KR19980067579A - High efficiency regenerative cooling system using midnight power - Google Patents

Abstract

It is an object of the present invention to operate a compressed refrigerator using cheap midnight power during operation of a phase change material (PCM) and ice heat storage system, and store the cold heat in the heat storage tank as a PCM or ice form using the cold heat manufacturing process of the evaporator. The present invention relates to a high efficiency regenerative cooling system using a late night electric power, which is used for cooling air conditioning by recovering cold water from a heat storage tank as needed.

The configuration of the present invention comprises a storage device for cold storage consisting of an outdoor unit, an expansion valve, an evaporator and a storage tank performing the functions of a compressor, a condenser and a regenerator; The liquid solution dehumidification apparatus which becomes a dehumidifier including a rare solution tank provided with a solution pump, a concentrated solution tank, a regenerator containing a condenser, and an air tank is integrated together.

Description

High efficiency regenerative cooling system using midnight power

According to the present invention, a cold freezer is operated using a low-temperature late night electric power during operation of a phase change material (hereinafter, referred to as PCM) and an ice storage system. The present invention relates to a high efficiency regenerative cooling system using a late night electric power that collects cold water from a heat storage tank and uses it for cooling air conditioning during the day. In particular, the condenser is used as a regenerator of a liquid dehumidifier to dehumidify liquid. Is used as a regenerated heat source for energy storage, and at the same time saves cold heat (electrical energy as thermal energy) and condenser array makes dehumidifying solution as agricultural solution (heat energy as concentration difference chemical energy). High-efficiency cold storage using midnight power to increase energy utilization It relates to a complex cooling system.

In general, the conventional liquid dehumidifier has been used a lot of processes, such as low humidity or constant humidity is required for industrial purposes, the principle is as follows.

Dehumidification solution (triethylene glycol, lithium chloride solution, etc.) having a strong affinity for moisture is to control the humidity of the treated air by adjusting the temperature and concentration of the solution.

The liquid dehumidifier is divided into three parts: a dehumidifying unit, a solution heat exchanger, and a regenerating unit.

The dehumidifying unit wets the air-liquid contactor (fill tower, pin-coil type, spray type) to remove moisture from the treated air so that the dehumidifying solution sprayed from the solution distributor is well in contact with the air so as to dehumidify and cool the air well. Will be absorbed.

The dehumidifying solution absorbed by the moisture is passed through the solution heat exchanger by the solution pump, enters the regeneration unit, and is heated and dehumidified by the regeneration heat source to be used as a concentrated solution.

In the solution heat exchanger, the ash solution from the dehumidifying part, which is a low temperature part, is exchanged with the hot agricultural solution from the regeneration part, which is a high temperature part, thereby increasing the temperature of the rare solution to save the amount of regenerative heat required for heating to the required regeneration temperature, and dehumidifying It is to lower the temperature of the agricultural solution entering the part so that the moisture absorption in the dehumidification unit.

The regeneration unit heats the rare solution from the dehumidifying unit by an external heat source to increase the vapor pressure of the solution than the regeneration air, thereby transferring water vapor from the solution to the regeneration air, that is, regenerating (dehumidifying) the solution. The temperature and amount will vary depending on the humidity level of the process air required in the dehumidifying section.

The present invention has been made in consideration of the above circumstances, and an object thereof is to combine a liquid dehumidifier with a PCM and an ice storage type cooling system to increase the efficiency of use of each energy and to save energy related to a cooling power load in the summer season. It is to provide a high-efficiency, refrigerated cooling system using a late-night power that can utilize the late-night power and waste heat, such as developed countries, by reducing the power demand for the daytime power by using the midnight power.

The present invention provides an accumulator comprising an outdoor unit, an expansion valve, an evaporator, and a cold storage tank performing the functions of a compressor, a condenser, and a regenerator to achieve the above object; By providing a high efficiency regenerative cooling system using a midnight electric power by integrally combining a liquid solution dehumidification apparatus, which is a rare solution tank having a solution pump and a farm solution tank, a regenerator including a condenser, and a dehumidifier including an air tank. Is achieved.

