JP2847130B2 - Control method of ice heat storage unit - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a method for controlling an ice heat storage unit which can be suitably applied to a small to large-scale air conditioning system. "Conventional technology" In recent years, it has been possible to cut power consumption during the daytime and to shift to nighttime. The heat storage system is in the limelight as a way to achieve this. This heat storage system performs night-time heat storage operation by using cheap electric power in the middle of the night, extracts heat from a heat storage tank at night or daytime, and uses it for cooling and heating. As one of such heat storage systems, the present applicant has previously developed an ice heat storage unit that performs heat exchange with an air heat source heat pump and stores the heat exchange in an ice heat storage tank using latent heat of ice. (Product name; Storage Master). This ice heat storage unit performs ice heat storage operation in summer,
In winter performs hot water thermal storage operation, for example, a total of 10000 m ² about an area intended to be utilized for small to medium sized air conditioning systems with a combination of multiple, more by the combination of the heat pump type refrigerator, the ice storage unit Can be operated in parallel. [Problems to be Solved by the Invention] By the way, according to the ice heat storage unit, when a plurality of ice heat storage units are used in combination, as a practical matter, there is a problem in the pipe construction, and the pipe loss of the heat medium flowing into each ice heat storage unit is caused by the problem. Since the energy is varied, there is a problem that the flow rate of the heat medium flowing into each unit varies. For this reason, at the time of taking out ice heat storage, the amount of ice stored in each ice heat storage unit is different for each ice heat storage unit, and there is no problem with the unit alone, but the amount of ice remaining in each ice heat storage unit varies. For this reason, it has been difficult to comprehensively control each ice heat storage unit and efficiently extract necessary and sufficient heat storage from each ice heat storage unit. Thus, the combination number further increased in the ice thermal storage units, an attempt to apply the ice storage unit in a large-scale building air conditioning system having an area of about total 20000 m ² for example, the above problem is further expanded, the ice storage There is a problem that the efficiency of taking out heat storage from the unit is deteriorated. For this reason, the current heat storage system cannot cope with the air conditioning system of a large-scale building having the above-mentioned size. The present invention has been made in view of the above circumstances, and it is possible to efficiently operate a plurality of ice heat storage units in parallel, and to appropriately cope with ice heat storage units from small to medium size to large-scale air conditioning systems. It is an object of the present invention to provide a method for controlling an ice storage unit that can be used. Means for Solving the Problems The present invention relates to a method for controlling an ice heat storage unit having a heat pump that exchanges heat with the outside via a heat medium, and an ice heat storage tank that stores ice from the heat pump via the heat medium. The ice heat storage units are connected in parallel as a set of two ice heat storage units, the flow rate of the heat medium flowing through each ice heat storage unit is detected, and the flow rate of the heat medium is set based on the flow rate data. It is characterized by being controlled by. In addition, a flow meter that detects the flow rate of the heat medium is installed in units of sets upstream of each ice heat storage unit, and a valve that controls the flow rate of the heat medium based on the flow rate data is provided downstream of each ice heat storage unit. It is desirable to install them in pairs. [Operation] According to the ice heat storage unit control method of the present invention, by connecting two ice heat storage units as a set and connecting them in parallel in units of a set, instead of distributing the air conditioning load in units of one unit, Can be distributed. Further, the flow rate of the heat medium flowing through each ice heat storage unit is detected, and the flow rate of the heat medium is controlled in units of sets based on the flow rate data. The air-conditioning load can be evenly leveled for each group. Therefore,
By changing the number of connected ice heat storage units in groups, the ice heat storage unit can be applied from small-scale air conditioning to large-scale air conditioning. Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows a heat source flow used in an air conditioning system of a large-scale building to which the present invention is applied, and FIG. 2 shows an ice heat storage unit used in a heat source flow. As shown in FIG. 2, the ice heat storage unit U includes a heat pump 1 for performing heat exchange with the outside air via a medium, and a heat storage tank 2 for storing heat from the heat pump 1 via the medium. It has been. The heat pump 1 includes an air heat exchanger 3 and a compressor 4,
The heat exchangers 5 and 5 are configured to exchange heat with the heat storage tank 2 and the room S via the heat exchangers 5 and 5. Since the ice heat storage unit U stores heat using the latent heat of ice, it is possible to store heat with a much higher heat capacity than water heat storage. Further, the ice heat storage unit U enables the ice heat storage operation and the hot water heat storage operation by operating the heat pump 1 in the normal and reverse directions, and further uses the heat storage cold / hot water alone, the combined use of the heat storage cold / hot water and the heat pump 1, the heat pump 1 Only the operation is possible, and it can be used as a cooling and heating system. According to the present invention, as shown in the heat source flow of FIG. 1, two ice heat storage units U are connected in parallel to distribute the load evenly, and a set of the two units is composed of a parent and child unit U '.
Further, the parent-child unit U 'is basically configured and connected in parallel to a plurality of sets (a total of three sets in the present embodiment) to cope with a large-capacity air-conditioning load of a large-scale building or the like. Is what you do. In the present invention, in order to cope with a large-capacity air-conditioning load, in order to efficiently use heat storage, a device for uniformly distributing the air-conditioning load for each parent-child unit U 'is performed. That is, in the heat source flow of this embodiment, a flow meter 6 for detecting the flow rate flowing in each parent-child unit U 'is provided in the middle of a pipe 7 in which water as a heat medium flows, upstream of each parent-child unit U'. Similarly, downstream of each parent-child unit U ', a valve 8 for uniformly adjusting the flow rate of water flowing through each parent-child unit U' is provided in the middle of the pipe 7, respectively. Then, the flow rate data obtained by each of the flow meters 6... Is immediately sent to the control device 10 via the transmission cable 9, and the entirety of the parent-child unit U ′ obtained by each flow meter 6 is transmitted from the control device 10. The control signal is sent to each valve 8 based on the flow rate data of the above, and the opening degree of each valve 8 is adjusted to adjust the flow rate, thereby making the flow rate of the water flowing through the pipe 7 uniform for each parent-child unit U ′. Like that. by this,
By making the amount of ice remaining in the heat storage tank 2 of each parent-child unit U 'equal, and maintaining the balance of the amount of residual ice as a whole, the heat storage can be taken out from each parent-child unit U' evenly and efficiently, so that the load can be reduced. To each parent-child unit U '
To ensure optimal and maximum use of heat storage. Further, in the present embodiment, the parent-child unit U 'is combined with an accessory for air-conditioning and annual cold water.
As the accessory, a refrigerator 11 for taking out cold and hot water and a refrigerator 12 for taking out only cold water throughout the year are used. These accessories are connected and used in parallel with the parent-child units U 'through a pipe 7. ing. On the other hand, each of the parent-child units U 'performs a load prediction control on a group basis. The load prediction is performed using, for example, the outside air temperature (wet bulb temperature) at the start of air conditioning as basic data. Then, based on this load prediction, a control device (not shown) selects and performs the above-described four operations of the two ice heat storage units U in each parent-child unit U ′. Similarly, the accessory machines also perform predictive control based on the outside air temperature as described above, and perform unit control. Further, the prediction of the load is not limited to the outside air temperature, and the load on the secondary side (air conditioning side) of the heat source flow may be measured by a calorie meter or the like, and the number of units may be controlled according to the load on the secondary side. Alternatively, the operating number of the parent-child unit U ′ and the accessory machine may be determined on a monthly basis. Next, regarding the heat source flow described above, the heat storage tank 2
The cooling operation during the time period (hereinafter referred to as “time”), the cooling operation during the night heat storage, the heating operation during the time, and the heating operation during the night heat storage will be described.

