KR20190054704A - Prediction method of energy consumption in commercial buildings - Google Patents

Abstract

The present invention provides a method for predicting ventilation energy consumption in a commercial building which can more accurately predict ventilation energy including ventilation by air circulation by heating and cooling and the ventilation by a fan which is a ventilation unit in commercial buildings and, also, can more accurately predict ventilation energy consumption by distinguishing an air conditioning room and a non-air conditioning room in the commercial buildings to individually calculate the ventilation energy consumption of the air conditioning room and the ventilation energy consumption of the non-ventilation room. In addition, the method for predicting ventilation energy consumption in a commercial building comprises the steps of: generating a monthly ventilation energy consumption prediction model of an air conditioning room; determining whether a predicted space of a commercial building to be predicted is the air conditioning room or a non-air conditioning room; calculating monthly ventilation energy consumption of the air conditioning room when the predicted space is the air conditioning room; calculating the monthly ventilation energy consumption of the non-air conditioning room when the predicted space is the non-air conditioning room; and outputting ventilation energy consumption in the commercial building to be predicted.

Description

{Prediction method of energy consumption in commercial buildings}

The present invention relates to a method for predicting ventilation energy usage of a commercial building, and more particularly, to a method for predicting ventilation energy consumption of a commercial building capable of predicting ventilation energy consumption from energy consumption of a commercial building.

Generally, a facility system installed in a commercial building includes a refrigerator or a boiler installed in an underground machine room, an air conditioner installed in each floor or each room, and a ventilation facility for supplying cold air or hot air generated by the air conditioner to each room Fans, and the like.

The cold air or the hot air generated by the air conditioner is supplied to each room by a fan, which is a ventilation equipment, and the energy of the ventilation equipment occupies a large part in the cooling and heating energy.

In order to establish an energy saving plan of the ventilation equipment, it is necessary to accurately grasp the amount of ventilation energy used in the ventilation equipment.

However, in the case of the above-mentioned ventilation equipment, there is a wide variety of facilities related to cooling and heating, and since the energy use of each ventilation equipment continuously changes with time, it is very inaccurate to estimate the energy consumption by simply using the facility capacity and the usage time of the ventilation equipment Do.

Korean Patent No. 10-1767387

It is an object of the present invention to provide a method for predicting ventilation energy usage in a commercial building.

The method for predicting the amount of ventilation energy used in a commercial building according to the present invention is characterized in that a system for predicting the amount of ventilation energy used for a commercial building is selected from among commercial buildings constructed in advance, Cooling and heating energy simulations are performed in accordance with facility parameters including a cooling and heating heat source system, an air conditioning system, and a ventilation unit, and the ventilation energy data used in the air conditioning room of the standard building is collected from the simulation results, Generating a monthly ventilation energy usage prediction model of the living room according to the building variables, the operating variables, the local variables, and the facility variables of the living room; Determining whether the predicted space of the commercial building to be predicted is a living room or a non-living room for predicting ventilation energy usage; Wherein if the object space is the air conditioner, the user inputs information including the building variables, the operating variables, the local variables, and the equipment parameters for the forecasted commercial building to the input unit of the system, Selecting a monthly ventilation energy usage prediction model of the air conditioner according to the information input to the input unit and calculating the monthly ventilation energy usage amount of the air conditioner from the selected monthly ventilation energy usage prediction model; If the target space is the non-air-conditioned room, the calculating unit calculates the monthly ventilation energy usage amount of the non-air-conditioned room from the power, the operation number, and the monthly operation time of the fans as the ventilation unit installed in the non- Wherein the calculating unit sums the monthly ventilation energy usage amount of the air conditioning room and the ventilation energy usage amount of the non-air conditioning room, and the output unit of the system outputs the summed value as the ventilation energy usage amount of the forecasted commercial building.

The present invention has the advantage of more accurately estimating the ventilation energy including the ventilation by the air circulation by the cooling and heating in the commercial building and the ventilation by the fan which is the ventilation unit.

In addition, since the ventilation energy consumption of the air conditioning room and the ventilation energy consumption of the non-ventilation room are separately calculated by dividing the air conditioning room and the non-air conditioning room in the commercial building, the ventilation energy consumption can be more accurately predicted.

1 is a flowchart illustrating a method for predicting ventilation energy usage of a commercial building according to an embodiment of the present invention.
FIG. 2 is a flowchart illustrating a monthly ventilation energy usage forecasting method for a climate control room according to an embodiment of the present invention.
3 is a flowchart illustrating a method of predicting monthly ventilation energy usage in a non-ventilating room according to an embodiment of the present invention, and a method of knowing and knowing the fan specifications.
FIG. 4 is a flowchart illustrating a method for estimating monthly ventilation energy usage in a non-ventilating room according to an embodiment of the present invention.
FIG. 5 is a flowchart illustrating a method for estimating monthly ventilation energy usage of a non-ventilating room according to an embodiment of the present invention when the fan specification is unknown.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

Ventilation of general commercial buildings includes ventilation by air circulation by cooling and heating in the air conditioning room, and ventilation by general ventilation in the non-ventilation room.

