KR102316780B1 - Frost detection device using optical method and defrosting method using the Frost detection device - Google Patents

Abstract

A frost sensing device using an optical method according to the present invention is coupled over an air flowing path of a plurality of cooling fins constituting an evaporator of a refrigerator to control defrosting. The evaporator comprises: coolant pipes which are formed in a plurality of rows forming multiple stages; and a plurality of cooling fins of a flat plate body shape coupled to the coolant pipes. The frost sensing device comprises: a mount unit which is arranged to come in contact with the outer side of the plurality of cooling fins; a pair of optical fiber units which are extended in a state of being spaced apart from the mount unit at a predetermined interval; and a circuit unit which is electrically connected to the pair of optical fibers in a state of being buried in the mount unit. Here, the pair of optical fiber units are inserted along the space between a pair of cooling fins adjacent to each other among the plurality of cooling fins, and, depending on the degree of frost generation which is detected by the plurality of frost sensing sensors arranged at the pair of optical fiber units in a longitudinal direction, selectively enable the operation of a defrosting heater arranged over the evaporator.

Description

Frost detection device using an optical method and an evaporator defrosting method using the frost detection device

The present invention provides a frost detection device that enables the drive of a defrost heater selectively according to the amount of frost detected using an optical method in a state coupled to an air flow path of a cooling fin constituting an evaporator, and the frost detection device using the It relates to an evaporator defrosting method.

Industrial cold storage or agricultural cold storage is a box-shaped device for storing food or medicines at low temperatures, and consists of a storage room and a cooling device, and is cooled using ice, electricity, gas, etc. Each of these cold storages includes a compressor, a condenser and an evaporator, and according to the principle of the refrigeration cycle, the temperature inside the storage is lowered to facilitate storage and storage.

The cooling cycle includes a compressor, a condenser for condensing the compressed refrigerant, an expansion valve for adiabatically expanding the condensed refrigerant, and an evaporator for evaporating the expanded refrigerant. Here, it may further include a blower fan for supplying the cold air generated by the evaporator disposed in the storage chamber to each storage chamber, and a step valve provided between the condenser and each evaporator to selectively supply the refrigerant to each evaporator. According to this configuration, the air cooled by heat exchange in the evaporator is circulated to the storage chamber through a blower fan to cool the storage chamber.

The circulating air in the storage is sucked into the cooling chamber by the blower fan to form heat exchange with the evaporator, and the process of being discharged to the storage chamber through the outlet of the cold air duct is repeatedly performed. Frost is formed by the temperature difference with the circulating air inside the furnace. That is, when the air circulated by the blower fan exchanges heat in the evaporator, the evaporator operates at a very low temperature, so that the surrounding air is condensed on the surface of the evaporator and the generated frost adheres to it, thereby forming a frost layer.

In other words, over-floating occurs in which water vapor contained in the air is frozen in the evaporator. This over-settling interferes with air circulation and reduces evaporation efficiency, so a defrosting operation is required to remove it.

When the total integration time of the compressor for the defrost operation passes the preset defrost start time or the absolute time has elapsed since the operation of the refrigerator, it enters the defrost mode and heats the defrost heater provided separately in the evaporator, or drives the blower to activate the evaporator Methods such as removing the frost that have been implanted in the On the other hand, when entering the defrost mode only by the above method, the defrost does not operate at an appropriate time because it cannot respond to changes in the internal environment that are fluidly changed depending on the situation inside the refrigerator, resulting in deterioration of refrigeration and freezing performance.

In general, a defrost heater is provided on the lower side of the evaporator in order to remove the frost. The prior art operates a defrost heater with only the temperature of the evaporator regardless of changes in the surrounding environment of the refrigerator, so that even if frost is thinly formed around the actual evaporator, it cannot be detected.

The present invention is to solve the above conventional problems, and in a state coupled to the air flow path of the cooling fins constituting the evaporator, it is possible to selectively drive the defrost heater according to the amount of frost detected using an optical method. It relates to a frost detection device and a method for defrosting an evaporator using the frost detection device.

