JP4142837B2 - Power use device and power control method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power use device such as a heat accumulator or a power storage device used for a heater or a water heater, and a power control method used for the power use device.
[0002]
[Prior art]
The amount of power used varies between day and night. In general, on weekdays, the lowest load time is usually around 4 o'clock in the morning. The time from 11 o'clock in the evening to 7 o'clock in the morning including this minimum load time is called a specific power time zone, specifically, a midnight power time zone.
[0003]
Here, FIG. 20 shows how the power is used in the specific power time zone. As shown in this figure, the power usage situation has a concave curve that peaks at the start and end times of the specific power time period. In this concave curve, the minimum load time is shifted to the morning side in the specific power time zone, and is 5 hours from 23:00 to 4 o'clock, and about 3 hours from 4 o'clock to 7 o'clock. The minimum load time is roughly shown in this figure although there is a slight difference depending on the season and region.
[0004]
Here, a hot water storage type electric water heater or the like that uses electric power to boil hot water during the specific electric power time period is generally used. In this electric water heater, the required energization time for the heater is obtained based on the measurement data such as the temperature of hot water and the amount of remaining hot water already existing in the hot water tank, and boiling is performed within a specified power time zone in consideration of this necessary energization time. The energization start time for starting energization of the heater in the hot water tank is determined in accordance with a predetermined energization shift mode so that the raising is completed.
[0005]
Here, as a method for determining the energization start time, a method using an energization shift mode in which the power load is increased in the first half of the specific power time period, or an energization shift mode in which the power load is increased in the second half as much as possible is used. There are also things. Moreover, in the hot water storage type electric water heater described in JP-A-6-180147 and JP-A-6-180148, the reference time is set in a time zone in which the demand for midnight power is low. Then, when the required energization time is less than the time from the reference time to the midnight power end time, according to a predetermined energization shift mode, the heater is energized to increase the power during the time when there is little midnight power demand. Yes.
[0006]
[Problems to be solved by the invention]
By the way, in the above-described technique, there is a bias that power loads are concentrated in the first half and the second half of the specific power time zone. For this reason, it is difficult to level the power load. Further, in the hot water storage type electric water heater described in the above-mentioned Japanese Patent Laid-Open Nos. 6-180147 and 6-180148, if the required energization time is short, a temporary effect can be obtained. When becomes longer, it is biased toward the first half or the second half of the specific power time. For this reason, it is difficult to fundamentally level the power load.
[0007]
The present invention has been made based on the above circumstances, and an object thereof is to provide a power utilization device and a power control method capable of leveling a power load.
[0008]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the power utilization device of the present invention is an object to be heated or Power storage unit To store heat using the power of a specific power hour such as midnight Electricity storage In the power usage equipment that performs heating, heat the object to be heated or Electricity storage A heating means, an operation control means connected to the heating means for controlling the operation of the heating means, a heat storage temperature and a remaining hot water amount, Storage amount Based on the measured data of Electricity storage From the minimum load time obtained from the state of the load power amount in the specific power time zone to the end time of the specific power time zone. The time is calculated as the reference time, and it is determined whether or not the half of the required energization time is greater than the reference time. If it is determined that the reference time is large, the total time in the specific power time zone Subtract the reference time from the value, and then subtract one half of the required energization time to calculate the standby time from the start time of the specific power time zone. If it is determined that the reference time is small, the specific power An arithmetic processing unit that calculates a standby time by subtracting the required energization time from the end time of the time zone, and determines whether the necessary energization time has elapsed after the standby time has elapsed and the charging unit has been activated. Control signal to operation control means Are anda energization end determining means for emitting.
[0009]
This power utilization device is preferably applied to the current midnight power time zone in which the time of the minimum load is shifted from the center of the specific power time zone to the end time side. That is, when the value of one half of the required energization time is smaller than the reference time, the necessary energization time is equally allocated to both sides around the time of the lowest load, and the load is efficiently distributed. Further, when one half of the required energization time is larger than the reference time, the operation can be performed to ensure that the necessary energization time ends at the end time of the specific power time, and power is supplied around the minimum load time. Will be allocated.
[0022]
Furthermore, the power control method of the present invention includes an object to be heated existing inside or Power storage unit To store heat using the power of a specific power hour such as midnight Electricity storage In the power control method, the reference time calculation for determining the minimum load time setting step for setting the minimum load time within the specific power time zone and the time between the minimum load time and the end time of the specific power time zone as the reference time Process and heated object or Power storage unit Heat storage by means of applying electricity to Electricity storage The required energization time acquisition process for obtaining the required energization time for performing the process or receiving the data of the required energization time calculated in advance, and determining whether or not the half of the required energization time is greater than the reference time Based on the first determination step and the determination result in the first determination step, when the value of one half of the required energization time is smaller than the reference time, the reference time is determined from the total time in the specific power time zone. And subtracting one half of the required energization time to calculate the standby time from the start time of the specific power time zone, and the determination in the first determination step Based on the result, when the half of the required energization time is larger than the reference time, the second standby time for calculating the standby time by subtracting the necessary energization time from the end time of the specific power time period First from the calculation process and the start time of the specific power time zone When it is determined that the standby time calculated in the standby time calculation step or the second standby time calculation step has elapsed or not and the standby time has elapsed in the second determination step And a third determining step for determining whether or not the operation time of the charging means in the charging means operating step has passed the required energization time, And an operation stop step for stopping the operation of the charging means based on the determination result in the determination step.
