KR102467449B1 - system for error detection of indirect cooling refrigerator - Google Patents

Abstract

The present invention relates to a commercial indirect cooling refrigerator error detecting system which has improved inspection convenience, comprising: a power unit; a compressor driving detection unit; an internal refrigerator temperature detection unit; a defrosting temperature detection unit; a defrosting driving detection unit; a fan driving detection unit; a door opening detection unit; a control unit; and a light emitting diode.

Description

Industrial indirect cooling refrigerator error detection system {system for error detection of indirect cooling refrigerator}

The present invention relates to a method and system for detecting errors in commercial intercooler refrigerators, and more particularly, to an error detection system for commercial intercooler refrigerators with improved inspection convenience.

In general, a refrigerator is an electronic product used to keep food fresh for a certain period of time. It includes a main body having a freezing compartment for storing food frozen and a refrigerating compartment for refrigerating storage therein, and installed on the front of the main body to open and close the freezer compartment. A freezing compartment door that opens and closes the refrigerating compartment and a refrigerating compartment door that opens and closes the freezing compartment and the refrigerating compartment, a heat exchange unit that generates cold air necessary for cooling the freezing compartment and the refrigerating compartment, and a cold air supply unit that supplies the cold air generated in the heat exchange unit to the freezing compartment and the refrigerating compartment. can be configured.

Here, the heat exchange unit includes a compressor for compressing a low-temperature, low-pressure gas refrigerant into a high-temperature, high-pressure gas refrigerant, a condenser for condensing the high-temperature and high-pressure gas refrigerant into a high-temperature, high-pressure liquid refrigerant, and a high-temperature, high-pressure liquid A capillary that converts refrigerant into a low-temperature, low-pressure liquid refrigerant, an evaporator that evaporates a low-temperature, low-pressure liquid refrigerant into a low-temperature, low-pressure gaseous refrigerant, and a connecting pipe that integrates the above-mentioned components and provides a passage for refrigerant movement. can be configured.

Therefore, when power is supplied in a state in which food for freezing is filled in the freezing chamber and food for refrigeration is filled in the refrigerating chamber, the compressor constituting the heat exchange unit is driven by receiving a control signal from the controller to convert low-temperature, low-pressure gas refrigerant to high-temperature, high-pressure gas. compressed with refrigerant. And, the compressed high-temperature, high-pressure gaseous refrigerant is guided through the connection pipe and condensed into a high-temperature, high-pressure liquid refrigerant while passing through the condenser. After being converted into a low-temperature, low-pressure liquid refrigerant that has rapidly dropped, it is continuously guided to a connecting pipe and passed through an evaporator, where it can be converted into a low-temperature, low-pressure gaseous refrigerant and evaporated.

At this time, since the surrounding air is heat-exchanged by the evaporation action of the evaporator, cool air is generated. As described above, since a part of the cold air generated in the evaporator is supplied to the freezing chamber by the cold air supply means to cool the freezing chamber, food stored in the freezing chamber is frozen and a part of the cold air is supplied to the refrigerating chamber to cool the refrigerating chamber. Food stored in the refrigerator compartment is refrigerated.

However, conventional refrigerators have a problem in that it is difficult for the user to visually check the temperature state of the refrigerator or whether an error has occurred.

Korean Patent Publication No. 10-1997-0081534

In order to solve the above problems, an object of the present invention is to provide an error detection system for commercial intercooler refrigerators with improved inspection convenience.

In order to solve the above problems, the present invention provides a power supply unit for supplying power for driving a refrigerator; It is connected to the power supply unit, and is connected to a compressor voltage detection sensor and a compressor current detection sensor that are circuit-connected to a compressor for compressing gaseous refrigerant to detect power supply of the compressor and to generate a compression drive signal for detecting circuit disconnection and short circuit. mechanical movement detection unit; a freezer temperature sensor that is circuit-connected to a refrigerator compartment temperature sensor and a freezer compartment temperature sensor for detecting temperatures inside the refrigerator and freezer compartments provided in the refrigerator to generate a freezer temperature signal; A defrost temperature sensor for generating a defrost temperature signal by being circuit-connected to a defrost temperature sensor for detecting a temperature of a defrost heater provided to remove frost formed on a refrigerant pipe bent in an evaporator that evaporates liquid refrigerant; Circuit connected to a defrost voltage detection sensor and a defrost current detection sensor for detecting power supply of a defrosting means including a plurality of heat radiation fins provided between the refrigerant pipes and the defrost heater to generate a defrost drive signal for detecting circuit disconnection and short circuit Defrost drive detection unit; a fan drive detection unit that is circuit-connected to a rotation sensor that electrically detects whether or not the drive fan provided in the refrigerator is driven and generates a rotation signal; a door open detector circuit connected to an open sensor that electrically detects a disconnection of a switching circuit that is disconnected when a door unit provided in the refrigerating chamber and the freezing chamber is opened and generates a door open detecting signal; Circuits are connected to the compressor driving detection unit, the refrigerator internal temperature detection unit, the defrost temperature detection unit, the defrosting driving detection unit, the fan driving detection unit, and the door opening detection unit, and the compression driving signal, the refrigerator internal temperature signal, and the defrost temperature a control unit receiving a control signal including a signal, the defrost drive signal, the rotation signal, and the door open detection signal; and a light emitting diode connected to the power supply unit and connected to a circuit to the control unit, provided as an element emitting light in at least three colors, and emitting light in a plurality of different colors in response to the control signal, wherein the light emitting diode comprises: and a plurality of monochromatic light source units emitting different monochromatic light sources to selectively emit light sources of three primary colors including red, green, and blue, wherein the controller corresponds to the control signal and emits different monochromatic light sources from the monochromatic light source units. Independently and individually control each of the monochromatic light source units so that the combination is performed, and the control unit detects that the compression drive signal is not detected from the compressor drive sensor for a predetermined time or longer and the rotation signal is not detected from the fan drive sensor. When the defrost drive signal is not detected from the defrost drive sensor for a predetermined time or longer and the defrost temperature signal from the defrost temperature sensor is not detected to be higher than a preset temperature within a preset time, the light emitting diode displays the first color. generating a first control signal to emit light, and the control unit generates a second control signal so that the light emitting diode emits light in a second color when the internal temperature signal from the internal temperature sensor deviates from a predetermined range; When the door open detection signal from the open detection unit is detected for a predetermined time or more, a third control signal is generated so that the light emitting diode emits light in a third color, and the compression drive signal, the rotation signal, and the defrost drive signal are sensed, When the defrost temperature signal is detected to be less than the preset temperature within a preset time, the refrigerator internal temperature signal is detected within a preset range, and the door open detection signal is not detected for less than a preset time, the light emitting diode displays a fourth It provides an error detection system for a commercial in-fridge refrigerator, characterized in that it generates a fourth control signal to emit light in color.

