JP7103114B2 - Boiler system - Google Patents

Description

The present invention relates to a boiler system.

A technique has been proposed in which the water supply is heated by using the heat of the heat source water and the generated hot water is supplied to the hot water tank of the boiler. By supplying the hot water from the hot water tank to the boiler, the fuel required to generate steam in the boiler is reduced. Patent Document 1 discloses a technique relating to constant outlet temperature control for adjusting the flow rate of water supply so that the temperature of the generated hot water is maintained at a target temperature.

Japanese Unexamined Patent Publication No. 2017-146033

If the water supply requirement of the boiler increases sharply, the hot water tank will be in a low water level close to drought, and there is a concern that the operation of the boiler cannot be continued. If cold water is replenished to the hot water tank in order to eliminate the low water level state of the hot water tank, the water temperature of the hot water tank will drop and the fuel reduction effect in the boiler will be reduced.

An object of the present invention is to provide a boiler system capable of preventing a low water state of a hot water tank and a decrease in water temperature.

According to the aspect of the present invention, a boiler group composed of a plurality of boilers, a steam header for collecting steam generated in the boiler group, and a combustion state of the boiler group based on the steam pressure inside the steam header. A first unit control means for controlling the above, a water supply heating unit group composed of a plurality of water supply heating units, a hot water tank that stores hot water generated by the water supply heating unit group and supplies the hot water to the boiler group. The second number control means includes a water level detecting means for detecting the water level of the hot water tank and a second number control means for controlling the number of operating units of the water supply heating unit group, and the second number control means is the detection water level of the water level detecting means. Based on the value, the number determination unit that determines the basic operation number of the water supply and heating unit group and the operation information of the boiler group acquired from the first unit control means are used to correct the basic operation number. It has a number correction unit for deriving the corrected operation number, and an operation command unit for instructing each machine of the water supply heating unit group to operate or stop based on the corrected operation number derived by the number correction unit. , Boiler system is provided.

According to the aspect of the present invention, there is provided a boiler system capable of preventing a low water level state of a hot water tank and a decrease in water temperature.

FIG. 1 is a schematic view showing an example of a boiler system according to the first embodiment. FIG. 2 is a functional block diagram showing an example of the boiler system according to the first embodiment. FIG. 3 is a diagram for explaining a control method of the boiler system according to the first embodiment. FIG. 4 is a flowchart for explaining a control method of the boiler system according to the first embodiment. FIG. 5 is a flowchart for explaining a control method of the boiler system according to the first embodiment. FIG. 6 is a flowchart for explaining a control method of the boiler system according to the second embodiment. FIG. 7 is a block diagram showing an example of a computer system. FIG. 8 is a schematic view showing an example of a heat exchanger according to another embodiment.

Hereinafter, embodiments according to the present invention will be described with reference to the drawings, but the present invention is not limited thereto. The components of the embodiments described below can be combined as appropriate. In addition, some components may not be used.

[1] First Embodiment <Boiler system>
FIG. 1 is a diagram schematically showing an example of a boiler system 100 according to the present embodiment. The boiler system 100 is installed in an industrial facility such as a factory.

The boiler system 100 controls the combustion state of the boiler group 60 composed of a plurality of boilers 52, the steam header 61 that collects the steam generated by the boiler group 60, and the steam pressure in the steam header 61. A first unit control device 70, a water supply heating unit group 20 composed of a plurality of water supply heating units 1, a water supply tank 2 for storing water supply CW, a heat source water tank 3 for storing heat source water SW, and water supply addition. The hot water tank 51 that stores the hot water HW generated by the hot unit group 20 and supplies it to the boiler group 60, the water level sensor 50 that detects the water level of the hot water tank 51, and the number of operating units of the water supply heating unit group 20 are controlled. A second unit control device 30 is provided.

Further, the boiler system 100 includes a water supply flow path 10 that connects the water supply tank 2 and each of the plurality of water supply and heating units 1, and a hot water flow path that connects each of the plurality of water supply and heating units 1 and the hot water tank 51. It has a bypass flow path 12 connecting the water supply tank 2 and the hot water tank 51, and a heat source water flow path 13 connecting the heat source water tank 3 and each of the plurality of water supply heating units 1.

The boiler group 60 is composed of a plurality of boilers 52. In the example shown in FIG. 1, the boiler group 60 includes two boilers 52. The number of boilers 52 constituting the boiler group 60 may be any number of 3 or more. Each of the plurality of boilers 52 has the same maximum evaporation amount and combustion control.

The hot water tank 51 stores the hot water HW generated by the water supply heating unit 1. The hot water tank 51 is connected to the water supply heating unit 1 via the hot water flow path 11. Further, the hot water tank 51 is connected to the boiler 52 via the hot water flow path 53. A hot water pump 54 is provided in the hot water flow path 53. By driving the hot water pump 54, the hot water HW of the hot water tank 51 is supplied to the boiler 52.

The boiler 52 is a steam boiler. The boiler 52 heats the hot water HW supplied from the hot water tank 51 to generate steam. By supplying the hot water HW of the hot water tank 51 to the boiler 52, the fuel required for generating steam in the boiler 52 is reduced. The steam generated in the boiler 52 is supplied to the steam header 61 via the steam flow path 62.

The steam header 61 stores steam supplied from each of the plurality of boilers 52. The steam header 61 is connected to the steam-using device 64 via the steam flow path 63. The steam of the steam header 61 is supplied to the steam-using device 64 via the steam flow path 63.

The steam header 61 has a vapor pressure sensor 65. The vapor pressure sensor 65 detects the vapor pressure of the steam header 61. The detected vapor pressure value indicating the vapor pressure of the steam header 61 detected by the vapor pressure sensor 65 is output to the first unit control device 70.

The first unit control device 70 includes a computer system. The first unit control device 70 functions as a first unit control means for controlling the combustion state of the boiler group 60 based on the vapor pressure inside the steam header 61.

The combustion state of the boiler group 60 includes the number of operating boilers 52 and the combustion amount of each of the plurality of boilers 52.

The number of operating boilers 52 refers to the number of operating boilers 52 among the plurality of boilers 52 in the boiler group 60. The first unit control device 70 outputs a unit command for controlling the number of operating units of the boiler group 60. The number command includes an operation command for operating the stopped boiler 52 and a stop command for stopping the operating boiler 52.

The combustion amount [kcal / h] of the boiler 52 means the amount of heat generated per unit time in the combustion chamber of the boiler 52 in which the burner is arranged. As the amount of fuel supplied to the burner increases, the amount of combustion of the boiler 52 increases. As the amount of fuel supplied to the burner decreases, the amount of combustion in the boiler 52 decreases. The first unit control device 70 outputs a combustion command for controlling the combustion amount of each of the plurality of boilers 52.

The first number control device 70 controls the combustion state of the boiler group 60 including the number of operating boilers 52 and the amount of combustion of the operating boilers 52 based on the detected vapor pressure value of the vapor pressure sensor 65.

The boiler 52 has a local control device 55. The first unit control device 70 outputs a number command and a combustion command to each of the plurality of local control devices 55. The local control device 55 receives a number command and a combustion command from the first unit control device 70, and controls the combustion state of the boiler 52 to which the local control device 55 belongs.

The water supply heating unit group 20 includes a plurality of water supply heating units 1. In the example shown in FIG. 1, the water supply heating unit group 20 includes two water supply heating units 1. The number of the water supply heating units 1 constituting the water supply heating unit group 20 may be any number of three or more. Each of the plurality of water supply heating units 1 has the same heating capacity and operation control.

The water supply tank 2 stores the water supply CW supplied to at least one of the water supply heating unit 1 and the hot water tank 51. The water supply tank 2 is connected to each of the plurality of water supply heating units 1 via the water supply flow path 10. The water supply tank 2 is also connected to the hot water tank 51 via the bypass flow path 12. The temperature of the water supply CW stored in the water supply tank 2 is, for example, 20 ° C. The water supply CW stored in the water supply tank 2 is soft water. Soft water from which the hardness component has been removed by a hard water softener (not shown) is stored in the water supply tank 2.