[0023]
This power control method is preferably applied to the current midnight power time zone in which the time of the minimum load is shifted from the center of the specific power time zone to the end time side. That is, when the value of one half of the required energization time is smaller than the reference time, the necessary energization time is equally allocated to both sides around the time of the lowest load, and the load is efficiently distributed. In addition, when the half of the required energization time is larger than the reference time, it can be operated to ensure that the required energization time ends at the end time of the specific power time, and around the minimum load time. Electric power will be allocated.
[0036]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. The apparatus of this embodiment is an electric water heater that is a type of heat storage device as well as a power utilization device.
[0037]
FIG. 1 is a schematic diagram of the electric water heater 1, FIG. 2 is a flowchart showing a procedure of power use, and FIG. 3 is a power usage diagram. In addition, by providing many electric water heaters 1 as shown below in each building, an efficient power utilization system is configured between the power supply source and the power consumer. In addition, as the specific power time zone, the current midnight power time zone of 11 pm to 7 am is adopted.
[0038]
This electric water heater 1 has a remaining hot water amount detection unit 2 that detects the amount of remaining hot water inside. This remaining hot water detection unit 2 is connected to the calculation means 3. Further, a remaining hot water temperature detection unit 4 for detecting the remaining hot water temperature is separately connected to the calculation means 3. Based on the detection results of the remaining hot water amount detection unit 2 and the remaining hot water temperature detection unit 4, the calculation means 3 performs various calculations. That is, the calculation means 3 is an information processing apparatus that can process various types of information. In addition, in the electric water heater 1, since the used water is normally supplied when it is used, the amount of remaining hot water is generally full. In addition, by setting the remaining hot water temperature detection unit 4 to a constantly detected state, the heater 7 may be turned off separately from the time control when the predetermined temperature is reached by heating by the heater 7.
[0039]
In addition, it is good also as a structure which connects a hot water supply means separately to the electric water heater 1 of this embodiment, provides a hot water supply temperature sensor corresponding to this, and connects this hot water supply temperature sensor to the calculating means 3 separately. Further, the operation control means 6 is connected to the calculation means 3 via a determination means 10 described later. The operation control means 6 is connected to the heater 7 and performs energization control on the heater 7 serving as a heating means based on the calculation result of the calculation means 3.
[0040]
In the flowchart of FIG. 2, first, a minimum load time t0 is set (step 1; minimum load time setting step). Thereafter, a reference time T0 is calculated (step 2; reference time calculation step). In this case, the reference time is a time between the minimum load time and the end time of the specific power time zone. The formula in this case is
T0 = 7−t0 Equation 1
Ask for. This equation is stored in advance in the calculation means 3. For example, when the minimum load time is 4 o'clock, it is 3 hours from the end time 7 o'clock of the specific power time period.
[0041]
Then, it is determined by the time determination means 8 whether or not the current time is within the range of the specific power time zone from 23:00 to 7:00 (step 3). The time discriminating means 8 is connected to the computing means 3, and it is determined whether or not the computing means 3 performs the computation based on the discrimination result in the time discriminating means 8. Then, when it is determined that it is within the specific power time zone, the calculation means 3 calculates the required energization time T1 for how many hours the heater 7 is operated to actually boil the hot water thereafter. (Step 4; required energization time acquisition step).
[0042]
After calculating the required energization time T1, a time (T1 / 2) obtained by halving the required energization time T1 is calculated by the calculation means 3, and it is determined whether or not this (T1 / 2) is smaller than the reference time T0. Is performed by the determination means 9 (step 5; first determination step). This is shown in the following equation:
T0 ≧ T1 / 2/2 Formula 2
It becomes.
[0043]
As a result of this determination, when the time is smaller than T0, the necessary energization time is equally distributed before and after the minimum load time t0. This state is shown in FIG. For example, when the minimum load time is 4 o'clock and the required energization time is 5 hours, the time is allocated 2.5 hours before and after 4 o'clock. Therefore, the energization start time is 1:30 and the energization end time is 6:30.
[0044]
In this case, the operation control means 6 controls the energization of the heater 7 so that energization is started after the standby time Ts has elapsed from the start time of the specific power time period. For this reason, first, the waiting time Ts is calculated by the calculating means 3 (step 6; first waiting time calculating step). The waiting time Ts is shown in the following equation:
Ts = 8− (T0 + T1 / 2) Equation 3
It becomes.
[0045]
Note that the arithmetic processing means 5 is constituted by the arithmetic means 3, the time discriminating means 8 and the determining means 9 described above. Further, the arithmetic processing means 5 may include a determination means 10 that also serves as an energization end determination means.
[0046]
After this calculation, it is determined by the determination means 10 whether or not the standby time Ts has elapsed from 23:00 (step 7; second determination step). According to this determination, the heater 7 is not operated when Ts has not yet elapsed. However, when Ts has elapsed, a signal is issued to the operation control means 6 to activate the heater 7 (step 8; heating means). Operation process).
[0047]
Then, the above-mentioned determining means 10 determines whether or not the necessary energization time T1 has elapsed since the start of energization (step 9; third determination step). When the necessary energization time T1 has elapsed, the discrimination means 10 issues a control signal to the operation control means 6. Then, the heater 7 is stopped by the operation control means 6 to end the energization (step 10; operation stop process). With the above operation, the power supply for the day is terminated and the content is reset.
