KR20090121790A - Electric hob - Google Patents

Abstract

PURPOSE: An electric hob is provided to reduce the number of process and part by simply tightening a casing. CONSTITUTION: An electric hob comprises a casing(10), a top plate(20), a control assembly(30) and an induction heating module(40). The casing is cube and has an opened top. An air inhalation part inhaling the air to cool the induction heating module is formed on bottom of the casing. An elastic support(15) is located on the bottom of the casing and supports the induction heating module. The top plate has a food container and is combined on top of the casing. The control assembly is equipped in the center front of the casing in the front of the induction heating module. The induction heating module includes an inverter assembly(100) and a working coil assembly(200).

Description

Electric Hob

The present invention relates to a cooking appliance, and more particularly, to an electric hob for cooking food using electricity.

An electric hob is a cooking apparatus which heats food using an induction heating heater or an electric resistance heater. The electric hob is provided with a plurality of electrical components for the operation of the heater. The electrical component is installed inside a predetermined casing. In addition, a cooling fan is installed inside the casing to form an airflow for cooling the electrical components. The casing generally includes a base provided with a predetermined space and a cover that shields the space. However, in the related art, since the base and the cover are fastened by two or more fasteners, a disadvantage arises in that the number of parts and the number of working hours are increased.

The present invention is to solve the problems caused by the prior art as described above, it is an object of the present invention to provide an electric hob that the fastening of the casing is configured more simply.

According to an embodiment of the present invention for achieving the object as described above, the present invention is a base plate formed in a polyhedral shape at least one surface is opened; A part installed in the base plate; A cover plate for shielding an open side of the base plate; First and second fastening members respectively preventing movement of the cover plate in one direction and a direction orthogonal to the base plate while the cover plate shields an open surface of the base plate; It includes.

According to the present invention, there is an advantage that the base plate and the cover plate are more simply fastened.

Hereinafter, the configuration of an embodiment of an electric hob according to the present invention will be described in more detail with reference to the accompanying drawings.

1 is an exploded perspective view showing an embodiment of an electric hob according to the present invention.

Referring to Figure 1, the electric hob 1 according to the present invention, the food is cooked by induction heating to heat the container itself containing the food. The electric hob 1 includes a casing 10, a top plate 20, a control assembly 30, and an induction heating module 40.

The casing 10 is formed in a flat hexahedral shape with an upper surface open. The casing 10 forms a bottom surface and an rim surface appearance. In addition, a plurality of inlets 11 are formed on the bottom surface of the casing 10 to serve as an entrance area through which air for cooling the inductance heating module 40 is sucked.

In addition, the vent grill 13 is provided at an outer side of the rear surface of the casing 10. The vent grill 13 serves as an outlet through which the air cooling the inductance heating module 40 is discharged to the outside. In this embodiment, the vent grill 13 discharges the air cooled by the inductance heating module 40 to face upward.

The bottom surface of the casing 10 is provided with a plurality of elastic support (15). The elastic support 15 serves to support the inductance heating module 40. For example, the elastic support part 15 may include a support boss protruding upward from the bottom surface of the casing 10 and an elastic spring provided on an outer circumferential surface of the support boss.

On the other hand, the top plate 20 is where the container containing the food is seated. The top plate 20 may be formed of, for example, a ceramic material. The top plate 20 is coupled to the upper portion of the casing 10. The top plate 20 is provided with a container seating portion 21 for indicating where the container is seated.

The control assembly 30 is provided at the front end portion of the casing 10 corresponding to the front of the inductance heating module 40. The control assembly 30 receives an operation signal for the operation of the electric hob 1, more specifically, the operation of the inductance heating module 40.

The inductance heating module 40 is a portion for cooking food by induction heating substantially. In the present embodiment, two inductance heating modules 40 are installed inside the casing 10, but the number of inductance heating modules 40 is not limited thereto. The inductance heating module 40 includes an inverter assembly 100 and a working coil assembly 200, respectively.

The inverter assembly 100 includes various electrical elements including printed circuit boards 151 and 155 (see FIG. 2) for the operation of the working coil assembly 200. The inverter assembly 100 supplies a high frequency low pressure to the working coil assembly 200. Detailed description thereof will be described later. The working coil assembly 200 operates by a high frequency current applied from the inverter assembly 100 to generate an alternating magnetic field for induction heating of a container containing food.

