KR20100131821A - Air conditioner and method for embodying optimum energy using pmv value of start and end - Google Patents

Abstract

PURPOSE: An air conditioner satisfying the optimized thermal comfort sensation and an energy optimizing method using PMV values corresponding to the starting and ending points of the air conditioner are provided to operate the air conditioner based on the thermal comfort sensation, entry time and leaving time. CONSTITUTION: Air-conditioner controls an indoor temperature in consideration of sensed indoor and outdoor temperatures and a target temperature. Air-conditioner comprises an input part(11), a driving part(15) and a controller(20). The input part comprises the keys about the drive and setting of an air-conditioner. The driving part operates the air-conditioner in a heating mode and a cooling mode. The controller calculates how long it takes to get a specific heat comfort index.

Description

Air conditioner and energy optimization method using PMB value of start and end {AIR CONDITIONER AND METHOD FOR EMBODYING OPTIMUM ENERGY USING PMV VALUE OF START AND END}

The present invention relates to an air conditioner, and in particular, an air conditioner capable of controlling an air conditioner according to a start time and a stop time of an air conditioner in consideration of operation efficiency and indoor thermal comfort, and a start and end thereof. The present invention relates to an energy optimization method using PMV value of.

In general, an air conditioner includes a heating device that warms indoor cold air and supplies it to a room, and a cooling device that supplies cold indoor hot air to a room.

In addition, there is a cooling and heating device that has a cooling function and a heating function, and an air conditioner that includes a cleaning function to clean the contaminated indoor air and a humidification and dehumidification function to maintain the humidity of the room at a constant humidity.

Such an air conditioner is a centrally controlled air conditioner for controlling a crab drive in a center to drive an air conditioner and an individually controlled air conditioner for individually controlling a drive of an air conditioner.

However, the conventional air conditioner simply considers the occupancy and departure time, and operates the air conditioner before the occupancy time and stops the operation of the air conditioner before the departure time. According to the Predicted Mean Vote, hereinafter abbreviated as "PMV." There is a problem that thermal comfort is inevitably lowered.

That is, since operation of the air conditioner is determined according to the simply set time without considering the PMV, the air conditioner driving method satisfies only the energy efficient aspect.

Accordingly, in order to satisfy the PMV in consideration of the thermal comfort of the occupants, the air conditioner is operated before or after the preset time of commencement of work or after the predetermined time of commencement or work. Although the thermal comfort is increased, in spite of the condition that the air conditioner should be operated or stopped in terms of energy efficiency, the air conditioner operates in an inefficient way in terms of energy.

The present invention has been made in view of the above problems, in consideration of the operation efficiency and indoor thermal comfort, the air conditioner and the start to control the air conditioner according to the start time and stop time of the air conditioner And to provide an energy optimization implementation method using the PMV value of the end.

Another object of the present invention is to provide an air conditioner capable of controlling the operation of an air conditioner in consideration of indoor comfort comfort and a preset air conditioner and an energy optimization method using PMV values of start and end of the air conditioner. In providing.

The object of the present invention is not limited to the above-mentioned object, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

In the air conditioner according to an aspect of the present invention for achieving the above object, in the air conditioner for controlling the indoor temperature in consideration of the preset room time, departure time and desired temperature and the sensed indoor and outdoor temperature, An input unit having keys for driving and setting the air conditioner; A driving unit for driving in a heating and cooling mode; And operating the driving unit at a time before the first calculated time based on the re-learning time by first calculating a time for reaching the specific thermal comfort index, and reaching the specific thermal comfort index after stopping the air conditioner. And a controller configured to stop the operation of the driving unit at a time before the second calculated time based on the departure time based on the second operation.

Here, the drive unit, a cooling drive unit for cooling the drive under the control of the control unit; A heating driving unit configured to drive heating under the control of the controller; And it characterized in that it comprises a humidity control drive for driving to control the humidity of the room under the control of the controller.

Here, the control unit calculates a first time for reaching the specific thermal comfort index before operating the air conditioner, and calculates a second time for reaching the specific thermal comfort index after stopping the air conditioner. A first calculation unit to perform; Calculating an operation start control time corresponding to the first computed time transfer time based on the re-real time, and calculating an operation stop control time corresponding to the second computed time transfer time based on the departure time Two calculation units; And a driving control unit which operates the driving unit in accordance with the calculated operation start control time and stops the driving unit in accordance with the calculated operation stop control time.

