Cogeneration system for controlling fuel cell devices based on operation mode

The invention claimed is: 1. A cogeneration system, comprising: a plurality of fuel cell devices supplying heat and power to a heat load and a power load; and a control device connected to the fuel cell devices, the control device programmed to calculate a heat demand value of the heat load, to determine an operation mode of the fuel cell devices on the basis of at least one of the calculated heat demand value of the heat load and a power demand value of the power load, wherein the heat load receives the heat from the plurality of fuel cell devices and the power load receives the power from the plurality of fuel cell devices, and to control a power generation efficiency and a heat recovery efficiency by controlling the fuel cell devices on the basis of the operation mode determined, to calculate the heat demand value and the power demand value on the basis of at least one of weather, gas rate, power selling or purchasing rate, break-even point of a consumer facility, day of week, degradation degree of the fuel cell devices, time of day, or gas consumption, wherein in response to the calculated heat demand value being smaller than a first predetermined value, the control device is programmed to determine a power generation efficiency priority mode as the operation mode, wherein, under the power generation efficiency priority mode, the control device is programmed to control the fuel cell devices to maximize power generation efficiency by controlling power generation amounts of the fuel cell devices to be the same, in response to the calculated heat demand value being equal to or greater than a second predetermined value that is greater than the first predetermined value, the control device is programmed to determine a heat recovery priority mode as the operation mode, wherein, under the heat recovery priority mode, the control device is programmed to control the fuel cell devices to maximize heat recovery efficiency by controlling a power generation amount of at least one of the plurality of fuel cell devices to become zero, the power generation efficiency is a ratio of a total electrical power generation amount to a gas consumption amount of the fuel cell devices, the heat recovery efficiency is a ratio of a total heat recovery amount to the gas consumption amount of the fuel cell devices, and when a power load factor increases, the power generation efficiency increases while the heat recovery efficiency decreases, the power load factor indicating a maximum power generation amount of the fuel cell devices. 2. The cogeneration system according to claim 1 , wherein the plurality of fuel cell devices is connected to a grid, and when power supply from the grid is disconnected, the control device is further programmed to control the plurality of fuel cell devices to supply heat or power preferentially to a load whose priority is set higher than other loads. 3. The cogeneration system according to claim 1 , wherein the control device is further programmed to calculate the heat demand value and the power demand value on the basis of a heat recovery target value and a power generation target value, respectively. 4. The cogeneration system according to claim 3 , wherein the control device is further programmed to determine the heat recovery target value on the basis of a heat storage capacity of a hot water tank contained in the heat load. 5. The cogeneration system according to claim 1 , wherein the control device is further programmed to: calculate a past cumulative total value of a life parameter on the basis of a value obtained by multiplying a power generation amount by a power generation hour with respect to each of the plurality of fuel cell devices or on the basis of a number of start-stop times with respect to each of the plurality of fuel cell devices, create an operation schedule for each of the plurality of fuel cell devices so that a difference in total of life parameter value is minimized, and operate each of the plurality of fuel cell devices on the basis of its respective operation schedule. 6. The cogeneration system according to claim 5 , wherein, when the control device stops operation of one of the plurality of fuel cell devices on the basis of the operation schedule, the control device is further programmed to add a predetermined value to a life parameter of the one of the plurality of fuel cell devices whose operation is stopped. 7. The cogeneration system according to claim 1 , wherein the control device is further programmed to: set a priority with respect to each of the plurality of fuel cell devices in decreasing order of cumulative power generation amount, determine an operation schedule of the plurality of fuel cell devices or an output of one of the plurality of fuel cell devices to be controlled immediately by assigning a power load factor corresponding to the priority, and control the plurality of fuel cell devices on the basis of the operation schedule. 8. The cogeneration system according to claim 1 , wherein each of the plurality of fuel cell devices is connected to a corresponding heat load, and the control device is further programmed to control the plurality of fuel cell devices depending on a heat demand with respect to each heat load. 9. A control method of a control device in a cogeneration system, the cogeneration system comprising a plurality of fuel cell devices supplying heat and power to a heat load and a power load, the control device connected to the fuel cell devices, the method comprising: calculating, by the control device, a heat demand value of the heat load; determining, by the control device, an operation mode of the fuel cell devices on the basis of at least one of the calculated heat demand value of the heat load and a power demand value of the power load, wherein the heat load receives the heat from the plurality of fuel cell devices and the power load receives the power from the plurality of fuel cell devices; calculating the heat demand value and the power demand value on the basis of at least one of weather, gas rate, power selling or purchasing rate, break-even point of a consumer facility, day of week, degradation degree of the fuel cell devices, time of day, or gas consumption, controlling, by the control device, a power generation efficiency and a heat recovery efficiency by controlling the plurality of fuel cell devices on the basis of the operation mode determined, wherein said controlling comprises: in response to the calculated heat demand value being smaller than a first predetermined value, determining a power generation efficiency priority mode as the operation mode, under the power generation efficiency priority mode, controlling the fuel cell devices to maximize power generation efficiency by controlling power generation amounts of the fuel cell devices to be the same, in response to the calculated heat demand value being equal to or greater than a second predetermined value that is greater than the first predetermined value, determining a heat recovery priority mode as the operation mode, and under the heat recovery priority mode, controlling the fuel cell devices to maximize heat recovery efficiency by controlling a power generation amount of at least one of the plurality of fuel cell devices to become zero, wherein the power generation efficiency is a ratio of a total electrical power generation amount to a gas consumption amount of the fuel cell devices, the heat recovery efficiency is a ratio of a total heat recovery amount to the gas consumption amount of the fuel cell devices, and when a power load factor increases, the power generation efficiency increases while the heat recovery efficiency decreases, the power load factor indicating a m