KR101443822B1 - Defrosting perception system using degree of superheat in refrigerant - Google Patents

Abstract

According to the present invention, there is provided a defrost detection system using superheat of a refrigerant, comprising: a compressor for compressing a gaseous refrigerant into a high-temperature and high-pressure state; A condenser for exchanging heat between the refrigerant introduced from the compressor and the external heat source; An expansion valve for expanding the refrigerant introduced from the condenser into a low-temperature and low-pressure state; And an evaporator that receives heat from an external heat source to heat the refrigerant flowing through the expansion valve and exchanges heat with the refrigerant to change the phase of the refrigerant into a vapor state, and the refrigerant discharged from the evaporator flows into the compressor The system comprising: an evaporation pressure sensor for sensing an evaporation pressure of a refrigerant in the evaporator and converting the evaporation pressure into an evaporation temperature; An evaporator temperature sensor for sensing a pipe surface temperature at the evaporator outlet; And a defrost termination sensor for detecting a surface temperature of the heat exchange fin of the evaporator.

Description

[0001] The present invention relates to a defrosting perception system using superheat of a refrigerant,

The present invention relates to a defrost detection system used in a refrigeration cycle.

Generally, a refrigeration cycle is a system that allows the temperature of a specific space to be controlled by using a refrigerant. The system to which the refrigeration cycle is applied is widely applied to refrigerator, freezer, air conditioner, heat pump system, and the like.

Basically, the refrigeration cycle includes a compressor, a condenser, an expansion valve, and an evaporator.

Generally, the temperature around the evaporator is lowered because the heat exchanger corresponding to the evaporator implements the phase change of the refrigerant by heat exchange between the refrigerant and the outside air. The temperature (sensible heat) and moisture (latent heat) must be removed in order to remove the indoor generating load from the evaporator. In this process, if the water becomes frosted and gets frozen in the evaporator, it should be removed.

Generally, when the evaporation occurs in the evaporator, the heat exchange efficiency of the evaporator is significantly lowered. Therefore, when a malfunction occurs in the evaporator, the air temperature around the evaporator and the evaporation pressure of the refrigerant flowing in the evaporator are lowered, so that the evaporator can not phase-change the refrigerant to the gaseous state. In other words, if sexuality occurs, it will not function as an evaporator.

In this case, the process of removing the gaps formed on the surface of the evaporator by applying a heat source to the evaporator is called a defrost. An example of such a defrosting system is disclosed in Laid-Open Patent Application No. 2012-0134251.

However, as a method of performing the defrosting in the conventional refrigeration cycle system, a timer method of activating the heater for defrosting unconditionally at a predetermined time interval is used. In this timer-type defrosting system, energy for defrosting is not efficiently used, and energy, that is, cost is wasted.

Meanwhile, as a method of performing defrosting in a conventional refrigeration cycle system, a method of starting defrosting by determining the defrosting time by measuring the temperature around the evaporator has been used. However, in the conventional defrosting method, the superheat degree of the refrigerant in the evaporator is not taken into consideration at all.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a refrigerating cycle system capable of detecting a defrosting time on the basis of the degree of superheat of refrigerant inside and outside the evaporator, And to provide a defrost detection system that significantly improves defrost efficiency.

According to an aspect of the present invention, there is provided a defrost detection system using a superheat degree of a refrigerant, comprising: a compressor for compressing a gaseous refrigerant into a high-temperature and high-pressure state;

A condenser for exchanging heat between the refrigerant introduced from the compressor and the external heat source;

An expansion valve for expanding the refrigerant introduced from the condenser into a low-temperature and low-pressure state; And

And an evaporator that receives heat from an external heat source to heat the refrigerant flowing from the expansion valve and exchanges heat with the refrigerant to change the phase of the refrigerant into a vapor state,

Wherein the refrigerant discharged from the evaporator is introduced into the compressor,

An evaporation pressure sensor for sensing the evaporation pressure of the refrigerant in the evaporator and converting the evaporation pressure into the evaporation temperature;

A compressor suction pipe temperature sensor for sensing a pipe surface temperature of the compressor inlet; And

And a defrost termination sensor for detecting the surface temperature of the heat exchange fin of the evaporator.

And an evaporator temperature sensor for sensing the surface temperature of the pipe at the outlet of the evaporator.

When the difference between the temperature sensed by the compressor suction pipe temperature sensor and the sensed temperature sensed by the evaporation pressure sensor reaches a preset value, the defrosting operation is started. When the temperature sensed by the defrost end sensor reaches a predetermined value The defrosting operation is terminated,

It is preferable that the compressor suction pipe temperature sensor and the evaporation pressure sensor do not sense the temperature until the defrosting operation is finished.

