KR100194359B1 - Air circulation structure of air curtain refrigerator - Google Patents

Abstract

The present invention relates to a cold air circulation structure of an air curtain refrigerator, and even when the door is closed, the cold air control device is intermittently operated so that the air flow that becomes an efficient air flow during the operation of the cold air control device can be actively utilized. The cold air outlet formed integrally with the discharge port 5 of the cold air control device so that the loss of the cooling function can be quickly restored to prevent the load loss of the cooler, and the cooling performance of the pocket installed in the door of the refrigerator compartment can be improved. 20), the cold air control means 40 which closes this cold air blower outlet 20 according to the opening of the door 56, and the drive of the cross flow fan 1 by the control of this cold air control means 40 are interrupted | blocked. Air curtain refrigerator equipped with a switching means (60) to operate, even if the door is closed, the cold air control device is intermittently operated to ensure efficient air flow during operation of the cold air control device It is used as active it will have the effect that the recovery of the lost cooling functions according to the opening and closing of the door quickly made, and prevents the load loss of the cooler, and particularly improves the pocket parts of the cooling performance, which is installed in the door of the refrigerator compartment.

Description

Air circulation structure of air curtain refrigerator

The present invention relates to a cold air circulation structure of an air curtain refrigerator, and in particular, an enlarged nozzle is formed at a discharge port through which an air curtain film performing an air curtain function is injected, and the enlarged nozzle is selectively opened and closed according to opening and closing of the door. The present invention relates to a cold air circulation structure of an air curtain refrigerator capable of further improving the cooling performance of a refrigerator compartment by operating a cross flow fan even when closed.

In general, a refrigerator is provided with a refrigerant heat circulation device to form a refrigeration cycle, and the heat load of air is converted in an evaporator, that is, a cooler of the refrigerant heat circulation device, and cold air having a cooling load is discharged into the freezing and refrigerating compartments, respectively. The cold air is circulated in the refrigerating chamber, and the cold air generated in the cooler is flowed into the refrigerating chamber by using a circulation fan, and then the cold air is discharged to the cold air outlet provided on the rear wall and the side wall of the refrigerating chamber to deliver the cold air to the stored food. The cold air circulated in this way flows into the inlet installed at the upper side of the front side of the refrigerating chamber and is circulated to the cooler through the duct installed inside the refrigerator.

In the conventional refrigerator, when the door of the refrigerator is opened, the cold air escapes from the air circulation path and is discharged to the outside of the refrigerator, and free air flows into the refrigerator freely due to the buoyancy caused by the density difference. As the temperature of the stored food is increased, the freezing and condensation of each part of the refrigerating chamber due to the outside air are generated unnecessarily, and the cooling function of the refrigerator is deteriorated due to the increase in the cooling time due to the recooling and the temperature imbalance between the cold air exposure parts.

Therefore, in recent years, a so-called air curtain refrigerator having a cold air control device that blocks cold and outdoor air has been developed to compensate for these disadvantages, which is normally installed at the rear of the freezing compartment F, as shown in FIG. A cooler 110, a cross flow fan 100 for forming cold air supplied from the cooler 110 into an air flow film, an induction pipe 120 through which the air flow film generated in the cross flow fan 100 is guided, and this induction. A discharge port 125 through which the airflow membrane guided to the pipe 120 is ejected, an inlet 135 for sucking the airflow membrane in multiple stages from the rear wall of the refrigerating chamber R, and the air sucked through the inlet 135 is a cross flow fan 100. It is provided with a multi-duct 130 to induce to re).

In the air flow of the conventional air curtain refrigerator having such a configuration, in the state where the door of the refrigerating chamber R is first closed, the control unit controls the temperature load of the cooler 110 according to the set temperature. In addition, since the heat exchange of the air is performed in the cooler 110 having this temperature load and the circulation fan 144 rotates, the cold air is led to the distribution duct 105 so that the distribution port piped to both sides of the rear wall of the refrigerating chamber R ( (Not shown) to the refrigeration chamber (R). The cold air ejected into the refrigerating compartment (R) circulates the refrigerating compartment so that the cold air is stored freezing, the cold air is lost to the temperature load flows into the inlet 135 and the refrigerating compartment (R) through the multi-duct (130) It flows into the recovery pipe (not shown) piped in the center of the rear wall. The cold air flowing into the recovery pipe is supplemented with the temperature load through the cooler 110 to repeat the above circulation process.