[Cooling operation in time]

The time period during which the heat storage tank 2 is used (for example, from 8:00 am to 6:00 pm) is set in the controller in advance. Then, in accordance with the load prediction from the outside air temperature in the morning, the controller controls the ice heat storage units U in units of the parent and child units U ′, and takes out cold water from the heat storage tanks 2 of the respective ice heat storage units U in each of the parent and child units U ′. The extracted cold water is pipe 7
Is sent to the secondary zone for air conditioning, and is used for air conditioning here. From the secondary zone, the secondary pump
The double water sent out by 13 is returned to each parent-child unit U 'through the pipe 7 again. During the above-mentioned cooling operation within the time period, the valve 8 of each parent-child unit U ′ is controlled by the control device 10 based on the flow rate data from each flow meter 6 so that the ice heat storage in each heat storage tank 2 can be optimally used. The flow rate flowing through the parent-child unit U 'is made uniform. As a result, the load is evenly distributed to each parent-child unit U ', and the optimal use of ice heat storage can be achieved.
When the air-conditioning load is light, only the heat storage tank 2 is used alone, and when the air-conditioning load is large, the heat pump 1 of the parent-child unit U 'is operated in an auxiliary manner to bear a part of the load. Further, as another means of load prediction in the parent-child unit U ′, the remaining amount of ice including the child device is always grasped by the parent device, and the result is used to directly take out cold water from the heat storage tank 2 or It is determined every predetermined time (for example, every 30 minutes) whether cold water is taken out by using the heat storage tank 2 and the heat pump 1 together.
, And switching of each operation mode can be performed. The switching of the operation mode may be performed by control from a control device (not shown) based on the data of the remaining ice amount. Furthermore, the parent-child unit U 'as described above
When the auxiliary operation of the heat pump 1 is performed, the beat pump 1
It is possible to determine whether the operating state of the vehicle is in the low load state or the fully open state, and use the result as the load predicting means for the determination data of the operation mode switching. In this way, the optimal use and maximum use of ice heat storage can be achieved. Also for the accessory machines, load prediction is performed by the above-described various load prediction means, and based on the load prediction, the number of the refrigerators 11 and 12 is controlled by a control device (not shown) so that the refrigerators 11 and 12 are operated during the operation within the time. Is optional. By the way, in the above-mentioned in-time operation, when condensed water from the secondary zone returns to the parent-child unit U 'when the secondary zone is under a low load, ice in the heat storage tank 2 is melted and heat loss occurs. There is fear. Therefore, a bypass valve 14 for dividing condensed water is provided in the pipe 7 between the secondary zone and the primary zone, and the opening degree of the bypass valve 14 is adjusted to reduce the flow rate of the return to the parent-child unit U '. To prevent heat loss in the heat storage tank 2. The degree of opening of the bypass valve 14 is adjusted by providing temperature sensors 15 for detecting the condensed water and outgoing water at the inlet and outlet pipes 7 of the primary zone, respectively, and controlling the temperature sensors 15 via cables 16. Water temperature data of condensed water and outgoing water is sent to the device 17, and the control device 17 controls the bypass valve 14 based on the water temperature data. At this time, the opening of the valve 18 on the side of the refrigerator 11 is also adjusted by the control device 17 in conjunction with the bypass valve 14, and the flow rate to be returned to the parent-child unit U 'is adjusted. Reference numeral 19 denotes a valve for adjusting the flow rate of the condensate to the refrigerator 12.