Here, the storage unit further comprises a storage unit for storing the return time, the departure time, the desired temperature, and the specific thermal comfort index.

The control unit may further include a readout unit configured to read the returning time, the leaving time, the desired temperature, and a specific thermal comfort index from the storage unit.

The reading unit may include: a time reading unit configured to read the returning time and the leaving time; And a comfort index reading unit for reading out the specific thermal comfort index.

Here, the specific thermal comfort index is characterized in that the index can be changed according to the wishes of the occupants.

Herein, the specific thermal comfort index is -0.5 at heating, and +0.5 at cooling.

Energy optimization method using the PMV value of the start and end of the air conditioner according to another aspect of the present invention, room temperature, outside air temperature, humidity and air flow rate and the amount of active calorie input from the occupants (metabolism) and In the implementation method using the PMV value of the air conditioner to control the room temperature in consideration of the wear amount (cloth insulation coefficient), the first time to reach a specific thermal comfort index according to the input setting state of the air conditioner Operating the air conditioner at a time before a first calculated time based on a preset real time based on a calculation; And a second calculation time for reaching the specific thermal comfort index when the air conditioner is stopped during operation of the air conditioner. It characterized in that it comprises the step of stopping the operation of.

Here, the method further includes the step of setting the rehabilitation time and leaving time, a desired temperature, and a specific thermal comfort index.

Here, the specific thermal comfort index is characterized in that it is obtained in consideration of at least one of the humidity, air flow rate, the amount of wear of the occupant, the amount of activity and the average radiation temperature and the indoor temperature and the outside air temperature.

Herein, the specific thermal comfort index is -0.5 at heating, and +0.5 at cooling.

The operation of the air conditioner may include calculating an operation start control time corresponding to the first calculated time before the real time, based on the re-real time, wherein the operation is performed according to the calculated operation start control time. It is characterized by operating an air conditioner.

Here, the step of stopping the operation of the air conditioner may include calculating an operation stop control time corresponding to a time before the second calculated time based on the exit time, wherein the operation stop control time is calculated. It characterized in that for stopping the air conditioner.

According to the above-mentioned problem solving means, the present invention operates the air conditioner at a time before the first calculated time based on the real time by first calculating a time for reaching a specific thermal comfort index, and after stopping the air conditioner, By stopping the operation of the air conditioner at a time before the second calculated time based on the departure time by calculating the second time to reach the thermal comfort index, the occupant can feel the optimal heat comfort desired at the same time as the room. It is effective to feel the optimal thermal comfort before leaving.

In addition, in consideration of the thermal comfort and the occupancy and departure time, the air conditioner is driven and stopped before the start time and stop time of the preset air conditioner, thereby satisfying the optimum heat comfort and having an effect in terms of power efficiency.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings, with reference to the parts necessary for understanding the operation and operation according to the present invention.

In the following description specific details of the air conditioner of the present invention and methods of implementing energy optimization using PMV values of its start and end are presented to provide a more comprehensive understanding of the present invention, without further modifications thereof. It will be apparent to those skilled in the art that the present invention can be easily implemented by means of the present invention.

On the other hand, the air conditioner of the present invention and the energy optimization method using the PMV value of the start and end of the air conditioner in consideration of the specific thermal comfort index, the preset rehabilitation time and departure time and the desired temperature and It proposes a technical configuration that enables the air conditioner to be driven in accordance with the stopping time so that the occupants feel comfortable at the entrance and exit.

1 is a block diagram of an air conditioner according to an embodiment of the present invention.

Referring to FIG. 1, the air conditioner according to the present invention includes an input unit 11, a sensing unit 13, an eastern part 15, a storage unit 17, a control unit 20, a display unit 19, and the like. do.

The input unit 11 is provided with keys for setting the environment related to the driving and driving of the air conditioner. That is, the input unit 11 is provided with keys for setting the occupancy and departure time, the amount of activity calories (metabolism), the amount of clothing (cloth insulation coefficient), the desired temperature (set room temperature), the indoor humidity, and the thermal comfort index. Here, the thermal comfort index may be set by changing the occupant according to the sensitivity of the warmth of the occupant.

