KR101812181B1 - Refrigerator having door locking apparatus - Google Patents

Abstract

A refrigerator according to the present invention includes a cabinet having a groove for locking in an inner wall of a storage space for storing food, a door rotatably mounted on one side of the cabinet for selectively opening and closing the storage space, And a locking device for locking the door by being coupled to the groove of the inner wall of the cabinet by rotation of the key. The locking device includes a key inserting portion for inserting a key into the outer surface of the door, a rotor provided inside the door to be connected to the key inserting portion and rotatable together with the key about a first rotational axis when the key is rotated, A locking portion protruding toward the storage space through the side surface and being rotatable about a second rotation axis spaced apart from the first rotation axis when the rotor rotates, the locking portion being coupled to a groove provided in the cabinet; And a power transmitting portion that connects the rotor and the rotor and transmits rotational force of the rotor to the locking portion.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a refrigerator having a door locking device,

The present invention relates to a refrigerator provided with a door locking device.

Generally, a refrigerator includes a cabinet filled with a heat insulating material and a door to form a food storage space capable of blocking heat penetrating from the outside, an evaporator for absorbing heat inside the food storage space, And a heat dissipating device for dissipating the heat generated by the microorganisms. The food storage space is maintained in a low temperature region where the microorganisms can not survive and proliferate, and the stored food is stored for a long time without deterioration.

Wherein the refrigerator is divided into a refrigerating chamber for storing food in a temperature region of the image and a freezing chamber for storing food in a temperature range of minus temperature and a top freeze chamber in which an upper freezing chamber and a lower refrigerating chamber are arranged, Top Freezer is classified into a bottom freezer refrigerator in which a refrigerator, a lower freezing room and an upper refrigerating room are arranged, and a side by side refrigerator arranged in a left freezing room and a right freezing room.

A plurality of shelves and drawers are provided in the food storage space in order to allow the user to conveniently store or retrieve food stored in the food storage space.

Meanwhile, the refrigerator may be provided with a locking device for locking the door. The locking device may include a key inserting portion provided outside the door, and a locking portion protruding to the inside of the door. When the user rotates the key, the locking part can be rotated together with the cabinet, so that the door can be locked.

However, in the conventional refrigerator, since the key inserting portion and the locking portion are located on the same rotation axis, if the position of the locking portion is determined, the position of the key inserting portion can not be determined. Therefore, there is a problem in that the position of the key insertion unit can not be freely changed according to the request of the user.

An object of the present invention is to provide a refrigerator which can change the position of a key inserting part according to a demand of a user.

A refrigerator for achieving an object of the present invention is a refrigerator comprising a cabinet having a storage space for storing food and having a groove for locking on an inner wall thereof, a rotatably mounted on one side of the cabinet, And a locking device installed on the door and locking the door by engaging with the groove of the inner wall of the cabinet by rotation of a key. The locking device may include a key inserting unit for inserting the key into the outer surface of the door to be connected to the key inserting unit, And a locking portion which is protruded toward the storage space through the inner side surface of the door and rotates around a second rotation axis spaced apart from the first rotation axis when the rotor rotates, And a power transmission part provided inside the door to connect the rotor and the locking part to each other and transmit the rotational force of the rotor to the locking part.

In the exemplary embodiments, the key insertion unit may include an outer cover coupled to an outer surface of the door and having a key insertion port, and a housing extending from the outer cover toward the inside of the door, And can be slidably moved along the first rotation shaft within the housing.

In exemplary embodiments, the inner circumferential surface of the housing may be provided with a first rotation preventing projection extending in the first rotation axis direction, and a first rotation preventing groove corresponding to the first rotation preventing projection may be formed on an outer circumferential surface of the rotor .

In the exemplary embodiments, the first anti-rotation projection may be separated from the first anti-rotation protrusion when the rotor slides along the first rotation axis in the inner direction of the door.

In the exemplary embodiments, the locking device may further include an elastic member provided between the rotor and the power transmitting portion to provide a restoring force for returning the rotor moved inward of the door to an original position .

In exemplary embodiments, the locking device may further include a locker coupled to an outer circumferential surface of the housing to prevent the key insertion portion from being detached from the door.

In the exemplary embodiments, the power transmitting portion may include: a main gear connected to the rotor and rotating about the first rotating shaft; a driven gear connected to the locking portion and rotating about the second rotating shaft; And a transmission gear disposed between the driven gear and the driven gear for transmitting rotational force of the driven gear to the driven sled.

In the exemplary embodiments, the main gear, the transmission gear, and the driven gear may all have the same size.

In exemplary embodiments, the power transmission portion may include a pair of pulleys connected to the rotor and the locking portion, respectively, and a belt for transmitting rotational force between the pulleys.