[0048]
In Step 5, when the time obtained by halving the required energization time T1 is larger than the reference time T0, the calculation means 3 performs an operation of subtracting the necessary energization time from the end time of the specific power time zone (Step 11). Second waiting time calculation step). For example, when the necessary energization time T1 is 7 hours, the required energization time of 7 hours is subtracted from 8 hours in the specific power period. This is shown in the following equation:
Ts = 8−T1 Equation 4
It becomes. Such a state is shown in FIG.
[0049]
Also in this case, after calculating the energization start time, it is determined by the determination means 10 whether or not Ts time has elapsed from 23:00 (step 12; second determination step). As a result of this determination, the heater 7 is not operated when the Ts time has not yet elapsed as described in step 8 above, but the heater 7 is operated when the Ts time has elapsed. The subsequent procedure is as described above.
[0050]
According to the electric water heater 1 and the power control method as described above, when the time required for halving the required energization time T1 is smaller than the reference time T0, the necessary energization time T1 at the time before and after the minimum load time. Are equally divided. For this reason, it is possible to use power so that a peak comes just at the minimum load time, and power utilization efficiency is improved. For this reason, the amount of power used in other time zones is reduced, and the power generation efficiency can be improved. For this reason, for example, in a thermal power plant, combined with improvement in utilization efficiency, it contributes to a reduction in the amount of carbon dioxide that is wasted.
[0051]
Further, when the time required for halving the required energization time T1 is greater than the reference time T0, the energization start time starts from a time that goes back the required energization time from 7:00 am, which is the end time of the specific power time period. To control. For this reason, it becomes suitable when the minimum load time is approaching the end time side of the specific power time zone, and the peak of nighttime power use can be brought close to the minimum load time. In the first embodiment, it is suitable when the minimum load time t0 is present on the end side from the center of the specific power time zone, but the minimum load time t0 is less than the center of the specific power time zone. When present on the start side, when the required energization time T1 is large, energization is started from the start time of the specific power time zone instead of the idea shown in FIG. 3B or in addition to the idea shown in FIG. You may adopt the idea.
[0052]
(Second embodiment)
Hereinafter, a second embodiment of the present invention will be described with reference to FIGS.
The second embodiment is also an electric water heater 1 having the same configuration as in FIG. 1, and FIG. 1 is also used.
[0053]
In the flowchart of FIG. 4, first, the minimum load time t0 shown in FIG. 6 is set (step 21; minimum load time setting step). Thereafter, a reference time T0 is calculated (step 22; reference time calculation step). In this case, the reference time is a time between the minimum load time and the end time of the specific power time zone. The formula in this case is the same as the previous formula 1. Equation 1 is stored in advance in the calculation means 3.
[0054]
Then, it is determined by the time determination means 8 whether or not the current time is within the range of the specific power time zone from 23:00 to 7:00 (step 23). The time discriminating means 8 is connected to the computing means 3, and it is determined whether or not the computing means 3 performs the computation based on the discrimination result in the time discriminating means 8. Then, when it is determined that it is within the specific power time zone, the calculation means 3 calculates the required energization time T1 for how many hours the heater 7 is operated to actually boil the hot water thereafter. Perform (step 24; required energization time acquisition step).
[0055]
After calculating the necessary energization time T1, it is determined whether or not the reference time is equal to or less than a half of the specific power time (step 25; reference time determination step). In this determination, it is determined whether the minimum load time is shifted to the start side or the end side from the center of the specific power time zone. If the result of step 25 is affirmative, that is, if the minimum load time is shifted to the end of the specific power time zone, then the time (T1 / 2) obtained by halving the required energization time T1 is calculated by the calculation means 3. The determination means 9 determines whether or not (T1 / 2) is smaller than the reference time T0 (step 26). This is shown in the following equation:
T0> T1 / 2 Formula 5
It becomes. Note that Formula 2 may be used instead of Formula 5.
[0056]
As a result of this determination, when it is smaller than T0, as shown in FIG. 6A, the necessary energization time is equally distributed before and after the minimum load time t0. For example, when the minimum load time is 4 o'clock and the required energization time is 3 hours, the time is distributed 1.5 hours before and after 4 o'clock. For this reason, the energization start time is 2:30 and the energization end time is 5:30.
[0057]
In this case, the operation control means 6 controls the energization of the heater 7 so that energization is started after the standby time Ts has elapsed from the start time of the specific power time period. For this reason, first, the waiting time Ts is calculated by the calculating means 3 (step 27). The waiting time Ts is expressed by the above Equation 3.
[0058]
The energization start time is determined by the determination means 10 by determining whether or not the standby time Ts has elapsed from 23:00 (step 28). According to this determination, the heater 7 is not operated when Ts has not yet elapsed, but when Ts has elapsed, a signal is issued to the operation control means 6 to activate the heater 7 (step 29).
[0059]
Then, the determination means 10 determines whether or not the necessary energization time T1 has elapsed since the start of energization (step 30). When the necessary energization time T1 has elapsed, the discrimination means 10 issues a control signal to the operation control means 6. Then, the heater 7 is stopped by the operation control means 6 to end the energization (step 31). With the above operation, the power supply for the day is terminated and the content is reset.
[0060]
In step 26, if the time required for halving the required energization time T1 is equal to or longer than the reference time T0, the process proceeds to step 32, and the necessary energization time T1 is subtracted from 8 hours, which is the total time of the specific power time zone. It is determined whether the time exceeds zero. In the affirmative case, half of the time obtained by subtracting the necessary time T1 from the total time in the specific power time zone is obtained as the standby time Ts (step 33). For example, when the required energization time T1 is 7 hours, the time obtained by subtracting the required energization time T1 (7 hours) from 8 hours, which is the total time of the specific power time zone, is halved. .5 hours, which is the waiting time Ts. This is shown in the following equation:
Ts = (8−T1) / 2 Equation 6
It becomes. By applying this equation, as shown in FIG. 6B, the result is that a waiting time Ts exists before and after the required energization time T1.