For example, if the occupants are sensitive to the sense of warmth, the range of the thermal comfort index can be set to -0.2 for heating and +0.2 for cooling. On the contrary, if the guest is insensitive to the sense of warming, the range of the thermal comfort index can be -0.7 for heating and +0.7 for cooling. Can be set to By default, however, the thermal comfort index is set to -0.5 for heating and +0.5 for cooling.

The sensing unit 13 includes an indoor temperature sensing unit 13-1 for sensing indoor temperature, a humidity sensing unit 13-2 for sensing humidity, an outside air temperature sensing unit 13-3 for sensing outside temperature, and airflow It is configured to include an air flow rate detecting unit 13-4 for detecting the speed, and a steam detecting unit 13-5 for detecting the steam.

The driving unit 15 includes a plurality of driving function blocks for driving the air conditioner with the corresponding function corresponding to the operation mode selected by the occupant, and the cooling driving unit 15-1 for driving the air conditioner to perform the cooling function and heating A heating driving unit 15-2 for driving the air conditioner to perform a function, and a humidity control driving unit 15-3 for driving the air conditioner to perform a humidity control function so that the room can be maintained at a constant humidity. do.

The storage unit 17 stores the occupancy time, departure time, desired temperature, and specific thermal comfort index set by the occupant. In addition, the storage unit 17 includes programs for operating and stopping the air conditioner at the time of starting and stopping the operation of the air conditioner in consideration of the specific thermal comfort index, re-emergence time and exit time according to the embodiment of the present invention. Stored.

The display unit 19 displays a screen and a message according to the driving and environment setting of the air conditioner. In this case, when the display unit 19 is a touch screen, an input means may be used to set a driving environment of the air conditioner, and a specific thermal comfort index, a desired temperature, a resent time, and a departure time may also be set.

The time measuring unit 21 measures the current time.

The control unit 20 operates the drive unit 15 at a time before the first calculated time based on the re-real time by first calculating a time for reaching the specific thermal comfort index, and after stopping the air conditioner, the control unit 20 applies the specific thermal comfort index to the specific thermal comfort index. The arrival time is calculated by the second operation so as to stop the operation of the driving unit 15 before the second calculated time based on the exit time. At this time, the control unit 20 controls the operation at a time at which the current time measured by the time measuring unit 21 becomes a time before the first computed time or a time before the second computed time. The control unit 20 can know the thermal comfort index after a predetermined time by the following method. In other words, the time to reach a specific thermal comfort index can be known by calculating the variables after a certain time that determines the thermal comfort index.

First, in order to calculate the room temperature after a predetermined time elapses, the change amount (Δtair) of the room temperature is calculated using Equation 1 below, and the calculated change amount is substituted into Equation 2 below to give the room after a predetermined time. Calculate the temperature.

In addition, in order to calculate the indoor steam pressure after a predetermined time elapses, the indoor steam pressure after a predetermined time is calculated using Equation 3 below.

Therefore, the indoor temperature and the water vapor pressure after a predetermined time are substituted into the thermal comfort index of Equation 4 below, and the metabolic amount (active calorie value) and clothing amount (garment adiabatic coefficient) inputted or set by the occupant are used. The specific thermal comfort index after a predetermined time can be calculated.

Where M is the calorific value of activity, I _cl is the clothing insulation coefficient, t _air is the room temperature, t _mrt is the radiation temperature, f _cl is the skin exposure area ratio at the time of wearing, and t _cl is the clothing surface temperature. do.

2 is a block diagram showing the internal configuration of the controller in FIG.

Referring to FIG. 2, the controller 20 according to the present invention includes a reader 21, a calculator 23, a drive controller 25, and the like.

The reading unit 21 reads a time reading unit 21-1 for reading the occupancy time and leaving time stored in the storage unit 13, and a comfort index reading for reading a specific thermal comfort index stored in the storage unit 13. It includes the exit 21-2.

The calculating part 23 calculates the 1st time to reach a specific thermal comfort index before operation of an air conditioner, and calculates the 2nd time to reach a specific thermal comfort index after stopping of an air conditioner. -1), and calculates an operation start control time corresponding to the time before the first calculated time on the basis of the occupancy time, and calculates an operation stop control time corresponding to the time before the second calculated time on the basis of the departure time. The second calculation unit 23-2 is included. That is, the first and second calculation units 23-1 and 23-2 may know first and second times of reaching the specific thermal comfort index using the above-described equations 1 to 4.