The heat source water tank 3 stores the heat source water SW supplied to the water supply heating unit 1. The heat source water tank 3 is connected to each of the plurality of water supply heating units 1 via the heat source water flow path 13. The heat source water SW includes waste hot water discharged from an industrial facility. The heat source water SW is supplied from the industrial facility to the heat source water tank 3 via the supply flow path 14. The heat source water tank 3 has an overflow path 15 that overflows the heat source water SW.

A replenishment pump 7 is provided in the bypass flow path 12. The replenishment pump 7 supplies the water supply CW stored in the water supply tank 2 to the hot water tank 51. By driving the replenishment pump 7, the water supply CW of the water supply tank 2 is supplied to the hot water tank 51 from the bypass flow path 12 without going through the water supply heating unit 1.

The replenishment pump 7 may be a variable capacity pump or a fixed capacity pump. The replenishment pump 7 switches between a distribution state in which the water supply CW is supplied to the hot water tank 51 and a non-distribution state in which the supply of the water supply CW to the hot water tank 51 is stopped. By driving the replenishment pump 7, the water supply CW is supplied from the water supply tank 2 to the hot water tank 51 in a distribution state. When the replenishment pump 7 is stopped, the supply of the water supply CW from the water supply tank 2 to the hot water tank 51 is stopped, resulting in a non-distribution state.

The water level sensor 50 functions as a water level detecting means for detecting the water level of the hot water tank 51. The water level of the hot water tank 51 refers to the height of the surface of the hot water HW stored in the hot water tank 51. In the present embodiment, the water level sensor 50 includes an electrode type water level sensor. As the water level sensor 50, for example, a plurality of electrode rods may be arranged in the hot water tank 51. The plurality of electrode rods are arranged in the hot water tank 51 so that the heights of the lower ends of the electrode rods are different. By identifying the electrode rod in contact with the hot water HW, the water level of the hot water tank 51 is detected. The water level sensor 50 only needs to be able to detect the water level of the hot water tank 51, and a capacitance type water level sensor or a pressure type sensor can be used in addition to the electrode type water level sensor.

The second unit control device 30 includes a computer system. The second unit control device 30 functions as a unit control means for controlling the number of operating units of the water supply / heating unit group 20.

<Water supply heating unit>
The water supply heating unit 1 uses the heat of the heat source water SW supplied from the heat source water tank 3 to heat the water supply CW supplied from the water supply tank 2 to generate hot water HW. The water supply heating unit 1 includes a heat pump 4 that heats the water supply CW to generate hot water HW, a heat source water pump 5 that switches between a flow state and a non-flow state of the heat source water SW with respect to the heat pump 4, and a water supply CW for the heat pump 4. It has a water supply pump 6 for adjusting the flow rate of the water supply, a temperature sensor 8 for detecting the temperature of the hot water HW generated by the heat pump 4, and a local control device 9.

The water supply pump 6 is provided in the water supply flow path 10. The water supply pump 6 supplies the water supply CW stored in the water supply tank 2 to the heat pump 4. By driving the water supply pump 6, the water supply CW of the water supply tank 2 is supplied to the heat pump 4 via the water supply flow path 10. The water supply pump 6 is a variable displacement pump. The water supply pump 6 can adjust the flow rate of the water supply CW with respect to the heat pump 4.

In the present embodiment, the drive frequency of the motor that drives the water supply pump 6 is controlled by the inverter. The rotation speed of the water supply pump 6 is linked to the drive frequency of the motor. By adjusting the rotation speed of the water supply pump 6, the flow rate of the water supply CW from the water supply tank 2 to the heat pump 4 is adjusted.

The water supply pump 6 switches between a distribution state in which the water supply CW is supplied to the heat pump 4 and a non-distribution state in which the supply of the water supply CW to the heat pump 4 is stopped. When the water supply pump 6 is driven, the water supply CW is supplied from the water supply tank 2 to the heat pump 4 in a distribution state. When the water supply pump 6 is stopped, the supply of the water supply CW from the water supply tank 2 to the heat pump 4 is stopped, resulting in a non-distribution state.

The heat source water pump 5 is provided in the heat source water flow path 13. The heat source water pump 5 supplies the heat source water SW stored in the heat source water tank 3 to the heat pump 4. By driving the heat source water pump 5, the heat source water SW of the heat source water tank 3 is supplied to the heat pump 4 via the heat source water flow path 13.

The heat source water pump 5 may be a variable capacity pump or a fixed capacity pump. The heat source water pump 5 switches between a flow state in which the heat source water SW is supplied to the heat pump 4 and a non-circulation state in which the supply of the heat source water SW to the heat pump 4 is stopped. By driving the heat source water pump 5, the heat source water SW is supplied from the heat source water tank 3 to the heat pump 4 in a distribution state. When the heat source water pump 5 is stopped, the supply of the heat source water SW from the heat source water tank 3 to the heat pump 4 is stopped, resulting in a non-distribution state.

In the present embodiment, the heat pump 4 is a steam compression type heat pump. The heat pump 4 includes a compressor 41, a condenser 42, an expansion valve 43, and an evaporator 44. The compressor 41, the condenser 42, the expansion valve 43, and the evaporator 44 are sequentially connected in an annular shape to form a circulation flow path 47. The refrigerant RE circulates in the circulation flow path 47 including the compressor 41, the condenser 42, the expansion valve 43, and the evaporator 44. The refrigerant RE flowing through the circulation flow path 47 includes a gas refrigerant REg which is a gas phase refrigerant RE and a liquid refrigerant REl which is a liquid phase refrigerant RE. The heat pump 4 takes out heat from the condenser 42.

Further, the heat pump 4 has a supercooler 45 arranged between the condenser 42 and the expansion valve 43 in the circulation flow path 47, and a waste heat recovery heat exchanger 46.

The water supply flow path 10 is connected to each of the waste heat recovery heat exchanger 46, the supercooler 45, and the condenser 42. The water supply CW sent from the water supply tank 2 to the water supply flow path 10 flows in the order of the waste heat recovery heat exchanger 46, the supercooler 45, and the condenser 42.

The heat source water flow path 13 is connected to each of the evaporator 44 and the waste heat recovery heat exchanger 46. The heat source water SW sent from the heat source water tank 3 to the heat source water flow path 13 flows in the order of the evaporator 44 and the waste heat recovery heat exchanger 46.

The refrigerant RE flows in the circulation flow path 47 in the order of the compressor 41, the condenser 42, the supercooler 45, the expansion valve 43, and the evaporator 44.

The compressor 41 compresses the refrigerant RE. The gas refrigerant REg is supplied to the compressor 41. The compressor 41 compresses the gas refrigerant REg to generate a high-temperature and high-pressure gas refrigerant REg. The high-temperature and high-pressure gas refrigerant REg generated by the compressor 41 is a high-temperature fluid used for heat exchange with the water supply CW.

The compressor 41 is driven by a motor (not shown). By driving the compressor 41, the gas refrigerant REg is compressed, and the high-temperature and high-pressure gas refrigerant REg is supplied to the condenser 42. When the compressor 41 is stopped, the supply of the gas refrigerant REg to the condenser 42 is stopped.

The condenser 42 condenses the gas refrigerant REg from the compressor 41. The water supply CW is supplied to the condenser 42 via the water supply flow path 10. The gas refrigerant REg is condensed in the condenser 42 to dissipate heat and give heat to the water supply CW. Further, the gas refrigerant REg is liquefied by radiating heat in the condenser 42 and converted into the liquid refrigerant REl. The condenser 42 heats the water supply CW by heat exchange between the gas refrigerant REg, which is a high-temperature fluid, and the water supply CW. The condenser 42 heats the water supply CW to generate hot water HW.