When the difference between the temperature sensed by the evaporator temperature sensor and the sensed temperature sensed by the evaporation pressure sensor reaches a predetermined value, the defrosting operation is started. When the temperature sensed by the defrost termination sensor reaches a predetermined value, Lt; / RTI >

After the defrosting operation is started, it is preferable that the evaporator temperature sensor and the evaporation pressure sensor do not sense the temperature until the defrosting operation is terminated.

Wherein the defrosting operation is started when a difference between an arithmetic mean value of the temperature detected by the evaporator temperature sensor and a temperature sensed by the compressor suction pipe temperature sensor and a temperature sensed by the evaporation pressure sensor reaches a preset value, The defrosting operation is terminated when the temperature sensed by the sensor reaches a certain value,

After the defrosting operation is started, the evaporator temperature sensor and the evaporation pressure sensor can not detect the temperature until the defrosting operation is terminated.

The defrosting operation may be started when the temperature sensed by the defrost end sensor reaches a predetermined defrost start temperature, and the defrosting may be terminated when the temperature sensed by the defrost end sensor reaches a preset defrost termination temperature.

The defrost detection system using the superheat degree of the refrigerant according to the present invention includes a sensor for detecting the evaporation pressure of the refrigerant in the evaporator, a sensor for detecting the surface temperature of the pipe flowing into the compressor, And detecting the start point of the defrost operation based on the degree of superheat of the refrigerant inside and outside of the evaporator, thereby providing an effect of precise and efficient defrost operation without being influenced by the external environment.

1 is a schematic block diagram of a defrost detection system using superheat of a refrigerant according to the present invention.

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

1 is a schematic block diagram of a defrost detection system using superheat of a refrigerant according to the present invention.

Referring to FIG. 1, a defrost detection system 10 (hereinafter referred to as a defrost detection system) using a superheat degree of a refrigerant according to a preferred embodiment of the present invention includes a compressor 20, a condenser 30, an expansion valve 40 An evaporator 50, an evaporation pressure sensor 60, an evaporator temperature sensor 65, a compressor intake pipe temperature sensor 70, and a defrost end sensor 75. The defrost detection system 10 sequentially connects the compressor 20, the condenser 30, the expansion valve 40 and the evaporator 50 to sequentially circulate the refrigerant to the compressor 20, And the refrigerant flow path. The known refrigerant cycle refrigerant can be charged into the refrigerant passage.

The compressor (20) is a device for compressing a gaseous refrigerant into a relatively high temperature and high pressure gaseous state. Since the structure of the compressor 20 is similar to that of a known compressor structure, a detailed description thereof will be omitted. Additional devices such as oil separators may be installed at the outlet of the compressor (20).

The condenser 30 is a type of heat exchanger, and is a component that lowers the temperature and pressure of the refrigerant by performing heat exchange between the high temperature high pressure refrigerant introduced from the compressor 20 and the external heat source. The external heat source for heat-exchanging with the condenser 30 may be configured in various ways such as water, air, and the like.

The expansion valve 40 is a component that expands the refrigerant introduced from the condenser 30 into a low-temperature and low-pressure state. The refrigerant flowing into the expansion valve (40) is in a liquid state at a middle temperature and a high pressure, and the refrigerant discharged from the expansion valve (40) is in a low-temperature,

The evaporator 50 is a component that receives heat from an external heat source to heat the refrigerant flowing from the expansion valve 40 and exchanges heat with the refrigerant, thereby converting the refrigerant into a vapor state.

The refrigerant discharged from the evaporator (50) flows into the compressor (20).

It is apparent that components other than the above-described components such as four-way valves for switching the circulation direction of the refrigerant can be added.

The evaporation pressure sensor 60 senses the evaporation pressure of the refrigerant in the evaporator 50 and converts the evaporation pressure to the evaporation temperature. The evaporation pressure sensor 60 is a sensor for sensing the evaporation pressure of the refrigerant, and the sensor includes a processing circuit for converting the evaporation pressure into a temperature. The evaporation pressure sensor 60 may convert the evaporation pressure to a temperature according to a table that converts the saturation pressure according to the type of the refrigerant to the saturation temperature. The evaporation pressure sensor 60 may employ a known sensor.

