JP6280736B2 - Energy management system and energy management method - Google Patents

Description

  The present invention relates to a technology of an energy management system and an energy management method capable of calculating an operation pattern of a power supply device according to a predetermined purpose.

  Conventionally, an energy management system and an energy management method that can calculate an operation pattern of a power supply device (particularly, a power supply device including a fuel cell) in accordance with a predetermined purpose are known. For example, as described in Patent Document 1.

  Patent Document 1 describes an energy management system including a storage battery, a fuel cell (first power generation device), and a control device (energy management device) that calculates an operation pattern of the fuel cell. In this energy management system, the control device operates the storage battery and the fuel cell (power supply device) so that the stored power (charged power) of the storage battery gradually decreases to a predetermined time and becomes 0 at the predetermined time. A pattern (control schedule) is calculated. The control device can prevent the power stored in the storage battery from being used up before a predetermined time by controlling the operation of the power supply device based on the calculated operation pattern. As a result, it is possible to prevent a situation in which the stored power of the storage battery is insufficient in a time zone where power is required.

  In addition, various energy management systems capable of calculating an operation pattern of the power supply apparatus according to a predetermined purpose have been proposed. However, none of the conventional energy management systems have taken into account the energy conversion efficiency of the fuel cell, and there is room for improvement.

JP2013-74689A

  The present invention has been made in view of the above circumstances, and the problem to be solved is to calculate the operation pattern of the power supply apparatus according to a predetermined purpose in consideration of the energy conversion efficiency of the fuel cell. It is to provide an energy management system and an energy management method that can be performed.

  The problem to be solved by the present invention is as described above. Next, means for solving the problem will be described.

前記制御装置は、前記燃料電池が消費する燃料の量と前記燃料電池が発電する電力量との関係から前記燃料電池発電係数及び前記燃料電池発電電力の定常損失を算出すると共に、前記燃料電池が消費する燃料の量と前記燃料電池が蓄熱する熱量との関係から前記燃料電池排熱回収係数及び前記燃料電池排熱回収量の定常損失を算出するものである。 That is, in claim 1, at least one power supply including a fuel cell that can generate power by consuming fuel and can store waste heat generated during power generation in a hot water storage tank. A power load that consumes electrical energy from the apparatus, a commercial power source and the power supply device, a thermal load that consumes thermal energy from the fuel cell, a pattern of electrical energy consumed by the power load in a predetermined period, and A control device that calculates an operation pattern of the power supply device according to a predetermined purpose based on a pattern of thermal energy consumed by the thermal load in the predetermined period, and can generate heat by consuming fuel. an energy management system comprising an auxiliary heat source, wherein the controller, when calculating the operation pattern of the power supply device, wherein While taking into account the energy conversion efficiency of the charge battery, when calculating the operation pattern of the power supply device, using a state space model represented in the following equation (1) up to 8,

The control device calculates the fuel cell power generation coefficient and the steady loss of the fuel cell generated power from the relationship between the amount of fuel consumed by the fuel cell and the amount of power generated by the fuel cell, and the fuel cell The fuel cell exhaust heat recovery coefficient and the steady loss of the fuel cell exhaust heat recovery amount are calculated from the relationship between the amount of fuel consumed and the amount of heat stored in the fuel cell .

  According to a second aspect of the present invention, the control device uses the relationship between the amount of fuel consumed by the fuel cell and the amount of power generated by the fuel cell as the energy conversion efficiency of the fuel cell.

  According to a third aspect of the present invention, the control device uses the relationship between the amount of fuel consumed by the fuel cell and the amount of heat stored in the fuel cell as the energy conversion efficiency of the fuel cell.

  According to a fourth aspect of the present invention, the power supply device includes a solar power generation unit capable of generating power using sunlight and / or a power storage device capable of charging and discharging power.

前記燃料電池が消費する燃料の量と前記燃料電池が発電する電力量との関係から前記燃料電池発電係数及び前記燃料電池発電電力の定常損失を算出すると共に、前記燃料電池が消費する燃料の量と前記燃料電池が蓄熱する熱量との関係から前記燃料電池排熱回収係数及び前記燃料電池排熱回収量の定常損失を算出するものである。 According to a fifth aspect of the present invention, there is provided at least one power supply device including a fuel cell that can generate power by consuming fuel and can store waste heat generated when generating power in a hot water storage tank. An energy management method for calculating an operation pattern, in which a power load that consumes electrical energy from a commercial power source and the power supply device consumes fuel and consumes electricity in a predetermined period, and generates heat. Power supply according to a predetermined purpose based on a pattern of thermal energy consumed in the predetermined period in a heat load that consumes thermal energy from the auxiliary heat source and the fuel cell, and an energy conversion efficiency of the fuel cell When calculating the operation pattern of the apparatus and calculating the operation pattern of the power supply apparatus, Using state space model represented by,

The fuel cell power generation coefficient and the steady loss of the fuel cell generated power are calculated from the relationship between the amount of fuel consumed by the fuel cell and the amount of power generated by the fuel cell, and the amount of fuel consumed by the fuel cell. The fuel cell exhaust heat recovery coefficient and the steady loss of the fuel cell exhaust heat recovery amount are calculated from the relationship between the amount of heat stored in the fuel cell and the amount of heat stored in the fuel cell .