In the exemplary embodiments, the interior of the door may be filled with a heat insulating material, and the locking device may further include a sealing portion for receiving the power transmitting portion and preventing the heat insulating material from penetrating into the power transmitting portion.

In the exemplary embodiments, the sealing portion may include: a first sealing cover that covers one side of the power transmitting portion; a second sealing cover that extends from the first sealing cover in the direction of the first rotation axis, A second sealing cover which covers the other side surface of the power transmitting portion in association with the first sealing cover and a second sealing cover which covers the other side surface of the power transmitting portion, And a second cylinder which extends in the direction of the second rotary shaft to engage with the locking portion and provides a passage for the locking portion to be connected to the power transmitting portion.

In exemplary embodiments, the first sealing cover and the second sealing cover may be bonded to each other by high frequency welding.

In exemplary embodiments, the coupling surfaces of the first and second sealing covers may have respective concave-convex structures corresponding to each other.

In the exemplary embodiments, the second rotation preventing groove may be formed on the end surface of the second cylinder in contact with the locking portion, the second rotation preventing groove extending in the circumferential direction by a predetermined angle, And a second rotation preventing protrusion inserted into the second rotation preventing protrusion.

In exemplary embodiments, the second rotation preventing groove may be formed in a range of about 90 degrees about the second rotation axis.

In the exemplary embodiments, the locking portion may further include a locking bar extending in a direction substantially perpendicular to the second rotation axis within the storage space, wherein the locking bar is provided in the cabinet by rotation of the locking portion, And can be inserted into the groove.

In exemplary embodiments, the first rotation axis and the second rotation axis may be at different heights from the ground.

In the refrigerator according to the exemplary embodiments, the key inserting portion and the locking portion are located on different axes, so that the position of the key inserting portion can be set regardless of the position of the locking portion.

Accordingly, it is possible to satisfy various demands of the user and to improve the beauty of the refrigerator.

However, the effects of the present invention are not limited to the above-mentioned effects, and may be variously expanded without departing from the spirit and scope of the present invention.

1 is a perspective view showing a refrigerator.
2 is a perspective view showing part A of Fig.
3 is an exploded view of a locking device in accordance with an embodiment of the present invention.
Fig. 4 is a perspective view showing the rotor of Fig. 3;
5 is a sectional view showing the movement of the rotor according to the key insertion.
Fig. 6 is a perspective view showing the locking part and the second sealing cover of Fig. 3;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the specific structural and functional embodiments are provided by way of illustration only, and are not intended to limit the invention to the particular forms disclosed, and all changes, modifications and variations that fall within the spirit and scope of the invention, It is to be understood that the invention includes equivalents and alternatives. In addition, the same reference numerals are used for the same constituent elements in the drawings, and redundant explanations for the same constituent elements are omitted.

1 is a perspective view showing a refrigerator. 2 is a perspective view showing part A of Fig. 3 is an exploded view of a locking device in accordance with an embodiment of the present invention. Fig. 4 is a perspective view showing the rotor of Fig. 3; 5 is a sectional view showing the movement of the rotor according to the key insertion. Specifically, Fig. 5 (a) is a sectional view showing a state where the key 200 is simply inserted, and Fig. 5 (b) is a sectional view showing a state in which the user pushes the key 200. Fig. Fig. 6 is a perspective view showing the locking part and the second sealing cover of Fig. 3;

1 and 2, the freezer compartment and the refrigerating compartment are not separately defined. However, the refrigerating compartment of the refrigerator of the top freeze type, the bottom freeze type refrigerator, the side by side type refrigerator, Can be similarly applied. Hereinafter, for convenience of explanation, only the refrigerator composed of the refrigerating compartment will be described.

1 to 6, a refrigerator 1 includes a cabinet 10 for forming a storage space for storing food, the cabinet 10 being rotatably mounted on one side of the cabinet 10, And a locking device 100 for fixing the door 20 to the cabinet 10 and preventing the door 20 from being opened.

The cabinet 10 may include an outer case 11 forming an outer shape of the refrigerator 1 and an inner case 13 forming the storage space inside the outer case 11. [ At this time, a heat insulating material is filled between the outer case 11 and the inner case 13 to prevent the cool air in the storage space from flowing out to the outside.

Further, a locking groove 15 for locking may be provided on one side wall of the inner case 13. The locking groove 15 may have a shape recessed from the surface of the inner case 13 toward the outer case 11. A locking portion 180 described later is inserted into the locking groove 15. In this case, the door 20 may be fixed to the cabinet 10 and may not be opened.

On the other hand, the position and shape of the locking groove 15 can be variously selected as needed. 2, the locking groove 15 may be located at the same height as the locking portion 180, and may be vertically extended in the vertical direction, for example, when the locking portion 180 has a " And may have an elongated rectangular shape.