The condenser 42 is connected to the hot water tank 51 via the hot water flow path 11. The hot water HW generated by the condenser 42 is supplied to the hot water tank 51 via the hot water flow path 11.

The expansion valve 43 expands the liquid refrigerant REl from the condenser 42. The expansion valve 43 reduces the pressure and temperature of the liquid refrigerant REl from the condenser 42.

The evaporator 44 evaporates the liquid refrigerant REl from the expansion valve 43. The heat source water SW is supplied to the evaporator 44 via the heat source water flow path 13. The liquid refrigerant REl absorbs heat by evaporating in the evaporator 44 and takes heat from the heat source water SW. Further, the liquid refrigerant REl is vaporized by absorbing heat in the evaporator 44 and converted into the gas refrigerant REg.

The supercooler 45 is an indirect heat exchanger that exchanges heat between the water supply CW before being supplied to the condenser 42 and the liquid refrigerant REl before being supplied to the expansion valve 43. The water supply CW is supplied to the supercooler 45 via the water supply flow path 10. The water supply CW supplied to the supercooler 45 supercools the liquid refrigerant REl before it is supplied to the expansion valve 43. The liquid refrigerant REl supplied to the supercooler 45 heats the water supply CW before it is supplied to the condenser 42. The refrigerant RE releases latent heat in the condenser 42 and sensible heat in the supercooler 45.

The waste heat recovery heat exchanger 46 is an indirect heat exchanger that exchanges heat between the water supply CW before being supplied to the supercooler 45 and the heat source water SW after passing through the evaporator 44. The water supply CW is supplied to the waste heat recovery heat exchanger 46 via the water supply flow path 10. The heat source water SW is supplied to the waste heat recovery heat exchanger 46 via the heat source water flow path 13. In the waste heat recovery heat exchanger 46, the water supply CW and the heat source water SW exchange heat to heat the water supply CW before being supplied to the supercooler 45.

By driving the compressor 41, the gas refrigerant REg is compressed, and the high-temperature and high-pressure gas refrigerant REg, which is a high-temperature fluid, is supplied to the condenser 42. When the compressor 41 is stopped, the supply of the gas refrigerant REg to the condenser 42 is stopped. The compressor 41 functions as a first flow switching means for switching between a flow state and a non-flow state of the high temperature fluid (gas refrigerant REg) with respect to the condenser 42. By driving the compressor 41, the gas refrigerant REg is supplied from the compressor 41 to the condenser 42, resulting in a distribution state. When the compressor 41 is stopped, the supply of the gas refrigerant REg from the compressor 41 to the condenser 42 is stopped, resulting in a non-distribution state.

The condenser 42 functions as a heat exchanger that heats the water supply CW by heat exchange between the high temperature fluid (gas refrigerant REg) and the water supply CW.

The heat source water pump 5 functions as a second flow switching means for switching between the flow state and the non-flow state of the heat source water SW with respect to the evaporator 44 and the waste heat recovery heat exchanger 46. By driving the heat source water pump 5, the heat source water SW is supplied from the heat source water tank 3 to the evaporator 44 and the waste heat recovery heat exchanger 46. When the heat source water pump 5 is stopped, the supply of the heat source water SW from the heat source water tank 3 to the evaporator 44 and the waste heat recovery heat exchanger 46 is stopped, resulting in a non-circulation state.

The water supply pump 6 functions as a third flow switching means for switching between a flow state and a non-flow state of the water supply CW for the waste heat recovery heat exchanger 46, the supercooler 45, and the condenser 42. By driving the water supply pump 6, the water supply CW is supplied from the water supply tank 2 to the waste heat recovery heat exchanger 46, the supercooler 45, and the condenser 42. When the water supply pump 6 is stopped, the supply of water supply CW from the water supply tank 2 to the waste heat recovery heat exchanger 46, the supercooler 45, and the condenser 42 is stopped, resulting in a non-distribution state. Further, the water supply pump 6 adjusts the flow rate of the water supply CW supplied to the waste heat recovery heat exchanger 46, the supercooler 45, and the condenser 42 via the water supply flow path 10. The water supply pump 6 functions as a flow rate adjusting means for adjusting the flow rate of the water supply CW to the waste heat recovery heat exchanger 46, the supercooler 45, and the condenser 42.

The temperature sensor 8 detects the temperature of the hot water CW generated by the condenser 42. The temperature sensor 8 is arranged in the hot water flow path 11. The hot water flow path 11 is connected to the outlet of the condenser 42. The temperature sensor 8 functions as a temperature detecting means for detecting the temperature of the hot water CW generated by the condenser 42.

The local control device 9 includes a computer system. The local control device 9 controls the compressor 41 (first distribution switching means), the heat source water pump 5 (second distribution switching means), and the water supply pump 6 (third distribution switching means, flow rate adjusting means). Functions as a means. The local control device 9 controls each of the compressor 41, the heat source water pump 5, and the water supply pump 6. The local control device 9 can switch the operation and stop of the water supply heating unit 1.

Operating the water supply heating unit 1 includes driving at least the compressor 41. In the present embodiment, operating the water supply heating unit 1 includes driving each of the compressor 41, the heat source water pump 5, and the water supply pump 6. The local control device 9 drives each of the compressor 41, the heat source water pump 5, and the water supply pump 6 to operate the water supply heating unit 1.

Stopping the water supply heating unit 1 includes at least stopping the compressor 41. In the present embodiment, stopping the water supply heating unit 1 includes stopping each of the compressor 41, the heat source water pump 5, and the water supply pump 6. The local control device 9 stops each of the compressor 41, the heat source water pump 5, and the water supply pump 6 to stop the water supply heating unit 1.

The control device 9 interlocks the compressor 41, the heat source water pump 5, and the water supply pump 6. When the compressor 41 is driven, the control device 9 also drives the heat source water pump 5 and the water supply pump 6. When the compressor 41 is stopped, the control device 9 also stops the heat source water pump 5 and the water supply pump 6.

Operating the water supply heating unit 1 includes driving at least the compressor 41. In the present embodiment, operating the water supply heating unit 1 includes driving each of the compressor 41, the heat source water pump 5, and the water supply pump 6. The local control device 9 drives each of the compressor 41, the heat source water pump 5, and the water supply pump 6 to operate the water supply heating unit 1.

Stopping the water supply heating unit 1 includes at least stopping the compressor 41. In the present embodiment, stopping the water supply heating unit 1 includes stopping each of the compressor 41, the heat source water pump 5, and the water supply pump 6. The local control device 9 stops each of the compressor 41, the heat source water pump 5, and the water supply pump 6 to stop the water supply heating unit 1.

The control device 9 interlocks the compressor 41, the heat source water pump 5, and the water supply pump 6. When the compressor 41 is driven, the control device 9 also drives the heat source water pump 5 and the water supply pump 6. When the compressor 41 is stopped, the control device 9 also stops the heat source water pump 5 and the water supply pump 6.

Driving the compressor 41 includes putting the refrigerant RE (REg, REl) in a distribution state in which the refrigerant RE (REg, REl) is circulated in the circulation flow path 47. Stopping the compressor 41 includes putting the refrigerant RE in the circulation flow path 47 into a non-circulation state in which the circulation of the refrigerant RE is stopped.

Driving the heat source water pump 5 includes putting the heat source water SW into a distribution state in which the heat source water SW is supplied to the evaporator 44 and the waste heat recovery heat exchanger 46. Stopping the heat source water pump 5 includes putting the heat source water SW into a non-circulation state in which the supply of the heat source water SW to the evaporator 44 and the waste heat recovery heat exchanger 46 is stopped.

Driving the water supply pump 6 includes putting the water supply CW into a distribution state in which the waste heat recovery heat exchanger 46, the supercooler 45, and the condenser 42 are supplied with the water supply CW. Stopping the water supply pump 6 includes putting the water supply CW into a non-circulating state in which the supply of the water supply CW to the waste heat recovery heat exchanger 46, the supercooler 45, and the condenser 42 is stopped.