The drive control unit 25 operates the drive unit 15 in accordance with the calculated operation start control time and stops the drive unit 15 in accordance with the calculated operation stop control time.

According to the operation of the control unit 20, the relationship between the PMV and the PPD is satisfied in consideration of a preset value of the thermal comfort index having the characteristics of the thermal comfort index as shown in FIG.

Therefore, the occupants can feel comfortable even at the time of entering and leaving the room.

4 is a flowchart illustrating a method of implementing energy optimization using PMV values of start and end of an air conditioner according to an exemplary embodiment of the present invention. The operation description of the driving method through FIG. 4 will be described in the order of algorithms for allowing the air conditioner to operate at the stop time after the algorithm description for operating the air conditioner at the optimum start time of the air conditioner.

 Referring to FIG. 4, the control unit 20 receives an occupancy, departure time, activity calorie (metabolism) and clothing amount (clothing thermal coefficient) from an occupant for an optimal driving start algorithm (S401).

Then, the control unit 20 measures the indoor temperature, outside temperature, humidity and airflow speed (S403), estimates the radiant temperature through solar radiation according to the weather forecast and the weather, and then measures the measured room temperature, outside air temperature, humidity and airflow. The current thermal comfort index is obtained in consideration of the speed and the estimated radiation temperature (S405 and S409). At this time, the correct current thermal comfort index is obtained by using the amount of clothing input, activity amount, desired thermal comfort, and number of occupants.

And the control unit 20 measures the current temperature and the outside temperature and humidity (S411), taking into account the measured current temperature and the outside temperature and humidity of the first calculation of the time the air conditioner reaches a specific thermal comfort index (S411) S413), an optimum start time (operation start control time) is set to operate the air conditioner at a time before the first calculated time on the basis of the preset real time (S415).

Next, the optimal driving termination algorithm will be described. The control unit 20 receives the occupancy and departure times from the occupants for the optimal driving termination algorithm (S417). At this time, if the occupant sets the exit time together with the occupancy time in step 401 (S401) described above, step 419 (S419) described below is performed without performing step 417 (S417). However, step 419 (S419) is also a setting process, and may be performed in the step of setting things to be set for the optimal operation start algorithm.

In step 419 (S419), the control unit 20 receives an input from the occupant to set the thermal comfort index. In other words, it is possible to set the thermal comfort index. If the thermal comfort index is not set, the default value is -0.5 for cooling and +0.5 for heating.

Thereafter, the control unit 20 measures room temperature, humidity, and airflow speed (S421), and acquires the current thermal comfort index in consideration of factors obtained through the operations as described above with steps 405 and 407 (S423). .

In addition, the control unit 20 considers the difference between the temperature and humidity of the current outside air and the bet to allow the occupant to feel the optimal thermal comfort to end the operation of the air conditioner. The difference is stored (S425).

The control unit 20 checks whether the operation of the air conditioner is the heating mode or the cooling mode (S427), and if the result of the check is the cooling mode, calculates the time for which the thermal comfort index reaches -0.5 (S429).

Thus, the control unit 20 sets the calculated time to an optimal stop time for stopping the operation of the air conditioner operating in the cooling mode (S431).

That is, during operation of the air conditioner, the control unit 20 cools the second time calculated before the second calculated time on the basis of the preset departure time by calculating the second time when the air conditioner reaches the thermal comfort index -0.5. Stop the operation of the air conditioner in the mode.

However, the control unit 20 calculates the time when the thermal comfort index reaches +0.5 in the heating mode as a result of confirmation (S433).

Thus, the controller 20 sets the calculated time to an optimal stop time (operation stop control time) that can stop the operation of the air conditioner operating in the heating mode (S431).

That is, during operation of the air conditioner, when the air conditioner is stopped, the control unit 20 performs a second calculation of a time at which the thermal comfort index reaches +0.5, and heats it at a time before the second calculated time based on the preset departure time. Stop the operation of the air conditioner in the mode.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

1 is a block diagram of an air conditioner according to an embodiment of the present invention.