The ventilation energy due to the air circulation in the air conditioning room is the energy by the air blowing fan of the air conditioner and the ventilation energy by the ventilation in the non-air conditioning room is the energy of the air supply fan, the exhaust fan and the attracting fan.

Therefore, in the present invention, the ventilation energy consumption in the commercial building is calculated by dividing the ventilation of the air conditioning room and the ventilation of the non-ventilation room.

1 is a flowchart illustrating a method for predicting ventilation energy usage of a commercial building according to an embodiment of the present invention.

1, a system for predicting ventilation energy usage of a commercial building generates a monthly ventilation energy usage prediction model for a ventilation room.

In the case of the air conditioner, ventilation by the air conditioner is mainly performed. Since the air amount varies continuously according to the cooling and heating load, it is difficult to estimate the ventilation energy consumption based on the power and operation time of the air supply fan or the exhaust fan of the air conditioner The monthly ventilation energy usage prediction model of the air conditioner is generated.

A method for generating a monthly ventilation energy use prediction model of the above-mentioned air conditioning room is as follows.

First, the system selects standard buildings from among the pre-built commercial buildings, and performs cooling and heating energy simulations on the standard buildings.

The input variables for the heating / cooling simulation include building variables, operating variables, local variables, and facility variables.

Table 1 shows the architectural and operating parameters for the heating / cooling simulation.

In Table 1, the level of alternatives is divided into three levels in order to apply the experimental design method.

The construction variables include the floor area of the reference layer, the effective area ratio, the longitudinal constipation, the ceiling height, the stiffness, the core shape, the number of storeys, the area ratio, the shielding coefficient, the heat conduction rate,

The operating variables include re-real time, set temperature, facility operating time, and the like.

division Alternative level ① ② ③ a Base floor area (m ² ) 400 800 1,200 b Effective area ratio (%) 75 80 85 c Constipation constipation 1: 1.0 1: 1.5 1: 2.0 d Ceiling height (m) (Floor height) 2.4 (3.4) 2.6 (3.8) 2.8 (4.2) e strike copper book south f Core type Eccentric Both ends center g Window area ratio (%) 0.40 0.65 0.90 h Shielding coefficient 0.30 0.60 0.90 i Heat conduction rate
(W / m ² K) outer wall 0.27 0.47 0.58 j Window 2.10 3.40 3.84 k Structure type (weight) Light Medium Heavy l Heat load (W / m ² ) 40 50 60 m Real time (hrs) 8 (09-17) 9 (09 ~ 18) 10 (09 ~ 19) m Set temperature
(° C) heating 18 20 22 o cooling 24 26 28 p Operating hours (hr) Pre-time 1.0 1.5 2.0 q, r Target area Seoul Daejeon Gwangju

Table 2 shows combinations of facility variables for the heating / cooling simulation.

Thermal circle method Air conditioning system Application of ventilation unit division My housewife Outer periphery Central style private dining room heating Hot water boiler, steam boiler, district heating, absorption chiller, EHP, GHP CAV
VAV FCU
FPU
Convector
Radiator O, X cooling Absorption chiller (gas, steam, hot water), compression chiller, ice storage, local cooling, absorption chiller, EHP, GHP, PAC

As shown in Table 2, the present invention includes the heating / heating equipment and the air conditioning equipment, which are mainly applied to domestic commercial buildings, and they can be suitably combined and simulated.

Wherein the heating heat source is at least one of a hot water boiler, a steam boiler, a district heating, an absorption type cold / hot water heater, an EHP, and a GHP, At least one of a refrigerator, an absorption chiller (gas, steam, hot water), a compression chiller, an ice chiller, a local chiller, an absorption chiller, an EHP, a GHP and a PAC is selected. Also, at least one of CAV and VAV is selected as the inner circumference air conditioning system, and at least one of the FCU, FPU, Convector, and Radiator is selected as the outer circumference air conditioning system. Also, whether or not the fan which is the ventilation unit is applied is selected and inputted.

After the simulation is performed, the ventilation energy data used in the air conditioning room of the standard building is collected from the simulation result.

And a monthly ventilation energy usage prediction model of the air conditioner is generated from the ventilation energy data.

Equation (1) represents a monthly ventilation energy usage prediction model of the above-mentioned air conditioner.

The monthly ventilation energy usage prediction model of the climate control room is generated as a linear function for the building variables a to l, the operating variables m to p, and the local variables q and r, do.

&Quot; (1) "

X8 * h + X9 * i + X10 * j + X11 * d + X5 * e + X6 * f + X7 * g + X8 * h + X9 * k + X12 * l + X13 * m + X14 * n + X15 * o + X16 * p + X17 * q + X18 * r

In Equation (1), a to r denote building variables, operating variables, and local variables in Table 1, respectively. In Equation (1), Y, X1 to X18 are the combinations of the facility variables shown in Table 2 and the coefficients according to the month.