The second unit control device 30 outputs a unit command for controlling the number of operating units of the water supply / heating unit group 20 to the local control device 9. The number command includes an operation command for operating the stopped water supply heating unit 1 and a stop command for stopping the running water supply heating unit 1. The second unit control device 30 outputs a unit command based on the detected water level value of the water level sensor 50. The local control device 9 controls the compressor 41, the heat source water pump 5, and the water supply pump 6 in response to the number command from the second unit control device 30, and operates the water supply heating unit 1 (heat pump 4). Switch between stop and stop.

Further, the second unit control device 30 outputs a flow rate command for adjusting the flow rate of the water supply CW to the heat pump 4 to the local control device 9. The second unit control device 30 outputs a flow rate command based on the detected water level value of the water level sensor 50. The local control device 9 receives a flow rate command from the second unit control device 30 and controls the water supply pump 6 to adjust the flow rate of the water supply CW to the heat pump 4.

The local control device 9 controls the compressor 41, the heat source water pump 5, and the water supply pump 6 in the flow state in response to the operation command from the second unit control device 30, while stopping from the second unit control device 30. In response to the command, the compressor 41, the heat source water pump 5, and the water supply pump 6 are controlled to be in a non-circulation state. When the compressor 41, the heat source water pump 5, and the water supply pump 6 are brought into circulation, the water supply heating unit 1 including the heat pump 4 operates. When the compressor 41, the heat source water pump 5, and the water supply pump 6 are in a non-circulating state, the water supply heating unit 1 including the heat pump 4 is stopped.

The local control device 9 is a compressor 41 so that the output (rotation speed) of the compressor 41 becomes constant during the operation of the heat pump 4 in which the compressor 41, the heat source water pump 5, and the water supply pump 6 are controlled to be in a flow state. To control. The drive frequency of the motor of the compressor 41 is maintained constant, and the compressor 41 is driven with a constant output. Further, the local control device 9 controls to adjust the opening degree of the expansion valve 43 so that the degree of superheat of the suction refrigerant of the compressor 41 becomes constant.

The local control device 9 is a water supply pump so that the detected temperature value Ts of the temperature sensor 8 becomes the target temperature value Tr during the operation of the heat pump 4 in which the compressor 41, the heat source water pump 5, and the water supply pump 6 are controlled in the flow state. The constant control of the hot water temperature that controls 6 is executed. In the constant hot water temperature control, the temperature of the hot water HW and the flow rate of the water supply CW are linked. In the constant hot water temperature control, the operation amount for the drive frequency of the water supply pump 6 is calculated by the speed type PID algorithm so that the detected temperature value Ts of the temperature sensor 8 converges to the target temperature value Tr, and the operation amount is calculated from the inverter circuit to the motor unit. The output frequency is adjusted.

The local control device 9 controls the water supply pump 6 so as to shut off the water supply CW while the heat pump 4 that controls the compressor 41 and the heat source water pump 5 in a non-circulation state is stopped.

<1st unit control device, 2nd unit control device, and local control device>
FIG. 2 is a functional block diagram showing an example of the first unit control device 70, the second unit control device 30, and the local control device 9 according to the present embodiment.

Note that FIG. 2 shows one local control device 9 that communicates with the second unit control device 30 for convenience, but there are a plurality of local control devices 9 that communicate with the second unit control device 30.

As shown in FIG. 2, the second unit control device 30 includes a detection water level acquisition unit 31, a storage unit 32, a number determination unit 33, an operation information acquisition unit 34, a number correction unit 35, and an operation command unit 36. It has an ability acquisition unit 37, a supply control unit 38, and an alarm control unit 39.

The detected water level acquisition unit 31 acquires the detected water level value Hs of the water level sensor 50. The detected water level value Hs of the water level sensor 50 corresponds to the amount of hot water HW stored in the hot water tank 51.

The storage unit 32 stores correlation data showing the relationship between the detected water level value Hs of the water level sensor 50 and the number of operating units of the water supply / heating unit group 20. The correlation data may be a correlation table or a correlation formula.

The number determination unit 33 determines the basic operating number N0 of the water supply heating unit group 20 based on the detected water level value of the water level sensor 50 acquired by the detection water level acquisition unit 31. In the present embodiment, the number determination unit 33 of the water supply heating unit group 20 is based on the detected water level value Hs of the water level sensor 50 acquired by the detection water level acquisition unit 31 and the correlation data stored in the storage unit 32. Determine the basic operating number N0.

FIG. 3 is a diagram for explaining a method of determining the basic operating number N0 of the water supply heating unit group 20 according to the present embodiment. In the following description, an example in which the water supply heating unit group 20 is composed of five water supply heating units 1 will be described. Further, each of the five water supply and heating units 1 is appropriately referred to as Unit 1, Unit 2, Unit 3, Unit 4, and Unit 5.

FIG. 3 schematically shows the correlation data stored in the storage unit 32. As shown in FIG. 3, the correlation data includes a correlation table showing the relationship between the detected water level value Hs of the water level sensor 50 and the number of operating units of the water supply heating unit group 20.

In the correlation data, the upper limit water level value Hh in the hot water tank 51 is set. The upper limit water level value Hh means the water level at which all the units (5 units) of the water supply and heating unit group 20 are stopped.

Further, in the correlation data, a unit change water level range lower than the upper limit water level value Hh is set. In the unit change water level range, the number of operating units of the water supply heating unit group 20 is increased or decreased by one according to the detected water level value Hs of the water level sensor 50. Specifically, the number of operating units increases as the detected water level value Hs of the water level sensor 50 decreases, and the number of operating units decreases as the detected water level value Hs of the water level sensor 50 increases.

In the present embodiment, the correlation data in the unit change water level range is such that the target temperature value Tr of all the hot water HWs of the water supply heating unit group 20 is the specified temperature value Te, and the water level of the hot water tank 51 is lowered. This is a correlation in which the number of operating units decreases as the number of units increases and the water level of the hot water tank 51 rises. The target temperature value Tr of the hot water HW may be changed according to the detected water level value of the water level sensor 50.

In the unit change water level range, the water level for determining the operating number of the water supply heating unit group 20 is set stepwise. In the unit change water level range, the water level for all units stopped, the first water level lower than the stopped water level for all units, the second water level lower than the first water level, the third water level lower than the second water level, and the fourth water level lower than the third water level. The water level and the bypass open water level lower than the 4th water level are set.

Further, in the correlation data, a low water level range lower than the unit change water level range is set. The low water level range is a water level range lower than the bypass open water level. The bypass open water level refers to the water level at which the replenishment pump 7 is driven to supply the water supply CW of the water supply tank 2 to the hot water tank 51 via the bypass flow path 12.

When the number determination unit 33 determines that the detected water level value Hs of the water level sensor 50 acquired by the detection water level acquisition unit 31 is the number change water level state within the number change water level range, the correlation stored in the storage unit 32. Based on the data, the number of operating units of the water supply and heating unit group 20 is increased or decreased one by one.

When the number determination unit 33 determines that the detected water level value Hs of the water level sensor 50 exists between the stop water level of all units and the first water level, the number 1 unit is set based on the correlation data stored in the storage unit 32. Operate and stop Units 2 to 5. When the detected water level value Hs exists between the stopped water level of all units and the first water level, the basic operating number N0 is determined to be one unit.

When the number determination unit 33 determines that the detected water level value Hs of the water level sensor 50 exists between the first water level and the second water level, the unit 1 and 2 are based on the correlation data stored in the storage unit 32. Operate Unit 3 and stop Units 3 to 5. When the detected water level value Hs exists between the first water level and the second water level, the basic operating number N0 is determined to be two.

When the number determination unit 33 determines that the detected water level value Hs of the water level sensor 50 exists between the second water level and the third water level, the unit 1 to 3 are based on the correlation data stored in the storage unit 32. Operate Unit 4 and stop Units 4 and 5. When the detected water level value Hs exists between the second water level and the third water level, the basic operating number N0 is determined to be three.