According to one aspect of the present invention for achieving the above object, a frost sensing device using an optical method controls defrost by combining on an air flow path of a plurality of cooling fins constituting an evaporator of a refrigerator, and the evaporator is multi-stage. A plurality of cooling fins in the shape of a flat body coupled to the refrigerant tubes and the refrigerant tubes formed in a plurality of rows constituting the

The frost sensing device may include: a mount unit disposed in close contact with the outside of the plurality of cooling fins; a pair of optical fiber units extending in a state spaced apart from the mount unit at a predetermined interval; and a circuit part electrically connected to the pair of optical fibers in a state embedded in the mount part, wherein the pair of optical fiber parts follow a space between a pair of adjacent cooling fins among the plurality of cooling fins. It is inserted, and selectively enables driving of the defrost heater disposed on the evaporator according to the degree of occurrence of frost detected through a plurality of frost detection sensors disposed along the longitudinal direction of the pair of optical fiber units.

The pair of optical fiber units includes a transmitting unit extending from the upper end of the mount unit and a receiving unit extending from the lower end of the mount unit to be spaced apart from the transmitting unit, wherein the transmitting unit and the receiving unit are inserted extending from the mount unit, respectively It has a rod and a plurality of optical fibers arranged in a line along a longitudinal direction of the insertion rod.

The shape of the mount part has a closed shape or a semi-open shape.

The optical fiber constituting the receiving unit has a larger diameter than the optical fiber constituting the transmitting unit.

Some of the plurality of colors generated by the optical laser are selectively sent to the optical fiber and used to detect frost.

In a defrosting method in an evaporator using an optical method according to another aspect of the present invention for achieving the above object, the frost detected through a plurality of frost detection sensors disposed in the longitudinal direction of the pair of optical fiber units occurs determining the degree; and selectively enabling driving of some of the plurality of defrost heaters disposed on the evaporator according to the degree of occurrence of the frost.

As described above, the apparatus for detecting frost using an optical method according to the present invention as described above provides a method for detecting frost using an optical method that has little heat effect such as a laser point, and sets the color of the laser pointer to blue, green, Check the frost detection response by using three colors such as red.

The frost detection device forms a frost detection area in a state of being inserted between the cooling fins constituting the evaporator, while narrowing the width between the cooling fins along the air flow direction flowing into the cooling fins and deeply inserted between the cooling fins. to have a form that becomes

That is, when the amount of frost generated at the inlet portion of the refrigerant is large and the amount of frost generated at the air inlet portion is small, there is an advantage that the defrost heater can be controlled by dividing the defrost heater left and right in the width direction of the cooling fins. That is, it is possible to adjust the operating position or time of the defrost heater according to the amount of frost generated at the refrigerant inlet and the air inlet.

1 shows a shape in which a frost detection device using an optical method is coupled on an evaporator according to an embodiment of the present invention.
2 shows a device for detecting a frost according to an embodiment of the present invention.
3 shows a device for detecting a frost according to another embodiment of the present invention.
FIG. 4 is a view viewed from the direction A of FIG. 1 .
FIG. 5 is a view viewed from the direction B of FIG. 1 .
FIG. 6 shows a cross-section taken along CC of FIG. 1 .

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be embodied in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and the scope of the invention to those of ordinary skill in the art It is provided for complete disclosure. In the drawings, like reference numerals refer to like elements.

In the present invention, in a state in which the frost sensing device 100 is disposed on the air flow path of the cooling fins constituting the evaporator, the degree of occurrence of frost occurring in the air flow path using the frost sensing device is measured using optical fibers. It is a key feature to effectively perform defrosting by selectively controlling the defrost heater in the detected state.

The evaporator 10 in which the frost detection device is disposed includes refrigerant tubes 11 formed in a plurality of rows forming a multi-stage and a plurality of cooling fins 13 in a flat body shape coupled to the refrigerant tubes 11 .

The frost sensing device 100 includes a mount unit 110 that is closely disposed on the outside of a plurality of cooling fins 13, a pair of optical fiber units 130 extending in a state spaced apart from the mount unit at a predetermined interval, and a mount unit. It includes a circuit unit 120 electrically connected to the pair of optical fiber units 130 in a state of being embedded in the image.