The evaporator temperature sensor 65 senses the surface temperature of the pipe at the outlet of the evaporator 50. The evaporator temperature sensor 65 measures the temperature of the air at the outlet of the evaporator 50. If the evaporator (50) is not hot, heat exchange between the air and the refrigerant is smoothly performed in the evaporator (50), so that the temperature of the refrigerant discharged to the evaporator (50) rises. In addition, the air around the outlet of the evaporator (50) can be regarded as air that is not heat-exchanged with the refrigerant. The reason is that since the refrigerant sufficiently exchanges heat with the air during the passage through the evaporator 50, no further heat exchange occurs at the outlet side of the evaporator 50. However, when the surface of the evaporator 50 is hot, heat exchange between the refrigerant and the air is not smoothly performed. Therefore, the temperature of the refrigerant passing through the evaporator 50 becomes relatively low. Therefore, the difference between the temperature measured by the evaporator temperature sensor 50 and the temperature measured by the evaporation pressure sensor 60 becomes large. This difference in temperature is defined as the basic superheat degree (C).

The compressor suction pipe temperature sensor 70 senses the pipe surface temperature at the inlet of the compressor 20. The compressor suction pipe temperature sensor 70 may measure the temperature of the refrigerant flowing into the compressor 20. The temperature sensed by the compressor suction pipe temperature sensor 70 may be used as the compressor suction overheat or as the defrost start temperature.

When the evaporator (50) becomes hot, the air flow around the heat exchanging pin of the evaporator (50) is reduced. Therefore, heat exchange between the refrigerant and the outside air in the evaporator 50 is not properly performed. Therefore, when the evaporator (50) becomes hot, the degree of superheat of the refrigerant inside and outside the evaporator (50) becomes low and the temperature of the outlet of the evaporator (50) does not rise. If the temperature of the outlet of the evaporator (50) is lowered, it can be determined that a malfunction occurs.

Generally, the evaporation pressure of the refrigerant is determined by the compressor selection, the evaporation pressure of the refrigerant is controlled by the expansion valve, and the expansion amount is changed. However, the evaporation pressure of the refrigerant is decreased as the evaporator temperature is lowered. Therefore, if a malfunction occurs in the evaporator, the degree of superheat of the refrigerant depends on the amount of air passing around the evaporator regardless of the change in evaporation pressure of the refrigerant. That is, if the amount of air passing around the evaporator is reduced, the degree of superheat of the refrigerant is lowered. It is possible to set the condition for starting the defrost operation by sensing the decrease in the superheat of the refrigerant.

The defrost termination sensor 75 is a sensor for detecting the surface temperature of the heat exchange fin of the evaporator 50.

Hereinafter, a method of starting and ending the defrost operation in the defrost system of the refrigeration cycle including such components will be described.

The start point of the defrosting operation is determined by combining the temperature values sensed by the evaporation pressure sensor 60, the evaporator temperature sensor 65, the compressor suction pipe temperature sensor 70 and the defrost end sensor 75 You can decide. Also, when the temperature T4 sensed by the defrost termination sensor 75 reaches a predetermined condition, the defrosting operation can be terminated.

As described above, the defrost operation start point and the defrost operation end point can be set by inputting the condition of how the temperature values measured by the respective sensors are combined in a separate controller (not shown).

A method of determining the defrosting operation by combining the evaporation pressure sensor 60, the evaporator temperature sensor 65 and the temperature T4 sensed by the defrost termination sensor 75 will be described.

The type of refrigerant is selected in the controller (not shown). For example, the controller selects R404A as the refrigerant.

Then, the defrost operation start condition is set. More specifically, when the difference (T3 - T2) between the temperature T3 sensed by the compressor suction pipe temperature sensor 70 and the temperature T2 sensed by the evaporation pressure sensor 60 reaches a predetermined value, Start operation. The difference T3-T2 between the temperature T3 detected by the compressor suction pipe temperature sensor 70 and the temperature T2 detected by the evaporation pressure sensor 60 is defined as a compressor suction superheating degree A, When the compressor suction superheat degree (A) is used as the start variable of the defrost operation, the user can set by inputting a constant value to the controller according to the use condition.

The defrosting operation may be terminated when the temperature T4 sensed by the defrost termination sensor 75 reaches a predetermined value. The defrosting operation can be terminated when the temperature T4 sensed by the defrost termination sensor 75 reaches, for example, 20 占 폚. It is preferable that the evaporator temperature sensor 65 and the evaporation pressure sensor 60 do not sense the temperature until the defrosting operation is terminated. This is to maintain the defrosting operation for a predetermined time. Further, it is possible to set the operation delay time so that the defrosting operation is started after a predetermined time elapses after the defrost operation start condition is detected. The operation delay time may be, for example, about 30 seconds.

