same as the case of manual control, and when calculating the output ventilation amount from the total required ventilation amount, In consideration of this, the output ventilation amount of the total heat exchanger is calculated (related to S40). Further, the total heat exchanger and the diffuser are controlled using the output ventilation amount and the required ventilation amount (related to S50).

Basic air flow rate means the minimum air flow amount for driving the ventilation control system in consideration of the length of the ventilation pipe. Therefore, the total required ventilation amount may be smaller than the basic airflow amount. For example, if the basic airflow amount is 60, the total required ventilation amount is 30 when only the room 3 is to be ventilated, which is smaller than the basic airflow amount.

In this case, when the main controller controls the total heat exchanger, when the output ventilation amount of the total heat exchanger is smaller than the basic airflow amount, the ventilation is not normally performed, and when the output ventilation amount is controlled to be higher than the basic airflow amount, the room to be ventilated excessively. Outdoor air may enter. Therefore, in consideration of this, it is necessary to control the total heat exchanger and the diffuser, and a control method is illustrated in FIG. 8.

Referring to FIG. 8, it is determined whether the total required ventilation amount is smaller than the basic airflow amount (S41). If not, the total required ventilation amount is calculated as the output ventilation amount (S40a). If the total required ventilation amount is smaller than the basic ventilation amount, the basic ventilation amount is calculated as the output ventilation amount (S40b).

Then, the main controller controls the total heat exchanger to the output ventilation amount (S51). In addition, the room controller calculates a ratio of the opening time t ₁ and the closing time t _{2 of the} damper, and controls the diffuser to periodically open and close the damper according to the ratio.

The ratio of the opening time t ₁ and the closing time t ₂ of the damper may be calculated as follows.

The above formula assumes that the capacity of each diffuser is the same, and the number of diffusers is the number of rooms requiring ventilation. The required ventilation amount of the room is the required ventilation amount of the room for which the ratio of the opening time (t ₁ ) and the closing time (t ₂ ) is to be obtained.

Based on this, only the room 3 having a required ventilation amount of 30 is ventilated. For example, when the basic air flow rate is 60, the damper opening time (t ₁ ) and closing time (t ₂ ) ratio are obtained.

Is, t _1: It can be seen that the resulting ratio of 1: t ₂ = 1.

The present invention relates to a ventilation control system for implementing the ventilation control method described in the first to seventh embodiments. The present invention is characterized in that it is possible to independently control the ventilation conditions of each room, it can be implemented with low cost and high efficiency by interlocking with the heating control.

In this specification, each embodiment has been divided and described, and specific values are used in describing each embodiment. However, since the specific numerical values are merely examples, the present invention may fall within the scope of the present invention even when the numerical values are changed, and the embodiments that may be derived by combining the embodiments may also fall within the scope of the present invention.

The above description is merely illustrative of the technical spirit of the present invention, and those skilled in the art to which the present invention pertains various modifications and variations without departing from the essential characteristics of the present invention. The scope of protection should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

10: heat exchanger 11: ventilation piping
21, 22, 23, 24: Diffuser 25: Damper
26 sensor 30 main controller
31: power supply 40, 41, 42, 43, 44: room controller
50: boiler 51: hot water pipe
52: hot water distributor system

Claims (16)

In the ventilation control system installed indoors,
Total heat exchanger;
A diffuser connected to the heat exchanger and installed in a plurality of rooms, respectively;
A room controller installed in each of the plurality of rooms and configured to set respective ventilation conditions of the plurality of rooms and connected to the diffuser installed in the corresponding room to control the diffuser according to the ventilation conditions; And
A main controller connected to the heat exchanger and the room controller to control the heat exchanger;
Including,
Independently controlling the ventilation conditions of the plurality of rooms through the room controller,
The main controller controls the total heat exchanger by calculating the output ventilation amount of the total heat exchanger from the total required ventilation amount by adding up all the necessary ventilation amounts of the open diffusers of the diffuser.
In the main controller, the basic airflow amount which is the minimum ventilation amount required for driving the ventilation control system is set, and when the total required ventilation amount is smaller than the basic airflow amount, the basic airflow amount is set as the output ventilation amount of the heat exchanger. To control,
The diffuser is formed with an opening in communication with the room,
The diffuser includes a damper that opens or closes the opening,
The room controller adjusts the opening degree of the opening,
The room controller calculates a ratio of the opening time (t ₁ ) and the closing time (t ₂ ) of the damper based on the basic airflow amount, the number of the diffusers to be opened, and the required ventilation amount of the diffuser, and the calculated opening time periodically open and close the damper according to the ratio of (t ₁ ) and the closing time (t ₂ ),
The ratio of the opening time t ₁ and the closing time t ₂ is

Ventilation control system, characterized in that calculated.
The method of claim 1,
A hot water distributor system connected to the boiler pipes of the plurality of rooms, respectively, to adjust a heating flow rate of the boiler pipes;
More,
The room controller may set the heating conditions of the room in which the room controller is installed,
The main controller is connected to the hot water distributor system, to control the hot water distributor system according to the heating conditions,
Ventilation control system, characterized in that for controlling the ventilation conditions and heating conditions of the plurality of rooms independently through the room controller.
delete The method of claim 2,
And the room controller controls the diffuser automatically or manually.
delete The method of claim 4, wherein
In case of controlling the room controller automatically,
The required ventilation amount of the diffuser is set differently according to the time zone.
The method of claim 4, wherein
In case of controlling the room controller automatically,
And the room controller controls the diffuser to selectively open any of the diffusers set according to time zones.
The method of claim 4, wherein
In case of controlling the room controller automatically,
The room controller calculates a difference between a current temperature of the corresponding room and a set temperature set as the heating condition, calculates a heating ratio and a ventilation ratio according to the difference between the current temperature and the set temperature, and generates the heating ratio and the ventilation ratio. To adjust the heating flow rate and the required ventilation amount of the diffuser in the boiler pipe,
And the main controller controls the total heat exchanger by calculating an output ventilation amount of the total heat exchanger from the total required ventilation amount by using a value obtained by adding all the required ventilation amounts of the diffuser.
The method of claim 8,
And as the difference between the present temperature and the set temperature decreases, the heating rate decreases, and the ventilation rate increases.
The method of claim 8,
When the present temperature is lower than the set temperature, the heating rate decreases as the difference between the present temperature and the set temperature decreases, and the ventilation ratio is zero,
And when the current temperature is equal to or higher than the set temperature, the heating rate is zero, and the ventilation rate increases with time.
The method of claim 4, wherein
In case of manually controlling the room controller,
The room controller, the ventilation control system, characterized in that for controlling the ventilation amount to the required ventilation amount of the diffuser.
The method of claim 11,
And the room controller receives a ventilation time together with the ventilation amount and opens the diffuser when the ventilation time arrives.
The method of claim 4, wherein
In case of controlling the room controller automatically,
The room controller stores the conventionally set ventilation conditions as data along with any one or more of the ventilation time, temperature, humidity, and whether the user is occupied at that time, and the current time, temperature, humidity, and the user's room among the data. Ventilation control system characterized in that for controlling the required ventilation amount of the diffuser in accordance with the ventilation conditions when any one or more match.
The method according to any one of claims 6 to 13,
The value of the total required ventilation amount is divided into a plurality of ranges,
The output ventilation amount is a ventilation control system, characterized in that assigned to a specific value according to the range.
delete delete

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