KR102163864B1 - Glass door for cold storage - Google Patents

Abstract

Disclosed is a glass door for a refrigerator, in which an assembly structure between a hinge of a door and a frame is improved to increase assembly and to easily perform accurate fasting. The glass door for a refrigerator is of a hinged type and includes a frame portion, a glass portion rotatably connected to the frame portion, and a hinge portion rotatably connecting the glass portion to the frame portion. An auto hinge portion for elastically restoring the glass portion in a rotational direction with respect to the frame portion is provided in the hinge portion. The hinge portion is composed of a first hinge portion coupled to the glass portion and a second hinge portion rotatable with respect to the first hinge portion and coupled to the frame portion, and a seating step portion for seating and fixing the second hinge portion is formed on the frame portion.

Description

Glass door for refrigerator {GLASS DOOR FOR COLD STORAGE}

The present invention relates to a glass door for a refrigerator, and more particularly, to a glass door for a refrigerator made of transparent glass so that the inside of the refrigerator can be viewed from the outside by being installed on a wall or an entrance of a refrigerated warehouse.

In general, a glass door for a refrigerator is coupled with glass to a door frame, and a packing means for improving refrigeration efficiency and maintaining a sealed state is installed on the door frame by airtight contact with the door frame.

1 is a front view showing a conventional glass door for a refrigerator. As shown in FIG. 1, a conventional refrigerator door 1 is composed of a rectangular frame 2 and a glass 3 coupled to the frame 2. In this case, in order to prevent condensation on the surface of the glass (3), a conductive transparent resistor is coated on the surface of the glass (3), a busbar is printed between both ends, and wires are welded to both ends of the busbar. Thus, by applying power from the outside, it is possible to forcibly generate heat on the glass surface.

In addition, the frame 2 is implemented as a rail structure having a predetermined thickness t, and each line segment is formed in the form of a long rod having a cross section of a "c" shape, and the overall shape is completed in a square shape. A hinge 5 is coupled to one side of the frame 2 and is installed to be opened and closed in a rotational manner.

The glass 3 is made of a transparent material so that the inside of the door can be visually confirmed, and may be made of single or multiple pieces, and is inserted into the concave portion of the “C”-shaped frame 2 and fixed to the frame 2. In addition, a handle 4 for gripping when entering or leaving the refrigerator door 1 is fastened. In this case, the handle 4 is attached to the frame 2 or glass 3 via a bond or the like.

A glass door for a refrigerator having a conventional opening and closing structure is difficult to assemble the glass 3 to the frame 2, and an elastic member that elastically restores the door in the closing direction when the hinge 5 is connected. There is a problem in that the hinge 5 is not fixed when assembling the hinge 5 to the frame 2 by this.

In order to solve such a conventional problem, the present invention provides a glass door for a refrigerator that improves the assembly structure by improving the assembly structure between the hinge of the door and the frame, and can easily perform accurate fastening.

A glass door for a refrigerator according to the present invention is a glass door for a refrigerator of a casement type including a frame part, a glass part rotatably connected to the frame part, and a hinge part rotatably connected to the frame part, The hinge portion includes an auto hinge portion for elastically restoring the glass portion in a rotational direction with respect to the frame portion, and the hinge portion is rotatable with respect to the first hinge portion and the first hinge portion coupled to the glass portion, and coupled to the frame portion It is composed of a second hinge portion, and a seating step portion for seating and fixing the second hinge portion to the frame portion is formed.

In the above, the auto hinge unit is configured to have an opening angle of 90°, the elastic restoring force is released at 90° or more, and the frame unit has a locking jaw that prevents the second hinge unit seated on the seating step from being separated in the rotation direction Is formed.

In the above, the range of the elastic restoring force of the auto hinge portion has a rotation angle range of 0° to 100°.

In the above, the hinge part is provided at an upper and lower part of one side of the glass part, and the upper hinge part has a pivot shaft protruding upward, and the lower hinge assembly consisting of the first hinge part, the second hinge part and the auto hinge part is It is provided in the lower part and connects the pivot shaft of the upper hinge part to the frame part by lifting the glass part, and the second hinge part of the lower hinge assembly is seated in the seating step and fastened to the frame part.

In the above, a handle is provided on the other side of the glass part opposite to the side where the hinge part is formed, and the fitting groove of the wedge cross section extends in the transverse direction of the frame part on the wall surface of the frame part, and has a wedge protrusion inserted into the fitting groove. A material buffer member is provided on the other side of the frame portion corresponding to the handle portion.

The glass door for a refrigerator according to the present invention is a very useful invention that improves the assembly structure between the hinge of the door and the frame, thereby improving the assembling property and easily performing accurate fastening.

1 is a front view showing a glass door for a conventional refrigerator,
2 is a front view showing a glass door for a refrigerator according to an embodiment of the present invention,
3 is a plan view of a glass door for a refrigerator according to an embodiment of the present invention,
4 is an enlarged view of “A” in FIG. 2,
Figure 5 is a side cross-sectional view of Figure 4,
6 is an enlarged view of "B" of FIG. 3,
7 is a diagram illustrating a frame part of a glass door for a refrigerator according to an embodiment of the present invention,
8 and 9 are schematic diagrams for explaining the operation of the lower hinge assembly of the glass door for a refrigerator according to an embodiment of the present invention.