Meanwhile, the present invention provides a first step in which power for driving the refrigerator is supplied through a power supply unit and temperatures inside the refrigerating compartment and the freezing compartment provided in the refrigerator are set; The compressor drive detection unit connected to the power supply unit and connected to the compressor voltage detection sensor and the compressor current detection sensor connected to the compressor circuit for compressing the gas refrigerant to detect the power supply of the compressor and the compression drive signal for detecting circuit disconnection and short circuit and a refrigerator compartment temperature sensor for detecting temperatures inside the refrigerator and freezer compartments and a freezer temperature sensor circuit connected to the refrigerator compartment temperature sensor, which are provided in the refrigerator, generate an internal temperature signal and are curved in the evaporator for evaporating liquid refrigerant. A defrost temperature sensor circuit connected to a defrost temperature sensor for detecting the temperature of the defrost heater provided for defrosting the defrost implanted in the refrigerant pipe generates a defrost temperature signal, and a plurality of heat radiation fins provided between the refrigerant pipes and the defrost heater A defrost drive detection unit connected to a defrost voltage detection sensor and a defrost current detection sensor for detecting the supply of power to the defrosting means including generates a defrost drive signal for detecting circuit disconnection and short circuit, and whether or not the driving fan provided in the refrigerator is driven. The fan drive detection unit circuit connected to the rotation detection sensor electrically detects a rotation signal, and the opening detection sensor electrically detects the disconnection of the switching circuit that is disconnected when the door unit provided in the refrigerating compartment and the freezing compartment is opened. A second step of generating a door open detection signal by the connected door open detection unit; and circuits connected to the compressor driving detecting unit, the refrigerator internal temperature detecting unit, the defrost temperature detecting unit, the defrost driving detecting unit, the fan driving detecting unit, and the door opening detecting unit, so that the compression driving signal, the refrigerator internal temperature signal, and the defrost A control unit receiving a control signal including a temperature signal, the defrost drive signal, the rotation signal, and the door open detection signal is connected to the power supply unit and is connected to a circuit to the control unit and is provided as an element that emits light in at least three colors In response to the control signal, the light emitting diode including a plurality of monochromatic light source units emitting light in a plurality of different colors and emitting different monochromatic light sources so that light sources of three primary colors including red, green, and blue are selectively emitted. Provided is a method for detecting an error in a commercial in-fridge refrigerator including a third step of individually and independently controlling each other so that different monochromatic light sources emitted from each of the monochromatic light source units are combined in response to a signal.

Through the above solution, the present invention provides the following effects.

First, the control unit controls the light emitting diodes that emit light in at least three colors to display the refrigerating and freezing operation states in various colors that are easily identifiable by the naked eye, corresponding to the normal operation state, the internal temperature state, the defrost state, and the door open state. Since the location of error occurrence can be easily identified only with the color, the inspection convenience can be remarkably improved.

Second, the control unit generates a first control signal so that the light emitting diode emits light in a first color only when the compression drive signal, the rotation signal, and the defrost drive signal are not detected, and the defrost temperature signal is not detected as higher than a preset temperature within a preset time. Since the user can easily recognize the indication of occurrence of an error in the warehouse by generating a , convenience of use can be improved.

Third, the control unit generates a second control signal so that the light emitting diode emits light in a second color when the internal temperature signal deviates from the predetermined range, and the light emitting diode emits light in a third color when the door opening detection signal is detected for a predetermined time or longer. If possible, the third control signal is generated so that the displayed color is changed according to the priority when an error occurs, so that inspection convenience can be improved.

Fourth, when the light emitting diode generates the first control signal displayed in the first color, the light emitting diode blinks with various blinking cycles in response to whether the compression drive signal, the rotation signal, the defrost drive signal, and the defrost temperature signal are individually detected or not detected. Therefore, it is possible to quickly determine the cause of the error and improve inspection convenience.

1 is a block diagram showing an error detection system for commercial in-fridge refrigerators according to an embodiment of the present invention.
2 and 3 are flowcharts illustrating a method for detecting an error in a commercial in-fridge refrigerator according to an embodiment of the present invention.

Hereinafter, a method and system for detecting an error in a commercial intercooler refrigerator according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing an error detection system for commercial intercooler refrigerators according to an embodiment of the present invention, and FIGS. 2 and 3 are flowcharts showing an error detection method for commercial intercooler refrigerators according to an embodiment of the present invention.