On the other hand, another defrost operation start condition can be set. That is, the arithmetic average value ((T1 + T3) / 2) of the temperature T1 detected by the evaporator temperature sensor 65 and the temperature T3 sensed by the compressor suction pipe temperature sensor 70, The defrosting operation can be started when the difference between the temperature T2 detected by the temperature sensor 60 reaches a preset value. An arithmetic mean value ((T1 + T3) / 2) of the temperature T1 detected by the evaporator temperature sensor 65 and the temperature T3 sensed by the compressor suction pipe temperature sensor 70 and the arithmetic average value ) Is defined as the average superheat degree (B). The average superheat degree (B) is advantageous in that it is possible to set a more stable starting point of the defrost operation as compared with the compressor suction superheat degree (A). The controller can set the defrosting operation to be started when the value of the average superheating degree (B) reaches, for example, 5.0K.

The defrosting operation is terminated when the temperature T4 detected by the defrost termination sensor 75 reaches a predetermined value (e.g., 20 DEG C). At this time, it is preferable that the evaporator temperature sensor 65 and the evaporation pressure sensor 60 do not sense the temperature until the defrosting operation is terminated after the defrosting operation is started. This is to maintain the defrosting operation for a predetermined time. Further, it is possible to set the operation delay time so that the defrosting operation is started after a predetermined time elapses after the defrost operation start condition is detected. The operation delay time may be, for example, about 30 seconds.

On the other hand, another defrost operation start condition can be set. That is, when the difference (T1-T2) between the temperature T1 detected by the evaporator temperature sensor 65 and the temperature T2 detected by the evaporation pressure sensor 60 reaches a predetermined value, defrosting operation is started do. The difference T1-T2 between the temperature T1 detected by the evaporator temperature sensor 65 and the temperature T2 detected by the evaporation pressure sensor 60 is defined as a basic superheat degree C, The defrosting operation can be started when the basic superheat degree C reaches, for example, 5.0K. The basic superheat degree C can be set by the user inputting the corresponding value in the controller according to the use condition. For example, when the refrigerant system is operated in a state where the front surface area of the air inlet side of the evaporator 50 is shut off as the basic superheat degree C, the temperature T1 detected by the evaporator temperature sensor 65 and the evaporation pressure The difference of the temperature T2 sensed by the sensor 60 can be set to the defrost operation starting point.

When the temperature T4 sensed by the defrost termination sensor 75 reaches a predetermined value, the defrosting operation is terminated. The defrosting operation can be terminated when the temperature T4 sensed by the defrost termination sensor 75 reaches, for example, 20 占 폚. It is preferable that the evaporator temperature sensor 65 and the evaporation pressure sensor 60 do not sense the temperature until the defrosting operation is terminated. This is to maintain the defrosting operation for a predetermined time. Further, it is possible to set the operation delay time so that the defrosting operation is started after a predetermined time elapses after the defrost operation start condition is detected. The operation delay time may be, for example, about 30 seconds.

On the other hand, another defrost operation start condition can be set. That is, the defrosting operation is started when the temperature sensed by the defrost end sensor 75 reaches a predetermined defrost start temperature. That is, it is possible to set the defrosting start point to be determined with only one defrost end sensor 75. For example, the controller can set the defrosting operation to start when the temperature T4 sensed by the defrost termination sensor 75 reaches -1 [deg.] C. When the temperature T4 sensed by the defrost termination sensor 75 reaches a predetermined defrost termination temperature (for example, 20 deg. C), the defrosting may be terminated at the controller.

As described above, the defrost detection system using the superheat degree of the refrigerant according to the present invention includes a plurality of sensors for measuring the superheat degree of the refrigerant flowing into the compressor from the evaporator, and the temperature difference sensed by the sensors reaches a predetermined value The defrosting operation is started. Therefore, the defrosting operation start point is set appropriately according to the external environment in which the defrosting system according to the present invention is installed, thereby providing the effect of enabling the defrosting operation stably and efficiently.

In the defrosting system according to the present invention, it is preferable that the controller sets the defrosting operation to start after the compressor has reached the minimum operation time. It is obvious that the defrosting system of the defrosting system according to the present invention can be applied to any one of electric defrosting by electric heater and hot gas defrosting method.

Meanwhile, the defrost system according to the present invention can set the maximum defrosting time in advance even if the sensed temperature by the defrost end sensor does not reach a preset value to prevent infinite defrosting operation from continuing.