When the number determination unit 33 determines that the detected water level value Hs of the water level sensor 50 exists between the third water level and the fourth water level, the unit 1 to 4 are based on the correlation data stored in the storage unit 32. Operate Unit 5 and stop Unit 5. When the detected water level value Hs exists between the third water level and the fourth water level, the basic operating number N0 is determined to be four.

When the number determination unit 33 determines that the detected water level value Hs of the water level sensor 50 exists between the fourth water level and the bypass open water level, the unit 1 to 5 are based on the correlation data stored in the storage unit 32. Operate the unit. When the detected water level value Hs exists between the fourth water level and the bypass open water level, the basic operating number N0 is determined to be five.

The operation information acquisition unit 34 acquires the operation information of the boiler group 60 from the first unit control device 70. The operation information of the boiler group 60 includes the operation number information indicating the number of operations of the boiler group 60 and the total combustion amount information indicating the total combustion amount of the boiler group 60. The total combustion amount of the boiler group 60 means the total combustion amount of the plurality of boilers 52. As described above, the first unit control device 70 controls the operating number of the boiler group 60 and the combustion state of the boiler group 60 including the combustion amount of the operating boiler 52 based on the detected vapor pressure value of the vapor pressure sensor 65. do. Therefore, the operation information acquisition unit 34 can acquire the operation information of the boiler group 60 from the first unit control device 70.

The number correction unit 35 corrects the basic operation number N0 determined by the number determination unit 33 based on the operation information of the boiler group 60 acquired by the operation information acquisition unit 34, and derives the corrected operation number N1.

The number correction unit 35 acquires the operation number information of the boiler group 60 from the operation information acquisition unit 34 as the operation information of the boiler group 60. When it is determined that there is no increase in the number of operations of the boiler group 60 based on the number of operations information, the number correction unit 35 does not correct the basic number of operations N0 determined by the number determination unit 33, but the basic number of operations. N0 is set to the latest corrected operation number N1. When it is determined that the number of operating units of the boiler group 60 has increased by one based on the number of operating units information, the number correction unit 35 adds one unit to the corrected number of operating units N1 immediately before this increase (N1 [units]. ] +1 [unit]) is set to the latest corrected operation number N1.

Further, when the corrected operation number N1 is updated due to the increase of one operation number of the boiler group 60, the number correction unit 35 sets the basic operation number N0 determined by the number determination unit 33 after a predetermined time has elapsed from the update. Set to the latest corrected operation number N1.

The operation command unit 36 commands each machine of the water supply / heating unit group 20 to start or stop based on the corrected operation number N1 derived from the number correction unit 35. That is, the operation command unit 36 outputs an operation command or a stop command to each of the local control devices 9 of the plurality of water supply and heating units 1 based on the corrected operation number N1 derived by the number correction unit 35.

The capacity acquisition unit 37 acquires hot water production capacity information indicating the hot water production capacity q of each water supply heating unit 1. The hot water production capacity q means the ability to produce hot water HW at a specified temperature by a specified flow rate per unit time.

The replenishment control unit 38 controls the replenishment pump 7 based on the detected water level value Hs of the water level sensor 50 acquired by the detected water level acquisition unit 31. The replenishment control unit 38 has a distribution state in which the replenishment pump 7 is driven to distribute the water supply CW to the bypass flow path 12, and a non-distribution state in which the replenishment pump 7 is stopped to block the flow of the water supply CW in the bypass flow path 12. To switch.

The alarm control unit 39 is in a high water level range in which the detected water level value Hs of the water level sensor 50 acquired by the detected water level acquisition unit 31 is higher than the upper limit water level value Hh, and is acquired by the detected water level acquisition unit 31. The alarm device 16 is operated in a low water level state in which the detected water level value Hs of the water level sensor 50 is in the low water level range lower than the lower limit water level value Hb. The alarm device 16 may be an alarm sound output device that outputs an alarm sound, or a display device that displays alarm display data.

The local control device 9 includes a first distribution switching control unit 91, a second distribution switching control unit 92, a detection temperature acquisition unit 93, and a flow rate control unit 94.

The first distribution switching control unit 91 receives a number command from the second number control device 30 and outputs a switching command for controlling the compressor 41. The switching command output from the first distribution switching control unit 91 is a distribution command that drives the compressor 41 to control the compressor 41 to the distribution state, and stops the compressor 41 to put the compressor 41 into the non-distribution state. Includes non-distribution directives to control. When the first distribution switching control unit 91 receives an operation command from the operation command unit 36, the first distribution switching control unit 91 outputs a distribution command for controlling the compressor 41 to a distribution state. When the first distribution switching control unit 91 receives a stop command from the operation command unit 36, the first distribution switching control unit 91 outputs a non-distribution command for controlling the compressor 41 to a non-distribution state.

The second distribution switching control unit 92 receives the number command from the second number control device 30 and outputs a switching command for controlling the heat source water pump 5. The switching command output from the second distribution switching control unit 92 is a distribution command that drives the heat source water pump 5 to control the heat source water pump 5 to the distribution state, and stops the heat source water pump 5 to operate the heat source water pump 5. Includes non-distribution directives that control non-distribution status. When the second distribution switching control unit 92 receives an operation command from the operation command unit 36, the second distribution switching control unit 92 outputs a distribution command for controlling the heat source water pump 5 to a distribution state. When the second distribution switching control unit 92 receives the stop command from the operation command unit 36, the second distribution switching control unit 92 outputs a non-distribution command for controlling the heat source water pump 5 to the non-distribution state.

The compressor 41 and the heat source water pump 5 are interlocked with each other. When a distribution command is output from the first distribution switching control unit 91 and the compressor 41 is controlled to the distribution state, the second distribution switching control unit 92 outputs the distribution command to control the heat source water pump 5 to the distribution state. do. When the non-distribution command is output from the first distribution switching control unit 91 and the compressor 41 is controlled to the non-distribution state, the second distribution switching control unit 92 outputs the non-distribution command to non-distribute the heat source water pump 5. Control the distribution status.

The detected temperature acquisition unit 93 acquires the detected temperature value Ts of the temperature sensor 8. The detected temperature value Ts of the temperature sensor 8 is the hot water discharge temperature from the condenser 42, that is, the hot water supply temperature to the hot water tank 51.

In the flow control unit 94, the detected temperature value Ts of the temperature sensor 8 acquired by the detected temperature acquisition unit 93 becomes the target temperature value Tr during the operation of the heat pump 4 in which the compressor 41 and the heat source water pump 5 are controlled in the flow state. As a result, a flow command for controlling the water supply pump 6 is output.

<Control method>
Next, a control method of the boiler system 100 according to the present embodiment will be described. FIG. 4 is a flowchart for explaining a control method of the boiler system 100 according to the present embodiment. The process shown in FIG. 4 is carried out at a specified cycle.

The water level sensor 50 detects the water level of the hot water tank 51. The detected water level acquisition unit 31 acquires the detected water level value of the water level sensor 50 (step S1).

The number determination unit 33 determines the basic operating number N0 of the water supply / heating unit group 20 based on the detected water level value of the water level sensor 50. As described with reference to FIG. 3, the number determination unit 33 is based on the detected water level value Hs of the water level sensor 50 acquired by the detected water level acquisition unit 31 and the correlation data stored in the storage unit 32. The basic operating number N0 of the water supply and heating unit group 20 is determined (step S2).

The number correction unit 35 executes the correction operation number derivation process. The correction operation number derivation process includes a process of acquiring the operation information of the boiler group 60 and a process of deriving the correction operation number N1. The number correction unit 35 corrects the basic operation number N0 based on the operation information of the boiler group 60 acquired from the first number control device 70, and derives the corrected operation number N1 (step S3).