Y, X1 to X18 are values stored in the database of the system according to the combination of the facility variables and different values according to the month according to the simulation results.

In such a manner, the system may generate a monthly ventilation energy usage prediction model for the climate control room.

If the user intends to predict the amount of ventilation energy, it is determined whether the predicted space of the commercial building to be predicted is an air conditioner room or a non-air conditioner room.

That is, in the present invention, the ventilation energy consumption is calculated by differentiating the air conditioning room and the non-air conditioning room of the commercial building.

If the predicted space is the air conditioner, the system may calculate the monthly ventilation energy usage E1 of the air conditioner using the monthly ventilation energy usage prediction model of the air conditioner.

A method of calculating the monthly ventilation energy usage amount E1 of the air conditioner will be described later in detail.

If the predicted space is a parking lot that is the non-air-conditioned room, the system may calculate the monthly ventilation energy use amount E2 of the parking lot by using the fan power and the running time.

 The method of calculating the monthly ventilation energy use amount E2 of the parking lot will be described later in detail.

The monthly ventilation energy usage amount E1 of the air conditioner and the monthly ventilation energy usage amount E2 of the parking space are calculated and then the total monthly ventilation energy amount Et2 of the commercial building can be calculated and output. (S6)

FIG. 2 is a flowchart illustrating a method of predicting a monthly ventilation energy usage amount E1 of a climate control room according to an embodiment of the present invention.

Referring to FIG. 2, a method of calculating the monthly ventilation energy usage amount E1 of the air conditioner will be described as follows.

First, information including the building variables, the operating variables, the local variables, and the facility variables for the prediction target building is input through the input unit of the system (S31)

The construction variables include the floor area of the reference layer, the effective area ratio, the longitudinal constipation, the ceiling height, the stiffness, the core shape, the number of storeys, the area ratio, the shielding coefficient, the heat conduction rate,

The operating parameters include a real time real time, a cooling and heating set temperature of the air conditioner, a facility operation time, and the like. The facility operation time includes an on time of the cooling and heating start time, a cooling and heating stop time, an on time of the cooling and heating equipment, and an off time of the cooling and heating equipment. In addition, the operating parameter may include a ventilation start time, a ventilation stop time, an average ventilation time, and the like when the fan of the ventilation unit is installed.

In addition, the system can fetch weather data of an area where the prediction target building is located from a weather station database. (S32)

Thereafter, the system determines whether or not the fan, which is the ventilation unit, is applied to the equipment parameters inputted in the above (S33)

The ventilation unit in the air conditioner means a fan installed only for ventilation in addition to the fan installed in the air conditioner.

When the fan as the ventilation unit is not installed, the calculation unit calculates the monthly ventilation energy usage amount E1 of the air conditioning room using only the monthly ventilation energy usage prediction model.

At this time, the operation unit of the system can select a monthly ventilation energy usage prediction model of the air conditioner based on the input information.

From the input information, a different value may be derived from the database on a monthly basis for Y to X18 in Equation (1) by using the combination of the facility variables. The coefficients (Y to X18) of Equation (1) are stored in advance in the database according to the combination of the facility variables and the month according to the simulation results.

If the coefficients (Y to X18) of the equation (1) are known, the building variables, operating variables and local variables (a to r) are inputted into the equation 1 to calculate the monthly ventilation energy usage amount E1 (S34)

Therefore, if the ventilation unit is not provided, the monthly ventilation energy usage amount E1 of the ventilation room can be calculated from the monthly ventilation energy usage prediction model of the ventilation room.

If the ventilation unit fan is installed, the user further inputs the power, operation number, and monthly operation time of the fan through the input unit. (S35)

The operation unit calculates the monthly ventilation energy usage amount of the fan from the power of the fan, the operation number, and the monthly operation time (S36)

The monthly ventilation energy usage amount E11 of the fan is calculated by multiplying the power of the fan by the monthly driving time and the operation log. When the power of the fan is not known, the required ventilation amount is calculated using the area of the ventilation chamber and the number of times of ventilation according to the characteristics of the ventilation chamber, and the power of the fan is calculated from the required ventilation amount, Of monthly energy use of the ventilator.

In addition, the calculation unit calculates the monthly ventilation energy usage amount E10 of the air conditioner from the monthly ventilation energy usage prediction model (S37)

Therefore, when the target space is the air conditioning room and the ventilation unit is additionally installed in the air conditioning room, the monthly ventilation energy use amount E11 of the fan and the monthly ventilation energy usage amount E10 of the air conditioner obtained from the prediction model are summed , And the monthly ventilation energy usage amount E1 of the final air conditioning room is derived (S38)

FIG. 3A shows a case in which the ventilation system is a duct system and the specification of the fan is known, and FIG. 3B shows a case in which the ventilation system is a duct system and the specification of the fan is unknown Lt; / RTI >

Referring to FIG. 3, a method of calculating the monthly ventilation energy use amount E2 of the non-air conditioning room will be described as follows.