  As effects of the present invention, the following effects can be obtained.

According to the first aspect, it is possible to calculate the operation pattern of the power supply apparatus according to a predetermined purpose in consideration of the energy conversion efficiency of the fuel cell. In addition, a mathematical programming method called a mixed integer programming problem can be used, and the most effective operation pattern for a predetermined purpose can be easily calculated.

  In claim 2, the energy conversion efficiency of the fuel cell can be simply expressed, and the energy conversion efficiency can be easily taken into consideration.

  In claim 3, the energy conversion efficiency of the fuel cell can be simply expressed, and the energy conversion efficiency can be easily taken into consideration.

  In Claim 4, the driving | operation pattern of the electric power supply apparatus containing a solar power generation part and / or an electrical storage apparatus is computable.

According to the fifth aspect , the operation pattern of the power supply device can be calculated according to a predetermined purpose in consideration of the energy conversion efficiency of the fuel cell. In addition, a mathematical programming method called a mixed integer programming problem can be used, and the most effective operation pattern for a predetermined purpose can be easily calculated.

The block diagram which showed the whole structure of the energy management system which concerns on 1st embodiment. The block diagram which showed the apparatus connected with the control apparatus of an energy management system. The figure which shows an electric power load pattern. The figure which shows a heat load pattern. (A) The figure which shows the relationship between fuel cell gas consumption and generated electric energy. (B) The figure which shows the relationship between the gas consumption of a fuel cell, and the collection | recovery amount of waste heat. (A) The figure which shows an electricity bill table. (B) The figure which shows a gas charge table. The figure which showed the operation example (thing regarding electric power) of the power supply apparatus according to the calculated driving | operation pattern. The figure which showed the operation example (thing regarding heat amount) of the electric power supply apparatus according to the calculated driving | operation pattern. The figure which showed the flow of design of the control method of an electric power supply apparatus. The figure which showed the energy loss of the fuel cell. The figure which showed the operation example (thing regarding electric power) of the electric power supply apparatus according to the corrected driving | operation pattern. The figure which showed the operation example (thing regarding calorie | heat amount) of the electric power supply apparatus according to the corrected driving | operation pattern. The block diagram which showed the modification using a center server. The figure which showed the flow which controls an energy management system in real time.

  First, the structure of the energy management system 1 which concerns on one Embodiment (1st embodiment) of this invention is demonstrated using FIG.1 and FIG.2.

  The energy management system 1 is provided in a house or the like, calculates an operation pattern (details will be described later) of the power supply device according to a predetermined purpose, and controls the operation of the power supply device based on the operation pattern. To do. The energy management system 1 mainly includes a solar power generation unit 2, a power storage device 3, a fuel cell 4, a power load 5, a heat load 6, and a control device 7.

  A solar power generation unit 2 shown in FIG. 1 is an embodiment of the power supply apparatus according to the present invention. The solar power generation unit 2 is a device that generates power using sunlight, which is natural energy, and is configured by a solar cell panel or the like. The solar power generation unit 10 is installed in a sunny place such as on the roof of a house, for example.

  The power storage device 3 is an embodiment of the power supply device according to the present invention. The power storage device 3 is a grid-connected power storage device (storage battery) that can charge and discharge power and is operated in a state of being connected to a commercial power source 11 (power system of a power company). The power storage device 3 is composed of a lithium ion battery or the like. The power storage device 3 is connected to the commercial power supply 11 while being connected to the commercial power supply 11, and can supply power to the power load 5 described later.

  The fuel cell 4 is an embodiment of the power supply apparatus according to the present invention. The fuel cell 4 is capable of generating power using supplied fuel (in this embodiment, gas fuel). Further, the fuel cell 4 includes a hot water storage tank (not shown), and uses the heat (exhaust heat) generated during power generation to boil the hot water in the hot water storage tank (that is, store the exhaust heat in the hot water storage tank). Can do. Further, the fuel cell 4 includes an auxiliary heat source (a hot water supply device that boils hot water using fuel) (not shown), and can boil hot water when necessary.

  The auxiliary heat source is not limited to the one provided in (inside) the fuel cell 4, and may be provided separately from the fuel cell 4.

  The electric power load 5 is an electric product or the like that is provided in the house or the like and consumes electric energy (electric power). For example, the power load 5 includes a lighting fixture, a television, a washing machine, and the like.

  The heat load 6 is provided in the house or the like and consumes heat energy. For example, the heat load 6 includes a hot water supply facility for supplying hot water, a heating facility such as floor heating, and the like.

  The control device 7 shown in FIG. 2 calculates the operation pattern of the power supply device based on various information, and controls the operation of the power supply device. As the control device 7, HEMS (Home Energy Management System) provided in a house or the like is used. The control device 7 is previously input with the unit price of the electricity charge and the gas charge.

  The control device 7 is connected to the solar power generation unit 2 and can receive various information related to the solar power generation unit 2 such as information related to the power generated by the solar power generation unit 2.