As shown in FIGS. 1 to 3, the error detection system 100 for commercial intercooler refrigerators according to an embodiment of the present invention includes a power supply unit 10, a compressor drive detection unit 20, a refrigerator internal temperature detection unit 30, a first It includes an upper drive detection unit 40, a defrost temperature detection unit 50, a fan operation detection unit 60, a door open detection unit 70, a control unit 80, and a light emitting diode 90.

In addition, in the method for detecting an error in a commercial intercooler refrigerator according to an embodiment of the present invention, the power supply, the internal temperature of the refrigerating chamber and the freezing chamber are set (s10), the compressor driving detection unit generates a compression driving signal for circuit disconnection and short circuit detection, Temperature sensor generates internal temperature signal, defrost drive sensor that detects power supply to defrost unit generates defrost drive signal for detecting disconnection and short circuit, defrost temperature sensor generates defrost temperature signal, fan drive sensor generates rotation signal and door open sense The branch generates a door open detection signal (s20), and the control unit is provided as an element that emits light in at least three colors, and emits light in a plurality of different colors in response to the control signal, but a light source of three primary colors including red, green, and blue The light emitting diodes including a plurality of monochromatic light source units emitting different monochromatic light sources to selectively emit light are individually and independently controlled to combine the different monochromatic light sources emitted from each monochromatic light source unit in response to a control signal (s30 ) includes a series of steps.

Here, the power supply unit 10 is preferably provided to supply power for driving the refrigerator 200 . At this time, the power supply unit 10 includes the compressor drive detection unit 20, the freezer temperature detection unit 30, the defrost temperature detection unit 50, the defrost drive detection unit 40, and the fan drive detection unit 60. ), the door open detection unit 70, the control unit 80, the light emitting diode 90, the compressor 230, the condenser 240 condensing the gaseous refrigerant into a liquid, the evaporator 250, the defrosting means 260 Power is connected to the driving fan 270 to supply power.

Further, the compressor driving detection unit 20 is connected to the power supply unit 10 and is circuit-connected to the compressor 230 that compresses the gaseous refrigerant to detect power supply of the compressor 230 to detect circuit disconnection and short circuit. It is preferable to be provided to generate a compression drive signal for.

At this time, the compressor driving detection unit 20 may include a compressor voltage detection sensor and a compressor current detection sensor to detect circuit disconnection and short circuit of the compressor 230 . In addition, the compressor driving detection unit 20 repeatedly generates a compression driving signal at a predetermined cycle when detecting power supply to the circuit through receiving sensor signals from the compressor voltage detection sensor and the compressor current detection sensor, and generates the compression driving signal It may be provided as a microprocessor that transmits to the control unit 80.

On the other hand, the freezer temperature sensor 30 is connected to the power supply unit 10 and is configured to sense the internal temperatures of the refrigerator compartment 210 and the freezer compartment 220 provided in the refrigerator 200 to generate an interior temperature signal. It is desirable to be

Here, the freezer temperature sensor 30 includes a refrigerator compartment temperature sensor provided to detect the temperature inside the refrigerator compartment 210 and a freezer compartment temperature sensor provided to detect the temperature inside the freezer compartment 220. It is desirable to have

In addition, the freezer temperature detection unit 30 repeatedly generates freezer temperature signals including the refrigerator compartment temperature signal and the freezer compartment temperature signal at predetermined intervals by receiving sensor signals from the refrigerator compartment temperature sensor and the freezer compartment temperature sensor. and may be provided as a microprocessor for transmitting the internal temperature signal to the controller 80.

On the other hand, the defrost drive detection unit 40 is connected to the power supply unit 10, a plurality of heat dissipation fins (not shown) provided between refrigerant pipes (not shown) curvedly disposed in the evaporator 250 for evaporating liquid refrigerant. ) And the power supply of the defrosting means 260 including the defrosting heater 261 for defrosting the refrigerant pipe (not shown) is provided to generate a defrosting drive signal for detecting circuit disconnection and short circuit this is preferable

At this time, the defrost drive detection unit 40 may include a defrost voltage detection sensor and a defrost current detection sensor for supplying power to the defrost heater 261 of the defrosting means 260 and detecting circuit disconnection and short circuit. have. In addition, the defrost drive detection unit 40 repeatedly generates a defrost drive signal at a predetermined cycle when detecting power supply to the circuit through sensor signal reception from the defrost voltage detection sensor and the defrost current detection sensor, and the defrost drive signal It may be provided as a microprocessor that transmits to the control unit 80.

And, the defrost temperature sensor 50 is connected to the power supply unit 10 and may include a defrost temperature sensor for detecting the temperature of the defrost heater 261, and is provided to generate a defrost temperature signal this is preferable Here, the defrost temperature detection unit 50 repeatedly generates the defrost temperature signal at a predetermined cycle by receiving a sensor signal from the defrost temperature sensor for detecting the temperature of the defrost heater 261, and converts the defrost temperature signal to the defrost temperature signal. It may be provided as a microprocessor that transmits to the control unit 80.

In addition, the fan drive detection unit 60 may include a rotation sensor that is connected to the power supply unit 10 and electrically detects whether or not the driving fan 270 provided in the refrigerator 200 is driven. , The fan drive detection unit 60 may be provided as a microprocessor that repeatedly generates a rotation signal at a predetermined cycle by receiving a sensor signal from the rotation sensor and transmits the rotation signal to the control unit 80. At this time, at least one driving fan 270 is provided to circulate air inside each of the refrigerating compartment 210 and the freezing compartment 220 in the inter-cooling refrigerator, and may be disposed in the refrigerating compartment 210 and the freezing compartment 220. have. At this time, the rotation detection sensor may be provided with a motion detection sensor, a laser sensor, etc. to electrically detect whether the driving fan 270 is driven, but is not limited thereto.