[0061]
Also in this case, after the calculation, the determination means 10 determines whether or not Ts time has elapsed from 23:00 (step 34). According to this determination, the heater 7 is not operated when the Ts time has not yet elapsed, but when the Ts time has elapsed, the routine proceeds to step 29 where the heater 7 is operated. The subsequent procedure is as described above.
[0062]
In step 25, when the reference time exceeds one half of the specific power time, that is, when the minimum load time is on the start side from the center of the specific power time zone, the flow proceeds to the flow shown in FIG.
[0063]
In step 41 of FIG. 5, the determination means 9 determines whether or not the time (T1 / 2) obtained by halving the required energization time T1 is smaller than the value obtained by subtracting the reference time T0 from the specific power time. This is shown in the following equation:
8-T0> T1 / 2/2 Formula 7
It becomes.
[0064]
As a result of this determination, when it is smaller than (8−T0), the necessary energization time is equally distributed before and after the minimum load time t0. That is, the waiting time Ts is obtained by the same expression 3 as in step 27 (step 42). For example, when the minimum load time is 2:00 am and the required energization time is 5 hours, the time is allocated 2.5 hours before and after 2:00 am. Therefore, the energization start time is 11:30 pm, and the energization end time is 4:30 am.
[0065]
Then, after this calculation, the determination means 10 determines whether or not the standby time Ts has elapsed from 23:00 (step 43). According to this determination, the heater 7 is not operated when Ts has not yet elapsed, but when Ts has elapsed, the routine proceeds to step 29 where a signal is sent to the operation control means 6 to operate the heater 7. Thereafter, the process proceeds to steps 30 and 31, and is reset when the heater 7 is stopped.
[0066]
If the determination in step 41 is negative, the process proceeds to step 44, where it is determined whether or not the time obtained by subtracting the necessary energization time T1 from the specific power time exceeds zero. In the case of affirmative, half of the time obtained by subtracting the necessary energization time T1 from 8 hours of the specific power time is obtained as the standby time Ts (step 45). The calculation formula at this time is the same as the formula 6 in step 33. When this equation 6 is applied, as shown in FIG. 6B, a standby time Ts exists before and after the required energization time T1.
[0067]
Also in this case, after calculating the waiting time Ts, the determining means 10 determines whether or not Ts time has elapsed from 23:00 (step 46). According to this determination, the heater 7 is not operated when the Ts time has not yet elapsed, but when the Ts time has elapsed, the routine proceeds to step 29 where the heater 7 is operated. The subsequent procedure is as described above.
[0068]
According to the electric water heater 1 and the power control method as described above, it is applied not only when the minimum load time t0 is shifted to the end side from the center of the specific power time zone but also to the start side. Can do. In addition, when the time required to halve the required energization time T1 is shorter than the minimum load time t0 and the time until the start or end of the specific power time period, which is shorter, the minimum load time t0 is set. The necessary energization time T1 is equally divided into the time before and after the center. For this reason, it is possible to use power so that the peak comes just at the minimum load time t0, and the power utilization efficiency is improved. For this reason, the amount of power used in other time zones is reduced, and the power generation efficiency can be improved.
[0069]
In addition, if the time when the required energization time T1 is halved is larger than the minimum load time t0 and the time until the start or end of the specific power time period, which is shorter, the start of the specific power time period And the idle time of the end time will be controlled equally. For this reason, it is possible to avoid load concentration at the start and end times of the specific power period.
[0070]
When the electric water heater 1 and the power control method of the second embodiment are adopted, the additional load is as shown in FIG. That is, a mountain-shaped load as shown by the dotted line in FIG. 7A is formed by the control equivalent to both sides of the minimum load time, which is the control as shown in FIG. 6A, whereas, as shown in FIG. 6B. With a uniform control between both sides, a trapezoidal load as shown by a one-point difference line in FIG. 7A is formed. And it becomes an additional load as shown as a continuous line as a whole. With such an additional load, the power demand is raised as shown in FIG. In this manner, the portion of the minimum load time t0 is greatly raised and the load does not concentrate on each time portion of the start (23:00) and the end (7 o'clock).
[0071]
(Third embodiment)
Hereinafter, a third embodiment of the present invention will be described with reference to FIGS. The third embodiment is also an electric water heater 1 having the same configuration as in FIG. 1, and FIG. 1 is also used.
[0072]
In the flowchart of FIG. 8, first, it is determined by the time determination means 8 whether or not the current time is within the range of the specific power time zone from 23:00 to 7:00 (step 51). The time discriminating means 8 is connected to the computing means 3, and it is determined whether or not the computing means 3 performs the computation based on the discrimination result in the time discriminating means 8. Then, when it is determined that it is within the specific power time zone, the calculation means 3 calculates the required energization time T1 for how many hours the heater 7 is operated to actually boil the hot water thereafter. It is performed (step 52; required energization time acquisition step).
