KR101994408B1 - Driving method for defrosting of showcase cooling system - Google Patents

Abstract

The present invention relates to a method for controlling a defrosting operation of a showcase in which a defrosting operation is carried out in a showcase cooling system comprising a compressor, a condenser, an expansion valve and an evaporator, A control method comprising the steps of: (a) confirming a cooling temperature set for driving a cooling system; (b) a cooling mode operation step of driving a cooling cycle by cooling operation if the cooling temperature is 0 ° C or more; (c) if the cooling temperature is less than 0 ° C, extracting operation data including a cooling time and a stop time corresponding to the cooling temperature from the DB storage unit; (d) a temperature sensing step of sensing whether or not a set cooling temperature is reached while the cooling cycle is being driven by the cooling operation; (e) a defrosting mode operation step of driving a cooling cycle while repeating the cooling operation and the stop operation according to the extracted operation data after reaching the cooling temperature.

Description

Technical Field [0001] The present invention relates to a defrosting of a showcase cooling system,

The present invention relates to a running control of a showcase, and more particularly, to a method of controlling a natural defrosting operation of a showcase in which natural defrosting of an evaporator is performed without a defrost heater.

BACKGROUND ART Generally, a show case is a device for displaying these products while maintaining the freshness of foods such as meat, vegetables and beverages. Recently, it has also been used for storing and displaying medicines and cosmetics which should be kept at a certain temperature. The showcase generates cool air by using a cooling cycle and keeps the freshness by keeping the product refrigerated or frozen with this cool air.

1, an evaporator 5 is installed in an upper space of a housing 1 having a display space, and a compressor 2, a condenser 3, and an expansion valve 4) is installed. The show case generates cold air by heat exchange between the evaporation heat of the evaporator and the outside air temperature during the cooling cycle of the compressor 2, the condenser 3, the expansion valve 4 and the evaporator 5. At this time, the evaporator gathers on the surface due to the difference between the heat of evaporation and the temperature of the outside air. As described above, the frost formed on the surface of the evaporator gradually increases the heat exchange effect of the evaporator and increases the power consumption . Therefore, the show case is configured such that the defrost mode operation to remove the defrosting amount when it is excessively increased is essential.

In the conventional showcase, as shown in the figure, a defrost heater 6 is provided around the evaporator 5 to operate the heater 6 at a preset time to dissolve and freeze the frost formed in the evaporator 5 do.

As described above, the defrosting method using the defrost heater has a merit that defrosting is performed in a short time by providing high-temperature heat to the evaporator, but also the temperature inside the show case increases in the defrosting mode. Generally, in a showcase using a heater, it is confirmed that immediately after defrosting is completed, the temperature rises instantaneously to about 15 ° C higher than the set cooling temperature of the show case. Therefore, in the conventional showcase, the temperature inside the case rises to a temperature higher than the proper temperature of the product in a state where defrosting is completed, thereby affecting the quality of the product being displayed or stored. There is a drawback that this is consumed.

Further, in the conventional showcase using the defrost heater, the temperature of the evaporator tube and the temperature of the refrigerant flowing in the tube together with the defrosting of the surface of the evaporator are raised together by using the heater, There is a fear that the load is transmitted to cause malfunction of the cooling cycle or damage of the component.

In order to solve such a problem, a 'show case and its operation control method' of Korean Patent No. 10-0412533 (prior art document 1) includes a pair of evaporators provided on display shelves, and while the defrosting operation is performed in one evaporator, So that the temperature inside the display space is kept constant. The operation control method of the prior art 1 can exhibit the effect of not decreasing the temperature inside the display space but there is still a problem that the overpressure is applied to the pressure vessel because the temperature of the refrigerant and the evaporator tube operating in the defrosting mode are increased together In particular, since a pair of evaporators and defrost heaters must be installed in one display space, the structure is complicated and the manufacturing cost is increased.

In order to solve the above-mentioned problems, a 'control method of a refrigerated flat-type showcase' of the Korean Patent No. 10-0800619 (Prior Art 2) is a method of operating in a pre- The temperature inside the case is controlled in advance so as to become lower than the set reference temperature, thereby preventing the internal temperature from rising to a temperature higher than the temperature of the merchandise being displayed during the defrosting mode operation. The operation control method of the prior art document 2 shows an effect of preventing the internal temperature from rising beyond the predetermined temperature after the defrosting mode operation when considering only the maximum rising temperature, Therefore, there is a problem in the show case that the product is deformed or damaged due to a sudden temperature drop (i.e., freezing), and power consumption by the pre-cool mode is further consumed.