Hereinafter, the technical configuration of a glass door for a refrigerator will be described in detail according to the accompanying drawings.

2 is a front view showing a glass door for a refrigerator according to an embodiment of the present invention, FIG. 3 is a plan view of a glass door for a refrigerator according to an embodiment of the present invention, and FIG. 4 is a reference to “A” in FIG. 5 is a side cross-sectional view of FIG. 4, FIG. 6 is an enlarged view of "B" of FIG. 3, and FIG. 7 is a frame part of a glass door for a refrigerator according to an embodiment of the present invention. 8 and 9 are schematic diagrams for explaining an operation of a lower hinge assembly of a glass door for a refrigerator according to an embodiment of the present invention.

In the following description, the horizontal direction in FIG. 2 is the horizontal direction, and the vertical direction is the vertical direction. In addition, the left side of FIG. 5 is the direction outside the high-rise (outdoor), and the right side is the interior (indoor) side.

2 to 9, the glass door for a refrigerator according to an embodiment of the present invention may be installed and used in a refrigerated warehouse, a showcase used in various stores, and is made so that the inside can be seen from the outside. 110), and a glass portion 120 and a hinge portion 130.

The glass door for a refrigerator is made of an opening type. That is, the frame unit 120 is rotatably connected to the frame unit 110, and the hinge unit 130 rotatably connects the glass unit 120 to the frame unit 110.

The glass door for a refrigerator includes an auto hinge part 140. The auto hinge unit 140 is provided on the hinge unit 130 and functions to elastically restore the glass unit 120 to the frame unit 110 in the rotational direction.

The frame part 110 has a substantially rectangular shape on the front view of the door and has a predetermined thickness. The glass part 120 is made of a transparent material so that the inside of the door can be visually confirmed, and is made of one or multiple. The glass part 120 may be provided with a separate heating means to prevent dew formation on the surface.

The hinge part 130 is provided at the upper and lower sides of the glass part 120, respectively. That is, the hinge part 130 is provided on one of both sides in the transverse direction of the glass part 120, and is provided on both sides in the longitudinal direction (up-down direction).

The hinge part 130 located on the upper part of the glass part 120 has a pivot axis protruding upward. In addition, the hinge portion 130 located under the glass portion 120 constitutes a lower hinge assembly. The lower hinge assembly includes a first hinge part 131, a second hinge part 132, and an auto hinge part 140.

That is, the lower hinge portion 130 is composed of a first hinge portion 131 and a second hinge portion 132. The first hinge portion 131 is coupled to the glass portion 120, and a bolt fastening hole 133 penetrating the vertical direction is formed. The first hinge part 131 is coupled to the glass part 120 through bolt fastening.

The second hinge part 132 is rotatable with respect to the first hinge part 131 and is coupled to the frame part 110. A bolt fastening hole 134 penetrating the vertical direction is formed in the second hinge part 132. The second hinge portion 132 is coupled to the frame portion 110 through bolt fastening. In addition, the shaft 135 of the auto hinge part 140 is inserted into the central axis of the first hinge part 131 and the second hinge part 132.

The frame portion 110 is provided with a seating step portion 116. The seating step portion 116 is for seating and fixing the second hinge portion 132, and is formed under the frame portion 110. That is, the seating step portion 116 is formed on the upper surface of the lower frame portion 110 which is a position corresponding to the hinge portion 130 formed under the glass portion 120.

Referring to FIG. 9, the auto hinge unit 140 has an opening angle of 90° and is configured to release the elastic restoring force at 90° or more. More specifically, the range of the elastic restoring force of the auto hinge unit 140 has a rotation angle range of 0° to 100°. The auto hinge unit 140 is a device that provides an elastic force so that the glass unit 120 is automatically closed with respect to the frame unit 110, and is configured to control the closing speed.

In addition, the auto hinge unit 140 is smoothly closed by reducing the closing speed from a predetermined interval before the glass unit 120 is completely closed with respect to the frame unit 110 until it is completely closed. Accordingly, the door is rapidly closed until a certain interval (for example, 10 mm) for the glass portion 120 to be completely closed with respect to the frame portion 110, and then slowly closed in a section less than 10 mm to be closed smoothly.

Through the auto hinge unit 140, the glass unit 120 can control the closing speed of the frame unit 110 and may be implemented to automatically close within a certain angle. For example, when the elastic restoring force range of the auto hinge part 140 has a rotation angle range of 0° to 100°, the range may be set to -7° to 90°, and the spring restoring force may be set to break at 3°. In this case, the restoring force range may be appropriately changed according to the design of the auto hinge unit.

If the maximum opening angle of the door is 90°, the elastic restoring force is destroyed when the auto hinge unit 140 is rotated by 93° or more, so that the door can no longer return to the closed direction and is in an open state.