1 is an overall configuration diagram of the present invention,

2 is a flow chart of using midnight power in accordance with the present invention;

3 is a flowchart used during the day according to the present invention.

Explanation of symbols on the main parts of the drawings

1 ... compressor 2 ... outdoor unit

3 ... expansion valve 4 ... evaporator

5 ... axial cold air conditioning 6 ... air conditioner

7 ... solution tank 8 ... farm solution tank

9, 10 ... solution pump 11 ... cold water pump

12, 15 ... solution collector 13, 16 ... eliminator

14 ... solution distributor

Next, embodiments of the present invention will be described in detail with reference to the drawings.

1 to 3 illustrate a high efficiency regenerative cooling system using a midnight power according to the present invention. The high efficiency regenerative cooling system using a late night power is an outdoor unit including a compressor 1 and a condenser as shown in FIG. (2), a storage cooler composed of an expansion valve (3), an evaporator (4) and a storage cooling tank (5), an outdoor unit (2) equipped with a solution tank (7, 8), a regenerator, and an air conditioner (6). The liquid dehumidifier is composed of a complex system.

By using the condenser of the compressed cooling and cooling system as a regenerator of the liquid dehumidifier, the compactness of the device can be achieved, and at the same time, the energy utilization efficiency can be improved by using the regeneration heat source of the condenser array.

Figure 2 is a flow chart using a late night power in accordance with the present invention, the operation system diagram at the time of energy storage (cooling and agricultural liquid storage) utilizing cheap night power in the late night time zone (for example 22:00 ~ 08:00) As shown, the part indicated by the dotted line shows the pipe portion that does not work at night.

The refrigerant compressed by the high temperature and high pressure in the compressor 1 is transferred to the condenser of the outdoor unit 2 through the pipe 17 to condense by transferring heat to the dehumidifying rare solution and regenerated air sprayed by the solution distributor 14.

The high pressure condensed refrigerant is depressurized while passing through the expansion valve 3 through the pipe 18 and moved to the evaporator 4 through the pipe 19.

The evaporator (4) cools the brine solution from the cold storage tank (5) by evaporation of the refrigerant, and stores the PCM or water stored in the cold storage tank (5) using low temperature brine made in the evaporator (4) through the pipe (22). Freeze to cool.

In addition, the refrigerant evaporated by taking heat from the brine in the evaporator 4 enters the compressor 1 through a pipe 20 to form a compression refrigeration cycle.

Thus, during the late-night power utilization storage refrigeration cycle, the rare solution stored during the day in the rare solution tank (7) is sent to the solution distributor (11) by the solution pump (9) and sprayed on the surface of the condenser (2) heat exchanger fin-tube to provide It receives heat from the high temperature and high pressure refrigerant of the heat and is regenerated by releasing moisture to the external regeneration air.

The dehumidifying solution scattered in the regeneration air is collected by the eliminator 13 and collected on the solution collecting plate 12 and stored in the concentrate tank 8.

This stored concentrate is used when daytime dehumidification load treatment is required.

3 is a flow chart used during the day according to the present invention, which shows an operating system diagram when the air conditioner is operated during the day.

When there is a cooling load in the building due to the high outside temperature, cold water is pumped by the cold water pump 11 to the indoor air conditioner 6 through the pipe 23 in the cold storage tank 5 stored in the late night time to process the indoor cooling load. The cold water having a high temperature is recovered to the cold storage tank 5 through the pipe 24.

In addition, the dehumidification solution which is regenerated and stored in the middle of the night using the condenser 2 arrangement is sent from the storage tank 8 to the air conditioner 6 through the pipe 25 by the solution pump 10 and by the solution distributor 14. (6) Spray on the outer surface to remove moisture from the supply air to handle the dehumidification load.

The dehumidifying rare solution absorbed by the moisture is collected in the solution collecting plate 15, stored in the rare solution tank 7 through the pipe 26, and regenerated at night.

Since the cold storage tank 5 is thermal energy storage, heat insulation is necessary to prevent heat loss, but solution storage does not need heat insulation, and only blocks external air, thereby reducing the facility cost.