In order to calculate the monthly ventilation energy use amount E2 of the parking lot that is the non-air conditioning room, the ventilation energy can be predicted from the power of the fan which is the ventilation unit installed in the parking lot.

At this time, the system divides the ventilation system of the parking lot into the duct system and the ductless system, and the ventilation energy can be calculated by different methods in the case of knowing the specification of the fan and the case of not knowing it in each system.

First, the user inputs the monthly operation time of the fan installed in the parking lot (S41)

When the monthly operation time of the fans is inputted, the operation time of the fans installed in the parking lot is input. That is, when the parking lot ventilation system is a duct system using only the air supply fan and the exhaust fan, the monthly operation time of the air supply fan and the monthly operation time of the exhaust fan are input. The monthly operation time of the air supply fan, the monthly operation time of the air supply fan, and the monthly operation time of the air supply fan are set to be the same as the air supply time of the air supply fan .

The operation unit may determine the ventilation mode of the parking lot according to the monthly operation time of the fan inputted through the input unit. (S42)

The ventilation energy is calculated in different ways because the fans used are different depending on whether the ventilation system of the parking lot is a duct system or a no duct system.

If the ventilation mode of the parking lot is the duct type, it is determined whether the user knows the power of the fans (S43) (S44)

Referring to FIG. 3A, when the user knows the power of the fan among the specifications of the fan, the user controls the power and the operation number of the air supply fan, the power and the operation number of the air supply fan through the input unit (S45) (S46)

The operation unit calculates the monthly energy consumption of the air supply fan by multiplying the power of the air supply fan, the number of the air supply fan, and the monthly operation time of the air supply fan.

The calculating unit calculates the monthly ventilation energy consumption of the exhaust fan by multiplying the power of the exhaust fan, the number of the exhaust fans, and the monthly operation time of the exhaust fan.

The operation unit may calculate the monthly ventilation energy usage amount E2 of the parking lot by summing the monthly ventilation energy usage amount of the air supply fan and the monthly ventilation energy usage amount of the exhaust fan. (S47)

Therefore, when the parking lot is a duct type and the user knows the power of the fan, the monthly energy consumption E2 of the parking lot can be derived by using the power, the number of driving and the monthly operation time of the fans inputted in the above .

3B, if the user does not know the power of the fans, the user further inputs the area of the parking lot (S48)

The operation unit compares the building permission year of the predictable building with a preset reference year (S49)

Since the calculation unit is set differently for the ventilation amount calculation method according to the construction permission year of the predictable building, the construction permission year is compared with the reference year. Here, the reference year is set as February 13, 2006, for example.

If the building permission year is after the reference year, the area of the parking lot is compared with a preset reference area (S50)

Here, the reference area is 2000 m ² , for example.

When the area of the parking lot is equal to or larger than the reference area, the required ventilation amount per area of the parking lot is preset to 27CM / m ² or more. The required amount of ventilation per area may be set differently according to the relevant regulations.

Therefore, the necessary ventilation amount of the parking lot can be obtained by multiplying the area of the parking lot by the required ventilation amount per area (S51)

The operation unit can calculate the power of the fans from the required ventilation amount of the parking lot.

Equation (2) represents an equation for calculating the power (F) of the fans from the required ventilation amount of the parking lot.

&Quot; (2) "

Here, Qr represents the required ventilation amount (blowing amount) (m ³ / h), and P _T represents the voltage (mmAq) of the fan.

The calculation unit may calculate the power F of the air supply fan and the power F of the exhaust fan through the equation (2) (S52) (S53)

The calculation unit calculates the monthly ventilation energy usage amount of the air supply fan from the power of the air supply fan calculated above, the number of operation of the air supply fan inputted in the above, and the monthly operation time of the air supply fan inputted in the above.

The calculation unit calculates the monthly ventilation energy usage amount of the exhaust fan from the power of the exhaust fan calculated in the above, the number of operation of the exhaust fan inputted in the above, and the monthly operation time of the exhaust fan inputted in the above.

The calculation unit may calculate monthly monthly energy consumption E2 of the parking lot by summing monthly energy consumption of the air supply fan and monthly energy consumption of the exhaust fan. (S54)

Therefore, when the parking lot is in the duct system and the user does not know the power of the fan, if the construction permission year of the parking lot is after the reference year and the area of the parking lot is the reference area or more, Can be used to calculate the monthly ventilation energy use amount E2 of the parking lot.

On the other hand, if the building permission year of the parking lot is before the reference year, the user further inputs the average parking lot number of the parking lot (S55)

The calculation unit calculates a carbon monoxide (CO) emission amount M of the parking lot according to the average parking number of the parking lot and calculates a required amount Qr of the parking lot according to the carbon monoxide emission amount M. (S56)

Equation (3) shows a method of calculating the carbon monoxide emission amount (M) of the parking lot.