Hereinafter, the inverter assembly constituting the electric hob according to the present invention will be described in more detail with reference to the accompanying drawings.

Figure 2 is an exploded perspective view showing an inverter assembly in an embodiment of the present invention, Figure 3 is a plan view showing a base plate in an embodiment of the present invention, Figure 4 is a longitudinal sectional view showing the main portion of the base plate in an embodiment of the present invention. 5 is a front view showing a heat sink in an embodiment of the present invention.

Referring to FIG. 2, the inverter assembly 100 includes an inverter casing 110 and 130, a cooling fan 140, a printed circuit board 151 and 155, and a heat sink 160. The cooling fan 140, the printed circuit boards 151, 155, and the heat sink 160 are installed in the inverter casing. The printed circuit boards 151, 155 and the heat sink 160 are cooled by an airflow formed by driving the cooling fan 140 in a state installed inside the inverter casing 110, 130. do. In other words, the inverter casing (110) 130, the space for the cooling fan 140, the printed circuit board 151 (155) and the heat sink 160 is installed and the drive of the cooling fan 140. The air flow formed by the air flow forms a space.

In more detail, the inverter casing 110, 130 includes a base plate 110 and a cover plate 130. For example, the base plate 110 and the cover plate 130 may be formed by injection molding.

2 and 3, the base plate 110 is formed in a flat polyhedral shape with an approximately upper surface opened. Inside the base plate 110, a fan mounting unit 111, a heat sink mounting unit 112, and first and second substrate mounting units 113 and 114 are provided. The fan mounting portion 111 is provided on the left side of the front end of the base plate 110 in the drawing. The heat sink mounting portion 112 is provided on the left side of the rear end of the base plate 110 in the drawing. In addition, the heat sink mounting unit 112 is provided at the right end of the base plate 110 in the drawing. Finally, the second substrate mounting portion 114 is provided on the right side of the front end of the base plate 110 in the drawing. The fan mounting unit 111 is in communication with the heat sink mounting unit 112 and the first and second substrate mounting units 113 and 114, respectively, and the first and second substrate mounting units 113 and 114. ) Are in communication with each other. The heat sink mounting unit 112 and the first substrate mounting unit 113 are partitioned from each other by the shielding rib 121 and the partition rib 137 which will be described later.

On the other hand, the intake hole 115 is formed in the front end portion of the base plate 110. The intake hole 115 has an entrance area through which air is sucked by the driving of the cooling fan 140. The intake hole 115 is formed at one side of the front end portion of the base plate 110 corresponding to the inside of the fan installation part 111.

In addition, an exhaust opening 116 is formed at a rear end of the base plate 110, that is, at a rear end of the heat sink mounting unit 112 and the first substrate mounting unit 113. The exhaust opening 116 is formed by substantially opening the rear surface of the base plate 110, and the air sucked through the intake hole 115 through the exhaust opening 116 is the printed circuit board ( 151 and 155 are cooled and discharged to the outside.

A plurality of support ribs 117 are provided outside the edge surface of the base plate 110. The support rib 117 is for supporting the inductance heating module 40 in the casing 10. The support ribs 117 are formed with a boss through hole 117A through which the support boss penetrates. The bottom surface of the support rib 117 is supported by the elastic spring while the support boss penetrates through the boss through hole 117A, so that the inductance heating module 40 is supported by the elastic support 15. It is elastically supported inside the casing 10.

In addition, a plurality of fastening protrusions 118 is provided at the upper edge portion of the outer surface of the base plate 110. The fastening protrusion 118 is formed to have a predetermined length in the horizontal direction on the outer upper end portion of the edge surface of the base plate 110. The fastening hook 131 to be described later is fastened to the fastening protrusion 118. A fastening boss 119 is provided outside the edge surface of the base plate 110. The fastening boss 119 is where the fastener S for fastening the cover plate 130 is fastened.

A shielding rib 121 is provided at the rear end center of the bottom surface of the base plate 110 corresponding to the inside of the first substrate mounting unit 113. The shielding rib 121 protrudes upward by a predetermined height from the bottom surface of the base plate 110 so as to form a closed curve as a whole. The shielding rib 121 is for protecting the switching device to be described later. In addition, the shielding rib 121 may also divide the rear end portion of the base plate 110 into the heat sink mounting portion 112 and the first substrate mounting portion 113.