In addition, when the door is opened, as shown in FIG. 2, first, when the door 140 of the refrigerating chamber R is opened, the door switch 142 transmits the open state of the door 140 to a controller (not shown). The signal sensed by the controller stops the operation of the circulation fan 144 and simultaneously activates the cross flow fan 100. The cold air flow circulating in the refrigerating chamber R by the operation of the cross flow fan 100 is guided to the inlet 135, and the cold air does not flow from the inlet 135 through the multi duct 130 to the recovery pipe, and thus the cross flow fan ( 100). This is because the operation of the circulation fan 144 is stopped and the cross flow fan 100 is operated so that the flow force of the cold air flows to the cross flow fan 100 without flowing to the recovery pipe because there is no flow force of the circulation fan 144. The cold air thus induced is formed as a laminar flow airflow film in which air particles flow in an orderly manner by the crossflow fan 100. The laminar airflow membrane is led from the transverse flow fan 100 to the induction pipe 120, and the airflow membrane is formed by the induction pipe 120 at the lower end of the flow with some turbulence. The airflow membrane of the complex flow is injected from the induction pipe 120 to the discharge port 120 installed on the front upper side of the refrigerating chamber R. The airflow membrane is a strong plane having a flow velocity of 5 kPa or more by the crossflow fan 100 and the discharge port 120. It is formed by jets. The airflow membrane of the jet stream is injected from the discharge port 125 into the refrigerating chamber (R), and the airflow membrane is circulated through the refrigerating chamber (R) from the upper front side of the refrigerating chamber (R) to the rear, and then formed in the inlet ( 135), in which the air inlet 135 is designed to have a strong suction force from the upper side to the lower side so that the airflow membrane is effectively delivered to the lower end of the refrigerating chamber (R). Circulated. The cold air circulated in this way is guided to the multi duct 130 at the suction port 135, and the cold air is recycled to the crossflow fan 100 by the multi duct 130. That is, when the door of the refrigerating chamber (R) is opened, the cold air is circulated only in the refrigerating chamber (R) without passing through the cooler 100 through the recovery pipe (136).

On the other hand, the air flow in the state in which the door 140 is opened as described above, the air flow membrane blocks the outside air, so that the cold air in the refrigerating chamber (R) is blocked, when the door 140 of the refrigerating chamber (R) is closed again, the door switch 142 transmits the closing signal of the door 140 to the control unit, which stops the rotation of the cross flow fan 100. In the state where the rotation of the cross flow fan 100 is stopped and the air flow film is not formed, the refrigerating chamber circulation fan 144 is intermittently operated and the cooler is operated according to the set temperature to supply cold air to the refrigerating chamber R. To circulate.

However, if the door opening time of such a refrigerator is delayed for a long time or the cooling load of the refrigerating chamber R drops due to frequent opening and closing of the door 140, the operating time of the cooler 110 must be operated for a long time to compensate for the lost temperature load. In addition, the air flow in the refrigerating chamber (R) designed appropriately for the air flow of the airflow membrane is not desired during the time that the cooler 110 is operated, so the load loss of the cooler 110 for restoring the cooling function is not desired. This is caused, especially the stored food of the pocket portion 145 installed on the door 140 side of the refrigerating chamber has a problem that the cold air delivery is not always desired.

The present invention has been invented in view of the above problems, and even when the door is closed, the cold air control device is intermittently operated so that the air flow can be actively utilized to enable efficient air flow during operation of the cold air control device. It is an object of the present invention to provide a cold air circulation structure of an air curtain refrigerator, in which the recovery of the lost cooling function is quickly performed, thereby preventing the loss of the load of the cooler and improving the cooling performance of the pocket installed in the door of the refrigerator compartment.