In this way, when the maximum opening angle of the auto hinge unit 140 is 90°, the rotation range is set to be greater than that, so when the second hinge unit 132 is bolted to the frame unit 110, the second hinge unit ( 132 is not fixed to the frame unit 110 and deviates in the direction of rotation of the door. Therefore, in order to fix the second hinge part 132 to the frame part 110, the operator inevitably attaches the second hinge part 132 with a hand (or using another tool) to assemble the frame part 110. The bolt is assembled into the bolt fastening hole 134 in a fixed position.

The frame part 110 is provided with a locking protrusion 115 that prevents the second hinge part 132 seated on the seating step 116 from being separated in the rotation direction. In this way, the assembly of the door may be improved through the configuration of the seating step 116 and the locking projection 115.

That is, looking at the process of assembling the glass part 120 to the frame part 110, first, the glass part 120 is lifted and the pivot axis of the upper hinge part 130 is connected to the frame part 110. Thereafter, the second hinge portion 132 of the lower hinge assembly is seated on the seating step portion 116 and fastened to the frame portion 110. In the process of fastening the second hinge part 132 to the frame part 110, as described above, the second hinge part 132 is attached to the frame part 110 by the seating step 116 and the locking protrusion 115. It is possible to perform stable bolting work in the state of being supported and fixed.

On the other hand, the handle 121 is provided on the other side of the glass portion 120 that is the opposite side to the side on which the hinge portion 130 is formed. In addition, a fitting groove 118 having a wedge cross section is formed extending in the transverse direction of the frame portion 110 on the wall surface of the frame portion 110. In addition, a buffer member 119 made of a soft material having a wedge protrusion 114 inserted into the fitting groove 118 is provided on the other side of the frame portion 110 corresponding to the handle portion 121.

A display unit 117 for indicating a correct position when bolts are fastened may be formed at the mounting step 116 of the frame unit 110. Through the configuration of the buffer member 119, when the glass portion 120 is closed, the rear surface of the glass portion 120 contacts the buffer member 119 to absorb the shock. In this case, as the buffer member 119 is not formed over the entire transverse direction of the frame unit 110 and is partially formed only at the corresponding portion of the handle unit 121, the manufacturing cost can be lowered.

In addition, it is preferable to form a gap between the glass portion 120 and the frame portion 110 to 2mm to 5mm. Through this configuration, it is possible that the above-described buffer member 119 is formed only in part of the frame part 110, and the gasket used to seal between the existing glass part 120 and the frame part 110 Can be deleted. When the gap between the glass portion 120 and the frame portion 110 is formed to be 2mm to 5mm, condensation that may occur in the glass portion 120 can be effectively prevented.

Until now, the glass door for a refrigerator according to the present invention has been described with reference to the embodiment shown in the drawings, but this is only exemplary, and anyone of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection should be determined by the technical spirit of the appended claims.

110: frame part 114: wedge protrusion
115: locking jaw 116: seating step
117: display portion 118: fitting groove
119: buffer member 120: glass portion
121: handle 130: hinge
131: first hinge portion 132: second hinge portion
135: axis 140: auto hinge

Claims (6)

Includes a frame part 110, a glass part 120 rotatably connected to the frame part 110, and a hinge part 130 rotatably connecting the glass part 120 to the frame part 110 In the casement type refrigerator glass door,
The hinge part 130 includes an auto hinge part 140 for elastically restoring the glass part 120 in a rotational direction with respect to the frame part 110,
The hinge portion 130 is a first hinge portion 131 coupled to the glass portion 120 and a second hinge portion rotatable with respect to the first hinge portion 131 and coupled to the frame portion 110 ( 132),
A glass door for a refrigerator having a seating step 116 for seating and fixing the second hinge portion 132 on the frame portion 110. The method of claim 1,
The auto hinge part 140 is configured to have an opening angle of 90°, and the elastic restoring force is released at 90° or more,
A glass door for a refrigerator, characterized in that the frame portion 110 has a locking projection 115 that prevents the second hinge portion 132 seated on the seating step 116 from being separated in the rotational direction. The method of claim 2,
A glass door for a refrigerator, characterized in that the auto hinge part 140 has a rotation angle range of 0° to 100°. The method of claim 1,
The hinge part 130 is provided at the upper and lower sides of the glass part 120, respectively,
The upper hinge portion 130 is formed with a pivot shaft protruding upward,
The lower hinge assembly consisting of the first hinge part 131, the second hinge part 132 and the auto hinge part 140 is provided under the glass part 120,
The frame part ( 110) for a refrigerator glass door. The method of claim 4,
The handle 121 is provided on the other side of the glass portion 120 that is the opposite side of the side where the hinge portion 130 is formed,
The fitting groove 118 of the wedge cross section is formed extending in the transverse direction of the frame unit 110 on the wall surface of the frame unit 110
A glass door for a refrigerator in which a soft material buffer member 119 having a wedge protrusion 114 inserted into the fitting groove 118 is provided on the other side of the frame unit 110 corresponding to the handle unit 121. The method of claim 1,
The auto hinge unit 140 is a refrigerator glass, characterized in that the closing speed can be adjusted when the glass unit 120 is closed, and the closing speed is reduced from a certain interval before being completely closed until it is completely closed, and is driven to close smoothly door.

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