&Quot; (3) "

(= Turnover rate = 3.6) * N / 8 hours / day = 0.45 * N (m3 / h) ), L: parking distance (m), v: average driving speed (km / h), Mi: idling CO emission (= 0.0126CMM / vehicle), Xi: idling car number Ti: average idling time (min) (= 2 minutes / large).

Table 3 shows the average emission amount (m) of CO gas during traveling according to the area of the parking lot.

Parking area (㎥) CO gas average emission (m3 / min) Less than 500m2 0.045 500 to 1,000 0.040 1,000 to 1,500 0.035 1,500 to 2,000 0.030 2,000 or more 0.030

Table 4 shows the average running speed (v) according to the area of the parking lot.

Parking area (㎥) Average driving speed (km / h) Less than 500m2 5 500 to 2,000 10 2,000 or more 15

If the amount of carbon monoxide emission M is calculated through Equation (3), the required amount Qr of the parking space can be calculated according to the amount of carbon monoxide emission.

Equation (4) is an equation for calculating the required ventilation amount Qr of the parking lot according to the carbon monoxide discharge amount M.

(F) of the air supply fan, the power (F) of the exhaust fan, and the air flow rate of the air supply fan are calculated from the required ventilation amount (Qr) of the parking lot through Equation (2) (S52) (S53)

The operation unit may calculate the monthly ventilation energy usage amount of the air supply fan from the power of the air supply fan calculated above, the operation number of the air supply fan inputted in the above, and the monthly operation time of the air supply fan inputted in the above.

Also, the calculation unit calculates the monthly ventilation energy usage amount of the exhaust fan from the power of the exhaust fan calculated in the above, the number of operation of the exhaust fan inputted in the above, and the monthly operation time of the exhaust fan inputted in the above .

The operation unit may calculate the monthly ventilation energy usage amount E2 of the parking lot by summing the monthly ventilation energy usage amount of the air supply fan and the monthly ventilation energy usage amount of the exhaust fan. (S54)

Therefore, when the parking lot is in the duct system and the user does not know the power of the fan, if the building permission year of the parking lot is before the reference year, the monthly ventilation energy usage amount E2) can be calculated.

On the other hand, if the parking lot is a duct type, the user does not know the power of the fan, the building permission year is after the reference year, or the area of the parking lot is below the reference area, the user can calculate the necessary ventilation amount using the carbon monoxide emission amount It is possible to select and apply the necessary ventilation amount calculation method based on the parking area (S57)

FIG. 4 is a flowchart illustrating a method of predicting the monthly ventilation energy usage of a non-ventilating room according to an embodiment of the present invention, in which the fan specification is known.

3 and 4, if it is determined that the ventilation mode of the parking lot is the no-duct type, it is determined whether the user knows the power of the fans (S60) (S61)

If the user knows the power of the fans, the user can recognize the power and operation number of the air supply fan, the power and operation number of the air discharge fan, the type of the fan, (S62) (S63) (S64)

Here, the form of the above-mentioned induction fan includes a single fan, a long fan, and the like.

The calculation unit calculates the monthly energy consumption of the air supply fan by multiplying the power of the air supply fan, the number of the air supply fan, and the monthly operation time of the air supply fan.

The calculating unit calculates the monthly ventilation energy consumption of the exhaust fan by multiplying the power of the exhaust fan, the number of the exhaust fans, and the monthly operation time of the exhaust fan.

Also, the calculation unit calculates the monthly ventilation energy usage amount of the attractee fan by using the type of the attractee fan, the number of the attractee fans, and the monthly operation time of the attractee fan. (S65) The monthly energy use amount of the user fan is calculated by multiplying the power according to the type of the user fan by the number of operations and the operation time.

The calculation unit may calculate monthly monthly energy consumption E2 of the parking lot by summing the monthly energy consumption of the air supply fan, the monthly energy consumption of the exhaust fan, and the monthly energy consumption of the fan. (S66)

Thus, if the parking lot is of the duct-free type and the user knows the power of the fans, monthly energy consumption E2 of the parking lot can be derived.

As described above, when the parking lot is ventilated in a duct-free manner, the amount of ventilation energy used by the air supply fan and the exhaust fan as well as the amount of ventilation energy used is also summed up.

FIG. 5 is a flowchart illustrating a method of predicting a monthly ventilation energy usage amount in a non-ventilating room according to an embodiment of the present invention, in which the fan specification is unknown.

On the other hand, when the user does not know the power of the fans, the user inputs the area of the parking lot (S67)

The operation unit compares the building permission year of the predicted building with the reference year (S68)

Since the calculation unit is set differently for the ventilation amount calculation method according to the construction permission year of the predictable building, the construction permission year is compared with the reference year. Here, the reference year is set as February 13, 2006, for example.

If the building permission year is after the reference year, the area of the parking lot is compared with the reference area. (S69)

Here, the reference area is 2000 m ² , for example.

When the area of the parking lot is equal to or larger than the reference area, the required ventilation amount per area of the parking lot is preset to 27CM / m ² or more. The required amount of ventilation per area may be set differently according to the relevant regulations.