In order to achieve the above object, the present invention provides an enlarged nozzle having an enlarged discharge port through which an airflow film generated in a cold air control device is injected, a partition partitioning the enlarged nozzle and the discharge port, and selectively opening and closing the enlarged nozzle. A damper having a pressing piece formed in an upright direction from both sides, a guide bracket formed on both sides of the damper and attached to an upper wall of the refrigerating chamber, and having a guide hole into which the pressing piece is fitted, a spring installed on the guide bracket and supporting the damper; Air having a pressing protrusion formed to face the pressing piece of the damper on both sides of the door, a door switch turned on / off by the pressing protrusion, and switching means for intermittently driving the cross-flow fan based on a signal of the door switch. It is achieved by providing a cold air circulation structure of the curtain refrigerator.

1 is a schematic view showing the configuration of a conventional air curtain refrigerator;

2 is a reference diagram showing a cold air circulation when the refrigerator door of FIG. 1 is closed;

3 is a perspective view showing a state in which the cold air control means of the present invention is installed,

Figure 4a is a schematic cross-sectional view showing a door open state of the refrigerator according to the present invention,

Figure 4b is a schematic cross-sectional view showing a closed state of the door of the refrigerator according to the present invention,

Figure 5a is a schematic cross-sectional view showing another embodiment of the present invention,

Figure 5b is a circuit diagram of a switching means according to another embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

1 Cross flow fan 5 Discharge port

10: cooler 12: circulation fan

14 multi duct 16 inlet

20: cold air outlet 22: expansion nozzle

24: bulkhead 40: cold air control means

42: damper 44: push piece

46: guide bracket 48: guide

50: spring 52: pusher

55: door switch 56: door

60: switching means 62: time switching

64: microcomputer 70: switching circuit

72: comparator 74: control signal unit

80: temperature sensor

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

As shown in FIG. 3 and FIG. 4, the cold air ejection opening 20 formed in the airflow film injection part of the cold air control device provided in the air curtain refrigerator, and the cold air ejection opening 20 are opened in the door 30. As shown in FIG. The cold air control means 40 to close according to the control unit, and the switching means 60 to control the drive of the cross-flow fan (1) in accordance with the control of the cold air control means (40).

The cold air outlet 20 is composed of a discharge port 5, the expansion nozzle 22 and the partition wall 24, the expansion nozzle 22 is installed on the front upper wall of the refrigerating chamber (R) to perform an air curtain function It is formed to be slightly larger than the width of the discharge port 5 inside the discharge port 5 through which the airflow film is sprayed, that is, the front is enlarged integrally with the discharge port 5, and the partition 24 has the discharge port 5 and the expansion nozzle 22. ), The airflow film is formed horizontally with the spraying direction of the airflow film so as to be divided and sprayed into the enlarged nozzle 22 and the discharge port 5.

The cold air control means 40 includes a damper 42, a guide bracket 46, a pusher 50, and a door switch 55, and the damper 42 includes an enlarged nozzle 22. It is formed in a width that can close enough to selectively open and close the enlarged nozzle 22 and the discharge port 5, the pressing piece 44 is formed on both sides in the standing direction. In addition, the guide bracket 46 is attached to the upper wall of the refrigerating chamber R at both sides of the cold air outlet 20 to support the opening and closing operation of the damper 42, and the pressing piece 44 on one side of the bottom surface of the guide bracket 46. The guide hole 48 is inserted is formed and a spring 50 for supporting the damper 42 is installed at the rear. In addition, the pressing protrusion 50 is formed at a position opposite to the pressing piece 44 of the damper 42 above the door 56 to enable the opening and closing operation of the damper 42, the door switch 55 Is turned on / off by opening and closing the door 56.

In addition, the switching means 60 is a time switching 62 for rotating the cross flow fan 1 at regular intervals by the on / off of the door switch 55 is embedded in the microcomputer 64 to control the overall function of the refrigerator. It is.

Next will be described the operation of the present invention made as described above.