Korean Registered Patent No. 10-0412533 (Registered, Showcase, and Operation Control Method thereof) Registered Patent No. 10-0800619 (2008.01.28. Registered, Operation Control Method for Frozen Floor Showcase)

Disclosure of the Invention The present invention has been proposed in order to solve the above problems, and it is an object of the present invention to provide a showcase operation control method which can prevent a temperature rise inside a case by a defrost heater by removing a heater for defrosting inside a showcase The purpose is to provide.

It is another object of the present invention to provide an operation control method of a show case in which defrosting can be performed with low power by not requiring external power for heating the inside of the case.

In addition, the present invention provides a method of controlling a showcase operation in which defrosting of an evaporator is performed using a defrost fan together with control of a cooling cycle, so that efficient defrosting can be achieved while minimizing a temperature change (rise) .

According to an aspect of the present invention, there is provided a method for controlling defrost operation in a showcase cooling system comprising a compressor, a condenser, an expansion valve, and an evaporator, the method comprising the steps of: (a) (b) a cooling mode operation step of driving a cooling cycle by cooling operation if the cooling temperature is 0 ° C or more; (c) if the cooling temperature is less than 0 ° C, extracting operation data including a cooling time and a stop time corresponding to the cooling temperature from the DB storage unit; (d) a temperature sensing step of sensing whether or not a set cooling temperature is reached while the cooling cycle is being driven by the cooling operation; (e) a defrosting mode operation step of driving a cooling cycle while repeating the cooling operation and the stop operation according to the extracted operation data after reaching the cooling temperature.

Further, in the present invention, the cooling system may further include a defrost fan for blowing air to the surface of the evaporator, and in the defrosting mode operation of the step (e), defrosting using the blowing of the defrost fan And fan cycle driving is further performed.

Further, the defrost fan is driven in conjunction with any one of the cooling operation and the stop operation.

Further, the defrosting operation control method of the showcase cooling system of the present invention further includes: (f) a forced defrosting mode operation step of stopping the cooling operation when the forced stop operation is inputted during the cooling operation.

Here, if the stop time is input, the forced defrost mode operation proceeds to stop operation according to the input stop time data, then returns to the defrost mode operation according to the operation data extracted from the DB storage unit, The control unit returns to the defrost mode operation according to the operation data extracted from the DB storage unit after the stop operation is performed according to the stop time data extracted from the DB storage unit.

Also, the DB storage unit stores a plurality of cooling temperature information, cooling operation time information for performing defrosting for each cooling temperature, and stop operation time information in a database, and when the defrost fan is not driven for each cooling temperature The first operation data DB in which the cooling operation time information and the stop operation time for the cooling cycle drive of the defrost fan are database, the cooling operation time information for the cooling cycle operation when the defrost fan is driven, 2 operation data DB.

According to the present invention having the above-described structure, since the defrost heater is not provided inside the show case, the temperature rise inside the case by the defrost heater is not originally generated.

In addition, the present invention does not require external power for heating the inside of the case for defrosting purposes, so that no separate power for defrosting is consumed.

Further, according to the present invention, at the same time as controlling the cooling cycle, defrosting is prevented from being formed on the surface of the evaporator by using the defrost fan, so that efficient defrosting can be achieved and the effect of minimizing temperature change inside the showcase is exhibited.

Brief Description of the Drawings Fig. 1 shows a schematic structure of a showcase according to the prior art,
2 is a block diagram showing a schematic structure of a show case according to an embodiment of the present invention;
3 is a block diagram schematically illustrating a defrost system according to an embodiment of the present invention;
4 is a flowchart showing a defrost operation of a show case according to an embodiment of the present invention;
5 is a flowchart illustrating a defrosting process of a show case according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a block diagram showing a schematic structure of a show case according to an embodiment of the present invention, and FIG. 3 is a block diagram schematically showing a defrost system according to an embodiment of the present invention.