[0073]
Next, the routine proceeds to step 53, where it is determined whether or not the time obtained by subtracting the required energization time T1 from the total time of 8 hours in the specific power time zone exceeds zero. In the affirmative case, half of the time obtained by subtracting the required energization time T1 from the total time in the specific power time zone is obtained as the standby time Ts (step 54). For example, when the required energization time T1 is 7 hours, the time obtained by subtracting the required energization time T1 (7 hours) from 8 hours, which is the total time of the specific power time zone, is halved. .5 hours, which is the waiting time Ts. The equation for obtaining the waiting time Ts is the same as the equation 6 shown above.
[0074]
Also in this case, after the energization start time is calculated, the determination means 10 determines whether or not Ts time has elapsed from 23:00 (step 55). If it is determined that the Ts time has not yet elapsed, the heater 7 is not operated. However, if the Ts time has elapsed, the routine proceeds to step 56 where the heater 7 is operated. Then, Steps 57 and 58 corresponding to Steps 9 and 10 described above are performed and reset.
[0075]
In the third embodiment, as shown in FIG. 9A, even if the required energization time T1 is short, the open portions on both sides of the required energization time T1 are evenly allocated. That is, the open portions on both sides are open for the waiting time Ts. Further, even when the required energization time T1 is so long as to be close to 8 hours, as shown in FIG. 9B, the waiting time Ts occurs on both sides of the necessary energization time T1.
[0076]
According to the third embodiment, as shown in FIG. 10A, the additional load is formed in a mountain shape with the center of the specific power time zone as the apex. For this reason, as shown in FIG. 10B, the power demand curve is raised compared to the current curve, and the load is not concentrated at the start and end times of the specific power time period. . In addition, when the minimum load time t0 is the center of the specific power time zone, it is particularly preferable because the uniform load increases.
[0077]
(Fourth embodiment)
Hereinafter, a fourth embodiment of the present invention will be described with reference to FIGS. The fourth embodiment is also an electric water heater 1 having the same configuration as that shown in FIG. 1, and FIG. 1 is also used.
[0078]
In the flowchart of FIG. 11, first, a minimum load time t0 is set (step 61; minimum load time setting step). Thereafter, a reference time T0 is calculated (step 62; reference time calculation step). In this case, the reference time is a time between the minimum load time and the end time of the specific power time zone. The formula in this case is the formula 1 shown above. Equation 1 is stored in advance in the calculation means 3. For example, when the minimum load time is 4 o'clock, it is 3 hours from the end time 7 o'clock of the specific power time period.
[0079]
Then, it is determined by the time determination means 8 whether or not the current time is within the range of the specific power time zone from 23:00 to 7:00 (step 63). The time discriminating means 8 is connected to the computing means 3, and it is determined whether or not the computing means 3 performs the computation based on the discrimination result in the time discriminating means 8. Then, when it is determined that it is within the specific power time zone, the calculation means 3 calculates the required energization time T1 for how many hours the heater 7 is operated to actually boil the hot water thereafter. (Step 64; required energization time acquisition step).
[0080]
After calculating the necessary energization time T1, a time ratio n is obtained from the specific power time T and the reference time T0 using the calculation means 3 (step 65). Thereafter, the waiting time Ts is obtained from the time ratio n, the reference time T0, and the necessary time T1. In the case of the fourth embodiment, the necessary energization time T1 is proportionally distributed before and after the minimum load time t0. For example, when the minimum load time is 4 o'clock and the required energization time T1 is 5 hours, 3 hours 7 minutes 30 seconds (= 5 hours x 5/8) are allocated before 4 o'clock. 1 hour 52 minutes 30 seconds (= 5 hours × 3/8) is allocated. For this reason, the energization start time is 0:52:30, and the energization end time is 5:52:30.
[0081]
In this case, the operation control means 6 controls the energization of the heater 7 so that energization is started after the standby time Ts has elapsed from the start time of the specific power time period. For this reason, first, the waiting time Ts is calculated by the calculating means 3 (step 66). The waiting time Ts is shown in the following equation:
Ts = 8−T0 + T1 × n Equation 8
It becomes. FIG. 12 shows which part each value corresponds to. Note that FIG. 12B is a partially enlarged view of FIG. 12A and shows in an easy-to-understand manner what each value indicates.
[0082]
The energization start time is determined by the determination means 10 by determining whether or not the standby time Ts has elapsed from 23:00 (step 67). According to this determination, the heater 7 is not operated when Ts has not yet elapsed, but when Ts has elapsed, a signal is issued to the operation control means 6 to activate the heater 7 (step 68).
[0083]
Then, the above-mentioned determining means 10 determines whether or not the necessary energization time T1 has elapsed since the start of energization (step 69). When the necessary energization time T1 has elapsed, the discrimination means 10 issues a control signal to the operation control means 6. Then, the heater 7 is stopped by the operation control means 6 to end the energization (step 70). With the above operation, the power supply for the day is terminated and the content is reset.
[0084]
In the fourth embodiment, as shown in FIG. 13A, the added load has a mountain shape that is slightly inclined with the minimum load time t0 as the apex. When this embodiment is adopted, the power demand is allocated according to the ratio of each time from the start time before and after the minimum load time t0 to the end time. For this reason, as shown in FIG. 13 (B), the lower the power demand portion, such as the minimum load, the higher the power demand, and the bottom-up effect can be sufficiently expected.
[0085]
Further, in the fourth embodiment, in the specific power time zone indicating a gentle concave power demand among various specific power time zones, the position of the minimum load time t0 in the specific power time zone is Even in this case, a sufficient bottom-up effect occurs. In addition, load concentration at the beginning and end of the specific power time period does not occur.