Meanwhile, referring to FIGS. 2 to 4, the base plate corresponding to the boundary between the motor mounting unit 111, the heat sink mounting unit 112, and the first and second substrate mounting units 113 and 114 ( First to third air guides 123 and 124 and 125 are provided on the bottom surface of the 110. The first to third air guides 123, 124 and 125 are configured to pass the airflow formed by the driving of the cooling fan 140 to the heat sink mounting portion 112 and the first and second air guides. It is partitioned into the substrate installation unit 113, 114 serves to guide the flow.

More specifically, the first air guide 123, the air flow by the drive of the cooling fan 140, the heat sink mounting portion 112 and the first and second substrate mounting portion 113, 114 It is divided into) and flows. The first air guide 123 extends from one side of the fan installation unit 111 toward the boundary of the heat sink installation unit 112 and the first substrate installation unit 113. In this case, the first air guide 123 is inclined at a predetermined angle toward the rear of the base plate 110.

In addition, the second air guide 124 protrudes upward by a predetermined height from the bottom surface of the base plate 110 corresponding to the front end of the heat sink installation part 112 in the drawing. The front surface 124A of the second air guide 124 extends upwardly at a predetermined angle toward the rear of the base plate 110. The rear surface 124B of the second air guide 124 extends inclined downward toward the rear of the base plate 110. Therefore, the airflow guided to the heat sink installation part 112 in the drawing by the second air guide 124 is the heat by the front surface 124A and the rear surface 124B of the second air guide 124. Guided to the top or bottom of the sink installation 112.

The third air guide 125 has an airflow guided to the first and second substrate mounting portions 113 and 114 by the first air guide 123 and the first substrate mounting portion 113. It is partitioned into the second substrate installation unit 114 serves to guide the flow. The third air guide 125 includes first and second guide parts 126 and 128. The first guide part 126 extends from one side of the fan mounting part 111 toward the boundary of the first and second substrate mounting parts 113 and 114. In this case, the first guide part 126 is inclined at a predetermined angle toward the rear of the base plate 110 to be substantially parallel to the first air guide 123. The first guide part 126 guides a part of the airflow by the cooling fan 140 to the first substrate installation part 113. In addition, the air flow opening 127 is formed in the first guide part 126. The air flow opening 127 has an entrance area in which a part of the air flow guided by the first guide part 126 flows to the second substrate installation part 114. The second guide portion 128 extends inclined at a predetermined angle toward the front of the base plate 110 at one side of the first guide portion 126 adjacent to the air flow opening 127. The second guide portion 128 serves to guide the air flow flowing through the air flow opening 127 to the second substrate mounting portion 114.

The cover plate 130 shields the opened upper surface of the base plate 110. That is, substantially, the fan mounting portion 111, the heat sink mounting portion 112 and the first and second substrate mounting portion 113, 114 is shielded by the cover plate 130. To this end, the cover plate 130 is formed in a shape corresponding to the opened upper surface of the base plate 110. However, the cover plate 130, the rear end is preferably spaced apart from the exhaust opening 116 by a predetermined distance for easy discharge of the airflow by the cooling fan 140.

A plurality of fastening hooks 131 are provided at the edge of the cover plate 130. The fastening hook 131 is formed in an L-shape opening toward the front. The cover hook 130 is horizontal with respect to the base plate 110 in a state in which the bottom surface of the cover plate 130 is in close contact with an upper end of the edge surface of the base plate 110. The fastening protrusion 118 is walked by the relative movement to the.

In addition, one through hole 133 is formed at the edge of the cover plate 130. The through hole 133 is formed at one side of the cover plate 130 corresponding to the fastening boss 119. The through hole 133 is a place through which the fastener S fastened to the fastening boss 119 passes.

The top and bottom surfaces of the cover plate 130 are provided with a plurality of reinforcing ribs 135. The reinforcing rib 135 protrudes upward or downward from an upper surface or a lower surface of the cover plate 130 to reinforce the cover plate 130.

On the other hand, a partition rib 137 is provided on the bottom of the cover plate 130. The partition rib 137 serves to partition the upper end of the rear end of the base plate 110 into the heat sink mounting unit 112 and the first substrate mounting unit 113. To this end, the partition rib 137 extends long forward and backward on the bottom surface of the cover plate 130.