First, the air of the refrigerating chamber (R) is a temperature load is converted in the cooler 10 is supplied to the refrigerating chamber (R), the air supplied to the refrigerating chamber (R), that is, the temperature of the cold air is set manually and automatically The set value is the temperature control circuit because the microcomputer 64 is built-in to control the driving of the cooler (10). At this time, the microcomputer 64 controls the operation of the cooler 10 according to the set temperature, and simultaneously operates the circulation fan 12 to circulate the cold air in the refrigerating chamber R so that the cold air is not shown in the cooler 10. Guided to the distributor. The cold air is ejected into the refrigerating chamber (R) by the circulation fan 12 in a state where the cross flow fan (1) is not operated, and this cold air circulates through the refrigerating chamber (R) and delivers the cold air to the storage of the refrigerating chamber (R). do. The air delivering the cold air is circulated in the refrigerating chamber (R) and then recycled to the cooler (10) through an inlet not shown. The air passes through the cooler 10 according to the set temperature of the microcomputer 64 and is recycled back to the refrigerating chamber R or the temperature load is converted again in the cooler 10 and recycled to the refrigerating chamber R. The temperature is kept the same as the set temperature.

On the other hand, as described above, while the cold air circulates through the refrigerating chamber R, the pressing protrusions 50 formed on both sides of the door 56 hold down the pressing pieces 44 of the damper 42, and the damper 42 is a cold air jetting outlet ( 20 is located in a state in which only the discharge port 5 is closed.

When the door 56 of the refrigerating chamber R is opened in the above state, as shown in FIG. 4A, the pressing protrusion 50 is rotated together with the door 56 so that the pressing piece 44 Since the retractor is retracted from the front, the damper 42 which is blocking the discharge port 5 of the cold air outlet 20 is held by the elastic force of the spring 50 installed in the guide bracket 46, so that the damper 42 is supported by the position of the damper 42. To the enlarged nozzle 22 side. The damper 42 moved in this way closes the expansion nozzle 22 and at the same time opens the discharge port 5, and the door switch 55, which is turned on / off in accordance with the opening and closing of the door 56, opens the refrigerating chamber R. It detects whether or not to apply a signal indicating the opening of the door 56 to the microcomputer (64). The open signal of the door 56 is applied from the microcomputer 64 to the cross flow fan 1 so that the cross flow fan 1 rotates. The airflow film generated by the rotation of the crossflow fan 1 is guided to the discharge port 1 from the crossflow fan 1, and the airflow film is formed by the damper 42 opening the discharge port 5 and closing the expansion nozzle 22. Because of the state, the width of the discharge port 5 is formed to a standard for effectively injecting the airflow film, and the laminar airflow film is injected from the front upper side to the lower side of the refrigerating chamber R only through the discharge port 5. The airflow membrane sprayed in this way performs a blocking function between the outside air and the refrigerating chamber R in front of the refrigerating chamber R to prevent cold air from flowing out of the refrigerating chamber R, and prevents air from entering the refrigerating chamber R. Since the curtain function is performed, the cold air in the refrigerating chamber (R) is guided to the optimum loss to maintain the temperature load. The air curtain membrane performing the air curtain function is sucked into the suction port 16 formed on the rear wall and the lower end of the refrigerating chamber R, and the sucked cold air is recycled to the cross flow fan 1 through the multi duct 14.