And, the door opening detection unit 70 is connected to the power supply unit 10 and includes a refrigerating compartment door 211 and a freezing compartment door 221 provided in the refrigerating compartment 210 and the freezing compartment 220, respectively. It is preferable to be provided to generate a door open detection signal when the door parts 211 and 221 are opened.

Here, a plurality of door open detection units 70 are provided to selectively open the refrigerating compartment door 211 hinged to the refrigerating compartment 210 and the freezing compartment 220 to selectively open the refrigerating compartment 210. Each of the freezer compartment door parts 221 hingedly connected to the freezer compartment 220 may be disposed.

The door open detection unit 70 includes a switching circuit that is disconnected when the refrigerating compartment door unit 211 and the freezer compartment door unit 221 are opened, and an open sensor that electrically detects disconnection of the switching circuit. may be provided. At this time, when the switching circuit is disconnected, the door open detection unit 70 may repeatedly generate the door open detection signal at a preset cycle through receiving a sensor signal from the door open detection sensor. That is, the door open detection unit 70 repeatedly generates the door open detection signal at a preset cycle when the refrigerating compartment door 211 and the freezing compartment door 221 are opened, and transmits the defrosting drive signal to the control unit 80. It can be provided as a microprocessor that transmits to.

Meanwhile, the control unit 80 is connected to the power supply unit 10, and includes the compressor drive detection unit 20, the refrigerator internal temperature detection unit 30, the defrost temperature detection unit 50, and the defrost operation detection unit ( 40), circuit connected to the fan drive detection unit 60 and the door open detection unit 70 to detect the compression drive signal, the refrigerator internal temperature signal, the defrost temperature signal, the defrost drive signal, the rotation signal, and the door open detection Preferably, it is provided to receive a control signal including a signal to perform an operation process. At this time, the controller 80 may include a timer circuit for counting time. In addition, the compressor operation detection unit 20, the freezer temperature detection unit 30, the defrost temperature detection unit 50, the defrost operation detection unit 40, the fan drive detection unit 60, and the door open detection unit 70 may be integrated with the controller 80 as a single microprocessor, or may be electrically connected to each other in a separately provided state.

At this time, in the present invention, the control unit 80 includes the compressor drive detection unit 20, the refrigerator internal temperature detection unit 30, the defrost temperature detection unit 50, the defrost drive detection unit 40, and the fan driving feeling. Receiving a control signal including the compression drive signal, the internal temperature signal, the defrost temperature signal, the defrost drive signal, the rotation signal, and the door open detection signal from the branch 60 and the door open detection unit 70 A case in which calculation processing is performed will be described as an example, but in some cases, the compressor drive detection unit 20, the refrigerator internal temperature detection unit 30, the defrost temperature detection unit 50, and the defrost operation detection unit 40 In the fan drive detection unit 60 and the door open detection unit 70, sensor signal reception and calculation processing may be individually performed.

In addition, the light emitting diode 90 is connected to the power supply unit 10 and circuit connected to the control unit 80, and is provided as an element emitting light in at least three or more colors, corresponding to the control signal. It is preferable to be provided to emit light in color.

In detail, the light emitting diode 90 may include a plurality of monochromatic light source units 91 emitting different monochromatic light sources to selectively emit light sources of three primary colors including red, green, and blue. In this case, the monochromatic light source unit 91 may be provided as a three-primary color light emitting diode (RGB LED) including a red light source unit, a green light source unit, and a blue light source unit.

Further, the control unit 80 corresponds to the control signals including the compression drive signal, the freezer temperature signal, the defrost temperature signal, the defrost drive signal, the rotation signal, and the door opening detection signal, and each of the monochromatic light source units It is preferable to independently and individually control each of the monochromatic light sources emitted in (91).

For example, the control unit 80 supplies and controls power to the red light source unit so that the red light source unit of the monochromatic light source unit 91 is turned on, and the green light source unit and the blue light source unit are turned off so that the green light source unit and the blue light source unit are turned off. When power is cut off and controlled, the light emitting diode 90 may emit red light. At this time, in one embodiment of the present invention, the first color may be set to red light.

In addition, the control unit 80 supplies and controls power to the blue light source unit so that the blue light source unit of the monochromatic light source unit 91 is turned on, and the green light source unit and the red light source unit are turned off so that the green light source unit and the red light source unit are turned off. When power is cut off and controlled, the light emitting diode 90 may emit blue light. At this time, in one embodiment of the present invention, the second color may be set to blue light.

In addition, the control unit 80 supplies and controls power to the green light source unit so that the green light source unit of the monochromatic light source unit 91 is turned on, and the red light source unit and the blue light source unit are turned off so that the red light source unit and the blue light source unit are turned off. When power is cut off and controlled, the light emitting diode 90 may emit green light. At this time, in one embodiment of the present invention, the third color may be set to green light.

In addition, when the control unit 80 applies power to the red light source unit, the green light source unit, and the blue light source unit so that the red light source unit, the green light source unit, and the blue light source unit of the monochromatic light source unit 91 are all turned on at the same time, the light emitting diode 90 may emit white light. At this time, in one embodiment of the present invention, the fourth color may be set to white light.

Here, when the control unit 80 cuts off the power to the red light source unit, the green light source unit, and the blue light source unit so that the red light source unit, the green light source unit, and the blue light source unit of the monochromatic light source unit 91 are all turned off at the same time, the light emitting diode ( 90) can be stopped.