The door 20 can be rotatably mounted on one side of the cabinet 10. For example, the door 20 may be hinged to the front of the cabinet 10. The user can rotate the door 20 by pulling the handle 25 attached to the door 20 so that the storage space can be opened.

The locking device 100 may be installed to penetrate the door 20. One side of the locking device 100 is exposed to the outer surface of the door 20 so that a key 200 can be inserted and the other side is protruded from the inner side of the door 20 toward the storage space, 15). ≪ / RTI > When the other side of the locking device 100 is coupled to the locking groove 15, the door 20 is locked and when the other side of the locking device 100 is detached from the locking groove 15, the door 20 is unlocked .

In this case, one surface of the door 20 contacting the outside is defined as an outer surface of the door 20, and a surface opposite to the storage space is defined as an inner surface of the door 20. Therefore, the direction from the door 20 to the outside is the outside direction of the door 20, and the direction from the door 20 toward the storage space is the inside direction of the door 20.

The locking device 100 is accommodated in the key insertion portion 110 and the key insertion portion 110 exposed to the outer surface of the door 20 so that the key 200 can be inserted therein, The rotor 130 rotates with the key 200 about the first rotation axis X ₁ when the key 200 rotates. The rotor 130 protrudes toward the storage space through the inner surface of the door 20, A locking part 180 that rotates around a second rotation axis X _{2 that} is spaced apart from the first rotation axis X ₁ during rotation and is coupled to the locking groove 15; And a sealing portion 150 (not shown) which is provided in the door 20 and is connected to the key inserting portion 110 and the locking portion 180 and accommodates the power transmitting portion 170 therein, , 160).

The key inserting unit 110 may include an outer cover 111 coupled to the outer surface of the door 20 and a housing 113 extending from the outer cover 111 inward of the door 20.

The outer cover 111 is exposed to the outside of the door 20 and includes a key insertion port 112 for insertion of the key 200. The key insertion hole 112 can communicate with the key receiving groove 134 of the rotor 130. 5, the outer surface of the outer cover 111 is exposed to the outside and the inner surface of the outer cover 111 is inserted into the door 20. However, the outer cover 111 is not limited thereto and may be provided in various forms as needed. For example, the inner surface of the outer cover 111 may be in contact with the outer surface of the door 20.

The housing 113 extends from the outer cover 111 to the inner side of the door 20 and can engage with the first sealing cover 150.

For example, as shown in FIG. 5, the housing 113 can be coupled to the first sealing cover 150 so as to surround the end of the first cylinder 157. Accordingly, it is possible to prevent the heat insulating material from penetrating into the housing 113 and the first cylinder 157. In this case, the coupling protrusion 158 formed on the outer circumferential surface of the first cylinder 157 is fastened to the coupling groove 115 formed in the housing 113, so that the ease of coupling can be increased.

The housing 113 has a cylindrical shape and can receive the rotor 130 therein. When the user pushes the key 200, the rotor 130 slides inside the housing 113 and can linearly move inward of the door 20. Also, the rotor 130 may rotate inside the housing 113 when the key 200 is rotated. In this case, at least one first rotation preventing protrusion 117 extending in the direction of the first rotation axis X ₁ may be provided on the inner circumferential surface of the housing 113. The first rotation preventing protrusion 117 may be coupled to the first rotation preventing groove 132 of the rotor 130 to prevent the rotor 130 from rotating. This will be described later.

The locking device 100 may further include a locker 120 for preventing the key insertion unit 110 from being detached from the door 20 by being coupled to the outer circumferential surface of the housing 113.

In one embodiment, the locker 120 may have a ring shape with one side open to increase ease of engagement with the key insertion portion 110. For example, as shown in Fig. 3, the locker 120 may have a " C " shape. Accordingly, the locker 120 can be engaged with the side of the key insertion unit 110 after the key insertion unit 110 is coupled to the first sealing cover 150.

In addition, a locking protrusion 121 may be provided on the inner circumferential surface of the locker 120. 5, the locking protrusion 121 may be inserted into the locking groove 114 provided on the outer circumferential surface of the housing 113. As shown in FIG. Accordingly, the locker 120 can support the key inserting portion 110 so as not to fall outwardly of the door 20.

In one embodiment, the locker 120 may be snugly engaged with the housing 113 of the key insertion portion 110. That is, the diameter of the inner circumferential surface of the locker 120 may be smaller than the diameter of the outer circumferential surface of the housing 113. In this case, the locker 120 may press the housing 113 in the center direction to increase the coupling force between the housing 113 and the first cylinder 157.

The rotor 130 includes a rotor body 131 accommodated in the housing 113, a receiving portion 133 extending from the rotor body 131 in the outer direction of the door 20 and having a key receiving groove 134, And an extension portion 135 extending from the rotor body 131 in the inward direction of the door 20 and extending from the extension portion 135 in the inward direction of the door 20 to the power transmission portion 170, And may include a coupling portion 137.

