KR200237666Y1 - A cooling device with guide panel for cool air - Google Patents

Abstract

The present invention adjusts the movement of the cooled air installed inside the cooling device, so that the cooled air is distributed evenly on the upper and lower ends as well as the lower end of the cooling device to maintain a constant temperature inside the cooling device. The refrigerator has a cold air circulation wall structure.

In order to achieve the same purpose as described above, a plurality of cold air flow guide plates are provided on a predetermined portion of the rear surface of the cooling device so that the cooled air hits the cold air flow guide plate when the cooled air flows down to the lower part of the cooling device by its own weight. The cooled air stayed and the remaining cooled air flowed to the lower end.

In the refrigerator having the cold air circulation wall structure having the above configuration, the cooled air is evenly distributed throughout the inside of the refrigerator to maintain a uniform temperature throughout the interior.

Description

A cooling device with guide panel for cool air

The present invention relates to a wall structure for the circulation of cold air in the showcase, and in particular, the evaporator 28 attached to the top of the rear surface of the cooling device and the motor fan that sends air to the cooling device door toward the evaporator and the evaporator. In order to maintain the freshness of the goods displayed on the inside of the cooling device by flowing the cooled air to the rear surface 32 of the cooling device, the cooling air to maintain the entire inside of the cooling device at a uniform temperature A chiller having a cold air flow restraint for regulating flow.

The structure of the conventional cooling apparatus is shown in FIG. As shown in FIG. 1, a condenser 16 and a condenser fan motor for making a high-temperature and high-pressure working fluid (hereinafter, refrigerant) into a medium temperature and a medium pressure in the compressor 12 and the compressor 12 operated by applying power. 14), the evaporator 28 for cooling the temperature inside the chiller using latent heat of evaporation of the refrigerant, and the door 22 and the inside of the chiller to prevent seepage and leakage of cold air displayed on the evaporator fan motor and the chiller. Fluorescent lamps and fluorescent lamp cover 20 for illuminating the goods on display, drainage port 24 for draining defrost water during defrosting and drainage plugs and the like.

In addition, air is circulated by the fan motor inside the product to cool the exhibited goods. At this time, the air circulation direction is sucked from the front (door side) of the cooling device and discharged to the rear foot surface 32 to smooth the cooling. It is.

The operation process of the conventional cooling apparatus is as follows. For convenience of description, the same reference numerals are used for the same components of the prior art and the present invention.

When power is applied to the power cord 10, the compressor 12 operates and the refrigerant flows through the refrigerant pipe to the condenser 16 DVBDLQHLAU where the condenser fan motor 14 for dissipating the refrigerant of air temperature is operated and the refrigerant is evaporator ( While passing through 28), the refrigerant is cooled by latent heat of evaporation and the evaporator fan motor is used for the purpose of smoothing the cooling action. By the continuous repetition of this cooling operation, the inside of the cooling apparatus is maintained at a constant temperature.

Through this repetitive cooling action, the temperature inside the cooling apparatus reaches a constant temperature and the temperature inside the cooling apparatus is interrupted by a temperature sensor.

As shown in FIG. 1, a fan motor 14 for a condenser is usually used to improve cooling efficiency. In general, a cooling device sucks air from the front of the cooling device and discharges the air into the cooling device. The air entering the cooler is moved to the evaporator side by a motor fan installed at the upper end of the cooler, and the air cooled through the evaporator flows down along the rear surface 32 of the cooler to cool the temperature inside the cooler. .

During operation of the cooling device, the air sucked by the fan motor inside the cooling device is cooled while passing through the evaporator 28. The air passing through the evaporator 28 does not flow uniformly, or the cooled air is lowered. If it sinks in, there will be a deviation in cooling temperature between the top and bottom of the chiller. Accordingly, the temperature of the product is not uniform, so in the case of frozen foods such as ice cream, the cold air sinks to the bottom due to the frequent opening and closing of the door 22, and the air at the top cools quickly. There is a risk of product deterioration.

The present invention is to improve the temperature deviation between the air inside the cooling device, which is a problem of the prior art described above, when the cooled air passes through the rear wall by installing a cool air flow guide plate for each height of the upper and It is an object of the present invention to provide a chiller having a cold air flow guide plate which eliminates the temperature deviation between the bottoms.

1 is a block diagram of a conventional cooling device.

2 is a configuration diagram of a cold air circulation wall structure according to the present invention.