  The control device 7 is connected to the power storage device 3 and can receive various information related to the power storage device 3, such as information related to the amount of power charged in the power storage device 3 (power storage amount). Further, the control device 7 can issue commands for charging power and discharging power to the power storage device 3 to control the operation of the power storage device 3.

  The control device 7 is connected to the fuel cell 4 and relates to the fuel cell 4 such as information about the amount of hot water stored in the hot water storage tank of the fuel cell 4 and information about the amount of heat stored in the hot water storage tank (heat storage amount). Various information can be received. In addition, the control device 7 can issue a command to start and stop the fuel cell 4 and control the operation of the fuel cell 4.

  Next, an outline of the operation of the entire energy management system 1 configured as described above will be described.

  In the energy management system 1 (see FIG. 1), the electric power generated by the solar power generation unit 2 is appropriately supplied to the power storage device 3 and the power load 5. The surplus power (surplus power) out of the power generated by the solar power generation unit 2 is limited to the commercial power supply 11 (only when the power (system power) is not purchased (purchased) from the commercial power supply 11. Reverse power flow (to sell electricity).

The fuel cell 4 can generate power using gas fuel purchased from the gas company 12. The electric power generated by the fuel cell 4 is supplied to the power storage device 3 and the electric power load 5 as appropriate. Further, the fuel cell 4 collects the exhaust heat, boiles the hot water in the hot water storage tank, and supplies the hot water to the heat load 6 as appropriate. The fuel cell 4 boils hot water using the auxiliary heat source and supplies the hot water to the heat load 6 as appropriate when hot water is not accumulated in the hot water storage tank. The amount of heat in the hot water storage tank of the fuel cell 4 is discharged (discarded) to the outside as necessary.
In the present embodiment, the generated power of the fuel cell 4 is generated following the charging power of the power load 5 and the power storage device 3.

  The power storage device 3 charges power from the solar power generation unit 2 and the fuel cell 4 and power from the commercial power source 11. In addition, the power storage device 3 supplies charged power (power storage power) to the power load 5 as appropriate.

  The control device 7 calculates the operation pattern of each power supply device according to a predetermined purpose, and controls the operation of each power supply device (in particular, the power storage device 3 in the present embodiment) according to the operation pattern.

The electric power load 5 can operate by consuming electric power from the solar power generation unit 2, the power storage device 3 and the fuel cell 4, and electric power (electric energy) from the commercial power source 11.
Further, the heat load 6 can consume hot water (that is, thermal energy) from the fuel cell 4 (more specifically, the hot water storage tank and auxiliary heat source of the fuel cell 4).

  Next, modeling of the energy management system 1 for calculating operation patterns of the solar power generation unit 2, the power storage device 3, and the fuel cell 4 according to a predetermined purpose will be described.

  When modeling the energy management system 1, a time change pattern of power consumed by the power load 5 (power load pattern) and a time change pattern of heat energy consumed by the heat load 6 (heat It is assumed that the load pattern) is stored in the control device 7 in advance.

  In the present embodiment, it is assumed that the power load pattern shown in FIG. 3 and the heat load pattern shown in FIG. As the electric power load pattern and the thermal load pattern, it is possible to use data learned in advance, data estimated by the control device 7 (HEMS), or the like. As shown in the figure, the power load pattern and the thermal load pattern according to the present embodiment are assumed to be in a period of one day (from 0:00 to 24:00). In addition, it is assumed that the power load pattern and the heat load pattern are created using data obtained at intervals of 5 minutes.

  The energy management system 1 can be modeled by a state space model as shown in Equation 1 below.

  Here, t means time. In the present embodiment, since data obtained at intervals of 5 minutes are used as the power load pattern and the heat load pattern, the time is 0: 0 in the case of t = 0, and the data in the case of t = 1. It means time 0: 5, and when t = 2, it means time 0:10.

  Further, each variable and coefficient of the above equation 1 are expressed by the following equations 2 to 8.

  The state of supply of each input amount in Equation 3 is shown in FIG. Hereinafter, the input amount represented by the above formula 3 is referred to as an “operation pattern” of the power supply device (solar power generation unit 2, power storage device 3, and fuel cell 4) according to the present embodiment.

It is assumed that the value of the coefficient in consideration of self-discharge of power storage device 3 in Equation 5 is normally 1 (in the case where reduction in the amount of power stored in power storage device 3 due to self-discharge is not considered). When considering a decrease in the amount of power stored in the power storage device 3 due to self-discharge, the value of the coefficient considering the self-discharge of the power storage device 3 is set to a value smaller than 1.
In addition, the value of the coefficient in consideration of the heat dissipation of the hot water storage tank of the fuel cell 4 in the above equation 5 is normally 1 (when the heat dissipation from the hot water storage tank is not considered). When considering the heat dissipation (loss) from the hot water storage tank, the value of the coefficient considering the heat dissipation of the hot water storage tank of the fuel cell 4 is set to a value smaller than 1.

  Note that the power storage device charging efficiency, the power storage device discharge efficiency, and the auxiliary heat source heat generation coefficient in Equations 6 and 7 are values determined in advance based on the performance of the auxiliary heat source of the power storage device 3 and the fuel cell 4. These values are stored in the control device 7 in advance.