The key receiving recess 134 can communicate with the key inserting port 112 of the key inserting portion 110. Accordingly, the key 200 inserted through the key insertion opening 112 can be inserted up to the key receiving recess 134. The key receiving groove 134 may extend to the inside of the rotor body 131 and the extended portion 135 according to the length of the key 200. [

In one embodiment, the diameter of the outer circumferential surface of the receiving portion 133 may be larger than the diameter of the key insertion port 112. [ Thus, the receiving portion 133 can be prevented from protruding through the key insertion opening 112 to the outside.

The rotor body 131 is accommodated in the housing 113 and the first cylinder 157, and is capable of linearly reciprocating and rotating. For example, the housing 113, the first cylinder 157, and the rotor body 131 each have a cylinder shape, and the outer peripheral diameter of the rotor body 131 is larger than the outer diameter of the housing 113 and the first cylinder 157 so that the rotor body 131 can perform linear and rotational movements in the housing 113 and the first cylinder 157. In addition,

The key receiving groove 134 of the receiving portion 133 extends to the inside of the rotor body 131 so that a portion of the key 200 can be received in the rotor body 131. Thus, when the user rotates the key 200, the rotor body 131 can rotate with the key 200 as well.

In one embodiment, a structure for restricting rotation of the rotor body 131 may be provided between the rotor body 131 and the housing 113.

For example, at least one first rotation preventing protrusion 117 extending in the direction of the first rotation axis X ₁ is provided on the inner peripheral surface of the housing 113, and on the outer peripheral surface of the rotor body 131, And a first rotation preventing groove 132 corresponding to the first rotation preventing groove 117 may be provided. The rotation of the rotor body 131 can be restricted by engaging the first rotation preventing protrusion 117 with the first rotation preventing groove 132. [ At this time, the shape, position and number of the first rotation preventing protrusion 117 and the first rotation preventing groove 132 can be appropriately selected depending on the situation.

The extension 135 may extend from the rotor body 131 in the inward direction of the door 20 and its distal end may be spaced a predetermined distance from the first sealing cover 150. When the user pushes the key 200 inserted into the key receiving groove 134, the rotor 130 moves inward of the door 20 and the end of the extending portion 135 moves to the first sealing cover 150, / RTI > When the extension part 135 contacts the first sealing cover 150, the rotor 130 can not advance further in the direction of the first rotation axis X ₁ . That is, the movable range of the rotor 130 in the direction of the first rotational axis X ₁ can be limited to the distance that the extended portion 135 is spaced from the first sealing cover 150.

The key receiving groove 134 of the receiving portion 133 may extend to the inside of the extended portion 135 and a portion of the key 200 may be received in the extended portion 135 as well. Thus, when the user rotates the key 200, the extension 135 can rotate with the key 200 as well.

In one embodiment, the diameter of the extension 135 may be less than the diameter of the rotor body 131. One end of the elastic member 140 is supported by the rotor body 131 and the other end of the elastic member 140 is supported by the first sealing cover 150. In this case, have. Accordingly, when the rotor 130 moves inward of the door 20, the elastic member 140 can be compressed.

The first coupling portion 137 extends from the extended portion 135 toward the inner side of the door 20 and is coupled to the power transmission portion 170 so that the rotational force of the rotor 130 can be transmitted to the power transmission portion 170 have.

In one embodiment, the first coupling portion 137 may be a pair of hooks inserted into the power transmitting portion 170. The hook may be inserted into the spur gear 171 of the power transmitting portion 170 and may have a first locking protrusion 138 at its distal end. The first engaging protrusion 138 contacts the fixing protrusion 172e of the driven gear 171 to prevent the rotor 130 from being separated from the driven gear 171. [

In this case, the first locking protrusion 138 and the fixing protrusion 172e may have a tapered shape with respect to each other. That is, the width of the first locking projection 138 may be narrower than the width of the rear side, and the fixing projection 172e may have a wider width at the entrance side. Accordingly, the first engaging portion 137 can be easily inserted into the main gear 171 and can not be easily released after being inserted.

Hereinafter, the movement of the rotor 130 will be described in more detail.

5A, the key 200 is inserted into the key receiving groove 134 through the key insertion slot 112 of the key insertion portion 110. As shown in FIG. In this state, since the first rotation preventing groove 132 of the rotor body 131 is engaged with the first rotation preventing protrusion 117 inside the housing 113, the rotor 130 can not rotate. However, since the first rotation preventing groove 132 extends in the direction of the first rotation axis X ₁ , the rotor 130 can also linearly move inward of the door 20 along the first rotation axis X ₁ Do.