Referring to FIG. 2, a showcase according to an embodiment of the present invention includes an evaporator 14 disposed in an upper space of a housing (see 1 in FIG. 1) forming a display space, A condenser 12 and an expansion valve 13 are arranged and a refrigerant circulates along a tube connecting the compressor 11, the condenser 12, the expansion valve 13 and the evaporator 14, And the cold air is supplied to the display space inside the housing by the heat exchange action by the driving of the cooling cycle (10). A defrosting system 100 for controlling the driving of the cooling cycle 10 is provided on one side of the cooling cycle 10 to prevent the frost from growing on the surface of the evaporator 14. At the same time, The defrost fan 200 is installed.

Here, the defrost system 100 is a configuration for controlling the cooling cycle operation of the showcase under the optimum condition in which no evaporation is formed in the evaporator. The defrost system 100 is implemented in a microcomputer format in which a predetermined operation program is embedded It can be installed inside the show case. In addition, the defrost fan 200 is installed on the upper portion of the evaporator, and controls the cooling cycle operation by the defrost system 100 to provide wind to the evaporator 14 to prevent the casting of the cast on the surface of the evaporator. At this time, the driving of the defrosting fan 200 is also controlled by the defrosting system 100.

3, the defrosting system 100 according to the embodiment of the present invention includes a cooling temperature collecting unit 120, an operation data extracting unit 130, a cooling cycle driving unit 140, a defrost fan driving unit A temperature control unit 160, a mode selection unit 170, a display unit 180, a database unit 190, and a control unit 110 for controlling the operation of these units.

Here, the cooling temperature collecting unit 120 collects the preset cooling temperature in the basic mode or collects the cooling temperature set by the user in a configuration for collecting the showcase internal temperature aiming at cooling. The cooling temperature of the basic mode can be set in advance by a predetermined program at the time of producing the show case, and the user-set cooling temperature can be arbitrarily inputted by the user through the temperature controller 160.

The operation data extracting unit 130 is configured to extract time data of the cooling operation and the stop operation in accordance with the set cooling temperature. The operation data extracting unit 130 includes a cooling operation time and a stop operation time corresponding to the cooling temperature by the basic mode or the user input Extracts the data from the database unit 190, and provides the extracted data to the control unit 110.

The cooling cycle driving unit 140 drives a cooling cycle of the showcase circulating the compressor, the condenser, the expansion valve, and the evaporator. At this time, the cooling cycle driving unit 140 drives the cycle while repeating the cooling operation and the stop operation in a predetermined time unit under the control of the control unit 110.

The defrost fan driving unit 150 is configured to drive the defrost fan 200 independently of the cooling cycle driving unit 140 or to operate the defrost fan in conjunction with the cooling cycle driving unit 140 . That is, the defrost fan driving unit 150 can selectively drive the defrost fan only when the defrost fan is driven at all times or when the cooling cycle is during the cooling operation or the stop operation. By selectively driving the defrost fan when the cooling cycle is in the cooling operation or the stop operation, efficient defrosting can be performed according to the defrosting state, and the power consumption due to the defrosting can be minimized.

The temperature control unit 160 is configured to arbitrarily adjust the cooling temperature by the user, and the user can arbitrarily set the cooling temperature differently from the cooling temperature set in the basic mode. The temperature input through the temperature controller 160 is collected by the cooling temperature collector 120 and provided to the controller.

The mode selection unit 170 selects a mode in which the user forcibly operates the defrosting system in the defrosting mode when the cooling cycle is driven. The defrost system of the show case is automatically controlled to selectively operate in the cooling mode or the defrosting mode according to the cooling temperature, but can be adjusted to operate in the forced defrosting mode according to the user's choice. That is, when the forced defrosting mode is inputted through the mode selection unit 170, the mode selecting unit 170 selects the defrosting system to operate in the forced defrosting mode manually by the user. . At this time, the stop operation time can also be arbitrarily inputted in the forced defrosting mode, and the control unit 110 controls the cooling cycle drive in which the cooling operation and the stop operation according to the original defrosting mode are repeated after stopping operation for the input time do. On the other hand, when the stop operation time by the user is not inputted in the forced defrosting mode, the control unit 110 performs the stop operation for the stop operation time according to the original defrost mode, .