[0086]
(Fifth embodiment)
The fifth embodiment of the present invention will be described below with reference to FIGS. The fifth embodiment is also an electric water heater 1 having the same configuration as in FIG. 1, and FIG. 1 is also used.
[0087]
In the flowchart of FIG. 14, first, it is determined by the time determination means 8 whether or not the current time is within the range of the specific power time zone from 23:00 to 7:00 (step 71). The time discriminating means 8 is connected to the computing means 3, and it is determined whether or not the computing means 3 performs the computation based on the discrimination result in the time discriminating means 8. Then, when it is determined that it is within the specific power time zone, the calculation means 3 calculates the required energization time T1 for how many hours the heater 7 is operated to actually boil the hot water thereafter. It is performed (step 72; required energization time acquisition step).
[0088]
The calculation of the necessary energization time T1 is performed by the computing means 3 by subtracting the necessary energization time T1 from the specific power time of 8 hours (step 73). At this time, the obtained N is a numerical value shown in units of one hour. Specifically, N is obtained by the following equation.
N = 8−T1 Equation 9
[0089]
Based on the value of N obtained by Equation 9, a plurality of waiting times are set by the calculation means 3 within the range of the value of N. Various methods are conceivable for setting the number of standby times. For example, the number of standby times from the end time of the specific power time zone or the number of standby times from the start time of the specific power time zone is set. Is preferable.
[0090]
For example, when the required energization time T1 is 5 hours and the number of standby hours is set from the start time of the specific power time zone, 0, 1, 2, 3 are set. Then, random number processing is performed by the calculation means 3 to determine an appropriate standby time Nr (step 74). Note that the setting of the waiting time number is not limited to this. For example, only a specific range may be subdivided so as to concentrate in the vicinity of the minimum load time.
[0091]
After the standby time Nr is determined, the energization start time Tn of the heater 7 is obtained by the calculation means 3 (step 75; energization start time determination step). This is shown in the following equation:
Tn = 23 + Nr Equation 10
It becomes. Here, when Nr is set to “2” in the previous example, Tn = 25, and energization starts at 1 am. The calculation units in steps 73 and 75 may be other calculation units such as 30 minutes or 15 minutes instead of 1 hour. Considering the effect of leveling and simplification of calculation, the unit of 30 minutes is preferable.
[0092]
Then, after this calculation, it is determined by the determining means 10 whether or not Tn has been reached (step 76). As a result of this determination, the heater 7 is not operated when the time Tn is not yet reached, but when the time Tn is reached, a signal is sent to the operation control means 6 to operate the heater 7 (step 77).
[0093]
Then, the determination means 10 determines whether or not the necessary energization time T1 has elapsed since the start of energization (step 78). When the necessary energization time T1 has elapsed, the discrimination means 10 issues a control signal to the operation control means 6. Then, the heater 7 is stopped by the operation control means 6 to end the energization (step 79). With the above operation, the power supply for the day is terminated and the content is reset.
[0094]
In the fifth embodiment, when various power use devices capable of executing this control method are driven by this power control method, the respective required energization times T1a to T1g are as shown in FIG. The start times are distributed. On the other hand, if it is equally distributed around the minimum load time t0, the necessary energization times T1h to T1k of various types of power utilization devices are concentrated in the minimum load time t0 portion as shown in FIG. For this reason, as shown by the dotted line in FIG. 15B, the minimum load time portion of the power demand curve protrudes in a mountain shape. In contrast, in the fifth embodiment, the additional load is smoothed as shown in FIG. For this reason, when the power usage equipment and the power control method according to the fifth embodiment are used, as shown in FIG. 16B, the power demand curve is uniformly raised as a whole, as shown in FIG. Such an abnormal protrusion does not occur.
[0095]
(Sixth embodiment)
Hereinafter, a sixth embodiment of the present invention will be described with reference to FIGS. The sixth embodiment is also an electric water heater 1 having the same configuration as that shown in FIG. 1, and FIG. 1 is also used.
[0096]
In the flowchart of FIG. 17, the computing means 3 first sets a target energization end time t00 (step 81; target energization end time determination step). The target energization end time t00 is determined in consideration of insufficient energization time due to the use of hot water within the specific power time period. This t00 is preferably set between the minimum load time t0 and the end time of the specific power time period. Next, it is determined by the time determining means 8 whether or not the current time is within the specific power time zone from 23:00 to 7:00 (step 82). The time discriminating means 8 is connected to the computing means 3, and it is determined whether or not the computing means 3 performs the computation based on the discrimination result in the time discriminating means 8. Then, when it is determined that it is within the specific power time zone, the calculation means 3 calculates the required energization time T1 for how many hours the heater 7 is operated to actually boil the hot water thereafter. (Step 83; required energization time acquisition step).
[0097]
After calculating the necessary energization time T1, it is determined in step 84 whether or not the time from the specific power time period start time ts to the target energization end time t00 is greater than the necessary energization time T1. If the result of this determination is affirmative, the start time of the required energization time T1 is set so that energization ends at the target energization end time t00. For example, when the target energization end time t00 is 6 am and the necessary energization time is 5 hours, the energization start time is 1 am and the energization end time is 6 am.
[0098]
In this case, the operation control means 6 controls the energization of the heater 7 so that energization is started after the standby time Ts has elapsed from the start time of the specific power time period. For this reason, first, the waiting time Ts is calculated by the calculating means 3 (step 85). The waiting time Ts is shown in the following equation:
Ts = (t00−ts) −T1 Equation 11
It becomes. This relationship is shown in FIG.