Furthermore, the control unit 80 may independently and individually control each of the monochromatic light source units 91 so that different monochromatic light sources emitted from each of the monochromatic light source units 91 are combined in response to the control signal.

For example, the control unit 80 supplies and controls power to the red light source unit and the green light source unit so that the red light source unit and the green light source unit of the monochromatic light source unit 91 are turned on, and the blue light source unit is turned off so that the blue light source unit is turned off. When power is cut off, the light emitting diode 90 may emit yellow light in which red and green are mixed. At this time, in one embodiment of the present invention, the fifth color may be set to yellow light.

In addition, the control unit 80 supplies and controls power to the red light source unit and the blue light source unit so that the red light source unit and the blue light source unit of the monochromatic light source unit 91 are turned on, and the green light source unit is turned off so that the green light source unit is turned off. When power is cut off, the light emitting diode 90 may emit red and blue mixed magenta light. At this time, in one embodiment of the present invention, the sixth color may be set to magenta light.

In addition, the control unit 80 supplies and controls power to the green light source unit and the blue light source unit so that the green light source unit and the blue light source unit of the monochromatic light source unit 91 are turned on, and the red light source unit is turned off so that the red light source unit is turned off. When power is cut off, the light emitting diode 90 may emit cyan light (Cyan) in which green and blue are mixed. At this time, in one embodiment of the present invention, the seventh color may be set to cyan light.

On the other hand, the control unit 80 determines that the compression drive signal is not detected from the compressor drive sensor 20 for a predetermined time or more, and the rotation signal is not detected from the fan drive sensor 60, and the defrost drive feeling is detected. When the defrosting drive signal from the branch 40 is not detected for more than a preset time and the defrost temperature signal from the defrost temperature sensor 50 is not detected as higher than a preset temperature within a preset time, the light emitting diode 90 ) may generate a first control signal to emit light in the first color.

For example, the control unit 80 detects that the compression drive signal from the compressor drive detection unit 20 is not detected for more than a preset time set to 2 hours, and the rotation signal from the fan drive detection unit 60 is set to 2 hours. It is not detected for more than a preset time, the defrost drive signal from the defrost drive detection unit 40 is not detected for more than a preset time set as 2 hours, and the defrost temperature signal is set to 10 ° C within a preset time set as 2 hours. When it is not detected as higher than a preset temperature, the first control signal may be generated.

The controller 80 may generate a second control signal so that the light emitting diode 90 emits light in the second color when the internal temperature signal from the internal temperature sensor 30 deviates from a preset range. have.

For example, the controller 80 controls the internal temperature sensor 30 to detect the light emitting diode ( 90) may generate a second control signal to emit light in the second color.

In addition, the control unit 80 may generate a third control signal so that the light emitting diode 90 emits light in the third color when the door open detection signal from the door open detection unit 70 is detected for a predetermined time or longer. have.

For example, the control unit 80 sends a third control signal so that the light emitting diode 90 emits light in the third color when the door open detection signal from the door open detection unit 70 is detected for a predetermined time period of 60 seconds or more. can create

In addition, the control unit 80 detects the compression drive signal from the compressor drive detection unit 20, detects the rotation signal from the fan drive detection unit 60, and detects the defrost drive detection unit 40. A defrost drive signal is detected, the defrost temperature signal from the defrost temperature detection unit 50 is detected as less than a preset temperature within a preset time, and the refrigerator internal temperature signal from the freezer temperature detector 30 is within a preset range. When detected within the range and the door open detection signal from the door open detection unit 70 is not detected for a predetermined time or more, a fourth control signal may be generated so that the light emitting diode 90 emits light in the fourth color.

Furthermore, the control unit 80 controls each of the monochromatic light sources individually and independently in response to the control signal, and controls the first control signal, the second control signal, the third control signal, and the fourth control signal. Correspondingly, the light emitting diodes may be controlled to emit light with different predetermined blinking cycles.

For example, the control unit 80 may repeatedly apply and block the first control signal at a predetermined first cycle. At this time, the first period may be set to 500 ms. Accordingly, the red light in the light emitting diode 90 may be blinked at a cycle of 500 ms.

Meanwhile, a method for detecting an error in a commercial in-fridge refrigerator according to an embodiment of the present invention will be described in detail below.

First, power for driving the refrigerator 200 is supplied through the power supply unit 10, and internal temperatures of the refrigerating compartment 210 and the freezing compartment 220 provided in the refrigerator 200 are set (s10).

Here, from the power supply unit 10, the compressor drive detection unit 20, the refrigerator internal temperature detection unit 30, the defrost temperature detection unit 50, the defrost drive detection unit 40, and the fan drive detection unit 60 ), the door open detection unit 70, the control unit 80, the light emitting diode 90, the compressor 230, the condenser 240, the evaporator 250, the defrosting means 260 and the driving Power is supplied to each fan 270 (s11). Accordingly, the compressor operation detection unit 20, the freezer temperature detection unit 30, the defrost temperature detection unit 50, the defrost operation detection unit 40, the fan drive detection unit 60, the door open feeling The branch 70, the controller 80, the light emitting diode 90, the compressor 230, the condenser 240, the evaporator 250, the defrosting means 260 and the driving fan 270 can be driven

In addition, the internal temperatures of the refrigerating compartment 210 and the freezing compartment 220 provided in the refrigerator 200 are set (s12). In addition, when the temperatures inside the refrigerating compartment 210 and the freezing compartment 220 are set, the compressor 230, the condenser 240, The evaporator 250, the defrosting unit 260, and the driving fan 270 may be controlled and driven by the controller 80.