The display unit 180 is configured to display the operation status of the defrost system and may include a plurality of lamps using LEDs. The display unit 180 may display a cooling operation, a stop operation, an automatic mode, a forced mode, To the driver.

The temperature control unit 160, the mode selection unit 170, and the display unit 180 may be provided on one side of the housing of the show case so that the user can easily operate and confirm the control unit 110, .

In addition, the database unit 190 stores data such that the optimum defrosting operation can be performed according to the cooling temperature, and the operation data including the cooling operation time and the stop operation time according to each cooling temperature is stored in a database . The cooling temperature can be divided into 0 ° C or higher, -3 ° C, -5 ° C, -8 ° C, -10 ° C, etc., and the cooling operation time and the stop operation time of the cooling cycle according to each cooling temperature are stored. In this case, the cooling operation time and the stop operation time according to the respective cooling temperatures can be determined through repeated experiments. For example, when the cooling temperature is 0 ° C or more, the cooling operation = ∞ and the stop operation time = When the cooling temperature is -5 ° C, the cooling operation time is 4 hours and the stop operation time is 20 minutes. Thus, the cooling operation for 4 hours and the stop operation for 20 minutes can be repeatedly operated. The data on the cooling operation time and the stop operation time should be determined so as to minimize the rise of the internal temperature while optimal defrosting is performed with respect to the cooling temperature.

The operation data stored in the database unit 190 includes first operation data for the cooling operation time and the stop operation time when only the cooling cycle is driven, the cooling operation time when the defrost fan is driven together, and the stop operation time As shown in FIG. That is, when the defrost fan 100 is driven together, the defrosting system 100 can reduce the burden on the defrosting control by the cooling cycle drive, thereby increasing the cooling operation time and reducing the stopping operation time. It can be minimized. At this time, the second operation data when the defrosting fan is driven are the third operation data when the defrost fan is normally driven, the fourth operation data when the defrost fan is driven only during the cooling operation, The second operation data may be stored separately.

The defrost system 100 having the above-described structure drives the cooling cycle with the time data of the cooling operation and the stop operation corresponding to the optimal conditions according to the set cooling temperature, thereby minimizing the temperature rise and power consumption inside the showcase Ensure that the amplifier is not impregnated or that the impregnated impurities are easily removed. Hereinafter, a defrosting operation process of the show case by the defrost system will be described.

FIGS. 4 and 5 are flowcharts illustrating a defrosting operation of a show case according to an embodiment of the present invention. FIG. 4 shows a defrosting process according to a basic mode, and FIG. 5 shows defrosting processes according to a cooling temperature input.

Referring to FIG. 4, the defrosting operation of the show case according to the basic mode will be described. First, when the power is supplied to start the cooling operation of the show case, the cooling cycle driving unit performs the cooling operation so that the inside of the show case is cooled to the set temperature (S11, S12). When it is confirmed that the cooling cycle driving unit is cooled to the set temperature through the temperature sensor, the cooling operation is stopped and the stop operation is performed (S13). After the stop operation is performed for a predetermined time, The cooling operation and the stop operation are repeated to drive the cooling cycle (S12, S13). At this time, the operation data on the cooling temperature of the basic mode and the cooling operation time and the stop operation time of the repeated cooling cycles are stored in advance in the database unit. For example, in the basic mode, the cooling temperature is set to -5 After the initial cooling operation has proceeded to -5 deg. C, the cooling operation for 4 hours and the stop operation for 20 minutes are set to be repeated. At this time, the defrost fan can also be driven simultaneously with the cooling cycle in which the cooling operation and the stop operation are repeated (S15). The defrost fan is driven in conjunction with any one of the cooling operation or the stop operation, As shown in FIG.

The cooling cycle of the defrosting mode is repeatedly performed until the operation termination command is inputted (S14). The defrosting is efficiently performed by the cooling operation and the stop operation according to the optimum condition, so that the temperature rise inside the showcase is minimized . When the cooling temperature is set to -5 DEG C in the defrosting control operation of the present invention, when the cooling operation for 4 hours and the stop operation for 20 minutes are repeated as described above, the cooling operation and the stop operation In a temperature range of 5 ° C or less.