The mount unit 110 has a structure in which the circuit unit 120 is embedded therein, and an air inlet hole 101 is formed to allow air to flow through the center thereof.

2 and 3 , the shape of the mount part may have a closed shape or a semi-open shape. It can be seen in FIG. 2 that it has a closed closed state. In the above embodiment, the first and second circuits constituting the circuit unit 120 may be disposed on both left and right sides with respect to the air inlet hole 101 . On the other hand, it can be seen that it has an open state in FIG. 3 . In the above embodiment, the first and second circuits constituting the circuit unit 120 may be disposed on both upper and lower sides with respect to the air inlet hole 103 .

On the other hand, it can be assumed that the frost sensing device having a closed closed state is disposed on one side of the upper side of the evaporator 10 , while the frost detecting device having an open open state is disposed on the other side of the lower side of the evaporator 10 . have. That is, it is possible for the frost sensing device having the open and closed shapes to be disposed in a diagonally opposite shape on the side of the evaporator.

The pair of optical fiber units 130 includes a transmitter 131 extending from the upper end of the mount unit 110 and a receiver 133 extending from the lower end of the mount unit to be spaced apart from the transmitter.

The transmitter 131 and the receiver 133 each have an insertion rod extending from the mount unit 110 and a plurality of optical fibers 132 and 134 arranged in a line along the length direction of the insertion rod.

The insertion rod is designed to have a width narrow enough to be inserted between a pair of adjacent cooling fins among the cooling fins 13 . To this end, it may have a rigid material in which carbon fibers are mixed so as to have rigidity even in a state with a narrow width. That is, the insertion rod may be a member in the form of starting from one side of the cooling fins and extending to approach the other side.

Here, referring to FIGS. 4 and 5 , the frost sensing area A into which the transmitter 131 and the receiver 133 are inserted may designate an upper one side area on the evaporator. The frost sensing area (A) may be formed to be deep while being narrow in width along the air flow direction. That is, in that the amount of frost generated at the refrigerant inlet portion of the evaporator is large, while there is a practical limit in that the amount of frost generation is small at the air inlet portion, the shape of the sending and receiving units 131 and 133 is formed narrow and long, and it is preferable to be sufficiently inserted between the cooling fins. can do. In addition, the degree of rigidity or rigidity of the transmitter/receiver into which the optical fiber enters should be secured.

The optical fiber unit 130 in the present invention detects frost using an optical method that has little heat effect, such as a laser point. The color of the optical laser is blue, green, and red depending on the wavelength. That is, colors such as red, green, and blue generated through the optical laser can be sent to the optical fiber to detect frost.

Meanwhile, the light-receiving fiber 134 constituting the receiving unit 133 has a larger diameter than the light-emitting fiber 132 constituting the transmitting unit 131 . This enables smooth reception of the emitted laser light.

With reference to FIGS. 4 to 6 , it will be described that the defrost heater can be selectively driven according to the amount of frost detected using an optical method.

The defrost heaters 141 and 143 are configured to be spaced apart from each other in the longitudinal direction of the transmitting and receiving units 131 and 133 . That is, it includes a first defrost heater 141 disposed close to the mount portion and a second defrost heater 143 spaced apart from the first defrost heater 141 toward the inner side of the cooling fins 13 . The defrost heaters 141 and 143 may be disposed between the transmitting and receiving optical fibers 132 and 134 respectively disposed in the transmitting and receiving units 131 and 133 . That is, the defrost heaters 141 and 143 may be disposed on an intermediate point between a pair of adjacent light emitting fibers 134 disposed in the transmitter 133 .

The defrost heaters 141 and 143 selectively enable driving of the defrost heater in order to conduct intensive heating to a place recognized as an area where a lot of frost has occurred according to the sensing of the frost sensing device 100 .

Referring to FIG. 6, the amount of frost generated at the inlet portion of the refrigerant spaced relatively far from the mount unit according to the refrigerant flow is large, and the amount of frost generation is small at the air inlet portion disposed relatively close to the mount unit according to the air flow. , there is an advantage that it is possible to control the defrost heater by dividing it left and right in the width direction of the cooling fins. That is, the air inlet portion is located at a relatively closer distance to the mount portion than the inlet portion of the refrigerant. In this state, a relatively large amount of frost is generated on the inlet of the refrigerant compared to the inlet of the air, so that light is not smoothly incident from the light emitting fiber 132 to the light receiving fiber 134 .