Here, the industrial intercooler refrigerator error detection system 100 according to an embodiment of the present invention may include an input unit (not shown) connected to the control unit 80 and provided on the surface of the refrigerator 200. Internal temperatures of the refrigerating compartment 210 and the freezing compartment 220 may be input by a user through an input unit (not shown).

Further, the control unit 80 sends a preliminary signal, the fifth color, so that the light emitting diode 90 emits light in the fifth color before the temperature sensed by the refrigerator temperature sensor 30 reaches within a predetermined range from the set temperature. A control signal may also be generated. At this time, the control unit 80 supplies and controls power to the red light source unit and the green light source unit so that the red light source unit and the green light source unit of the monochromatic light source unit 91 are turned on, and the blue light source unit is turned off so that the blue light source unit is turned off. When power is cut off, the light emitting diode 90 may emit yellow light in which red and green are mixed. At this time, in one embodiment of the present invention, the fifth color may be set to yellow light.

Then, in a step described later, the control unit 80 controls the light emitting diode 90 to emit light in the second color when the refrigerator internal temperature signal from the refrigerator temperature sensor 30 deviates from the set temperature. A second control signal may be generated.

Meanwhile, the compressor driving detection unit 20 generates the compression driving signal, the refrigerator internal temperature detection unit 30 generates the refrigerator internal temperature signal, and the defrost driving detection unit 40 generates the defrost driving signal. The defrost temperature sensor 50 generates the defrost temperature signal, the fan drive sensor 60 generates the rotation signal, and the door open sensor 70 generates the door open sensor signal. Do (s20).

In detail, the compressor drive detection unit 20 connected to the power supply unit 10 and circuit-connected to the compressor 230 that compresses gaseous refrigerant to detect power supply of the compressor 230 detects circuit disconnection and short circuit. Generates the compression drive signal for (s21). At the same time, the fan drive detection unit 60 electrically detecting whether the drive fan 270 provided in the refrigerator 200 is driven generates the rotation signal (S21). In addition, the freezer temperature sensor 30 detecting the internal temperature of the refrigerating compartment 210 and the freezing compartment 220 provided in the refrigerator 200 generates the freezer temperature signal (s21). At the same time, when the door parts 211 and 221 respectively provided in the refrigerating compartment 210 and the freezing compartment 220 are opened, the door opening sensing unit 70 generates the door opening sensing signal (s21).

Subsequently, a plurality of the heat dissipation fins (not shown) and the refrigerant pipe (not shown) provided between the refrigerant pipes (not shown) connected to the power supply unit 10 but curvedly disposed in the evaporator 250 for evaporating liquid refrigerant. ) The defrost drive detection unit 40 for detecting the power supply of the defrost means 260 including the defrost heater 261 for removing frost is driven (s21), and the defrost drive detection unit ( 40) determines whether the defrost drive signal generated as power is supplied to the defrost heater 261 of the defrost means 260 is detected (s22).

Here, when the defrost drive sensor 40 detects the defrost drive signal, the defrost temperature sensor 50 for sensing the temperature of the defrost heater 261 generates the defrost temperature signal (s23) . On the other hand, when the defrost drive sensor 40 does not detect the defrost drive signal, the step of generating the defrost temperature signal by the defrost temperature sensor 50 (S23) is omitted.

On the other hand, the control unit 80 is provided as an element that emits light in at least three colors, and emits light in a plurality of different colors in response to a control signal, but mutually so that light sources of three primary colors including red, green, and blue selectively emit light. The light emitting diodes 90 including a plurality of the monochromatic light source units 91 emitting different monochromatic light sources are configured to combine the different monochromatic light sources emitted from the monochromatic light source units 91 in response to the control signal. They are controlled independently of each other (s30).

Here, the control unit 80 is connected to the power supply unit 10, and the compressor drive detection unit 20, the refrigerator internal temperature detection unit 30, the defrost temperature detection unit 50, the defrost operation detection unit ( 40), circuit connected to the fan drive detection unit 60 and the door open detection unit 70 to detect the compression drive signal, the refrigerator internal temperature signal, the defrost temperature signal, the defrost drive signal, the rotation signal, and the door open detection It is preferably provided to receive a control signal comprising a signal.

In detail, the control unit 80 determines that the compression drive signal is not detected from the compressor drive detection unit 20 for more than a predetermined time, the rotation signal is not detected from the fan drive detection unit 60, and the defrost driving feeling is detected. Comparing whether conditions in which the defrost drive signal from the branch 40 is not detected for a predetermined time or more and the defrost temperature signal from the defrost temperature sensor 50 is not detected as a predetermined temperature or more within a predetermined time are satisfied at the same time It is judged (s31).

Here, the control unit 80 determines that the compression drive signal is not detected from the compressor drive detecting unit 20 for a predetermined time or more, and the rotation signal is not detected from the fan driving detecting unit 60, and the defrost drive feeling is detected. When the conditions that the defrosting drive signal from the branch 40 is not detected for a predetermined time or longer and the defrost temperature signal from the defrosting temperature sensor 50 is not detected at a predetermined temperature or higher within a predetermined time are simultaneously satisfied , a first control signal is generated so that the light emitting diode 90 emits light in the first color (S32). Accordingly, the light emitting diode 90 may emit light in the first color.

On the other hand, the control unit 80 detects the compression drive signal from the compressor drive sensor 20 for less than a predetermined time, detects the rotation signal from the fan drive sensor 60, and detects the defrost drive feeling. When the defrosting drive signal from the branch 40 is detected for less than a preset time and the defrost temperature signal from the defrost temperature detector 50 is detected to be less than a preset temperature within a preset time, the freezer temperature detector ( 30), it is compared and judged whether the internal temperature signal is out of the preset range (s33).