5 (b), when the user pushes the key 200 inward of the door 20, the rotor 130 rotates in the housing 113 and the first cylinder 157 by the first rotation axis X ₁ ) and moves inward of the door 20. As a result, the first rotation preventing groove 132 is separated from the first rotation preventing projection 117, and the rotor 130 becomes rotatable. Further, the elastic member 140 can be compressed.

Thereafter, when the user rotates the key 200, the rotor 130 can rotate together with the key 200. When the rotor 130 rotates, the main gear 171 connected to the rotor 130 also rotates together, so that the rotational force of the rotor 130 can be transmitted to the locking portion 180 through the power transmitting portion 170 .

Finally, when the force applied to the key 200 is removed, the resilient member 140 presses the rotor 130 toward the outside of the door 20 by the restoring force. The rotor 130 moves in the outer direction of the door 20 along the first rotation axis X ₁ in the housing 113 and the first cylinder 157 and can return to the original position.

The power transmitting portion 170 is disposed inside the door 20 and can transmit the rotational force of the rotor 130 to the locking portion 180. [

For example, the power transmitting portion 170 is connected to the rotor 130 and is connected to the main gear 171 and the locking portion 180 that rotate around the first rotation axis X ₁ , and the second rotation axis X ₂ And a transmission gear 175 disposed between the driven gear 171 and the driven gear 173. The driven gear 173 rotates around the driven gear 173 and the driven gear 173. When the rotor 130 rotates the driven gear 171, the transmission gear 175 and the driven gear 173, which are sequentially connected to the driven gear 171, can also rotate. Thus, the locking portion 180 can be rotated. At this time, the center of the driven gear 171 coincides with the first rotation axis X ₁ , and the center of the driven gear 173 coincides with the second rotation axis X ₂ . Accordingly, the rotational force about the first rotational axis X ₁ can be transmitted to the second rotational axis X ₂ through the power transmitting portion 170.

Alternatively, the power transmitting portion 170 may be constituted by a pair of pulleys and a belt. That is, the power transmitting portion 170 may include a driving pulley connected to the rotor 130, a driven pulley connected to the locking portion 180, and a belt connecting the driving pulley and the driven pulley. When the rotor 130 rotates the drive pulley, the drive pulley and the driven pulley connected by the belt can also rotate. Thus, the locking portion 180 can be rotated.

In addition, the power transmitting portion 170 may be configured in various forms as long as it can transmit the rotational force about the first rotational axis X ₁ to the second rotational axis X ₂ . Hereinafter, only the case where the power transmitting portion 170 is composed of a plurality of gears will be described for convenience of explanation.

In one embodiment, the main gear 171, the transmission gear 175, and the driven gear 173 may all have the same size.

That is, the main gear 171, the transmission gear 175, and the driven gear 173 may each have a gear ratio of 1: 1. When the gear ratio is not 1: 1, one gear must be larger in size than the other gears, and the size of the power transmitting portion 170 must be increased. In the present invention, the size of the power transmitting portion 170 can be minimized by setting each gear ratio to be 1: 1 so that the gears are the same size.

Meanwhile, the sizes of the gears 171, 173, and 175 may be variously selected as needed. That is, the user can freely adjust the interval between the first rotation axis X ₁ and the second rotation axis X ₂ by adjusting the size of the gears 171, 173, and 175.

In one embodiment, transmission gear 175 may include two or more gears.

In other words, although the transmission gear 175 is shown as only one gear in FIG. 3, the transmission gear 175 may include two or more gears. The gap between the first rotation axis X ₁ and the second rotation axis X ₂ can be freely adjusted.

When the transmission gear 175 includes an odd number of gears, the main gear 171 and the driven gear 173 rotate in the same direction. However, when the transmission gear 175 includes an even number of gears, The gear 171 and the driven gear 173 can rotate in opposite directions to each other.

In one embodiment, the main gear 171, the transmission gear 175, and the driven gear 173 may all have the same shape.

The main gear 171, the transmission gear 175, and the driven gear 173 may all have the same outer shape. However, the main gear 171 and the driven gear 173 need internal structures 172c, 172d and 172e to be connected to the rotor 130 and the locking portion 180, respectively, There is a difference in that it is not necessary to provide the internal structure as described above. However, the main gear 171, the transmission gear 175, and the driven gear 173 may be provided so as to have the same internal structure for cost reduction. Hereinafter, the structure of the driven gear 171 will be described with reference to Figs. 3 and 5. Fig.

The main gear 171 includes a rotating body 172a inserted between the first and second sealing covers 150 and 160, a plurality of teeth 172b protruding in the circumferential direction from the rotating body 172a, And a through hole 172c formed in the entire body 172a.