  Here, the fuel cell power generation coefficient, the fuel cell exhaust heat recovery coefficient, the steady loss of the fuel cell generated power, and the steady loss of the fuel cell exhaust heat recovery amount in the above formulas 6, 7, and 8 will be described below.

  The fuel cell power generation coefficient, the fuel cell exhaust heat recovery coefficient, the steady loss of the fuel cell generated power, and the steady loss of the fuel cell exhaust heat recovery amount are determined by modeling the performance (energy conversion efficiency) of the fuel cell 4. The

  Specifically, as shown in FIG. 5A, the relationship between the amount of gas (gas fuel) consumption of the fuel cell 4 and the amount of power generated by the fuel cell 4 is expressed as the output of the fuel cell 4 (in this embodiment). Is measured a plurality of times by changing 50 (W), 200 (W), 500 (W) and 700 (W)). As a measurement method, the output of the fuel cell 4 is set to one point (50 (W), 200 (W), etc.), and the amount of generated power and gas consumption for a certain time (for example, 1 hour or 1 day) are measured. The generated power amount and the gas consumption amount are converted into desired time intervals. For example, in the case of measuring for 1 hour and converting to a time interval of 5 minutes (interval matched with the data interval of the power load pattern and the thermal load pattern), the measured power generation amount and gas consumption amount are 12 respectively. It can be obtained by dividing. In this embodiment, the time interval is converted to a time interval of 5 minutes. Then, the relationship between the gas consumption amount of the fuel cell 4 and the power generation amount of the fuel cell 4 at each output is approximated by one straight line (see the broken line in FIG. 5A). In the approximate expression representing this straight line, ba is the fuel cell power generation coefficient, and e1 is the steady loss of the fuel cell power generation.

  Further, as shown in FIG. 5B, the relationship between the amount of gas (gas fuel) consumed by the fuel cell 4 and the amount of exhaust heat recovered from the fuel cell 4 (the amount of heat stored in the hot water storage tank) Change the output of 4 and measure multiple times. Here, in this embodiment, it is assumed that the time interval of 5 minutes is converted in the same manner as described above (relation between the gas consumption amount of the fuel cell 4 and the power generation amount of the fuel cell 4). Then, the relationship between the gas consumption amount of the fuel cell 4 and the exhaust heat recovery amount of the fuel cell 4 at each output is approximated by one straight line (see the broken line in FIG. 5B). In the approximate expression representing this straight line, bb is the fuel cell exhaust heat recovery coefficient, and e2 is the steady loss of the fuel cell exhaust heat recovery amount.

  The fuel cell power generation coefficient, the fuel cell exhaust heat recovery coefficient, the steady loss of the fuel cell generated power, and the steady loss of the fuel cell exhaust heat recovery amount are calculated in advance and stored in the control device 7.

  Thus, the performance (energy conversion efficiency) of the fuel cell 4 can be linearly approximated by expressing the relationship between the gas consumption and the amount of generated power, and the relationship between the gas consumption and the exhaust heat recovery amount. , Making the calculation easier. Further, the intercept of each straight line calculated at this time (the steady loss e1 of the fuel cell generated power and the steady loss e2 of the fuel cell exhaust heat recovery amount) is consumed by the fuel cell 4 itself to operate the fuel cell 4. Energy.

  Next, the constraint conditions of the energy management system 1 will be described.

  In the energy management system 1 modeled as described above, the following constraint conditions from Equation 9 to Equation 13 are set.

  Here, “the upper limit of the heat storage amount of the hot water storage tank of the fuel cell” in the above formula 9 is “(hot water supply temperature (temperature of hot water supplied to the thermal load 6)) − tap water temperature (before being heated by the fuel cell 4). Water temperature)) × hot water storage tank capacity × specific heat ”.

Here, the “binary variable” in Equation 10 is a variable that takes only one value of 0 or 1. The binary variable takes a value of 1 when the fuel cell 4 is operated (that is, generating power) and takes a value of 0 when the fuel cell 4 is not operated.
Further, the “minimum output” and the “maximum output” in the above formula 10 mean the minimum output and the maximum output of the fuel cell 4 when the fuel cell 4 is operating.

  The above formula 10 means the limit of the power generated by the fuel cell 4.

  Here, the “binary variable” in Equation 11 is a variable that takes only one value of 0 or 1. The binary variable takes a value of 1 when the power storage device 3 is discharged and 0 in other cases.

  The above formula 11 means that the power storage device 3 is not charged and discharged at the same time, and the maximum charge power amount and the maximum discharge power amount of the power storage device 3 are limited.

  Here, the “binary variable” in Equation 12 is a variable that takes only one value of 0 or 1.

  The above equation (12) means a restriction that power purchase from the commercial power supply 11 and power sale from the solar power generation unit 2 to the commercial power supply 11 are not performed simultaneously.

  Note that, among the constraint conditions of the above formulas 9 to 13, values not particularly mentioned are values determined from the performance of each device (power storage device 3 and the like). These values are stored in the control device 7 in advance.

  Next, an evaluation function for calculating an operation pattern of the power supply apparatus according to a predetermined purpose will be described.