Here, the controller 80 generates a second control signal so that the light emitting diode 90 emits light in the second color when the internal temperature signal generated from the internal temperature sensor 30 deviates from a preset range. Do (s34). Accordingly, the light emitting diode 90 may emit light in the second color.

On the other hand, when the internal temperature signal of the refrigerator has a value within a predetermined range, the control unit 80 compares and determines whether the door open detection signal from the door open detection unit 70 is detected for a predetermined time or longer (s35). .

Here, the controller 80 generates a third control signal so that the light emitting diode 90 emits light in the third color when the door open detection signal from the door open detection unit 70 is detected for a predetermined time or longer ( s36). Accordingly, the light emitting diode 90 may emit light in the third color.

On the other hand, the controller 80 generates a fourth control signal so that the light emitting diode 90 emits light in the fourth color when the door open detection signal from the door open detection unit 70 is not sensed for less than a preset time. Do (s37).

That is, the controller 80 detects the compression drive signal from the compressor drive detector 20, detects the rotation signal from the fan drive detector 60, and detects the defrost drive detector 40 from the defrost drive detector 40. A defrost drive signal is detected, the defrost temperature signal from the defrost temperature detection unit 50 is detected as less than a preset temperature within a preset time, and the refrigerator internal temperature signal from the freezer temperature detector 30 is within a preset range. When detected within the range and the door open detection signal from the door open detection unit 70 is not detected for less than a preset time, a fourth control signal may be generated so that the light emitting diode 90 emits light in the fourth color. .

As such, according to the present invention, the controller 80 controls the light emitting diodes 90 emitting light in at least three colors to correspond to the normal operation state, the internal temperature state, the defrost state, and the door open state, thereby controlling the refrigerating and freezing driving states. Since it is displayed in various colors that are easy to identify with the naked eye, the location of error occurrence can be easily identified with only the color, so the convenience of inspection can be remarkably improved.

Here, the light emitting diode 90 includes a plurality of monochromatic light source units 91 emitting different monochromatic light sources so that light sources of three primary colors including red, green, and blue are selectively emitted. Since each of the monochromatic light source units 91 is independently and individually controlled so that different monochromatic light sources emitted from each of the monochromatic light source units 91 are combined in response to a control signal, the unit can perform the above operation in normal operation, in the freezer temperature state, in the defrost state, and in the door open state. Since the light emitting diodes 90 are displayed in different colors, inspection convenience can be remarkably improved.

In addition, the control unit 80 determines that the compression drive signal is not detected from the compressor drive detection unit 20 for more than a predetermined time, the rotation signal is not detected from the fan drive detection unit 60, and the defrost drive feeling is detected. The light emitting diode ( 90) generates the first control signal to emit light in the first color, so that the user can easily recognize the indication of an error occurrence in the chamber, and the convenience of use can be remarkably improved.

In addition, the control unit 80 generates a second control signal so that the light emitting diode 90 emits light in a second color when the internal temperature signal from the refrigerator temperature sensor 30 deviates from a predetermined range, and When the door open detection signal from the door open detection unit 70 is detected for a predetermined time or longer, a third control signal is generated so that the light emitting diode 90 emits light in a third color, so that the displayed color changes according to the priority when an error occurs. Therefore, inspection convenience can be remarkably improved.

In addition, the control unit 80 detects the compression drive signal, the rotation signal, and the defrost drive signal, detects the defrost temperature signal as less than a preset temperature within a preset time, and sets the refrigerator temperature signal within a preset range. Algorithm that generates a fourth control signal so that the light emitting diode emits light in a fourth color when the door open detection signal is not detected for less than a preset time so that the user can easily recognize the normal operation state display of the refrigerator. As a result, the convenience of use can be significantly improved.

Furthermore, the control unit 90 controls each of the monochromatic light sources individually and independently in response to the control signal, and controls the first control signal, the second control signal, the third control signal, and the fourth control signal. Correspondingly, the light emitting diodes may be controlled to emit light with different predetermined blinking cycles, so that identification may be further facilitated during visual confirmation.

Furthermore, although not shown in the drawings, in some cases, when the first control signal is generated, if the compression drive signal is not detected from the compressor drive detection unit 20 for a predetermined time or more, the control unit 80 sets a preset The light emitting diode may be controlled to emit light in a first flickering cycle.

In addition, when the rotation signal is not sensed from the fan driving sensor 60 when the first control signal is generated, the control unit 80 may control the light emitting diode to emit light at a predetermined second flickering cycle.

In addition, when the first control signal is generated, the controller 80 determines that the defrost drive signal is not detected from the defrost drive sensor 40 for a predetermined time or more, and the defrost temperature sensor 50 detects the defrost. When a temperature signal is not sensed as higher than a preset temperature within a preset time, the light emitting diode may be controlled to emit light in a preset third flashing cycle.

Furthermore, when the first control signal is generated, the control unit 80 controls the light emitting diode to emit light at a preset fourth blinking cycle when the compression driving signal is not detected for a predetermined time or more and the rotation signal is not detected at the same time. can do.

In addition, when the control unit 80 generates the first control signal, the compression drive signal is not detected for more than a preset time and at the same time the defrost drive signal is not detected for more than a preset time, and the defrost temperature signal is preset. If the predetermined temperature or higher is not detected within the time, the light emitting diode 90 may be controlled to emit light in a predetermined fifth flickering cycle.