Therefore, the necessary ventilation amount of the parking lot can be obtained by multiplying the area of the parking lot by the necessary ventilation amount per area. (S70)

The calculation unit can calculate the power of the air supply fan and the power of the air discharge fan from the required ventilation amount of the parking lot. (S71)

The power of the air supply fan and the power of the air discharge fan can be obtained from Equation (2).

The operation unit calculates the monthly ventilation energy usage amount of the air supply fan by multiplying the power of the air supply fan calculated above, the operation number of the air supply fan, and the monthly operation time of the air supply fan.

The operation unit calculates the monthly ventilation energy usage of the exhaust fan by multiplying the power of the exhaust fan, the number of operation of the exhaust fan, and the monthly operation time of the exhaust fan calculated above.

On the other hand, in the case of the no-duct system, the user also operates the user's fan, so the user further inputs the type of the user's fan (S73)

The operation unit calculates the power and the operation number of the attracting fan (S74)

Each of the attracting fans is installed every 300 m ² , and the attracting fan is set to 100 W per one. Therefore, if the area of the parking lot is known, the number of the attracting fans can be calculated, and if the operating number of the attracting fans is known, the power of the attracting fans can be calculated. The number of installed fans per area of the fan can be set differently according to the type of the fan.

The operation unit calculates the monthly ventilation energy usage amount of the attracting fan by using the power of the attracting fan calculated above, the number of operating the attracting fan, and the monthly operating time of the attracting fan (S75).

A total monthly energy consumption of the air supply fan, a monthly energy consumption of the air discharge fan, and a monthly energy consumption of the user's fan. If the parking lot is of a ductless type and the user does not know the power of the fan, The ventilation energy use amount E2 can be calculated (S76)

Therefore, when the parking lot is of the duct-free type and the user does not know the power of the fan, if the building permission year of the parking lot is after the reference year and the area of the parking lot is the reference area or more, The monthly ventilation energy use amount E2 of the parking lot can be calculated using the ventilation amount.

On the other hand, if the building permission year of the parking lot is before the reference year, the user further inputs the average parking lot number of the parking lot (S77)

The calculation unit calculates the carbon monoxide (CO) emission amount (M) of the parking lot from the equation (3) according to the average parking number of the parking lot.

Further, the necessary ventilation amount Qr of the parking lot according to the carbon monoxide emission amount M is calculated from the above equation (4) (S78)

(F) of the air supply fan, the power (F) of the exhaust fan, and the air flow rate of the air supply fan are calculated from the required ventilation amount (Qr) of the parking lot through Equation (2) Respectively. (S71)

The operation unit may calculate the monthly ventilation energy usage amount of the air supply fan from the power of the air supply fan calculated above, the operation number of the air supply fan inputted in the above, and the monthly operation time of the air supply fan inputted in the above. Also, the calculation unit calculates the monthly ventilation energy usage amount of the exhaust fan from the power of the exhaust fan calculated in the above, the number of operation of the exhaust fan inputted in the above, and the monthly operation time of the exhaust fan inputted in the above . (S72)

On the other hand, in the case of the no-duct system, the user also operates the user's fan, so the user further inputs the type of the user's fan (S73)

The operation unit calculates the power and the operation number of the attracting fan (S74)

Each of the attracting fans is installed every 300 m ² , and the attracting fan is set to 100 W per one. Therefore, if the area of the parking lot is known, the number of the attracting fans can be calculated, and if the operating number of the attracting fans is known, the power of the attracting fans can be calculated. The number of installed fans per area of the fan can be set differently according to the type of the fan.

The operation unit calculates the monthly ventilation energy usage amount of the attracting fan by using the power of the attracting fan calculated above, the number of operating the attracting fan, and the monthly operating time of the attracting fan (S75).

A total monthly energy consumption of the air supply fan, a monthly energy consumption of the air discharge fan, and a monthly energy consumption of the user's fan. If the parking lot is of a ductless type and the user does not know the power of the fan, The ventilation energy use amount E2 can be calculated (S76)

Accordingly, when the parking lot is of the duct-free type and the user does not know the power of the fan, if the building permission year of the parking lot is before the reference year, the monthly ventilation energy usage (E2) can be calculated.

On the other hand, if the parking lot is of the ductless type, the user does not know the power of the fan, the building permission year is after the reference year, or the area of the parking lot is below the reference area, the user can calculate the necessary ventilation amount And the necessary ventilation amount calculation method based on the parking area (S79).