The rotating body 172a has a smaller diameter than the teeth 172b but may have a greater thickness than the teeth 172b in the direction of the first rotational axis X ₁ . Accordingly, the rotating body (172a) may be respectively projected to the top and bottom of the teeth (172b) along the first rotation axis (X _1). The protruding portion of the rotating body 172a may be received in the first guide 153 and the second guide 163 provided in the first and second sealing covers 150 and 160, respectively. The first and second guides 153 and 163 guide the rotation of the driven gear 171 by receiving the projected portion of the rotating body 172a and can maintain the position of the driven gear 171 constant .

The teeth 172b are formed on the outer circumferential surface of the rotating body 172a and can be connected to the teeth of the adjacent transmission gears 175. [ When the teeth 172b of the driven gear 171 are rotated, the teeth of the transmission gear 175 engaged with the teeth can rotate. Accordingly, the rotational force of the driven gear 171 can be transmitted to the transmission gear 175. However, the transmission gear 175 rotates in opposite directions to the main gear 171.

The through hole 173c may provide a space in which the first engaging portion 137 of the rotor 130 is accommodated. Therefore, the inner diameter of the through hole 173c may be larger than the outer diameter of the first engaging portion 137, particularly, the first engaging projection 138. [

A partition wall 172d for improving the strength and a fixing protrusion 172e for fixing the first latching protrusion 138 may further be provided in the through hole 173c. However, the internal structure of the through hole 173c may be variously changed depending on the shape of the first engaging part 137. [

On the other hand, in order to prevent the cool air in the storage space from flowing out, the interior of the door 20 may be filled with a heat insulating material. However, the heat insulating material may affect the power transmitting portion 170 during the heat insulating material filling process.

Specifically, a door 20 composed of an inner side surface and an outer side surface is formed, and the locking device 100 is disposed inside the door 20. Since the heat insulating material is wrapped around the power transmitting portion 170 of the locking device 100 during the process, the power transmitting portion 170 does not contact the inner surface of the door 20, You may not be able to rotate. In order to prevent this, the power transmitting portion 170 may be covered with the sealing portion to prevent the power transmitting portion 170 from being directly exposed to the heat insulating material.

The sealing portion may include a first sealing cover 150 and a second sealing cover 160 that cover one side of the power transmitting portion 170, respectively.

The first sealing cover 150 includes a first body 151 covering one side of the power transmitting portion 170 and a second body 151 disposed on the inner side of the first body 151 to detect the positions of the gears 171, And a first cylinder 157 extending from the first body 151 in the direction of the first rotation axis X ₁ and engaging with the key insertion unit 110.

The first guide 153 may have the same number as the number of gears constituting the power transmitting portion 170.

The first cylinder 157 has a cylindrical shape and may internally provide a passage for connecting the rotor 130 and the power transmitting portion 170. The rotor 130 can perform linear motion and rotational motion within the first cylinder 157. The outer circumferential surface of the first cylinder 157 may be provided with a coupling protrusion 158 and the coupling protrusion 158 may be fastened to the coupling groove 115 of the key insertion portion 110.

The second sealing cover 160 includes a second body 161 that covers the other side of the power transmitting portion 170 and a second body 161 that is provided on the inner side of the second body 161 to detect the positions of the gears 171, And a second cylinder 167 which extends from the second body 161 in the direction of the second rotation axis X ₂ and engages with the locking part 180. [

The second guide 163 may have the same number as the number of gears constituting the power transmitting portion 170.

The second cylinder 167 has a cylindrical shape and may internally provide a passage for connecting the locking portion 180 and the power transmitting portion 170. A portion of the locking portion 130 may perform rotational movement within the second cylinder 167. [ A stopper structure for limiting the radius of rotation of the locking part 180 may be employed on the end surface of the second cylinder 167 which contacts the locking part 180. This will be described later.

In one embodiment, the first sealing cover 150 and the second sealing cover 160 may be bonded to each other by high-frequency welding. The high-frequency welding is a method of heating a bonding surface of a material by generating high-frequency waves, and the sealing surface is excellent in airtightness. Therefore, it is possible to effectively prevent the power transmitting portion 170 from being exposed to the heat insulating material.

Alternatively, the first sealing cover 150 and the second sealing cover 160 may be bonded to each other by various methods such as ultrasonic welding, hot air blowing, and the like.

In one embodiment, the coupling surfaces of the first and second sealing covers 150 and 160 may be formed with concave and convex structures corresponding to each other.

5, the first sealing cover 150 includes a first protrusion 155 and a first groove 156, and the second sealing cover 160 includes a second protrusion 165 and a second protrusion 155. As shown in FIG. 5, the first sealing cover 150 includes a first protrusion 155 and a first groove 156, Grooves 166. In one embodiment, The first protrusion 155 may engage the second groove 166 and the second protrusion 165 may engage the first groove 156. The airtightness between the first and second sealing covers 150 and 160 can be further increased through the uneven structure.