And, when the control unit 80 generates the first control signal, the rotation signal is not detected and at the same time the defrosting drive signal is not detected for more than a preset time, and the defrost temperature signal is set at a preset temperature within a preset time. If the abnormality is not detected, the light emitting diode may be controlled to emit light in a preset sixth blinking cycle.

Here, it is preferable that the first blinking cycle, the second blinking cycle, the third blinking cycle, the fourth blinking cycle, the fifth blinking cycle, and the first blinking cycle are set to mutually different cycles.

Therefore, when the light emitting diode 90 generates the first control signal displayed in a first color, it corresponds to whether the compression drive signal, the rotation signal, the defrost drive signal, and the defrost temperature signal are individually detected or not sensed. Therefore, since the light emitting diode 90 is controlled to blink at various blinking cycles, the cause of the error can be quickly determined and the inspection convenience can be improved.

In this case, terms such as "include", "comprise" or "have" described above mean that the corresponding component may be present unless otherwise stated, excluding other components. It should be construed as being able to further include other components. All terms, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the art to which the present invention belongs, unless defined otherwise. Commonly used terms, such as terms defined in a dictionary, should be interpreted as consistent with the contextual meaning of the related art, and unless explicitly defined in the present invention, they are not interpreted in an ideal or excessively formal meaning.

As described above, the present invention is not limited to the above-described embodiments, and it is possible to modify and implement the present invention by those skilled in the art without departing from the scope claimed in the claims of the present invention. And, such modifications fall within the scope of the present invention.

10: power supply unit 20: compressor drive detection unit
30: freezer temperature detection unit 40: defrost drive detection unit
50: defrost temperature detection unit 60: fan drive detection unit
70: door open detection unit 80: control unit
90: light emitting diode 200: refrigerator
210: refrigerator compartment 220: freezer compartment
230: compressor 240: condenser
250: evaporator 260: defrosting means
261: defrost heater 270: driving fan
100: commercial intercooler refrigerator error detection system

Claims (5)

a power supply unit supplying power for driving the refrigerator;
It is connected to the power supply unit, and is connected to a compressor voltage detection sensor and a compressor current detection sensor that are circuit-connected to a compressor for compressing gaseous refrigerant to detect power supply of the compressor and to generate a compression drive signal for detecting circuit disconnection and short circuit. mechanical movement detection unit;
a freezer temperature sensor that is circuit-connected to a refrigerator compartment temperature sensor and a freezer compartment temperature sensor for detecting temperatures inside the refrigerator and freezer compartments provided in the refrigerator to generate a freezer temperature signal;
A defrost temperature sensor for generating a defrost temperature signal by being circuit-connected to a defrost temperature sensor for detecting a temperature of a defrost heater provided to remove frost formed on a refrigerant pipe bent in an evaporator that evaporates liquid refrigerant;
Circuit connected to a defrost voltage detection sensor and a defrost current detection sensor for detecting power supply of a defrosting means including a plurality of heat radiation fins provided between the refrigerant pipes and the defrost heater to generate a defrost drive signal for detecting circuit disconnection and short circuit Defrost drive detection unit;
a fan drive detection unit that is circuit-connected to a rotation sensor that electrically detects whether or not the drive fan provided in the refrigerator is driven and generates a rotation signal;
a door open detector circuit connected to an open sensor that electrically detects a disconnection of a switching circuit that is disconnected when a door unit provided in the refrigerating chamber and the freezing chamber is opened and generates a door open detecting signal;
Circuits are connected to the compressor driving detection unit, the refrigerator internal temperature detection unit, the defrost temperature detection unit, the defrosting driving detection unit, the fan driving detection unit, and the door opening detection unit, and the compression driving signal, the refrigerator internal temperature signal, and the defrost temperature a control unit receiving a control signal including a signal, the defrost drive signal, the rotation signal, and the door open detection signal; and
It is provided as an element that is connected to the power supply unit and connected to a circuit to the control unit, and emits light in at least three colors, including light emitting diodes that emit light in a plurality of different colors in response to the control signal,
The light emitting diode includes a plurality of monochromatic light source units that emit different monochromatic light sources so that light sources of three primary colors including red, green, and blue are selectively emitted, and the control unit emits light from each of the monochromatic light source units in response to the control signal. Independently and individually controlling each of the monochromatic light source units so that different monochromatic light sources are combined,
The control unit detects that the compression drive signal is not detected from the compressor drive sensor for a predetermined time or more, the rotation signal is not detected from the fan drive sensor, and the defrost drive signal is detected from the defrost drive sensor for a predetermined time or more. generating a first control signal so that the light emitting diode emits light in a first color when the defrosting temperature signal from the defrosting temperature detection unit is not detected as higher than a preset temperature within a preset time;
The control unit
generating a second control signal so that the light emitting diode emits light in a second color when the internal temperature signal from the internal temperature sensor deviates from a predetermined range;
generating a third control signal so that the light emitting diode emits light in a third color when the door open detection signal is sensed from the door open detection unit for a predetermined time or longer;
The compression drive signal, the rotation signal, and the defrost drive signal are detected, the defrost temperature signal is detected as less than a preset temperature within a preset time, the refrigerator internal temperature signal is detected within a preset range, and the door open detection When the signal is not detected for less than a predetermined time, a fourth control signal is generated so that the light emitting diode emits light in a fourth color. delete delete According to claim 1,
The controller controls each of the monochromatic light sources individually and independently in response to the control signal,
The first control signal, the second control signal, the third control signal, and the fourth control signal correspond to each other and control the light emitting diodes with different predetermined blinking cycles. delete

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