Referring to FIG. 5, the defrosting operation according to the external cooling temperature input is as follows. When the power is supplied and the cooling operation of the show case is started (S21), the cooling temperature collector confirms whether or not the cooling temperature is input (S22). The operation data extracting unit extracts operation data including a cooling operation time and a stop operation time for the inputted cooling temperature from the database unit (S23). When it is confirmed that the cooling cycle driving unit is cooled to the inputted temperature through the temperature sensing sensor while the cooling operation is performed so that the inside of the show case is cooled to the input temperature, the cooling operation is stopped and the stop operation is performed (S23, S24 ). In addition, the cooling cycle driving section performs the stop operation for a predetermined time in accordance with the operation data extracted from the database section, and then repeats the cooling operation and the stop operation to drive the cooling cycle. At this time, since the cooling operation time and the stop operation time at which the defrosting is performed under the optimal condition at each cooling temperature are stored in the database section, the cooling operation time for the cooling temperature inputted from the outside is also optimized The defrosting operation is carried out with the stop operation time, so that the defrosting can be performed efficiently.

The cooling cycle of the above process is repeatedly performed until the operation end command is input (S26), and the defrost fans may be driven together with the cooling cycle (S27).

In the defrosting operation of the above process, when it is not confirmed that the cooling temperature is input in the cooling temperature collecting unit, the cooling cycle is driven in the basic mode as shown in FIG. 4. When the cooling temperature of 0 ° C or more is inputted, And the cooling cycle is driven in the cooling mode in which only the cooling operation is continuously performed.

When the forced defrosting command is input by the user during the defrosting operation according to the above-described procedure, the cooling cycle driving unit stops the cooling operation even during the cooling operation and immediately switches to the stop operation. And then the cooling cycle in which the cooling operation and the stop operation are repeated is driven again.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

100: Defrost system
110: control unit 120: cooling temperature collecting unit
130: operation data extracting unit 140: cooling cycle driving unit
150: defrost fan driving unit 160: temperature adjusting unit
170: mode selection unit 180: display unit
190:

Claims (7)

A defrost operation control method for a showcase cooling system comprising a compressor, a condenser, an expansion valve and an evaporator,
(a) confirming the set cooling temperature for driving the cooling system;
(b) a cooling mode operation step of driving a cooling cycle by cooling operation if the cooling temperature is 0 ° C or more;
(c) if the cooling temperature is less than 0 ° C, extracting operation data including a cooling time and a stop time corresponding to the cooling temperature from the DB storage unit;
(d) a temperature sensing step of sensing whether or not a set cooling temperature is reached while the cooling cycle is being driven by the cooling operation;
(e) a defrosting mode operation step of driving a cooling cycle while repeating the cooling operation and the stop operation according to the extracted operation data after reaching the cooling temperature,
Wherein the cooling system further comprises a defrost fan for blowing air to the evaporator surface,
In the defrosting mode operation step of the step (e), the defrost fan cycle driving using the blowing of the defrost fan is performed in addition to the cooling cycle driving,
The DB storage unit stores,
A plurality of cooling temperature information, cooling operation time information for performing defrosting for each cooling temperature, and stop operation time information are stored in a database,
The first operation data DB in which the cooling operation time information and the stop operation time for the cooling cycle drive when the defrost fan is not driven are stored in the database, and the cooling cycle operation when the defrost fan is driven The cooling operation time information and the stop operation time are stored in the database as the second operation data DB,
The second operation data is divided into third operation data when the defrost fan is always driven, fourth operation data when the defrost fan is driven only during the cooling operation, and fifth operation data when the defrost fan is driven only during the stop operation Wherein the defrosting control is performed by the defrosting control unit. delete The refrigeration system of claim 1, wherein the defrost fan comprises:
Wherein the controller is driven in conjunction with any one of the cooling operation and the stop operation. The method according to claim 1,
(f) a forced defrosting mode operation step of stopping the cooling operation when a forced stop operation is inputted during the cooling operation. 5. The fuel cell system according to claim 4, wherein in the forced defrost mode operation,
When the stop time is inputted, the stop operation is performed according to the inputted stop time data, the operation returns to the defrost mode operation according to the operation data extracted from the DB storage unit,
Wherein when the stop time is not inputted, the stop operation is performed according to the stop time data extracted from the DB storage unit, and then the operation returns to the defrost mode operation according to the operation data extracted from the DB storage unit. Control method of defrosting operation of cooling system. delete delete

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