The operation command unit 36 adds a plurality of water supplies to the water supply heating unit group 20 so that the water supply heating unit group 20 operates with the correction operation number N1 based on the correction operation number N1 derived by the number correction unit 35. A number command including at least one of an operation command and a stop command is output to each of the temperature units 1 (step S4).

FIG. 5 is a flowchart for explaining a control method of the boiler system 100 according to the present embodiment. FIG. 5 shows a subroutine of the correction operation number derivation process (step S3) shown in FIG. The process shown in FIG. 5 is carried out at a specified cycle.

The operation information acquisition unit 34 acquires the operation information of the boiler group 60. In the present embodiment, the operation information acquisition unit 34 acquires the operation number information of the boiler group 60 as the operation information of the boiler group 60 from the first unit control device 70 (step S311).

The first unit control device 70 increases or decreases the number of operating units of the boiler 52 based on the detected vapor pressure value of the steam header 61. The number correction unit 35 determines whether or not the number of operations of the boiler 52 has increased based on the operation number information of the boiler group 60 acquired by the operation information acquisition unit 34 (step S312).

When it is determined in step S312 that the number of operating boilers 52 has not increased (step S312: No), the number correction unit 35 determines the basic operating number N0 of the water supply heating unit 1 determined by the number determination unit 33. The basic operation number N0 is set to the latest corrected operation number N1 without correction (step S313).

The number correction unit 35 derives the latest corrected operation number N1 set in step S313 as the number of operations of the water supply heating unit group 20 (step S317).

That is, when the operating number of the boiler 52 has not changed, the number correction unit 35 sets the basic operating number N0 determined based on the detected water level value Hs of the water level sensor 50 as the operating number of the water supply heating unit group 20. Derived.

When it is determined in step S312 that the number of operating boilers 52 has increased by one (step S312: Yes), the number correction unit 35 is for one corrected operation number N1 immediately before the increase in the number of operating boilers 52 occurs. The added number is set to the latest corrected operation number N1 (step S314).

For example, when the number of corrected operation units N1 immediately before the determination in step S312 is three and the number of operating units of the boiler 52 increases by one unit, the number correction unit 35 of the water supply heating unit group 20 in step S312. Judge that it is necessary to increase the number of operating units. The number correction unit 35 sets the latest correction operation number N1 (4 units) by adding one unit to the correction operation number N1 (3 units) immediately before the increase in the operation number of the boiler 52 occurs.

That is, when the number of operating boilers 52 increases, the number correction unit 35 derives the number of operating units of the water supply and heating unit group 20 by adding one to the immediately preceding corrected operating number N1. When the number of operating boilers 52 increases by one, the number correction unit 35 increases the number of operating water supply heating units 1 by one without considering the detected water level value of the water level sensor 50.

The number correction unit 35 adds one unit to the correction operation number N1 and determines whether or not a predetermined time has elapsed after updating the correction operation number N1 (step S315). The predetermined time is, for example, 10 minutes.

When it is determined in step S315 that the predetermined time has not elapsed (step S315: No), the number correction unit 35 sets the latest correction operation number N1 set in step S314 as the number of operations of the water supply heating unit group 20. Is derived (step S317).

When it is determined in step S315 that the predetermined time has elapsed (step S315: Yes), the number correction unit 35 sets the basic operation number N0 determined based on the detected water level value of the water level sensor 50 to the latest correction operation number. Set to N1 (step S316).

The number correction unit 35 derives the latest corrected operation number N1 set in step S316 as the number of operations of the water supply heating unit group 20 (step S317).

That is, when a predetermined time elapses without changing the operating number of the boiler 52 after increasing the operating number of the water supply heating unit 1 as the operating number of the boiler 52 increases, the number correction unit 35 uses the water level sensor. The basic operating number N0 determined based on the detected water level value of 50 is set to the latest corrected operating number N1. After the lapse of a predetermined time, the number of operating units of the water supply heating unit group 20 is controlled based on the detected water level value Hs of the water level sensor 50.

<Effect>
As described above, according to the present embodiment, in the situation where the operating number of the boiler 52 is not changed or the operating number of the boiler 52 decreases, the operating number of the water supply heating unit group 20 is the operating number of the water level sensor 50. It is increased or decreased based on the detected water level value. As a result, the hot water tank 51 is maintained at an appropriate water level. On the other hand, in a scene where the number of operating boilers 52 increases and the total water supply requirement Q1 of the boiler group 60 increases sharply, the number of operating units of the water supply heating unit group 20 is linked to the increase in the number of operating boilers 52. Will increase. As a result, even in a situation where the total water supply requirement Q1 of the boiler group 60 may suddenly increase and the water level of the hot water tank 51 may drop sharply, water supply is linked to the increase of the total water supply requirement Q1. Since the number of operating units of the heating unit group 20 increases, it is possible to prevent the hot water tank 51 from becoming in a low water level state. Further, since the hot water HW generated by the water supply heating unit group 20 is supplied to the hot water tank 51, not only the water level drop but also the water temperature drop is prevented in the hot water tank 51.

Control to increase or decrease the number of operating water supply heating unit groups 20 based on the detected water level value of the water level sensor 50 even when the number of operating units of the boiler 52 increases and the total water supply requirement Q1 of the boiler group 60 suddenly increases. If is maintained, there is a high possibility that the hot water HW will not be replenished from the water supply / heating unit group 20 to the hot water tank 51 in time, and the water level of the hot water tank 51 will drop to the bypass open water level. When the water level of the hot water tank 51 drops to the bypass open water level, the water supply CW (cold water) of the water supply tank 2 is supplied to the hot water tank 51 via the bypass flow path 12. As a result, the water temperature of the hot water tank 51 drops.

According to the present embodiment, when the number of operating boilers 52 increases and the total water supply requirement Q1 of the boiler group 60 increases sharply, the first number of boilers is controlled regardless of the detected water level value of the water level sensor 50. Based on the operation information of the boiler group 60 output from the device 70, the number of operating water supply and heating units 1 is increased in conjunction with the increase in the number of operating boilers 52. As a result, even in a situation where the total water supply requirement Q1 of the boiler group 60 may suddenly increase and the water level of the hot water tank 51 may drop, the hot water HW generated by the water supply heating unit group 20 may be the hot water tank 51. Is quickly replenished. Therefore, the low water level state of the hot water tank 51 and the decrease in water temperature are prevented.

Further, when the predetermined time elapses without changing the operating number of the boiler 52 after increasing the operating number of the water supply heating unit 1 in conjunction with the increase in the operating number of the boiler 52, the water supply heating unit group 20 The control of the number of operating units of the boiler group 60 shifts from the control based on the operation information of the boiler group 60 to the control based on the detected water level value of the water level sensor 50. As a result, the hot water tank 51 is maintained at an appropriate water level.

[2] Second Embodiment The second embodiment will be described. In the following description, the same or equivalent components as those in the above-described embodiment are designated by the same reference numerals, and the description thereof will be simplified or omitted.

FIG. 6 is a flowchart for explaining a control method of the boiler system 100 according to the present embodiment. FIG. 6 shows a subroutine of the correction operation number derivation process (step S3) of FIG. 4 described in the above-described embodiment. The process shown in FIG. 6 is carried out at a specified cycle.

The operation information acquisition unit 34 acquires the operation information of the boiler group 60. In the present embodiment, the operation information acquisition unit 34 acquires the total combustion amount information indicating the total combustion amount of the boiler group 60 as the operation information of the boiler group 60 from the first unit control device 70 (step S321).

The first unit control device 70 controls the total combustion amount of the boiler group 60 based on the detected vapor pressure value of the vapor pressure sensor 65. Therefore, the operation information acquisition unit 34 can acquire the total combustion amount information of the boiler group 60 from the first unit control device 70.

The number correction unit 35 calculates the total water supply request amount Q1 of the boiler group 60 based on the total combustion amount information of the boiler group 60 acquired by the operation information acquisition unit 34 (step S322).