In one embodiment, the lengths of the first cylinder 157 and the second cylinder 167 can be variously selected depending on the thickness of the door 20.

The locking portion 180 receives the rotational force from the power transmitting portion 170 and can rotate about the second rotational axis X ₂ . The locking portion 180 can be rotated and accommodated in the locking groove 15 formed in the inner case 13, in which case the door 20 can be locked.

In the exemplary embodiment, the locking portion 180 includes a locking body 181 inserted into the second cylinder 167, a locking bar 183 extending from the locking body 181 toward the storage space, An inner cover 185 which forms the boundary between the locking bar 181 and the locking bar 183 and contacts the end face of the second cylinder 167 and a second engaging portion 187 connected to the driven gear 173 can do.

The second engagement portion 187 may be substantially the same as or similar to the first engagement portion 137 of the rotor 130. The second coupling portion 187 extends from the locking body 181 to the outer side of the door 20 and is coupled to the driven gear 173 of the power transmission portion 170. The second coupling portion 187 receives rotational force . In addition, the second engaging portion 187 may be a pair of hooks having a locking projection formed at a distal end thereof, and the locking protrusion may have a tapered shape.

The inner cover 185 is in contact with the second cylinder 167 and may have a disc shape protruding in the radial direction from the outer peripheral surface of the locking body 181. At this time, the diameter of the inner cover 185 may be larger than the diameter of the inner circumferential surface of the second cylinder 167. Thus, the locking bar 183 can be prevented from entering the inside of the second cylinder 167.

In one embodiment, the inner cover 185 may contact the inner surface of the door 20. That is, the locking body 181 passes through the inner surface of the door 20, and the inner cover 185 covers the gap formed between the locking body 181 and the inner surface of the door 20, Can be prevented from flowing out to the outside.

The locking body 181 extends outwardly of the door 20 from the inner cover 185 and can be received inside the second cylinder 167. The rotational force of the driven gear 173 can be transmitted to the locking body 181 through the second engaging portion 187. [ Therefore, when the driven gear 173 rotates, the locking body 181 can also rotate.

The locking bar 183 may protrude from the inner cover 185 toward the storage space. The locking bar 183 can rotate about the second rotation axis X ₂ together with the locking body 181. The locking bar 183 can be inserted into the locking groove 15 of the inner case 13 through rotation. When the locking bar 183 is inserted into the locking groove 15, the door 20 can be locked.

In one embodiment, the locking bar 183 may have an " a " shape. That is, the locking bar 183 may include a horizontal extension extending from the inner cover 185 in the direction of the second rotation axis X ₂ , and a vertical extension extending from the horizontal extension in a direction perpendicular to the ground . In this case, by inserting the vertical extension into the locking groove 15, the door 20 can be locked.

In one embodiment, the locking portion 180 can be limited in its range of rotation so that it can rotate only within a predetermined angular range.

6, the locking portion 180 is provided with a second rotation preventing projection 189 extending from the inner cover 185 toward the second cylinder 167, and the second cylinder 167 may have a second rotation preventing groove 168 extending in the circumferential direction by a predetermined angle. When the locking portion 180 is engaged with the second cylinder 167, the second rotation preventing projection 189 can be received in the second rotation preventing groove 168. Accordingly, the rotatable range of the locking portion 180 can be limited to the angular range in which the second rotation preventing groove 168 is formed.

For example, the second rotation preventing groove 168 may be formed in a range of 90 degrees in the circumferential direction of the end surface of the second cylinder 167. In this case, even if the user rotates the key 200, the locking portion 180 can rotate within a range of 90 degrees.

As described above, the locking device 100 according to the exemplary embodiments rotates the rotor 130 using the rotational force of the key 200 inserted into the outside of the door 20, The rotation can be transmitted to the locking portion 180 protruding to the inside of the door 20 through the power transmitting portion 170. The locking portion 180 rotates and is accommodated in the locking groove 15 provided in the inner case 13, so that the door 20 can be locked.

In this case, the key 200 and the rotor 130 is rotated about the first rotation axis (X _1), the locking unit 180 includes a first rotation axis (X ₁₎ and spaced from the second rotation axis (X ₂ ). The distance between the first rotation axis X ₁ and the second rotation axis X ₂ is a distance between the center axis of the driven gear 171 and the center axis of the driven gear 173. That is, by adjusting the distance between the spur gear 171 and the driven gear 173, the position where the key 200 is inserted (first rotation axis) and the position where the locking portion 180 protrudes to the inside of the door 20 The second rotation axis). Therefore, the position of the key insertion unit 110 can be set regardless of the position of the locking groove 15 formed in the inner case 13. [

The vertical position of the key insertion unit 110 can also be adjusted by disposing the first rotation axis X ₁ and the second rotation axis X ₂ at different heights from the ground. This can be achieved by disposing the power transmitting portion 170 at an angle in the door 20 (see FIG. 2).