On the other hand, when the door 56 of the refrigerating chamber (R) is closed while the air curtain function as described above, as shown in Fig. 4 (b), the pressing projection 50 at the same time as the door 56 is closed Since the pressing piece 44 is pressed in the opposite position of the pressing projection 50, the position of the damper 42 which was blocking the expansion nozzle 22 of the cold air | gas outlet 20 is moved to the discharge port 5 side. The damper 42 moved in this way closes the discharge port 5 and opens the expansion nozzle 22, and the door switch 55 on / off according to the opening and closing of the door 56 is closed of the refrigerating chamber R. It detects whether or not to apply a signal indicating the closing of the door 56 to the microcomputer (64). The closing signal of the door 56 is applied to the switching means 60 incorporated in the microcomputer 64, and this signal is controlled by the switching means 60 to rotate the cross flow fan 1 at regular intervals. At this time, if the switching means 60 starts the rotation of the cross flow fan 1, the cross flow fan 1 is rotated so that the cross flow fan 1 forms an airflow film in the same action as the opening of the door 56. To the cold air outlet (20). As the airflow membrane guided to the cold air outlet 20 is discharged at the outlet 5 and the enlarged nozzle 22 is open, the partition wall 24 in the cold air outlet 20 guides the airflow membrane to the enlarged nozzle 22 and expands at the same time. It is injected into the refrigerating chamber (R) through the nozzle (22). At this time, since the injection direction of the expansion nozzle 22 is formed toward the door 56 side than the injection direction of the discharge port 5, the airflow film is injected into the refrigerating chamber R by the expansion nozzle 22, but mainly the refrigerating chamber R The airflow film is sprayed to the door 56 side, i.e., the pocket part 57 side. The jetted airflow film flows in turbulent flow due to the resistance of the pocket 57 unlike the jetting in the discharge port 5, but the jetting speed of the airflow film is the same as the speed of performing the air curtain function. Is held by the pocket portion 57, and the pressure is maintained so that the airflow film circulates through the refrigerating chamber R while maintaining strong cold air. Since the cold air circulated in the refrigerating chamber R is maintained in the closed state of the door 56, the temperature load is transmitted to the pocket 57 and the food stored in the refrigerating chamber R and guided to the suction port 16. The air guided to the inlet 16 thus rotates the cross flow fan 1 so that the refrigeration chamber continues to be circulated, and at the same time, the microcomputer 64 operates the circulation fan 12 that circulates the cold air of the refrigerating compartment R, and thus the refrigerating compartment R Part of the cold air circulated in the crossflow fan 1 is led to the cooler 10 through the return pipe 13. The cold air flow guided to the cooler is supplemented with cold air from the cooler 10 and ejected back to the refrigerating chamber R, and the cold air is joined in the cross flow fan 1 so that the circulating cold air is cooled according to the set temperature of the microcomputer 64. Is replenished and recycled.

When the cooling means 60 of the microcomputer 64 blocks the rotation signal of the cross flow fan 1 while the cold air is forcedly circulated by the cross flow fan 1 as described above, the cross flow fan 1 The rotation is stopped and the cold air circulation of the refrigerating chamber R is circulated by the circulation fan 12 in the same manner as the circulation path of the conventional refrigerating chamber R.

Thus, the circulation path circulates the refrigerating chamber R in the path as described above according to whether the cross flow fan 1 is operated, so that the cold air control device is periodically operated by the switching means 60 even in the closed state of the door 56. Since the cooling performance of the refrigerating chamber (R) is improved, and when the door 56 is opened again, the cold air conditioner is operated in the same manner as described above to perform the air curtain function.

On the other hand, according to another embodiment of the present invention, the temperature sensor 80 is provided on the side of the crossflow fan 1 in the multi-duct 14 in which cold air of the refrigerating chamber R is circulated. The detection signal is configured to be applied to the switching means 60 built in the microcomputer 64 only when the door 56 of the refrigerating chamber R is closed, and the switching means 60 is applied to the temperature sensor 80. The switching circuit unit 70 controls the rotation of the cross flow fan 1 by the comparator 72, which compares the sensed temperature signal input from the temperature sensor 80 with the reference value Vref. And a control signal portion 74 for controlling the rotation of the cross flow fan 1 based on the signal from the comparator 72.

The operation of another embodiment configured as described above is the same as that of the present invention when the door 56 is opened, and the temperature of the cold air circulated through the refrigerating chamber R by the circulation fan 12 when the door 56 is closed. Is sensed by the temperature sensor 80 in the multi-duct 14, the temperature detection signal is applied from the temperature sensor 80 to the switching means 60, that is, the switching circuit unit 70 of the microcomputer 64. This temperature sensing signal is input to the switching circuit section 70, and this temperature sensing signal is applied to the comparator 72 constituting the switching circuit section 70. The comparator 72 compares the set reference value Vref with its input signal. For example, when the value input from the temperature sensor 80 is smaller than the reference value Vref of the comparator 72, the comparator ( 72 outputs a low level signal, and the output low level signal is input to the control signal unit 74. The low level signal is selected by the control signal unit 74 to drive the cross flow fan 1, and the selected driving unit is controlled by the control signal unit 74 of the microcomputer 64 of the cooler 10 driving circuit unit ( The cooler 10 is driven by imparting a signal to the signal (not shown). Therefore, even when the door 56 is closed, the cross flow fan 1 is driven by the signal of the temperature sensor 80 so that cool air is injected through the expansion nozzle 22, and the refrigerating chamber R has the same effect as the present invention. ) Cold air is circulated.