3 is a configuration diagram of a cold air flow guide plate according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10: power cord 12: compressor

14: condenser fan motor 16: condenser

18: fluorescent lamp 20: fluorescent lamp cover

22: door 24: drain

26: evaporator fan motor 28: evaporator

30: cold air flow guide 32: rear side

In order to achieve the above object, a refrigerator having a cold air circulation wall structure according to the present invention includes a compressor 12 that is operated by applying power, and a condenser for making a high temperature and high pressure working fluid in the compressor 12 into a medium temperature and a medium pressure. 16 and the evaporator fan motor and the evaporator fan motor 26 and the rear surface of the cooling device 32, which cool the temperature inside the cooling device by using the latent heat of evaporation of the condenser fan motor and the refrigerant, and the evaporator fan motor. The cold air flow guide plate 30 which uniformly distributes the cold air forcedly circulated by the 26 at the upper end and the lower end of the inside of the cooling device, and the door 22 and the inside of the cooling device to prevent seepage and leakage of cold air are displayed. Fluorescent lamp 18 and fluorescent lamp cover 20 for illuminating a product and a drain 24 for draining defrost water during defrosting and a drain plug.

Referring to Figures 2 to 3 the configuration and operation of the cooling device having a cold air flow guide plate according to an embodiment of the present invention as follows. As shown in FIG. 2, when power is supplied to the cooling device, the compressor 12 operates and the refrigerant flows into the condenser 16 through the refrigerant pipe, where the condenser fan motor 14 heats up the high temperature refrigerant. The coolant is cooled by the latent heat of evaporation of the coolant while passing through the evaporator 28, and the coolant is continuously repeated, thereby maintaining the temperature inside the cooler at a constant temperature.

Through repeated cooling, the temperature inside the chiller reaches a constant temperature, and the temperature sensor keeps the temperature inside the chiller constant. Such a cooling device generally uses a fan motor for a condenser in order to improve the cooling efficiency as shown in FIG. 2, and generally sucks air from the front of the cooling device to introduce the air into the cooling device.

The air introduced into the chiller is forcibly moved to the evaporator 28 by a fan motor attached to the top of the chiller, and the air cooled through the evaporator 28 cools down as it flows through the rear surface 32 of the chiller. A plurality of cold air flow guide plates 30 are installed on the rear surface of the cooling apparatus in order to improve the occurrence of temperature deviation according to the height inside the apparatus. Cooled air at the top of the cooling device is moved to the bottom by its own weight, when the cooled air moves to the lower end, the cooled air hits the cold air flow guide plate 30 installed on the rear surface 32 of the cooling device Part of the cooling air is retained, and the remaining air is moved to the lower end so that the upper end and the lower end inside the cooling apparatus are maintained at the same temperature.

The configuration of the cold air flow guide plate 30 is shown in FIG. 3. As shown in FIG. 3, a plurality of cold air flow guide plates 30 are installed at predetermined intervals in the vertical direction on the rear surface 32 of the cooling apparatus. The cold air flow guide plate 30 is formed to have a longer length as it goes from the upper end to the lower end, so that only a part of the cooled gig stays at the upper end. In addition, by installing the cold air flow guide plate 30 on the upper side and the cold air flow guide plate 30 on the lower side to prevent the cooling air from staying only on the upper side.

As described above, in the cooling apparatus having the cold air flow guide plate according to the present invention, the cooled air is uniformly distributed in the cooling apparatus, so that the temperature is uniform, thereby maintaining the freshness of the exhibited product.

Claims (3)

A compressor for compressing the refrigerant; A condenser and a condenser fan motor for making a high temperature and a high pressure refrigerant of the compressor into a medium temperature and a medium pressure; An evaporator and an evaporator fan motor configured to DLDYDD latent heat of evaporation of the refrigerant to cool a temperature inside the cooling device; A housing in which the compressor, the condenser and the condenser fan motor, the evaporator and the evaporator fan motor are accommodated and installed; It is installed on the rear side of the housing, the lower part of the evaporator and comprises a plurality of cold air flow guide plate for allowing a portion of the cooled air to stay on the upper side of the cooling device to distribute the cooled air throughout the inside of the cooling device. A chiller having a cold air flow guide plate. The method of claim 1, wherein the evaporator fan motor Cooling with a cold air flow guide plate is characterized in that the suction of the air in the cooling device door forcibly circulated to the evaporator, the cold air flows through the evaporator to move from the upper end to the lower end along the rear surface of the cooling device. Device. The method of claim 1, wherein the plurality of cold air flow guide plate It is installed at a predetermined interval in the vertical direction, and the cold air flow guide plate at the upper end is arranged to be staggered with respect to the cold air flow guide plate at the lower end, and the door side length of the cold air flow guide plate at the upper end is shorter than the length of the cold air flow guide plate at the lower end. Cooling apparatus having a cold air flow guide plate, characterized in that.