Therefore, the present invention can set the position of the key insertion unit 110 regardless of the position of the locking groove 15 by adjusting the size and the installation inclination of the power transmission unit 170.

1: Refrigerator 10: Cabinet
11: outer case 13: inner case
15: locking groove 20: door
100: locking device 110: key insertion part
120: Locker 130: Rotor
140: elastic member 150: first sealing cover
160: second sealing cover 170: power transmitting portion
171: Main drive gear 173: Transfer gear
175: driven gear 180:
200: key X ₁ : first rotation axis
X ₂ : second rotation axis

Claims (17)

A cabinet forming a storage space for storing food and having a groove for locking on an inner wall thereof;
A door that is filled with a heat insulating material and is rotatably mounted on one side of the cabinet to selectively open and close the storage space; And
And a locking device installed on the door and locking the door by being engaged with the groove of the inner wall of the cabinet by rotation of a key,
The locking device comprises:
A key inserting portion which is exposed to an outer side surface of the door and into which the key is inserted;
A rotor disposed inside the door to be connected to the key inserting portion and rotated together with the key about a first rotational axis when the key is rotated;
A locking portion protruding toward the storage space through the inner side surface of the door and coupled to the groove provided in the cabinet by rotating around a second rotation axis spaced apart from the first rotation axis when the rotor rotates;
A power transmission unit provided inside the door to connect the rotor and the locking unit to each other, and to transmit the rotational force of the rotor to the locking unit; And
And a sealing part for receiving the power transmitting part and preventing the heat insulating material from penetrating into the power transmitting part,
The sealing portion
A first sealing cover covering one side of the power transmitting portion;
A first cylinder extending from the first sealing cover in the direction of the first rotation axis to be engaged with the key insertion portion and providing a passage therein for connecting the rotor to the power transmission portion;
A second sealing cover coupled to the first sealing cover to cover the other side of the power transmitting portion; And
And a second cylinder extending from the second sealing cover in the direction of the second rotation axis to be coupled to the locking portion and providing a passage for connecting the locking portion to the power transmission portion, . The method according to claim 1,
The key-
An outer cover coupled to an outer surface of the door and having a key insertion port; And
And a housing extending from the outer cover toward the inside of the door,
Wherein the rotor is slidable along the first rotation axis within the housing. 3. The method of claim 2,
And a first rotation preventing protrusion extending in the first rotation axis direction is provided on an inner circumferential surface of the housing,
And a first rotation preventing groove corresponding to the first rotation preventing projection is provided on an outer circumferential surface of the rotor. The method of claim 3,
And the first rotation preventing protrusion is detached from the first rotation preventing groove when the rotor slides inward of the door along the first rotation shaft. The locking device according to claim 4,
Further comprising an elastic member provided between the rotor and the power transmission unit to provide a restoring force for returning the rotor moved inward of the door to an original position. The locking device according to claim 2,
And a locker coupled to the outer circumferential surface of the housing to prevent the key insertion portion from being detached from the door. The power transmission unit according to claim 1,
A main gear connected to the rotor and rotating about the first rotation axis;
A driven gear connected to the locking portion and rotating about the second rotation axis; And
And a transmission gear disposed between the main gear and the driven gear for transmitting the rotational force of the main gear to the auxiliary synchronous gear. 8. The method of claim 7,
Wherein the main gear, the transmission gear, and the driven gear have the same size. The power transmission unit according to claim 1,
A pair of pulleys connected to the rotor and the locking portion, respectively; And
And a belt for transmitting rotational force between the pulleys. delete delete The method according to claim 1,
Wherein the first sealing cover and the second sealing cover are bonded to each other by high-frequency welding. The method according to claim 1,
Wherein a concave-convex structure corresponding to each other is formed on a mating surface of the first and second sealing covers. The method according to claim 1,
And a second rotation preventing groove extending in a circumferential direction by a predetermined angle is provided on an end surface of the second cylinder in contact with the locking portion,
And the locking portion is provided with a second rotation preventing protrusion inserted into the second rotation preventing groove. 15. The method of claim 14,
Wherein the second rotation preventing groove is formed in a range of 90 degrees around the second rotation axis. The method according to claim 1,
Wherein the locking portion further includes a locking bar extending in a direction substantially perpendicular to the second rotation axis in the storage space,
Wherein the locking bar is inserted into the groove provided in the cabinet by rotation of the locking portion. The method according to claim 1,
Wherein the first rotation axis and the second rotation axis are located at different heights from the ground.

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