  The evaluation function of the energy management system 1 according to the present embodiment can be expressed as the following Expression 14.

  Here, as the values of l1, l2, l3, l4, l5, and l11 in the above equation 14, values according to the purpose (predetermined purpose) of operation of the energy management system 1 are input. In the present embodiment, the energy management system 1 is intended to “minimize utility costs”. In this case, the value shown in the following Expression 15 is input to the Expression 14.

  Here, the grid power (electricity) charge unit price and the gas charge unit price in the above equation 15 are the electricity charge table shown in FIG. 6A (a metered light in this embodiment) and the gas charge shown in FIG. Predetermined from the table. Specifically, each unit price is determined from the approximate values of the amount of electricity (electricity consumption) and gas consumption estimated to be consumed by the energy management system 1 from past data and the like, and the control device 7 in advance. Remember me.

  In addition to the above, the method for determining each unit price is based on the method of determining the current unit price based on the accumulated usage for the current month (this month), and the model that the unit price changes according to the usage. There are also ways to reflect this.

  Under the conditions as described above, the control device 7 calculates an input amount (see Equation 3 above) that minimizes the evaluation function (see Equation 14 above). By operating each power supply device so as to have the calculated input amount (operation pattern), it is possible to achieve a predetermined object, that is, the object of “minimizing utility costs” in the present embodiment.

Next, an example of the operation pattern of the power supply device calculated using the above evaluation function will be specifically described.
In the present embodiment, for convenience of explanation, it is assumed that there is no power generation by the solar power generation unit 2.

  7 and 8 show examples of the operation pattern of the power supply device calculated using the above-described evaluation function. Since the fuel cell 4 generates power following the power load 5, the control device 7 controls only the charge amount and discharge amount of the power storage device 3, thereby controlling each power supply device according to the calculated operation pattern. Is possible. That is, it is not necessary to install a learning function or the like in the fuel cell 4.

  As shown in FIG. 7, when there is a margin in the output of the fuel cell 4, the power from the fuel cell 4 is charged in the power storage device 3. When the power required from the power load 5 exceeds the maximum output of the fuel cell 4, the power storage device 3 is discharged and the power from the power storage device 3 is supplied to the power load 5. With such an operation pattern, the purchase (purchase) of power from the commercial power supply 11 is suppressed to zero.

  In addition, as shown in FIG. 8, the amount of heat stored in the hot water storage tank increases as the fuel cell 4 generates power. Although the amount of heat stored in the hot water storage tank reaches the upper limit at a certain time (around 16:00), the fuel cell 4 continues to generate power thereafter (see after 16:00 in FIG. 7). In this way, if the fuel cell 4 continues to generate power in a state where the amount of heat stored in the hot water storage tank has reached the upper limit, the exhaust heat of the fuel cell 4 during that time is discarded and wasted. However, in this embodiment, it is determined that the utility cost can be minimized by continuing the power generation of the fuel cell 4.

  Next, a specific usage method of the above-described method for calculating the operation pattern of the power supply apparatus will be described.

  The above-described method for calculating the operation pattern of the power supply apparatus can be used when actually considering and designing the control method of the power supply apparatus. That is, a control method is designed in advance using the calculation method, and each device of the energy management system 1 provided in a house or the like is controlled based on the designed control method. FIG. 9 shows the flow up to the design.

  First, the control apparatus 7 is made to read an electric power load pattern and a thermal load pattern (refer FIG.3 and FIG.4) (step S101). Next, a gas company, a power company, and a contract menu are selected (steps S102 and S103). Next, based on the contract menu, the electric power unit price and the gas unit price (see FIG. 6) are read by the control device 7 (step S104).

  Next, based on the given conditions (see Step S101 and Step S104) by the control device 7, an optimum operation pattern corresponding to a predetermined purpose (in this embodiment, minimizing the utility cost) is set. Calculated (step S105).

  After the operation pattern is calculated, if calculation in another contract menu (step S106) or calculation in another gas company and electric power company (step S107) is necessary, the process returns to step SS102 or step S103, and the condition is again satisfied. Is reset and the operation pattern is calculated.

  When the calculation of the operation pattern under necessary conditions is completed, the calculation result is output (step S108), and the actual operation method of the energy management system 1 is examined based on the output calculation result (S109). . In this way, the method for calculating the operation pattern of the power supply apparatus described above can be used to study the control method for the power supply apparatus and to design an optimal operation pattern.

  By designing the operation pattern in this way, the designed operation pattern and the contract menu of the electric power company and the gas company at that time can be combined and proposed to the customer when selling the energy management system 1. Moreover, after the energy management system 1 is sold, the optimum operation pattern and the contract menus of the power company and the gas company can be proposed again from the customer's life data (power load pattern and heat load pattern).

  Next, a case where correction is further made to the operation pattern of the power supply device calculated using the above-described evaluation function will be described.

  For example, as shown in FIG. 10, the fuel cell 4 has a smaller loss as its output (generated power) increases. Further, since it is sometimes difficult to change the output of the fuel cell 4 in response to a sudden change in the power load 5, it is preferable that the fluctuation of the output is small.