The cooling fan 140 forms an air flow for cooling the printed circuit boards 151 and 155. To this end, the cooling fan 140 is installed in the fan installation unit 111. An intake portion (not shown) of the cooling fan 140 communicates with the intake hole 115. Therefore, when the cooling fan 140 is driven, air is sucked into the intake portion of the cooling fan 140 through the intake hole 115. In addition, the exhaust portion (not shown) of the cooling fan 140 faces the rear end of the base plate 110. Therefore, the air flow formed by the air discharged from the exhaust of the cooling fan 140 faces the rear end of the base plate 110.

The printed circuit boards 151 and 155 include an inverter board 151 and a filtering board 155. The inverter substrate 151 is installed in the first substrate installation unit 113, and the filtering substrate 155 is installed in the second substrate installation unit 114. The inverter substrate 151 is provided with a plurality of electrical elements including a plurality of switching elements 153 for supplying a high frequency voltage to the working coil assembly 200. The welding part of the lead terminal for connecting the switching element 153 to the pattern of the inverter substrate 151 while the inverter substrate 151 is installed on the first substrate installation unit 113, the shielding rib 121. ) And a bottom surface of the inverter substrate 151 is supported by the shielding rib 121. In addition, the filtering substrate 155 is provided with a plurality of electrical elements for removing noise included in the signal.

The heat sink 160 is for cooling the inverter substrate 151, particularly the switching element 153 that generates heat. The heat sink 160 is installed in the heat sink mounting unit 112 and is connected to the switching element 153 to receive heat from the switching element 153.

Referring to FIG. 5, the main body 161 of the heat sink 160 is formed in a plate shape having a predetermined length, more specifically, a shape and a size corresponding to the heat sink mounting unit 112. In addition, the body portion 161 is gradually reduced in thickness toward a portion having a relatively slow flow rate in a portion where the flow velocity of the air flow formed by the driving of the cooling fan 140 is relatively fast. In other words, the main body 161 has a thickness different in accordance with the flow velocity of the airflow in a direction orthogonal to an imaginary plane parallel to the flow direction of the airflow driven by the cooling fan 140. More specifically, both ends of the main body portion 161 in the flow direction of the air flow by the drive of the cooling fan 140, with the heat sink 160 is installed in the heat sink mounting portion 112. The other end of the upper surface of the main body portion 161 relatively spaced from the one end of the upper surface of the main body portion 161 adjacent to the discharge portion of the cooling fan 140 of the cooling fan 140 Towards the thickness of the body portion 161 is gradually reduced.

In addition, a connection portion 162 is provided at one end of the main body portion 161 adjacent to the discharge portion of the cooling fan 140. The connection portion 162 is substantially where the switching device 153 is connected. The connecting portion 162 is formed to be inclined downward at a predetermined angle with respect to an imaginary plane parallel to the flow direction of the air flow formed by the driving of the cooling fan 140. This is to increase the heat transfer area between the connecting portion 162 and the switching device 153, that is, the heat sink 160 and the switching device 153.

The upper and lower surfaces of the main body 161 are provided with a plurality of pins 163 and 165. Hereinafter, for convenience of description, the pin 163 provided on the upper surface of the main body 161 is referred to as an upper pin 163 and the pin 165 provided on the lower surface of the main body 161 is referred to as a lower pin 165. . However, the upper end of the upper pin 163 and the lower end of the lower pin 165 are preferably located on the same plane.

The upper fin 163 and the lower fin 165 are each formed long in the flow direction of the air flow formed by the driving of the cooling fan 140. In addition, the upper pin 163 and the lower pin 165 are spaced apart from each other by a predetermined distance in a direction perpendicular to the longitudinal direction. The upper fin 163 and the lower fin 165 are cooled by an air flow formed by driving of the cooling fan 140. At this time, the upper fin 163 is cooled by the air flow guided to the upper portion of the heat sink installation portion 112 by the front surface of the second air guide 124, the lower fin 165 is the second It is cooled by the airflow guided to the lower portion of the heat sink installation portion 112 by the rear surface of the air guide 124.