[Cooling operation after hours]

When the cooling operation is performed during a time period in which each heat storage tank 2 is not used, only the attached refrigerators 11 and 12 are operated to take out cold water. Downstream of each accessory machine, the extracted cold water is
Primary pump 20 for sending to secondary zone such as general air conditioning
Are provided respectively. Further, at night, the heat pump 1 of each ice heat storage unit U is operated using cheap electric power, and ice heat is stored in each heat storage tank 2. During the after-hour cooling operation, only the auxiliary equipment is operated, so that the bypass valve 14 is opened and the number of auxiliary equipment is controlled based on the temperature of the double water from the secondary zone. That is, the temperature of the double water is sensed by the temperature sensor 15, and the control device 17 controls the operation and stop of each of the refrigerators 11 and 12 based on the temperature data, and controls the number of the refrigerators 11 and 12. Thereby, optimal and efficient removal of cold water is performed.

[Heating operation in time]

In the winter season, when the daytime heating operation is performed, hot water is taken out of each heat storage tank 2 of each parent-child unit U 'that has stored hot water at night. The flow rate of the hot water flowing through each parent-child unit U 'is made uniform by each valve 8, and the load is leveled for each parent-child unit U' as a set. If the load cannot be covered only by each of the heat storage tanks 2, the heat pump 1 is operated in an auxiliary manner to perform two-stage heating to cope with a high load. It is optional to drive the accessory and take out hot and cold water from the accessory.

[Heating operation after hours]

When the heating operation is performed during a time period in which each heat storage tank 2 is not used, only the accessory device is operated to take out hot water and cold water. At night, each heat pump 1 is operated and each heat storage tank 2 is operated.
To store hot water. [Effects of the Invention] As described in detail above, the present invention provides an ice heat storage having a heat pump that exchanges heat with the outside via a heat medium, and an ice heat storage tank that stores ice heat from the heat pump via the heat medium. A method of controlling a unit, wherein two ice heat storage units are connected in parallel as a set of two units, a flow rate of a heat medium flowing through each ice heat storage unit is detected, and the heat medium of the heat medium is detected based on the flow rate data. Since the flow rate is controlled in units of sets, the air-conditioning load can be distributed in units of sets by connecting two units of ice heat storage units in parallel as a set. Since the flow rate of the flowing heat medium is controlled for each set, the flow rate of the heat medium flowing through each ice heat storage unit can be made uniform for each set, and the air conditioning load can be leveled for each set. This makes it possible to optimize and maximize the use of ice heat storage, and by changing the number of connected ice heat storage units in groups, from small-scale air conditioning to large-scale air conditioning, Can be easily applied to each air conditioning system.

[Brief description of the drawings]

1 and 2 show one embodiment of the present invention.
FIG. 1 is a flow diagram of a heat source to which the present invention is applied, and FIG. 2 is a schematic diagram of an ice heat storage unit. 1 ... heat pump, 2 ... heat storage tank, 6 ... flow meter, 7 ... piping, 8 ... valve, U ... ice heat storage unit, U '... parent-child unit.

Continuation of the front page (72) Inventor Utaro Seiki 2-16-1 Kyobashi, Chuo-ku, Tokyo Shimizu Construction Co., Ltd. (58) Field surveyed (Int. Cl. ⁶ , DB name) F28D 20/00 F24F 5 / 00 102

Claims (2)

(57) [Claims] 1. A method for controlling an ice heat storage unit, comprising: a heat pump that exchanges heat with the outside via a heat medium; and an ice heat storage tank that stores ice from the heat pump via a heat medium. Are connected in parallel as a set of two units, the flow rate of the heat medium flowing through each ice heat storage unit is detected, and the flow rate of the heat medium is controlled in the set unit based on the flow rate data. Characteristic method of controlling the ice heat storage unit. 2. A flow meter for detecting a flow rate of the heat medium is installed in a set unit upstream of each ice heat storage unit, and a flow rate of the heat medium is controlled downstream of each ice heat storage unit based on flow rate data. 2. The method of controlling an ice heat storage unit according to claim 1, wherein a set of valves is provided for each set.