  Therefore, the calculated operation pattern (see FIGS. 7 and 8) is modified and designed as shown in FIGS. FIG. 11 shows only the power load pattern and the output power of the fuel cell 4 for convenience. Specifically, a lower limit (minimum output) is provided for the output of the fuel cell 4 except for midnight (from 23:00 to 0:00). Thus, the loss of the fuel cell 4 can be reduced by maintaining the output of the fuel cell 4 at or above the lower limit value. At this time, the power remaining in the time zone in which the amount of power consumed by the power load 5 is small is charged in the power storage device 3.

  Further, in a time zone (from 20:00 to 22:00) in which the amount of heat energy consumed by the heat load 6 is large (see FIG. 12), the fuel cell 4 does not follow the power load 5 and has a rated output (maximum output). ) Has been modified to drive. Thus, exhaust heat can be continuously stored in the hot water storage tank during a time zone in which the amount of heat energy consumed is large. Furthermore, the fuel cell 4 is operated again so as to follow the power load 5 in a time period (from 23:00 to 0:00) in which the amount of heat energy consumed is small.

  In this way, by further arbitrarily correcting the calculated operation pattern, it is possible to control each device (power supply device) of the energy management system 1 in accordance with the purpose.

As described above, the energy management system 1 according to the present embodiment is
At least one power supply device including a fuel cell 4 capable of generating power while consuming fuel and capable of storing exhaust heat generated when generating power in a hot water storage tank;
A power load 5 that consumes electrical energy from the commercial power supply 11 and the power supply device;
A heat load 6 that consumes heat energy from the fuel cell 4, and
Based on a pattern of electrical energy consumed by the power load 5 in a predetermined period (one day) (FIG. 3) and a pattern of thermal energy consumed by the heat load 6 in the predetermined period (FIG. 4), a predetermined purpose is achieved. A control device 7 that calculates an operation pattern (the number 3) of the power supply device in response,
An energy management system 1 comprising:
The control device 7
The energy conversion efficiency of the fuel cell 4 is taken into account when calculating the operation pattern of the power supply device.
With this configuration, the operation pattern of the power supply device can be calculated according to a predetermined purpose in consideration of the energy conversion efficiency of the fuel cell 4. As a result, the energy management system 1 can be operated more efficiently.

In addition, the control device 7
As the energy conversion efficiency of the fuel cell 4,
The relationship between the amount of fuel consumed by the fuel cell 4 and the amount of electric power generated by the fuel cell 4 (FIG. 5A) is used.
By comprising in this way, the energy conversion efficiency of the fuel cell 4 can be represented simply, and the said energy conversion efficiency can be considered easily.

In addition, the control device 7
As the energy conversion efficiency of the fuel cell 4,
The relationship between the amount of fuel consumed by the fuel cell 4 and the amount of heat stored in the fuel cell 4 (FIG. 5B) is used.
By comprising in this way, the energy conversion efficiency of the fuel cell 4 can be represented simply, and the said energy conversion efficiency can be considered easily.

The power supply device includes:
It includes a solar power generation unit 2 capable of generating power using sunlight and / or a power storage device 3 capable of charging and discharging power.
By comprising in this way, the driving | running pattern of the electric power supply apparatus containing the solar power generation part 2 and / or the electrical storage apparatus 3 is computable.

In addition, the energy management system 1
An auxiliary heat source capable of generating heat by consuming fuel;
The control device 7
When calculating the operation pattern of the power supply device, using the state space model expressed by the above equations 1 to 8,
The control device 7 calculates the fuel cell power generation coefficient and the steady loss of the fuel cell generated power from the relationship between the amount of fuel consumed by the fuel cell 4 and the amount of power generated by the fuel cell 4, and the fuel cell 4 The fuel cell exhaust heat recovery coefficient and the steady loss of the fuel cell exhaust heat recovery amount are calculated from the relationship between the amount of fuel consumed and the amount of heat stored in the fuel cell 4.
With this configuration, a mathematical programming method called a mixed integer programming problem can be used, and the most effective operation pattern for a predetermined purpose can be easily calculated.

In addition, the energy management method according to the present embodiment is as follows.
An operation pattern of at least one power supply device including the fuel cell 4 that can generate power while consuming fuel and can store waste heat generated when generating power in a hot water storage tank is calculated. An energy management method,
A pattern of electrical energy consumed in a predetermined period (one day) in the power load 5 that consumes electrical energy from the commercial power supply 11 and the power supply device (FIG. 3), and heat that consumes thermal energy from the fuel cell 4 Based on the thermal energy pattern (FIG. 4) consumed in the predetermined period in the load 6 and the energy conversion efficiency of the fuel cell 4, the operation pattern of the power supply device corresponding to a predetermined purpose is calculated. .
With this configuration, the operation pattern of the power supply device can be calculated according to a predetermined purpose in consideration of the energy conversion efficiency of the fuel cell 4.

  Below, the modification (other embodiment) of the energy management system 1 which concerns on the above-mentioned 1st embodiment is demonstrated.