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

Claims (17)

Ventilation energy usage forecasting system for commercial buildings Select standard buildings from among the built commercial buildings, and include building variables, operating variables, local variables, cold, heating heat source, air conditioning system, ventilation unit Cooling and heating energy simulation is carried out according to the facility variables, and the ventilation energy data used in the air conditioning room of the standard building is collected from the simulation result, and the building variables, the operating parameters, the local variables, Generating a monthly ventilation energy usage forecasting model of the air conditioning room differently according to facility variables;
Determining whether the predicted space of the commercial building to be predicted is a living room or a non-living room for predicting ventilation energy usage;
If the target space is the air conditioning room, a user inputs information including the building variables, the operating variables, the local variables, and the equipment parameters for the forecasted commercial building into the input unit of the system,
Wherein the calculation unit of the system selects a monthly ventilation energy usage prediction model of the air conditioning room according to the information input to the input unit and calculates a monthly ventilation energy usage amount of the air conditioning room from the selected monthly ventilation energy usage prediction model;
If the target space is the non-air-conditioned room, the calculating unit calculates the monthly ventilation energy usage amount of the non-air-conditioned room from the power, the operation number, and the monthly operation time of the fans as the ventilation unit installed in the non-
Wherein the calculation unit sums the monthly ventilation energy usage amount of the air conditioning room and the ventilation energy usage amount of the non-air conditioning room, and the output unit of the system outputs the summed value as the ventilation energy usage amount of the forecasted commercial building A method for predicting ventilation energy usage of a ventilator. The method according to claim 1,
The monthly ventilation energy usage prediction model of the above-
A linear function for the building variable, the operating variable, and the local variable, wherein coefficients of the variables are generated differently according to the facility variable and the monthly,
Wherein the coefficients are estimated in accordance with a result of the simulation and stored in a database provided in the system. The method according to claim 1,
In calculating the monthly ventilation energy usage of the air conditioner,
Wherein the facility variables include a heating heat source method, a cooling heat source method, an inner circumference air conditioner, an outer circumference air conditioner, and a ventilation unit. The method of claim 3,
In calculating the monthly ventilation energy usage of the air conditioner,
When the ventilation unit fan is installed in the air conditioning room,
The user further inputs the power, the operation number, and the monthly operation time of the fan through the input unit,
Wherein the calculation unit calculates the monthly ventilation energy usage amount of the fan from the fan power, the operation number, and the monthly operation time,
Wherein the monthly ventilation energy usage of the fan is added to the monthly ventilation energy usage of the air conditioner. The method according to claim 1,
In calculating the monthly ventilation energy usage of the air conditioner,
The building variables include the floor area of the reference floor of the forecasted commercial building, the effective area ratio, the constellation constriction, the ceiling height, the building orientation, the core shape, the number of reference rooms, the window area ratio, the shielding coefficient, the outer wall heat conduction rate, A method for predicting ventilation energy usage in commercial buildings. The method according to claim 1,
In calculating the monthly ventilation energy usage of the air conditioner,
The operating variable includes a method for predicting the ventilation energy usage amount of a commercial building including the sleeping time of the air conditioning room, the heating start time, the heating stop time, the cooling start time, the cooling stop time, the ventilation start time, . The method according to claim 1,
In calculating the monthly ventilation energy usage of the non-air conditioning room,
Inputting a monthly operation time of the fans through the input unit if the object space is the non-air conditioning room and the parking lot;
Determining whether the ventilation system of the commercial building to be predicted is a duct system using only an air supply fan and an exhaust fan or a no duct system using both the air supply fan, the exhaust fan, and the induction fan;
The method of claim 1, wherein the ventilation mode is a duct type, and the user inputs power and operation number of the fans through the input unit when the user knows the power of the fans.
Wherein the calculation unit calculates the monthly ventilation energy usage amount of the parking lot from the power of the fans, the operation number, and the monthly operation time. The method of claim 7,
In calculating the monthly ventilation energy usage of the non-air conditioning room,
The method comprising the steps of: when the ventilation system is a duct system and the user does not know the power of the fans, the user inputting the area of the parking lot through the input unit;
Calculating a required ventilation amount of the parking lot according to a ventilation amount calculation method set differently according to a construction permission year of the forecasted commercial building;
Calculating the power of the fans from the required ventilation amount of the parking lot and the voltage of the fans;
Wherein the calculating unit further calculates monthly energy use of the parking lot using the power, the number of operations, and the monthly operation time of the fans. The method of claim 8,
In the process of calculating the necessary ventilation amount of the parking lot,
If the construction permitting year of the predicted commercial building is after the predetermined reference year and the area of the parking lot is equal to or larger than a preset reference area,
And estimating a ventilation amount of the parking lot by multiplying the parking area by a required ventilation amount per area set in advance. The method of claim 9,
In the process of calculating the necessary ventilation amount of the parking lot,
If the building permitting year of the forecast commercial building is before the preset reference year,
The user further inputs the average parking number of the parking lot,
Calculating a carbon monoxide (CO) emission amount of the parking lot according to an average parking number of the parking lot,
And calculating a required ventilation amount of the parking lot according to the carbon monoxide emission amount of the parking lot. The method of claim 10,
In the process of calculating the necessary ventilation amount of the parking lot,
