JPH0448416Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a circulating water antifreeze control device for an air conditioning system that prevents circulating water from freezing when the air conditioning system is stopped.

[Conventional technology]

A conventional circulating water freezing prevention control device for an air conditioning system is equipped with a detector that detects the circulating water temperature or ambient temperature, as described in Japanese Patent Application Laid-Open No. 13962/1983, and the ambient temperature detected by this detector is When a drop below the set value was detected, the circulation pump was operated at a constant flow rate to circulate the circulating water and prevent it from freezing.

[Problem that the invention attempts to solve]

However, the circulating water antifreeze control device for conventional air conditioning systems uses a circulation pump selected to supply the amount of circulating water necessary for air conditioning from a cold heat generating source to prevent the circulating water from freezing. The amount of water used was too large just to prevent the circulating water from freezing. Additionally, the circulating water system of an air conditioning system generally has a large heat capacity and a large time constant for temperature change, so even if it is detected that the temperature has dropped by 1°C below a predetermined temperature, for example, it will not freeze immediately. Therefore, immediately operating the circulation pump to prevent freezing or increasing the circulation flow rate after detecting a drop in water temperature wastes energy.

An object of the present invention is to provide a circulating water antifreeze control device for an air conditioning system that reduces energy consumption during antifreeze operation.

[Means for solving problems]

In order to achieve the above object, the present invention includes a detector that detects the temperature of circulating water, a circulating water system that determines the temperature of circulating water for each of multiple temperature ranges, and sets the circulating flow rate to increase as the temperature decreases. a storage unit that stores the flow rate signal; a selection unit that obtains the circulation signal corresponding to the temperature range division in the storage unit when the water temperature detected by the detector continues in that temperature range division for a predetermined time; The present invention is characterized in that it is provided with a flow rate variable mechanism that adjusts the circulation flow rate of the pump unit based on the circulation signal obtained by the selection section.

[Effect]

Since the circulating water freezing prevention control device for an air conditioning system according to the present invention has the above-described configuration, it is possible to obtain a circulating flow rate set for each temperature range, and to prevent freezing by appropriately setting the circulating water flow rate. The energy consumption of the operating pump unit can be suppressed. Moreover, since the selection section takes into account the duration of temperature range classification, the pump unit does not operate unnecessarily when there is no risk of freezing, and this also reduces energy consumption in the pump unit. be able to.

〔Example〕

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a system diagram of a control device for preventing freezing of circulating water in an air conditioning system using an inverter as a variable flow rate mechanism.

The air conditioning unit 1 is connected to a cold/heat source unit 2 via a pump unit 3, and this pump unit 3 circulates cold and hot water generated in the cold/heat source unit 2, and is controlled by an antifreeze device 9. There is. This antifreeze device 9 includes an inverter 4 that adjusts the circulating flow rate by changing the motor rotation speed of the pump unit 3, a storage section 5 that stores a preset circulating flow rate signal, and a detection section that detects the temperature of the circulating water. 6, and a selection section 7 which selects a circulation flow rate signal from the storage section 5 according to the signal from the detection section 6 and outputs it to the inverter 4. The storage unit 5 stores, for each of the plurality of water temperature ranges, an electric motor rotation speed signal corresponding to a flow rate that is effective for freezing prevention and consumes the least amount of energy, which has been determined in advance through experiments or the like. Further, the detection unit 6 is disposed inside the circulating water pipe, detects the water temperature, and sends the signal to the selection unit 7.
to communicate. The selection unit 7 stores freezing start times determined in advance through experiments, corresponding to each water temperature range in the storage unit 5, and also has a mechanism for integrating water temperature duration for each water temperature range. It is equipped.

Here, the antifreeze device 9 is configured to be inactive when the air conditioning system is in operation, and to be operated when the air conditioning system is inactive.

FIG. 2 exemplifies the relationship between the classification of water temperature ranges stored in the storage unit 5 and the rotational speed signal, with the horizontal axis representing the water temperature t, and the vertical axis representing the rotational speed signal n. In this example, the rotation speed signal is set high so that the lower the water temperature, the higher the circulation flow rate, and the water temperature range is
It is divided into T ₁ to T ₄ , and rotation speed signals N ₁ to _{N 4} are determined corresponding to these divisions.