  In the first embodiment, as shown in FIG. 2, the operation pattern is calculated in the control device 7 (HEMS) provided in a house or the like. However, as shown in FIG. 13, it is also possible to adopt a configuration in which the driving pattern is calculated in the center server 8 provided outside the house or the like. In this case, information such as the unit price of electricity is input to the center server 8, and the operation pattern of the power supply device is calculated by the center server 8. The calculated operation pattern is transmitted to the control device 7, and the control device 7 controls the power storage device 3 and the like.

  Thus, by calculating a driving pattern with the center server 8, driving patterns of a plurality of houses and the like can be calculated in a lump. This eliminates the need for calculation at each house and the like, thereby reducing costs for the calculation (time cost and equipment cost).

  In the first embodiment, the fuel cell power generation coefficient, the fuel cell exhaust heat recovery coefficient, the steady loss of the fuel cell generated power, and the steady loss of the fuel cell exhaust heat recovery amount are determined in the above formulas 6, 7, and 8. In this case, as shown in FIGS. 5A and 5B, an approximate expression approximated by one straight line is used. However, the points of 50 (W), 200 (W), 500 (W), and 700 (W) are connected by a straight line in order to obtain an expression representing each straight line, and the expression of each straight line is determined according to the output of the fuel cell 4. It is also possible to use a different structure.

  For example, when the output of the fuel cell 4 is 400 (W), a straight line connecting the point of 200 (W) and the point of 500 (W) is used. Further, when the output of the fuel cell 4 is 600 (W), a straight line connecting the point of 500 (W) and the point of 700 (W) is used. By configuring in this way, calculation is complicated, but calculation with higher accuracy is possible.

  In the first embodiment, “minimizing utility costs” is set as the operation purpose (predetermined purpose) of the energy management system 1, but other purposes can also be set.

  For example, for the purpose of “minimizing primary energy consumption”, the value shown in the following Expression 16 is input to the Expression 14.

  Here, the value of l11 is for considering the electric power to be sold out of the electric power generated by the solar power generation unit 2, but in the revised Energy Saving Law, the electric power sold is consumed as the primary energy consumption. The value is 0 because it is not considered to reduce the amount.

  Further, for example, when the purpose is to “minimize CO2 emission”, the value shown in the following Expression 17 is input to the Expression 14 above.

  Here, the value of l11 is 0 as in the case of Equation 16.

  As described above, by appropriately changing the value input in the above equation 14, it is possible to easily calculate an operation pattern according to an arbitrary purpose.

  Similarly to the first embodiment, even when the purpose of the operation of the energy management system 1 is to “minimize the utility cost”, the electricity rate table shows the unit price of the electricity according to the amount of electricity used. In the case of a time charging lamp in which the unit price of charge changes depending on the time zone instead of a changing metering lamp (see FIG. 6A), the following equation 18 is used as the evaluation function.

  In the above equation 18, the value shown in the following equation 19 is input.

  By using such an evaluation function, it is possible to cope with the case where the electric power contract with the electric power company is a time charging lamp.

  Moreover, in 1st embodiment, the control method of an electric power supply apparatus is designed beforehand using the calculation method of the operation pattern of an electric power supply apparatus (refer FIG. 9), and the energy management system 1 is based on the designed control method. An example in which is controlled. However, it is also possible to directly control the energy management system 1 using the calculated operation pattern (control in real time).

  In this case, as shown in FIG. 14, first, the control device 7 is made to read the power load pattern and the thermal load pattern (see FIGS. 3 and 4), the unit price of electricity and the unit price of gas (see FIG. 6) (step). S201 and step S202). Next, an optimal operation pattern corresponding to a predetermined purpose is calculated by the control device 7 based on the given condition (step S203). Finally, an operation command based on the calculated operation pattern is transmitted from the control device 7 to the power storage device 3 and the fuel cell 4 (step S204), and the operation of the power storage device 3 and the like is controlled.

  In addition, in this embodiment, although the solar power generation part 2, the electrical storage apparatus 3, and the fuel cell 4 were illustrated as an electric power supply apparatus, this invention is not limited to this. That is, it is possible to adopt a configuration in which another device (for example, a wind power generator or the like) is used as the power supply device.

  In addition, although the power storage device 3 is constituted by a lithium ion battery or the like, the present invention is not limited to this, and can be constituted by a nickel / hydrogen battery or the like.

  Moreover, in the said embodiment, although it described that it was not necessary to mount the learning function in the fuel cell 4, this invention is not limited to this. For example, it is also possible to employ a configuration in which a learning function is mounted on the fuel cell 4 and an electric power load pattern and a thermal load pattern are estimated using the learning function.

  Moreover, in the said embodiment, although the period of the electric power load pattern and thermal load pattern memorize | stored in the control apparatus 7 shall be 1 day (from 0:00 to 24:00), this invention is not limited to this. Absent. For example, it is possible to use a power load pattern and a heat load pattern for a period of one week or one month.

  In addition, when the operation pattern is calculated in real time and used for control as shown in FIG. 14, the estimated values of the power load pattern and the thermal load pattern stored in advance are used as the actually measured power load pattern and the thermal load. It is also possible to make a configuration in which correction is made based on the pattern and the operation pattern is recalculated each time.