The compressed cooling cycle is shown in the dashed line in the drawing, and may be operated during the day depending on the required cooling load and the capacity of the cold storage tank 5, or the cooling load may be fully loaded with only the cold storage tank 5 and the agricultural liquid. If it can be processed, it does not need to be operated.

Next, the effects will be described with reference to FIGS. 2 and 3.

In the present invention, by combining the principle of the liquid dehumidifier with the PCM and ice storage cooling system to increase the efficiency of the respective energy utilization and to expand the application field, the energy associated with the rapidly increasing summer cooling power load In terms of power leveling and reduction of daytime electric power demand through the use of energy saving and midnight power, it is possible to apply heat storage materials (PCM, ice) and heat storage system that can actively utilize late-night power and waste heat like the US and Japan. It can be.

In addition, the advantages obtained through the present invention for the case where the refrigeration system used in the complex system is a PCM material using refrigeration system is as follows.

In the case of the ice storage heat storage system that has been widely commercialized, the latent heat of fusion of ice is used, and thus, the evaporator operating temperature of the cycle is low, and thus the overall system coefficient is lowered. PCM is used for refrigeration air conditioning of latent heat of fusion of these materials.

That is, in the case of PCM storage cooling by operating the freezer by using midnight power, the evaporator operating temperature is higher than that of the ice storage heat storage system, and the system coefficient of the compression cycle during the storage cooling is increased.

However, the temperature of the cold water, which is made to utilize the latent heat of fusion of the cooled PCM, for air conditioning, is about 10 ~ 14 ℃.

When cooling the building by sending it to the fan coil unit with cold water in this temperature range, there is a disadvantage that it cannot handle the required dehumidification cooling load among the total building cooling load, and the latent heat of fusion of PCM is smaller than the latent heat of fusion of ice. Due to the disadvantage that the heat storage tank becomes larger for cooling loads, the conventionally developed PCM storage system has not been smoothly spread, while the present invention uses PCM storage for late-night power storage. In order to handle the load, the compression cycle performance factor of PCM using the PCM is higher than that of the ice heat storage system, and it has the advantage of handling both the dehumidification and the sensible cooling load during the day.

And when the ice is stored in the heat storage tank by using a compression refrigeration cycle for 10 hours from 22:00 to 8:00 am, which is the power saving time at night, the dehumidifying solution is used by using the condenser arrangement that was discarded in the conventional case. Energy storage efficiency is increased because it is stored as a farm solution.

In addition, it is possible to meet the required cold water temperature by mixing cold water extracted from the heat storage tank during the day and returning air after returning from the indoor air conditioning, and the field requiring low temperature dehumidification due to the expansion of the dehumidification capacity using the dehumidifying solution stored in the agricultural liquid chill. Expansion of applications can be achieved.

The present invention can reduce the capacity of the refrigeration system when combined with the night-time cold storage operation and daytime operation, and it is possible to further reduce the capacity of the heat source freezer by reducing the dehumidification load through the use of agricultural liquid storage. On the other hand, in the conventional air conditioning system, the heat source capacity is determined for the peak cooling load per hour, and the electric charge is the sum of the base rate and the meter rate, and the base rate is determined by the contracted power. The lower the number, the lower the base rate and the significant reduction in operating costs by the use of cheap midnight power.

Claims (4)

High efficiency regenerative cooling system using midnight power; a) a cold storage device comprising an outdoor unit, an expansion valve, an evaporator and a cold storage tank performing a function of a compressor, a condenser and a regenerator; b) It is characterized by integrally combining the liquid solution dehumidification apparatus, which is a rare solution tank having a solution pump, a concentrated solution tank, a regenerator including a condenser, and a dehumidifier including an air tank. The method of claim 1; And a condenser of the compressor storage device is operated as a regenerator of the liquid dehumidifier to use the condenser array as a regeneration heat source. The method of claim 1; The high-efficiency storage cooling system using a late-night power, characterized in that the farm solution tank for storing the regenerated farm solution using the late-night electricity is sealed so that moisture does not seep from the outside without the insulation construction. The method of claim 1; The dehumidification cooling load in the air conditioner is performed by the farm solution sent from the farm solution tank, and the sensible cooling load is performed by cold water made in the cold storage tank.