The water supply requirement of the boiler 52 is proportional to the combustion amount of the boiler 52. The total water supply requirement Q1 of the boiler group 60 is proportional to the total combustion amount of the boiler group 60. As an example, when the combustion rate [%] of the boiler 52 is A, the actual evaporation amount [kg / h] at a combustion rate of 100% is B, and the blow rate of the boiler water is 10 [%], the water supply of the boiler 52 is supplied. The required amount [L / h] is calculated by [A × B × 1.1].

The capacity acquisition unit 37 acquires hot water production capacity information indicating the hot water production capacity q for each water supply heating unit 1 (step S323).

The hot water production capacity q means the ability to produce hot water HW at a specified temperature by a specified flow rate per unit time. The water supply heating unit 1 includes a temperature sensor 8 that detects the temperature of the hot water HW discharged from the condenser 42, and a flow rate sensor (not shown) that detects the flow rate of the hot water HW discharged from the condenser 42. The detected temperature value of the temperature sensor 8 and the detected flow rate value of the flow rate sensor are output to the local control device 9. The local control device 9 calculates the hot water production capacity q of the water supply heating unit 1 to which the local control device 9 belongs based on the detected temperature value of the temperature sensor 8 and the detected flow rate value of the flow rate sensor. The capacity acquisition unit 37 can acquire the hot water production capacity q for each water supply / heating unit 1 from the local control device 9.

The number correction unit 35 calculates the total hot water production amount Q2 of the water supply heating unit group 20 based on at least the hot water production capacity information acquired by the capacity acquisition unit 37 (step S324).

The total hot water production amount Q2 is the total of the hot water production capacity q of the water supply heating unit 1 during operation. For example, when the number of operating water supply heating units 1 during operation is three and the hot water production capacity q of each of the three units is q1, q2, q3, the total hot water production amount Q2 is [q1 + q2 + q3]. be.

The hot water production capacity information for each water supply / heating unit 1 may be stored in the local control device 9 or the storage unit 32. The hot water production capacity q can be derived from the design information of the water supply / heating unit 1 or a preliminary survey, and can be stored in the local control device 9 or the storage unit 32. The hot water production capacity q stored in the local control device 9 or the storage unit 32 may be an average value (standard value) of the hot water production capacity q of the plurality of water supply and heating units 1. The capacity acquisition unit 37 may acquire hot water production capacity information for each water supply / heating unit 1 from the local control device 9 or the storage unit 32. When the average value of the hot water production capacity is q and the basic operating number derived from the detected water level value of the water level sensor 50 is N0, the total hot water production amount Q2 is [q × N0].

After the total water supply request amount Q1 and the total hot water production amount Q2 are calculated, the number correction unit 35 derives the correction operation number N1 by comparing the total water supply request amount Q1 and the total hot water production amount Q2 (step S325).

When the number correction unit 35 compares the total water supply request amount Q1 and the total hot water production amount Q2 and determines that the total water supply request amount Q1 exceeds the total hot water production amount Q2 (when Q1> Q2), the water supply addition unit 35 adds water. It is determined that the total hot water production amount Q2 by the hot unit group 20 is insufficient, that is, the flow rate of the hot water HW to the hot water tank 51 is insufficient. In that case, the number correction unit 35 corrects the basic operating number N0 so that the operating number increases, and derives the corrected operating number N1.

When the difference between the total water supply required amount Q1 and the total hot water production amount Q2 exceeds the hot water production capacity q of one water supply heating unit 1 (when Q1-Q2> q), the number correction unit 35 adds water supply. The latest corrected operation number N1 is set by adding two units to the basic operation number N0, which is the current operation number of the temperature unit group 20. That is, the number correction unit 35 sets the correction operation number N1 so that the condition of [N1 [unit] = N0 [unit] + 2 [unit]] is satisfied.

When the difference between the total water supply required amount Q1 and the total hot water production amount Q2 is equal to or less than the hot water production capacity q of one water supply heating unit 1 (when Q1-Q2 ≦ q), the number correction unit 35 supplies water. The latest corrected operating number N1 is set by adding one unit to the basic operating number N0, which is the current operating number of the heating unit group 20. That is, the number correction unit 35 sets the correction operation number N1 so that the condition [N1 [unit] = N0 [unit] + 1 [unit]] is satisfied.

When the number correction unit 35 compares the total water supply request amount Q1 and the total hot water production amount Q2 and determines that the total water supply request amount Q1 is less than the total hot water production amount Q2 (when Q1 <Q2), the water supply addition unit 35 adds water. It is determined that the total hot water production amount Q2 by the hot unit group 20 is surplus, that is, the flow rate of the hot water HW to the hot water tank 51 is excessive. In that case, the number correction unit 35 corrects the basic operating number N0 so that the operating number decreases, and derives the corrected operating number N1.

When the difference between the total water supply required amount Q1 and the total hot water production amount Q2 is equal to or greater than the hot water production capacity q of one water supply heating unit 1 (when Q2-Q1 ≧ q), the number correction unit 35 supplies water. The latest corrected operating number N1 is set by subtracting one unit from the basic operating number N0, which is the current operating number of the heating unit group 20. That is, the number correction unit 35 sets the correction operation number N1 so that the condition [N1 [unit] = N0 [unit] -1 [unit]] is satisfied.

When the difference between the total water supply required amount Q1 and the total hot water production amount Q2 is less than the hot water production capacity q of one water supply heating unit 1 (when Q2-Q1 <q), the number correction unit 35 adds water supply. The basic operating number N0, which is the current operating number of the temperature unit group 20, is not corrected, but is set to the latest corrected operating number N1. That is, the number correction unit 35 sets the correction operation number N1 so that the condition [N1 [unit] = N0 [unit]] is satisfied.

When the number correction unit 35 compares the total water supply request amount Q1 and the total hot water production amount Q2 and determines that the total water supply request amount Q1 and the total hot water production amount Q2 are equal (when Q1 = Q2), the water supply is supplied. It is determined that the total hot water production amount Q2 by the heating unit group 20 is appropriate, that is, the flow rate of the hot water HW to the hot water tank 51 is appropriate. In that case, the number correction unit 35 sets the latest corrected operation number N1 without correcting the basic operation number N0, which is the current operation number of the water supply / heating unit group 20. That is, the number correction unit 35 sets the correction operation number N1 so that the condition [N1 [unit] = N0 [unit]] is satisfied.

As described above, also in the present embodiment, the low water level state and the water temperature drop of the hot water tank 51 are prevented.

[3] Computer system FIG. 7 is a block diagram showing an example of the computer system 1000. The local control device 9 described above includes a computer system 1000. The computer system 1000 includes a processor 1001 such as a CPU (Central Processing Unit), a main memory 1002 including a non-volatile memory such as a ROM (Read Only Memory) and a volatile memory such as a RAM (Random Access Memory). It has a storage 1003 and an interface 1004 including an input / output circuit. The functions of the first unit control device 70, the local control device 55, the second unit control device 30, and the local control device 9 described above are stored as programs in the storage 1003. The processor 1001 reads the program from the storage 1003, expands it into the main memory 1002, and executes the above-described processing according to the program. The program may be distributed to the computer system 1000 via the network.

[4] Another Embodiment FIG. 8 is a schematic view showing an example of the heat exchanger 400 according to the present embodiment. In the above-described embodiment, the water supply heating unit 1 is provided with the steam compression type heat pump 4, the condenser 42 is provided as a heat exchanger, and the compressor 41 is provided as the first distribution switching means. Further, it was decided that the water supply CW is heated by heat exchange between the gas refrigerant REg and the water supply CW.