That is, it is possible to adjust the operating position or time of the defrost heater according to the amount of frost generated at the refrigerant inlet and the air inlet.

An apparatus for detecting frost using an optical method according to the present invention provides a method for detecting frost using an optical method that has little heat effect such as a laser point, and the laser pointer has three colors such as blue, green and red Check the frost-sensing reactivity by color.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: frost detection device
110: mount unit
120: circuit part
130: optical fiber unit

Claims (6)

In the frost sensing device for controlling defrost by combining on the air flow path of a plurality of cooling fins constituting the evaporator of the refrigerator,
The evaporator includes a plurality of cooling fins in the shape of a flat body coupled to the refrigerant tubes and the refrigerant tubes formed in a plurality of rows forming a multi-stage,
The frost detection device,
a plurality of mount portions closely disposed on the outside of the plurality of cooling fins;
a pair of optical fiber units extending in a state spaced apart from the mount unit at a predetermined interval; and
and a circuit part electrically connected to the pair of optical fibers in a state embedded in the mount part;
The mount part has a structure in which the circuit part is embedded therein, and a plurality of circuits constituting the circuit part are disposed on both sides based on the air inlet hole forming the center of the mount part,
A mount portion having a closed closed state is disposed on one side of the upper side of the evaporator, while a mount portion having an open open state is disposed on the other side of the lower side of the evaporator, so that a pair of mount portions are diagonally on the side of the evaporator. placed in a shape facing each other,
The pair of optical fiber units includes a transmitting unit extending from the upper end of the mount unit and a receiving unit extending from the lower end of the mount unit and spaced apart from the transmitting unit,
The defrost heater is spaced apart from the receiving unit and the transmitting unit in the longitudinal direction, so that the first defrost heater and the first defrost heater disposed close to the mount unit and the second defrost heater are spaced apart from the first defrost heater toward the inside of the cooling fin. and the defrost heater is disposed between the light-receiving and light-emitting fibers respectively disposed in the receiving unit and the transmitting unit,
The pair of optical fiber parts are inserted along a space between a pair of adjacent cooling fins among the plurality of cooling fins,
Frost detection using an optical method that selectively enables driving of a defrost heater disposed on the evaporator according to the degree of occurrence of frost detected through a plurality of frost detection sensors disposed in the longitudinal direction of the pair of optical fiber units Device.
The method of claim 1,
The transmitting unit and the receiving unit each having an insertion rod extending from the mount unit and a plurality of optical fibers arranged in a line along the longitudinal direction of the insertion rod,
Frost detection device using optical method.
delete 3. The method of claim 2,
The optical fiber constituting the receiving unit has a larger diameter compared to the optical fiber constituting the transmitting unit,
Frost detection device using optical method.
3. The method of claim 2,
Some of the plurality of colors generated through the optical laser are selectively sent to the optical fiber to be used to detect frost,
Frost detection device using optical method.
In the defrosting method in the evaporator of the refrigerator using the frost sensing device according to claim 1,
determining the degree of occurrence of the detected frost through a plurality of frost detection sensors disposed in the longitudinal direction of the pair of optical fiber units;
Including; selectively enabling driving of some of the plurality of defrost heaters disposed on the evaporator according to the degree of occurrence of the frost;
The pair of optical fiber units includes a transmitter extending from an upper end of a mount disposed on the outside of a cooling fin constituting the evaporator and a receiver extending from the lower end of the mount and spaced apart from the transmitter, the defrost heater is the A first defrost heater and a second defrost heater spaced apart from the first defrost heater to the inside of the cooling fin from the first defrost heater disposed close to the mount unit as being spaced apart along the longitudinal direction of the receiving unit and the transmitting unit, the defrosting The heater is disposed on between the light-receiving and light-emitting fibers respectively disposed in the receiving unit and transmitting unit,
Evaporator defrosting method using frost detection device.

Images