If the construction permitting year of the commercial building to be forecasted is after the preset reference year and the area of the parking lot is less than a preset reference area,
A method for predicting ventilation energy usage of a commercial building, the method comprising: determining whether to calculate a required ventilation amount of the parking lot according to a carbon monoxide emission amount of the parking space. The method of claim 7,
In calculating the monthly ventilation energy usage of the non-air conditioning room,
When the ventilation system is of a ductless type and the user knows the power of the fans, the user can know the power and operation number of the air supply fan, the power and operation number of the air discharge fan, the type of the fan, Inputting through the input unit;
Wherein the calculation unit further calculates monthly energy consumption of the parking lot using the power, the number of operations, and the monthly operation time. The method of claim 12,
In calculating the monthly ventilation energy usage of the non-air conditioning room,
A step of allowing the user to input the area of the parking lot through the input unit when the ventilation system is a ductless system and the user does not know the power of the fans;
Calculating a required ventilation amount of the parking lot according to a ventilation amount calculation method set differently according to a construction permission year of the forecasted commercial building;
Calculating a power of each of the air supply fan and the exhaust fan from the required ventilation amount of the parking lot and the voltage of the fans;
Inputting a form of the user's fan;
Calculating a power of the attracting fan using the type of the attracting fan and the area of the parking lot;
Wherein the calculation unit calculates the monthly ventilation energy usage amount of the fans by using each power of the air supply fan, the exhaust fan, and the manned fan, the number of each operation, and the monthly operation time, A method for predicting ventilation energy usage in a commercial building, the method comprising: 14. The method of claim 13,
In the step of calculating the necessary ventilation amount of the parking lot,
If the construction permitting year of the predicted commercial building is after the predetermined reference year and the area of the parking lot is equal to or larger than a preset reference area,
And estimating a ventilation amount of the parking lot by multiplying the parking area by a required ventilation amount per area set in advance. 15. The method of claim 14,
In calculating the required ventilation amount of the parking lot,
If the building permitting year of the forecast commercial building is before the preset reference year,
The user further inputs the average parking number of the parking lot,
Calculating a carbon monoxide (CO) emission amount of the parking lot according to an average parking number of the parking lot,
And calculating a required ventilation amount of the parking lot according to the carbon monoxide emission amount of the parking lot. 16. The method of claim 15,
In the step of calculating the necessary ventilation amount of the parking lot,
If the construction permitting year of the commercial building to be forecasted is after the preset reference year and the area of the parking lot is less than a preset reference area,
A method for predicting ventilation energy usage of a commercial building, the method comprising: determining whether to calculate a required ventilation amount of the parking lot according to a carbon monoxide emission amount of the parking space. The user estimating the ventilation energy usage includes determining whether the predicted space of the predicted commercial building is an air conditioner room or a non-air conditioner room;
If the target space is the non-air conditioning room and the parking lot, the user inputs the monthly operating time of the fans installed in the commercial building to be forecasted through the input unit;
Determining whether the ventilation system of the commercial building to be predicted is a duct system using only an air supply fan and an exhaust fan or a no duct system using both the air supply fan, the exhaust fan and the induction fan;
Wherein when the user knows the power of the fans, the user inputs the power and the operating number of the fans through the input unit, and the calculating unit calculates the power of the fans, the operated number, and the monthly operation Calculating a monthly ventilation energy usage of the parking lot by multiplying the time by a time;
Wherein when the ventilation system is a duct system and the user does not know the power of the fans, the user inputs the area of the parking lot through the input unit, and the arithmetic unit calculates the ventilation amount set in accordance with the construction permission year of the forecasted commercial building Calculating a required ventilation amount of the parking space according to a calculation method, calculating a power of the fans based on a required ventilation amount of the parking space and a voltage of the fans, and calculating the power of the fans based on the monthly power consumption, Calculating ventilation energy usage;
When the ventilation system is of a ductless type and the user knows the power of the fans, the user can know the power and operation number of the air supply fan, the power and operation number of the air discharge fan, the type of the fan, Wherein the calculation unit calculates the monthly ventilation energy usage amount of the parking lot using the power, the operation number, and the monthly operation time;
If the ventilation system is a duct-free system and the user does not know the power of the fans, the user inputs the area of the parking lot through the input unit, and the calculation unit is set differently according to the construction permission year of the forecasted commercial building Calculating the required ventilation amount of the parking space according to the ventilation amount calculation method, calculating the power of the air supply fan and the exhaust fans from the required ventilation amount of the parking space and the voltage of the fans, Calculates the monthly ventilation energy usage of the fans from the respective power, operation number, and monthly operation time of the air supply fan, the exhaust fan, and the manned fan, And calculating a monthly ventilation energy use amount of the parking lot by summing,
Calculating a necessary ventilation amount of the parking lot by multiplying the parking area by a required ventilation amount per area set in advance if the construction permission year of the forecasted commercial building is later than a preset reference year and the area of the parking lot is a predetermined reference area or more,
If the construction permitting year of the forecasted commercial building is before the preset reference year, the user further inputs the average parking number of the parking lot, and calculates the CO emission amount of the parking lot according to the average parking lot number of the parking lot A method for predicting ventilation energy usage in commercial buildings.

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