Assume that it is now a winter night and the air conditioning system is in a dormant state, and therefore the antifreeze device 9 is in an operating state. The detection section 6 detects the water temperature at any time and inputs a water temperature signal to the selection section 7. If the water temperature at this time is outside the temperature range classification of the storage unit 5 shown in FIG.
The selection section 7 does not output. Therefore, since no rotational speed signal is applied to the inverter 4, the motor of the pump unit 3 does not rotate.

However, when the water temperature decreases and reaches the temperature range classification _T1 shown in FIG. 2, the selection unit 6 starts integrating the duration of that temperature. If the water temperature rises again before this duration reaches the predetermined duration in the temperature region _T1 , that is, the freezing start time, the electric motor will not operate as in the case described above. However, when this duration reaches the freezing start time, the selection section 7
selects the rotational speed signal N ₁ corresponding to the temperature range division T ₁ from the storage unit 5 and outputs it to the inverter 4 .
Then, the inverter 4 provides an output corresponding to the rotational speed signal _N1 to the electric motor of the pump unit 3, so that the circulating water is circulated at a flow rate corresponding to the rotational speed signal.

Moreover, the water temperature further decreased and the temperature range classification T ₂
, and when the duration reaches the freezing start time, the selection unit 7 selects the rotational speed signal N ₂ and outputs it to the inverter 4 similarly to the above case.
The same applies to the other temperature range divisions T ₃ and T ₄ ,
In this way, freezing of the circulating water can always be prevented with minimum energy consumption.

In the above embodiment, the inverter 4 is used to adjust the circulating flow rate of the pump unit, but other flow rate variable mechanisms may also be used.

[Effect of idea]

As explained above, the present invention has a storage unit that stores a circulating flow rate signal that determines the temperature of circulating water for each of a plurality of temperature ranges, and sets the circulating flow rate so that the lower the temperature, the greater the circulating flow rate, and the detected temperature. a selection unit that obtains the circulation signal corresponding to the temperature range division in the storage unit when the water temperature of the range division continues for a predetermined period; and a flow rate that adjusts the amount of circulating water in the pump unit based on the circulation signal obtained by the selection unit. Since a variable mechanism is provided, the circulation flow rate can be selected to be small enough to prevent freezing, and
In addition, the selection unit takes into consideration the duration of water temperature and does not operate the pump unit when there is no risk of freezing, so the circulating water antifreeze control of the air conditioning system reduces energy consumption in the pump unit and prevents the circulating water from freezing. A device is obtained.

[Brief explanation of the drawing]

Fig. 1 is a principle diagram of a control device for preventing freezing of circulating water in an air conditioning system according to an embodiment of the present invention, and Fig. 2 is a characteristic diagram showing the relationship between the temperature range classification and the rotation speed signal stored in the storage unit of Fig. 1. It is a diagram. 1...Air conditioning unit, 2...Cold heat source unit,
3... Pump unit, 5... Storage section, 6... Detection section, 7... Selection section, 9... Freeze prevention device.

Claims (1)

[Scope of utility model registration request] Freezing of circulating water in an air conditioning system where a detector is installed to detect the temperature of the circulating water, and the pump unit is operated based on the detection results of this detector to circulate the circulating water from the cold/heat source unit to the air conditioning unit to prevent freezing. In the prevention control device, the temperature of the circulating water is determined for each of a plurality of temperature range divisions, and the storage unit stores a circulating flow rate signal set such that the lower the temperature, the larger the amount of circulating water is, and the sensor detects the circulating water. a selection section that obtains the circulating flow rate signal corresponding to the temperature range section in the storage section when the water temperature continues in that temperature range section for a predetermined period of time; A circulating water freezing prevention control device for an air conditioning system, characterized in that a variable flow rate mechanism is provided to adjust the circulating flow rate of the air conditioning system.