On the other hand, when the value input from the temperature sensor 80 is larger than the reference value Vref of the comparator 72, the comparator 72 outputs a high level signal, and the high level signal is output as a control signal unit. It is inputted by 74. The low level signal is selected by the control signal unit 74 to drive the cross flow fan 10, and the selected driving unit is controlled by the control signal unit 74 to the cooler 10 driving circuit unit of the microcomputer 64. Pass the signal. The cross flow fan 1 driven by such a signal stops its operation, and the cold air circulation of the refrigerator is circulated in the same manner as the cold air circulation of the circulation fan 12 as described in the present invention. Since the time or driving period of the cross flow fan 1 driven according to the detection signal of the temperature sensor 80 changes according to the reference value Vref of the comparator 72, the comparator The reference value Vref of 72) may be set, and since a general-purpose purge circuit is built in response to the temperature change of the refrigerating chamber R, the automatic adjustment may be performed by those skilled in the art in various ways within the scope of the present invention. You can do it.

As described above, the present invention performs the air curtain function by the rotation of the cross flow fan 1 in the state in which the door 56 is opened, and rotates the cross flow fan 1 intermittently even when the door 56 is closed and the expansion nozzle ( 22) to circulate the cool air in the refrigerating chamber (R) by spraying the airflow film.

The cold air circulation structure of the air curtain refrigerator according to the present invention can be utilized intermittently by operating the cold air control device even when the door is closed, thereby effectively utilizing the air flow which becomes an efficient air flow during operation of the cold air control device. Recovery of the cooling function is quickly performed to prevent the loss of the cooler, and in particular, the cooling performance of the pocket part installed in the door of the refrigerator compartment is improved.

Claims (6)

In the air curtain refrigerator having a cross flow fan (1) in the cold air control device, A cold air ejection outlet 20 through which cold air generated in the crossflow fan 1 is selectively ejected, cold air control means 40 which closes the cold air ejection outlet 20 according to the opening of the door 56, and the cold air control Cooling air circulation structure of the air curtain refrigerator, characterized in that the switching means for intermittent drive of the cross flow fan (1) according to the control of the means (40). 2. The cold air ejection opening (20) according to claim 1, wherein the cold air ejection opening (20) includes an ejection opening (5) through which an airflow film is ejected, an enlargement nozzle (22) formed integrally with the ejection opening (5), and the enlargement nozzle (22) and the ejection opening ( 5) The cold air circulation structure of the air curtain refrigerator, characterized in that consisting of partitions (24) partitioning. The damper (42) according to claim 1, wherein the cold air control means (40) is provided with a pressing piece (44) formed in both sides of the cold air control means (40) to open the discharge port (5) when the door (56) is opened. 42, a guide bracket 46 which is attached to the upper side of the refrigerating chamber on both sides of the refrigerating chamber and has a guide hole 48 into which the pressing piece 44 is fitted, and which is installed on the guide bracket 46 to support the damper 42. A spring 50 to be formed, a pressing protrusion 52 formed to face the pressing piece 44 of the damper 42 at both sides of the door 56, and the pressing protrusion 52 is provided with the pressing piece 44. Cold air circulation structure of the air curtain refrigerator, characterized in that consisting of a door switch 55 that is turned on / off by the door 56 at the same time. The cold air of the air curtain refrigerator according to claim 1, wherein the switching means (60) is a time switching (62) for rotating the cross flow fan (1) at regular intervals based on the control of the cold air control means (40). Circulation structure. The switching circuit part of claim 1, wherein the switching means (60) is controlled by a temperature sensor (80) installed on the side of the crossflow fan (1) in the multi-duct (14). 70) cold air circulation structure of the air curtain refrigerator. 6. The switching circuit unit (70) according to claim 5, wherein the switching circuit unit (70) is based on a comparator (72) for comparing the sensed temperature signal input from the temperature sensor (80) with a reference value (Vref) and a signal from the comparator (72). Cold air circulation structure of the air curtain refrigerator, characterized in that consisting of a control signal unit for controlling the rotation of the furnace cross flow fan (1).

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