  In the above embodiment, the data interval between the power load pattern and the thermal load pattern is 5 minutes, but the present invention is not limited to this. For example, the data interval can be set to 1 hour or the like. By increasing the data interval, the number of calculations can be reduced. However, when changing the data interval, it is necessary to change the coefficient of the model of the energy management system 1.

  Specifically, when the data interval is 1 hour (60 minutes), the approximate expressions shown in FIGS. 5A and 5B are changed to the following equations 20 and 21, respectively. .

  Thus, the coefficients (e1 and e2) when the data interval between the power load pattern and the thermal load pattern is 5 minutes are converted into the coefficients (e1 ′ and e2 ′) when the data interval is 1 hour (60 minutes). .

  Further, the above formula 10 is changed to the following formula 22.

  Further, in the above-described embodiment, the constraint conditions from the above formula 9 to the formula 13 are set, but the following constraint condition of the formula 23 (the fuel cell 4 is operated continuously and as necessary) It is also possible to set a constraint condition for limiting the operation time.

  Here, the “binary variable” in Equation 23 is a variable that takes only one value of 0 or 1.

  Further, in the above equation 23, for example, when the period for calculating the operation pattern is one day and the fuel cell 4 can be activated only once a day, λ = 1.

  In Equation 23, γ is calculated by “maximum operating time of the fuel cell 4” ÷ “data interval (time interval)”. For example, when the fuel cell 4 can only operate for 12 hours per day and the data interval is 5 minutes, γ = 12 ÷ (1/12) = 144.

  By setting the constraint condition as shown in Equation 23, the operation of the fuel cell 4 can be made closer to the actual operation. That is, once the fuel cell 4 starts (starts up) power generation, it cannot be easily stopped (stopped). Further, repeating the start and stop in a short time is a factor for shortening the life of the fuel cell 4. Therefore, by setting the constraint condition of Equation 23, the fuel cell 4 can be operated continuously, and the operation time can be limited as necessary (in the above example, for example, one day).

1 Energy management system 2 Solar power generation unit (power supply device)
3 Power storage device (power supply device)
4 Fuel cell (power supply device)
5 Electric power load 6 Thermal load 7 Control device

Claims (5)

At least one power supply device including a fuel cell capable of consuming electric power and generating electric power and storing exhaust heat generated when generating electric power in a hot water storage tank;
A power load that consumes electrical energy from a commercial power source and the power supply device; and
A heat load consuming heat energy from the fuel cell;
Based on a pattern of electrical energy consumed by the power load during a predetermined period and a pattern of thermal energy consumed by the thermal load during the predetermined period, an operation pattern of the power supply device corresponding to a predetermined purpose is calculated. A control device;
An auxiliary heat source capable of generating heat by consuming fuel;
An energy management system comprising:
The controller is
When calculating the operation pattern of the power supply apparatus, the energy conversion efficiency of the fuel cell is taken into account , and when calculating the operation pattern of the power supply apparatus, the following Expressions 1 to 8 are expressed. Using a state space model,

The control device calculates the fuel cell power generation coefficient and the steady loss of the fuel cell generated power from the relationship between the amount of fuel consumed by the fuel cell and the amount of power generated by the fuel cell, and the fuel cell The fuel cell exhaust heat recovery coefficient and the steady loss of the fuel cell exhaust heat recovery amount are calculated from the relationship between the amount of fuel consumed and the amount of heat stored in the fuel cell ,
Energy management system. The controller is
As the energy conversion efficiency of the fuel cell,
The relationship between the amount of fuel consumed by the fuel cell and the amount of power generated by the fuel cell is used,
The energy management system according to claim 1. The controller is
As the energy conversion efficiency of the fuel cell,
The relationship between the amount of fuel consumed by the fuel cell and the amount of heat stored in the fuel cell is used,
The energy management system according to claim 1 or 2. The power supply device
Including a solar power generation unit capable of generating power using sunlight and / or a power storage device capable of charging and discharging power,
The energy management system according to any one of claims 1 to 3. Energy for calculating an operation pattern of at least one power supply device including a fuel cell that can generate power by consuming fuel and can store waste heat generated during power generation in a hot water storage tank A management method,
A pattern of electrical energy consumed in a predetermined period in a power load that consumes electrical energy from a commercial power source and the power supply device, an auxiliary heat source capable of generating heat by consuming fuel, and thermal energy from the fuel cell Based on the thermal energy pattern consumed in the predetermined period in the heat load to be consumed and the energy conversion efficiency of the fuel cell, the operation pattern of the power supply device corresponding to a predetermined purpose is calculated, and the power supply When calculating the operation pattern of the device, using the state space model represented by the following equations 1 to 8,

The fuel cell power generation coefficient and the steady loss of the fuel cell generated power are calculated from the relationship between the amount of fuel consumed by the fuel cell and the amount of power generated by the fuel cell, and the amount of fuel consumed by the fuel cell. And the fuel cell exhaust heat recovery coefficient and the steady loss of the fuel cell exhaust heat recovery amount are calculated from the relationship between the amount of heat stored in the fuel cell and the amount of heat stored in the fuel cell,
Energy management method.

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