In addition, the upper and lower surfaces of the main body portion 161 is provided with a temperature sensor installation portion 167. The temperature sensor installation unit 167 is formed by substantially eliminating the upper pin 163 and the lower pin 165 on the upper and lower portions of the main body 161 or by reducing the height thereof relatively. In other words, a portion of the upper and lower surfaces of the main body 161 corresponding to the temperature sensor installation unit 167 is further spaced apart from the upper pin 163 and the lower pin 165. Therefore, substantially, the temperature sensor installation unit 167, the air flow guided by the second air guide 124, compared to the space between the upper pin 163 and the lower pin 165 flows It has a relatively large flow area.

In addition, a temperature sensor (not shown) is installed at the temperature sensor installation unit 167. The temperature sensor detects a temperature of the inverter substrate 151, more specifically, a temperature of the heat sink 160 to determine whether the switching device 153 is overheated. The temperature sensor is preferably installed in the central portion of the temperature sensor mounting portion 167 in the longitudinal direction of the heat sink 160.

When the heat sink 160 is described from another viewpoint, the cross section of the main body portion 161 orthogonal to an imaginary plane parallel to the flow direction of the airflow driven by the cooling fan 140 is substantially triangular, preferably. For example, it can be said that it is formed in the shape of an acute triangle. One of three surfaces of the main body 161 is the bottom surface, and one of the two surfaces forms the connection portion 162. Therefore, it can be seen that the thickness of the main body 161 is gradually reduced by the relationship between one surface serving as the bottom of the main body 161 and the other one surface.

Hereinafter, the operation of the electric hob according to the present invention.

First, the cooling of the inverter assembly in the embodiment of the electric hob according to the present invention will be described in more detail with reference to the accompanying drawings.

Figure 6 is a plan view showing the airflow inside the inverter assembly in the embodiment of the electric hob according to the present invention.

When a user manipulates the control assembly 30 to input an operation signal for the operation of the electric hob 1, a high frequency voltage is supplied from the inverter assembly 100 to the working coil assembly 200. In addition, an AC magnetic field is generated by operating by the high frequency voltage applied from the inverter assembly 100 by the working coil assembly 200. By the alternating magnetic field, a container in which food is placed on the top plate 20 is induction heated to cook food.

Meanwhile, referring to FIG. 6, the cooling fan 140 is driven by the operation of the electric hob 1. Therefore, air is sucked into the intake portion of the cooling fan 140 through the intake hole 115 (see FIGS. 2 and 3). Of course, the air sucked into the intake portion of the cooling fan 140 may be air introduced into the casing 10 through the intake port 11.

The air sucked into the intake portion of the cooling fan 140 is discharged through the exhaust port of the cooling fan 140. The air discharged through the exhaust port of the cooling fan 140 is guided by the first to third air guides 123, 124, and 125 to cool the heat sink 160, and the inverter substrate 151. ) And an air flow for cooling the filtering substrate 155.

More specifically, a part of the air discharged to the exhaust port of the cooling fan 140 is guided by the first air guide 123 to form an air flow flowing toward the heat sink 160. In addition, the airflow toward the heat sink 160 is partially cooled by the second air guide 124 to cool the upper fin 163 of the heat sink 160, and the other part of the heat sink is The lower pin 165 of the 160 is cooled. At this time, the temperature sensor installation unit 167 provided in the heat sink 160 has a relatively large flow cross-sectional area compared to the space between the upper fin 163 and the lower fin 165. Therefore, the air flow toward the heat sink 160 may flow without being interfered by the temperature sensor installed in the temperature sensor installation unit 167. The air cooled by the upper fin 163 and the lower fin 165 (see FIG. 5) is discharged through the exhaust opening 116.

Of course, a part of the air guided by the first air guide 123 flows toward the inverter substrate 151, but most of the air guided by the first air guide 123 is the heat sink 160. Cool down. Therefore, a part of the air guided by the first air guide 123 to cool the inverter substrate 151 will be ignored.

Some of the remaining air discharged through the exhaust port of the cooling fan 140 may be provided to the third air guide 125, more specifically, the first guide part 126 of the third air guide 125. It is guided to flow toward the inverter substrate 151 by. The airflow flowing toward the inverter substrate 151 cools the switching element 153 of the inverter substrate 151, particularly, the inverter substrate 151 and is discharged through the exhaust opening 116.