As shown in FIG. 8, the water supply heating unit 1 may be provided with a heat exchanger 400 that heats the water supply CW by heat exchange between the water supply CW and the heat source water SW. Further, as the first flow switching means for switching between the flow state and the non-flow state of the high temperature fluid (heat source water SW) to the heat exchanger 400, the heat source water capable of switching between the supply and stop of the heat source water SW to the heat exchanger 400. A pump 500 may be provided. Further, as the first distribution switching means, an on-off valve capable of switching between supply and stop of the heat source water SW to the heat exchanger 400 may be provided.

In the above-described embodiment, the water supply pump 6 is a variable displacement pump. The water supply pump 6 may be a fixed capacity pump. When the water supply pump 6 which is a fixed capacity pump is arranged in the water supply flow path 10, a proportional control valve functioning as a flow rate adjusting means may be arranged in the water supply flow path 10. By controlling the opening degree of the proportional control valve, the flow rate of the water supply CW to the condenser 42 (heat exchanger 400) is adjusted. During the operation of the water supply heating unit 1, the proportional control valve opens to supply the water supply CW to the condenser 42. When the water supply heating unit 1 is stopped, the proportional control valve closes and shuts off the water supply CW to the condenser 42. In the water level state where the number of units is changed, the opening degree of the proportional control valve is controlled so that the detected temperature value of the temperature sensor 8 becomes the target temperature value Tr.

For example, when the heat source water SW of the heat source water tank 3 is in a pressurized state, even if the heat source water pump 5 is omitted, the heat source water SW of the heat source water tank 3 is sent to the evaporator 44 via the heat source water flow path 13. Will be supplied. Therefore, when the heat source water SW of the heat source water tank 3 is in a pressurized state, an on-off valve may be provided in the heat source water flow path 13 as the second distribution switching means. By opening and closing the on-off valve, it is possible to switch between the flowing state and the non-circulating state of the heat source water SW with respect to the evaporator 44 (heat exchanger 400). During the operation of the water supply heating unit 1, the on-off valve opens and the heat source water SW is supplied to the evaporator 44. When the water supply heating unit 1 is stopped, the on-off valve closes and the supply of the heat source water SW to the evaporator 44 is cut off.

1 ... Water supply heating unit, 2 ... Water supply tank, 3 ... Heat source water tank, 4 ... Heat pump, 5 ... Heat source water pump (second flow switching means), 6 ... Water supply pump (flow control means), 7 ... Supply pump, 8 ... Temperature sensor (temperature detecting means), 9 ... Local control device (local control means), 10 ... Water supply flow path, 11 ... Hot water flow path, 12 ... Bypass flow path, 13 ... Heat source water flow path, 14 ... Supply flow path , 15 ... overflow path, 16 ... alarm device, 20 ... water supply and heating unit group, 30 ... second unit control device (second unit control means), 31 ... detection water level acquisition unit, 32 ... storage unit, 33 ... number determination Unit, 34 ... Operation information acquisition unit, 35 ... Number correction unit, 36 ... Operation command unit, 37 ... Capacity acquisition unit, 38 ... Supply control unit, 39 ... Alarm control unit, 41 ... Compressor (first distribution switching means) , 42 ... Condenser, 43 ... Expansion valve, 44 ... Evaporator, 45 ... Supercooler, 46 ... Waste heat recovery heat exchanger, 47 ... Circulation flow path, 50 ... Water level sensor (water level detecting means), 51 ... Hot water Tank, 52 ... Boiler, 53 ... Hot water flow path, 54 ... Hot water pump, 55 ... Local controller, 60 ... Boiler group, 61 ... Steam header, 62 ... Steam flow path, 63 ... Steam flow path, 64 ... Steam-using equipment , 65 ... Steam pressure sensor, 70 ... 1st unit control device (1st unit control means), 91 ... 1st distribution switching control unit, 92 ... 2nd distribution switching control unit, 93 ... Detection temperature acquisition unit, 94 ... Flow rate Control unit, 100 ... boiler system, CW ... water supply, HW ... hot water, RE ... refrigerant, REg ... gas refrigerant, REl ... liquid refrigerant, SW ... heat source water.

Claims (6)

A group of boilers consisting of multiple boilers,
A steam header that collects the steam generated in the boiler group,
A first unit control means for controlling the combustion state of the boiler group based on the steam pressure inside the steam header, and
A group of water supply and heating units consisting of multiple water supply and heating units,
A hot water tank that stores hot water generated by the water supply heating unit group and supplies it to the boiler group, and
A water level detecting means for detecting the water level of the hot water tank and
A second unit control means for controlling the number of operating units of the water supply / heating unit group is provided.
The second unit control means
A number determination unit that determines the basic operating number of the water supply heating unit group based on the detected water level value of the water level detecting means, and
Based on the operation information of the boiler group acquired from the first unit control means, the number correction unit that corrects the basic operation number and derives the corrected operation number, and
Based on the corrected operation number derived by the number correction unit, it has an operation command unit for instructing each machine of the water supply heating unit group to start or stop.
Boiler system. The number correction unit acquires the operation number information as the operation information of the boiler group from the first number control means, and if there is no increase in the operation number information, the latest correction without correcting the basic operation number. When the number of operating units is set and the information on the number of operating units increases by one, the number of units added by one to the corrected operating number immediately before the increase is set as the latest corrected operating number.
The boiler system according to claim 1. When the corrected operation number is updated by increasing the number of operations of the boiler group by one, the number correction unit sets the basic operation number to the latest corrected operation number after a predetermined time has elapsed from the update.
The boiler system according to claim 2. The second unit control means has an ability acquisition unit for acquiring hot water production capacity information for each of the water supply and heating units.
The number correction unit acquires total combustion amount information as operation information of the boiler group from the first number control means, calculates the total water supply request amount of the boiler group based on the total combustion amount information, and at least Based on the hot water production capacity information acquired by the capacity acquisition unit, the total hot water production amount of the water supply heating unit group is calculated, and the corrected operation number is derived by comparing the total water supply required amount and the total hot water production amount. do,
The boiler system according to claim 1. Each of the plurality of water supply heating units
A heat exchanger that heats the water supply by exchanging heat between the high-temperature fluid and the water supply,
A first flow switching means for switching between a flow state and a non-flow state of a high-temperature fluid with respect to the heat exchanger.
A flow rate adjusting means for adjusting the flow rate of water supply to the heat exchanger, and
A temperature detecting means for detecting the temperature of hot water generated by the heat exchanger, and
It has the first distribution switching means and the local control means for controlling the flow rate adjusting means.
The local control means controls the first distribution switching means into a distribution state in response to an operation command from the second unit control means, while the first distribution means receives a stop command from the second unit control means. During operation in which the switching means is controlled to the non-distribution state and the first distribution switching means is controlled to the distribution state, the flow rate adjusting means is controlled so that the detected temperature value of the temperature detecting means becomes the target temperature value. The flow rate adjusting means is controlled so as to shut off the water supply during the stoppage in which the first distribution switching means is controlled to the non-distribution state.
The boiler system according to any one of claims 1 to 4. Each of the plurality of water supply heating units
A steam compression heat pump in which a compressor, a condenser, an expansion valve, and an evaporator are sequentially connected in an annular shape to circulate a refrigerant and take out heat from the condenser.
A second flow switching means for switching between a flow state and a non-flow state of the heat source water with respect to the evaporator,
A flow rate adjusting means for adjusting the flow rate of water supply to the condenser, and
A temperature detecting means for detecting the temperature of the hot water generated by the condenser, and
It has the compressor, the second distribution switching means, and the local control means for controlling the flow rate adjusting means.
The local control means receives an operation command from the second unit control means to control the compressor and the second distribution switching means into a distribution state, while receiving a stop command from the second unit control means. During operation in which the compressor and the second distribution switching means are controlled to be in a non-distribution state and the compressor is controlled to be in a distribution state, the flow rate is adjusted so that the detected temperature value of the temperature detecting means becomes a target temperature value. The flow control means is controlled so as to shut off the water supply during the stoppage in which the means is controlled and the compressor is controlled to be in a non-circulation state.
The boiler system according to any one of claims 1 to 4.

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