2 is a block diagram showing the internal configuration of the control unit in FIG.

3 is a graph showing the relationship between PPD and PMV.

4 is a flowchart illustrating a method of implementing energy optimization using PMV values of start and end of an air conditioner according to an exemplary embodiment of the present invention.

Claims (15)

In the air conditioner that controls the room temperature in consideration of the preset re-establishment time, departure time and desired temperature and the detected temperature of the indoor and outdoor air, An input unit having keys for driving and setting the air conditioner; A driving unit for driving in a heating and cooling mode; And The driving unit is operated at a time before the first calculated time based on the re-real time by first calculating a time for reaching the specific thermal comfort index according to the input setting state of the air conditioner, And a control unit configured to stop the operation of the driving unit at a time before the second calculated time based on the exit time by calculating a second time for reaching the specific thermal comfort index after stopping. The method of claim 1, wherein the driving unit, A cooling driving unit for cooling driving under the control of the controller; A heating driving unit configured to drive heating under the control of the controller; And An air conditioner comprising a humidity control drive for driving to control the humidity of the room under the control of the controller. The method of claim 1, wherein the control unit, A first calculating unit calculating a first time of reaching the specific thermal comfort index before the air conditioner is operated, and calculating a second time of reaching the specific thermal comfort index after the air conditioner is stopped; Calculating an operation start control time corresponding to the first computed time transfer time based on the re-real time, and calculating an operation stop control time corresponding to the second computed time transfer time based on the departure time Two calculation units; And And a driving controller for operating the driving unit in accordance with the calculated operation start control time and stopping the driving unit in accordance with the calculated operation stop control time. The air conditioner according to claim 1, further comprising a storage unit for storing the returning time, the leaving time, the desired temperature, and the specific thermal comfort index. The method of claim 4, wherein the control unit, Air conditioner further comprises a reading unit for reading out the residing time and departure time, the desired temperature and the specific thermal comfort index from the storage. The method of claim 5, wherein the reading unit, A time reading unit for reading the re-emergence time and the leaving time; And An air conditioner comprising a comfort index reading unit for reading the specific thermal comfort index. The method of claim 1, wherein the specific thermal comfort index, Air conditioner, characterized in that the index is changeable according to the wishes of the occupants. The method of claim 7, wherein the specific thermal comfort index, An air conditioner comprising -0.5 at heating and +0.5 at cooling. The air conditioner according to claim 1, further comprising a time measuring unit measuring a current time. Implementation method using PMV value of air conditioner that controls room temperature in consideration of room temperature, outside air temperature, humidity and air flow rate and active calorie (metabolism) and clothing amount (cloth insulation coefficient) To Operating the air conditioner at a time before the first calculated time on the basis of a preset real time by first calculating a time for reaching a specific thermal comfort index according to an input setting state of the air conditioner; And During the operation of the air conditioner, when the air conditioner is stopped, the second operation time is calculated based on a departure time that is previously set by calculating a second time for reaching the specific thermal comfort index. An energy optimization implementation method using PMV values of the start and end of the air conditioner, characterized in that it comprises the step of stopping the operation. 11. The method of claim 10, further comprising the step of setting the rehabilitation time and the departure time, the desired temperature, and a specific thermal comfort index. The method of claim 10, wherein the specific thermal comfort index, Implementation method of energy optimization using PMV values of the start and end of the air conditioner, characterized in that obtained in consideration of at least one of the humidity, air flow rate, the amount of wear of the occupant, the amount of activity and the average radiation temperature and the room temperature and the outside temperature . The method of claim 10 or 12, wherein the specific thermal comfort index, Energy optimization implementation method using PMV value of the start and end of the air conditioner, characterized in that -0.5 when heating, +0.5 when cooling. The method of claim 10, wherein the operation of the air conditioner, Computing an operation start control time corresponding to the time before the first calculated time based on the re-real time, An energy optimization implementation method using PMV values of the start and end of the air conditioner, characterized in that for operating the air conditioner in accordance with the calculated operation start control time. The method of claim 10, wherein the step of stopping the operation of the air conditioner, Computing the operation stop control time corresponding to the time before the second calculated time based on the exit time, And the PMV value of the start and end of the air conditioner, wherein the air conditioner is stopped according to the calculated operation stop control time.

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