While the present invention has been described with reference to the preferred embodiments, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention as defined by the appended claims.

10: Defrost detection system using superheat of refrigerant
20: Compressor
30: condenser
40: expansion valve
50: Evaporator
60: Evaporation pressure sensor
65: Evaporator temperature sensor
70: compressor suction pipe temperature sensor
75: Defrost termination sensor
A: Suction heat of compressor
B: Average superheat degree
C: Basic superheat degree

Claims (6)

A compressor for compressing gaseous refrigerant into a high temperature and high pressure state;
A condenser for exchanging heat between the refrigerant introduced from the compressor and the external heat source;
An expansion valve for expanding the refrigerant introduced from the condenser into a low-temperature and low-pressure state; And
And an evaporator that receives heat from an external heat source to heat the refrigerant flowing from the expansion valve and exchanges heat with the refrigerant to change the phase of the refrigerant into a vapor state,
Wherein the refrigerant discharged from the evaporator is introduced into the compressor,
An evaporation pressure sensor for sensing the evaporation pressure of the refrigerant in the evaporator and converting the evaporation pressure into the evaporation temperature;
A compressor suction pipe temperature sensor for sensing a pipe surface temperature of the compressor inlet; And
And a defrost termination sensor for detecting a surface temperature of the heat exchange fin of the evaporator,
When the difference between the temperature sensed by the compressor suction pipe temperature sensor and the sensed temperature sensed by the evaporation pressure sensor reaches a preset value, the defrosting operation is started. When the temperature sensed by the defrost end sensor reaches a predetermined value The defrosting operation is terminated,
Wherein the compressor suction pipe temperature sensor and the evaporation pressure sensor do not sense the temperature until the defrosting operation is terminated after the defrosting operation is started. A compressor for compressing gaseous refrigerant into a high temperature and high pressure state;
A condenser for exchanging heat between the refrigerant introduced from the compressor and the external heat source;
An expansion valve for expanding the refrigerant introduced from the condenser into a low-temperature and low-pressure state; And
And an evaporator that receives heat from an external heat source to heat the refrigerant flowing from the expansion valve and exchanges heat with the refrigerant to change the phase of the refrigerant into a vapor state,
Wherein the refrigerant discharged from the evaporator is introduced into the compressor,
An evaporation pressure sensor for sensing the evaporation pressure of the refrigerant in the evaporator and converting the evaporation pressure into the evaporation temperature;
A compressor suction pipe temperature sensor for sensing a pipe surface temperature of the compressor inlet; And
And a defrost termination sensor for detecting a surface temperature of the heat exchange fin of the evaporator,
Further comprising an evaporator temperature sensor for sensing the temperature of the pipe surface at the outlet of the evaporator,
When the difference between the temperature sensed by the evaporator temperature sensor and the sensed temperature sensed by the evaporation pressure sensor reaches a predetermined value, the defrosting operation is started. When the temperature sensed by the defrost termination sensor reaches a predetermined value, Lt; / RTI >
Wherein the evaporator temperature sensor and the evaporation pressure sensor do not sense a temperature until the defrosting operation is terminated after the defrosting operation is started. A compressor for compressing gaseous refrigerant into a high temperature and high pressure state;
A condenser for exchanging heat between the refrigerant introduced from the compressor and the external heat source;
An expansion valve for expanding the refrigerant introduced from the condenser into a low-temperature and low-pressure state; And
And an evaporator that receives heat from an external heat source to heat the refrigerant flowing from the expansion valve and exchanges heat with the refrigerant to change the phase of the refrigerant into a vapor state,
Wherein the refrigerant discharged from the evaporator is introduced into the compressor,
An evaporation pressure sensor for sensing the evaporation pressure of the refrigerant in the evaporator and converting the evaporation pressure into the evaporation temperature;
A compressor suction pipe temperature sensor for sensing a pipe surface temperature of the compressor inlet; And
And a defrost termination sensor for detecting a surface temperature of the heat exchange fin of the evaporator,
Further comprising an evaporator temperature sensor for sensing the temperature of the pipe surface at the outlet of the evaporator,
Wherein the defrosting operation is started when a difference between an arithmetic mean value of the temperature detected by the evaporator temperature sensor and a temperature sensed by the compressor suction pipe temperature sensor and a temperature sensed by the evaporation pressure sensor reaches a preset value, The defrosting operation is terminated when the temperature sensed by the sensor reaches a certain value,
Wherein the evaporator temperature sensor and the evaporation pressure sensor do not sense a temperature until the defrosting operation is terminated after the defrosting operation is started. delete delete delete

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