In addition, the remaining air discharged to the exhaust port of the cooling fan 140 forms an air flow flowing to the filtering substrate 155 through the air flow opening 127 of the third air guide 125. At this time, the airflow flowing through the air flow opening 127 is guided toward the filtering substrate 155 by the second guide portion 128 of the third air guide 125 so that the filtering substrate 155 is provided. ) To cool. The airflow cooling the filtering substrate 155 flows toward the inverter substrate 151 and is discharged through the exhaust opening 116.

On the other hand, the part of the lead terminal of the switching element 153 is welded to the pattern of the inverter substrate 151 is shielded from the outside by a shielding rib 121 provided on the bottom surface of the base plate 110. Accordingly, the welding part of the lead terminal of the switching element 153 may be prevented from being damaged by foreign substances or insects that flow into the base plate 110 through the exhaust opening 116.

Next, the fastening process of the base plate and the cover plate in the embodiment of the electric hob according to the present invention will be described in more detail with reference to the accompanying drawings.

7 to 9 are longitudinal cross-sectional view showing the fastening process of the base plate and the cover plate in the embodiment of the electric hob according to the present invention.

First, as shown in FIG. 7, the bottom surface of the cover plate 130 is in close contact with the upper edge of the base plate 110. In this case, the fastening hook 131 is positioned adjacent to the fastening protrusion 118 in an open state toward the fastening protrusion 118.

As shown in FIG. 8, the cover plate 130 is moved horizontally with respect to the base plate 110, more specifically, to the right in the drawing. Therefore, as the fastening hook 131 is hooked on the fastening protrusion 118, the cover plate 130 is not moved up and down with respect to the base plate 110.

In this state, as shown in FIG. 9, the fastener S passing through the through hole 133 is fastened to the fastening boss 119. Therefore, the cover plate 130 is not moved in the horizontal direction with respect to the base plate 110, thereby fixing the base plate 110 and the cover plate 130.

Within the scope of the basic technical spirit of the present invention as well as many other modifications are possible to those skilled in the art, the scope of the present invention should be interpreted based on the appended claims. .

In the electric hob according to the present invention configured as described above, the fastener penetrating the through hole in the state in which the fastening hook is engaged with the fastening protrusion by the relative movement of the cover plate with respect to the base plate is fastened to the fastening boss. As a result, the base plate and the cover plate are fastened. Therefore, according to the present invention, the base plate and the cover plate are fastened more simply, so that the effect of reducing the number of parts and the labor can be expected.

1 is an exploded perspective view showing an embodiment of an electric hob according to the present invention.

Figure 2 is an exploded perspective view showing an inverter assembly in an embodiment of the present invention.

Figure 3 is a plan view showing a base plate in an embodiment of the present invention.

Figure 4 is a longitudinal sectional view showing the main portion of the base plate in an embodiment of the present invention.

5 is a front view showing the heatsink in the embodiment of the present invention.

Figure 6 is a plan view showing the airflow inside the inverter assembly in the embodiment of the electric hob according to the present invention.

7 to 9 is a longitudinal sectional view showing a fastening process of the base plate and the cover plate in the embodiment of the electric hob according to the present invention.

Claims (7)

A base plate formed in a polyhedral shape having at least one surface opened; A part installed in the base plate; A cover plate for shielding an open side of the base plate; And First and second fastening members respectively preventing movement of the cover plate in one direction and a direction perpendicular to the base plate while the cover plate shields one open surface of the base plate; Electric hob comprising a. The method of claim 1, The first fastening member is, Fastening protrusions provided on any one of the base plate and the cover plate; And A fastening hook provided on the other one of the base plate and the cover plate; Including, And the cover plate moves relative to the base plate so that the fastening hook hangs on the fastening protrusion. The method of claim 1, The second fastening member is, A fastening boss provided on any one of the base plate and the cover plate; A through hole provided in the other of the base plate and the cover plate; And A fastener fastened to the fastening boss by passing through the through hole; Electric hob comprising a. The method of claim 1, Wherein said component comprises a cooling fan forming an airflow and at least one printed circuit board cooled by said airflow. The method of claim 4, wherein The component further comprises a heat sink for dissipating heat of the printed circuit board. The method of claim 4, wherein The printed circuit board, the electric hob further comprises an inverter substrate and a filtering substrate. The method of claim 1, The base plate and the cover plate is an injection molding electric hob.

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