[0099]
The energization start time is determined by the determination means 10 by determining whether or not the standby time Ts has elapsed from 23:00 (step 86). According to this determination, the heater 7 is not operated when Ts has not yet elapsed, but when Ts has elapsed, a signal is sent to the operation control means 6 to activate the heater 7 (step 87). If the determination at step 84 is negative, the process immediately proceeds to step 87. That is, when the required energization time T1 is longer than the time from the specific power time zone start time ts to the target energization end time t00, the start time ts of the specific power time zone is set as the power start time as shown in FIG. The heater 7 is operated as follows.
[0100]
After the heater 7 is activated, in step 88, the calculation means 3 calculates the necessary energization time T1 again. This is because the required energization time T1 changes due to the use of hot water during the specific power period. In step 89, it is determined whether or not this new necessary energization time T1 has become zero. When the necessary energization time T1 becomes zero, the discrimination means 10 issues a control signal to the operation control means 6. Then, the heater 7 is stopped by the operation control means 6 to end the energization (step 90). With the above operation, the power supply for the day is terminated and the content is reset.
[0101]
In step 89, when the new necessary energization time T1 has not yet become zero, the process proceeds to step 91, and it is determined whether or not it is a specific power time zone (in this example, 11:00 pm to 7:00 am). If negative, the process proceeds to step 90 and the heater 7 is stopped. However, when it is during the specific power period, the process returns to step 88, and again, the calculation means 3 calculates the necessary energization time T1 and shifts to step 89. As long as the required energization time T1 does not become zero and is within the specific power energization time zone, the routines of steps 88, 89, and 91 continue to rotate. As shown by the arrow w in FIG. 18, there is also a power utilization device that ends after the target energization end time t00 is exceeded by this routine.
[0102]
In the sixth embodiment, the target energization end time t00 is appropriately set in consideration of the past actual condition and the energization is terminated at or around the time t00. As shown, load leveling and bottom-up are achieved. In addition, there is room before the end time of the specific power time zone (11:00 pm to 7:00 am in this example), and even if hot water or the like is used during the specific power time zone by effectively utilizing the surplus time It is possible to prevent shortage of heating time and the like. Note that it is conceivable to utilize the surplus time by repeating the recalculation of the required energization time T1 to set the energization end time to a time exceeding the target energization end time t00 and to enable appropriate heat storage.
[0103]
Each of the above embodiments is an example of a preferred embodiment of the present invention, but the present invention is not limited to these embodiments, and various modifications can be made within the scope of the gist of the present invention. is there. For example, as electric power use equipment, in addition to electric water heaters, heat storage devices such as electric heat storage type heaters, electric snow melting machines, etc., devices that want to make effective use of electric power at specific times such as nighttime and morning, chargers for electric vehicles, Various chargers such as an electric light vehicle charger may be employed.
[0104]
Further, the necessary energization time T1 may be set in advance in the device in addition to being calculated by the calculation means 3 in the device, or the set value may be variable. Further, the time T1 may be given to the power utilization device via communication means such as a wireless or wired network or other input / output means. Further, the routines of steps 88, 89 and 91 shown in the sixth embodiment may be applied to the first to fifth embodiments. Furthermore, in various calculations and time settings, depending on the application and type of equipment, such as seconds, minutes, 5 minutes, 10 minutes, 15 minutes, 20 minutes, 30 minutes, 1 hour, etc. Various units can be adopted. In each expression, ≦ may be used instead of <representing magnitude, or vice versa, or ≧ may be used instead of>, or vice versa.
[0105]
Further, as the specific power time zone, it is preferable to employ the current midnight power zone from 11 pm to 7:00 am or the second midnight power zone that exists in this midnight power zone. However, in terms of power leveling, for example, it may be 9 pm to 9 am, or another area may be employed. Furthermore, since the power demand curve is different in summer and winter and also greatly different in each region (for example, Okinawa and Hokkaido), the specific power time zone may be varied depending on the season or region. Further, since the minimum load time t0 varies depending on the era, region, season, etc., it is preferable that it can be changed as appropriate. In addition, when it is possible to change the specific power time zone or the minimum load time t0, it can be performed by operating a setting unit provided in the power usage device, or a communication means such as a wireless or wired network or other input means. A technique of changing the setting via the output unit may be employed.
[0106]
【The invention's effect】
As described above, according to the inventions, it is possible to further level the power load as compared with the prior art. In addition, by reducing the amount of power used in other time zones, the efficiency of power generation can be improved, and for example, in a thermal power plant, the amount of carbon dioxide generated can be reduced. .
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing a configuration of a power utilization device according to a first embodiment of the present invention.
FIG. 2 is a flowchart showing a power control method for the power usage device of FIG. 1;
FIG. 3 is a diagram for explaining a power control method of the power utilization device in FIG. 1;
FIG. 4 is a part of a flowchart showing a power control method of a power utilization device according to a second embodiment of the present invention.
FIG. 5 is the remaining part of the flowchart showing the power control method of the power usage device according to the second embodiment of the present invention.
FIG. 6 is a diagram for explaining a power control method for the power usage device according to the second embodiment shown in FIG. 4 and the like.
7 is a diagram for explaining changes in load when the power control method according to the second embodiment shown in FIG. 4 and the like is used for various types of power use devices. FIG. 7 (A) shows the state of the added load. (B) is a figure which shows the electric power demand curve at the time of employ | adopting the present electric power demand curve and this invention.
FIG. 8 is a flowchart showing a power control method for a power-using device according to the third embodiment of the present invention.
FIG. 9 is a diagram for explaining a power control method for the power usage device according to the third embodiment shown in FIG. 8 and the like;
FIG. 10 is a diagram for explaining changes in load when the power control method according to the third embodiment shown in FIG. 4 and the like is used for various types of power use devices. FIG. 10 (A) shows the state of an additional load. (B) is a figure which shows the electric power demand curve at the time of employ | adopting the present electric power demand curve and this invention.
FIG. 11 is a flowchart showing a power control method for a power-using device according to the fourth embodiment of the present invention.
FIG. 12 is a diagram for explaining a power control method of the power usage device according to the fourth embodiment shown in FIG. 11 and the like, and (B) is a partially enlarged view of (A).
FIG. 13 is a diagram for explaining a change in load when the power control method according to the fourth embodiment shown in FIG. 11 and the like is used for various types of power use devices; (A) shows the state of the added load. (B) is a figure which shows the electric power demand curve at the time of employ | adopting the present electric power demand curve and this invention.
FIG. 14 is a flowchart showing a power control method for a power-using device according to the fifth embodiment of the present invention.
FIG. 15 is a diagram for explaining a power control method for the power usage device according to the fifth embodiment shown in FIG. 14 and the like, and FIG. 15 (A) shows the start of energization of various power usage devices according to the fifth embodiment; (B) is a figure which shows the state from which various electric power utilization apparatuses other than 5th embodiment start electricity supply around the time of the minimum load.
FIG. 16 is a diagram for explaining changes in load when the power control method according to the fifth embodiment shown in FIG. 14 and the like is used for various types of power use devices; FIG. 16 (A) shows the state of an additional load. (B) is a figure which shows the electric power demand curve at the time of employ | adopting the present electric power demand curve and this invention.
FIG. 17 is a flowchart showing a power control method for a power-using device according to the sixth embodiment of the present invention.
FIG. 18 is a diagram for explaining a power control method of the power usage device according to the sixth embodiment illustrated in FIG. 17 and the like.
FIG. 19 is a diagram for explaining a change in load when the power control method according to the sixth embodiment shown in FIG. 17 and the like is used for various types of power use devices; FIG. (B) is a figure which shows the electric power demand curve at the time of employ | adopting the present electric power demand curve and this invention.
FIG. 20 is a diagram showing a power usage state in the current specific power time zone (midnight power time zone), and shows a current power demand curve with time on the X axis and load (power demand) on the Y axis. It is.
[Explanation of symbols]
1 Electric water heater (electric power equipment)
3 Calculation means
5 Arithmetic processing means
6 Operation control means
7 Heater (heating means)
8 Time discriminating means
9 Judgment means
10 Discriminating means (also serves as energization end discriminating means)

Claims (2)

In a power-use device that stores heat or stores electricity using a power in a specific power time period such as a midnight power time period in an object to be heated or a power storage unit existing in the inside, the object to be heated is heated or stored in the power storage unit Heat storage means, connected to the power supply means, and an operation control means for controlling the operation of the power supply means, and based on measurement data of the heat storage temperature, the amount of remaining hot water, and the amount of stored electricity , Alternatively, the necessary energization time for power storage is calculated, or data of the necessary energization time calculated in advance is received, and the specified power time period is calculated from the minimum load time obtained from the state of the load power amount in the specified power time period. When the time until the end time is calculated as the reference time, it is determined whether or not the half of the required energization time is greater than the reference time, and it is determined that the reference time is large Subtracts the reference time from the total time of the specific power time zone, further subtracts one half of the required energization time to calculate the standby time from the start time of the specific power time zone, An arithmetic processing means for subtracting the required energization time from an end time of the specific power time zone when the reference time is determined to be short to calculate the standby time; and the heating means after the standby time has elapsed A power utilization device comprising: an end-of-energization determining unit that determines whether or not the necessary energization time has elapsed after the operation of the unit and issues a control signal to the operation control unit. In a power control method for storing heat or storing electricity using a power in a specific power time zone such as a midnight power time zone for an object to be heated or a power storage unit located inside, the minimum load time for setting the minimum load time in the specific power time zone A load time setting step, a reference time calculation step for obtaining a time between the minimum load time and the end time of the specific power time zone as a reference time, and heat storage by a heating means or power to the heated body or power storage unit or The required energization time acquisition step for obtaining the required energization time for storing electricity or receiving the data of the required energization time calculated in advance, and whether or not the half of the required energization time is greater than the reference time Based on the determination result in the first determination step and the determination result in the first determination step, when the half value of the required energization time is smaller than the reference time, The first time for subtracting the reference time from the total time in the specific power time zone, and further subtracting the half of the required energization time to calculate the standby time from the start time of the specific power time zone Based on the determination results in the standby time calculation step and the first determination step, if the value of one half of the required energization time is greater than the reference time, the end time of the specific power time period A second standby time calculation step of calculating the standby time by subtracting the required energization time from the first standby time calculation step or the second standby time calculation step from the start time of the specific power time zone And a second determination step for determining whether or not the standby time calculated in step e has elapsed, and when it is determined in the second determination step that the standby time has elapsed, Electric means operating step and the above-mentioned charging means Based on the determination result in the third determination step for determining whether or not the operating time of the charging means in the process has passed the required energization time, and the determination result in the third determination step, A power control method comprising: an operation stop step for stopping the operation.

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