KR200497611Y1 - Device adjusting position of bottom pivot of floor hinge - Google Patents

Abstract

The lower pivot position adjusting device for mounting the lower pivot of the floor hinge to the lower frame of the door is a fixed block fixed to the bottom of the horizontal bulkhead formed in the lower frame and has a central hole, and is movably mounted along the bottom of the horizontal bulkhead. A movable block with a screw hole located on a concentric axis with the central hole, an adjustment bolt that penetrates the fixed block and has one end screwed into the screw hole, and a friction end that penetrates the movable block up and down and is in close contact with the bottom of the horizontal bulkhead. The lower pivot is fixed to the moving block and can be adjusted in position with the moving block, and the friction end of the friction adjusting screw is in close contact with the bottom of the horizontal bulkhead without penetrating the horizontal bulkhead. It is possible to limit the movement of the movable block relative to the lower frame by adjusting the height of the protruding friction end between the horizontal bulkhead and the movable block.

Description

{DEVICE ADJUSTING POSITION OF BOTTOM PIVOT OF FLOOR HINGE}

The present invention relates to a lower pivot position adjustment device that can suppress shaking in the process of adjusting and maintaining the position of the lower pivot bracket of a floor hinge.

In forming a wall structure using tempered glass, a window frame is used, and the window frame can fix single or double glass. Since the use of a single piece of glass reduces the thermal and soundproofing performance compared to the case of using double glass, most windows installed in the entrances of government offices, schools, hospitals, and shopping malls recently use double glass such as fair glass. .

Additionally, floor hinges are mainly used to secure tempered glass doors. The floor hinge consists of a hydraulically operated lower hinge body, a lower pivot plate connecting the lower hinge body and the lower part of the door, an upper hinge bracket mounted on the upper part of the door in response to the lower hinge, and an upper frame of the window in response to the upper hinge bracket. Includes an upper pivot mounted on the.

Typically, floor hinges are sold as a set of the lower hinge body, lower pivot plate, upper hinge bracket, and upper pivot, and can be manufactured in unique ways depending on the manufacturer.

Korean Patent No. 10-2099160, Korean Public Utility Model No. 20-2011-0003044, and Korean Patent No. 10-1216978 disclose that the position of the lower pivot can be adjusted by being mounted on a lower frame. The above patent and utility model move the lower pivot using movable moving blocks, transfer elements, gap adjustment blocks, etc., but since a high load force is applied to these moving blocks through the lower pivot, they may be shaken or shaken during the actual installation process. The rattling occurs, causing problems that prevent smooth installation.

Therefore, there was a need to effectively limit the movement of the moving block relative to the lower frame.

The present invention provides a lower pivot position adjustment device that can limit the movement of a movable block within the lower frame without fixing the movable block to the lower frame.

The present invention provides a lower pivot position control device that limits the movement of a moving block within a lower frame but can adjust its friction or resistance.

According to an exemplary embodiment of the present invention for achieving the above-described objectives of the present invention, the lower pivot position adjusting device for mounting the lower pivot of the floor hinge to the lower frame of the door is installed on the bottom of the horizontal partition formed on the lower frame. A fixed block is fixed to and has a central hole, a movable block is movably mounted along the bottom of the horizontal bulkhead and has a screw hole located on a concentric axis with the central hole, and one end penetrates the fixed block and is screwed into the screw hole. It includes an adjustment bolt and a friction adjustment screw including a friction end that penetrates the movable block up and down and comes into close contact with the bottom of the horizontal bulkhead, and the lower pivot is fixed to the movable block so that the position can be adjusted together with the movable block.

In particular, in this embodiment, the friction end of the friction adjustment screw does not penetrate the horizontal bulkhead and remains in close contact with the bottom surface of the horizontal bulkhead, and the user or worker adjusts the friction adjustment screw to separate the friction end between the horizontal bulkhead and the moving block. The protruding height can be adjusted, and by adjusting the height, the movement of the movable block relative to the lower frame can be restricted.

Even after friction or resistance of the movable block is formed by the friction adjustment screw, the user or worker can adjust the position of the movable block using the adjustment bolt exposed on the fixed block side. However, compared to the prior art, the position can be adjusted stably without shaking or rattling of the moving block.

A rail portion may be further formed in the lower frame to guide the longitudinal movement of the movable block, and the movable block may slide along the lower frame while remaining coupled to the rail portion. The rail portion may be formed during the process of extrusion molding the core of the lower frame, and the movable block may be fixed not only by the adjustment bolt but also remain bound by the rail portion, thereby enabling stable slide movement.

However, since the horizontal bulkhead and rail cannot be designed to form an interference fit with the moving block, and must allow for a certain degree of smooth slide movement, shaking is inevitable. When the friction adjustment screw lifts the movable block from the horizontal bulkhead, it can restrict the movement of the movable block in the rail section, etc.

The friction adjustment screw hole through which the friction adjustment screw passes may be formed at an eccentric position away from the center of the movable block. The lever principle can be used by lifting the moving block in an eccentric position, and the range of clearance is larger than when formed in the center of the moving block, allowing for fine adjustment.

The movable block is formed longer than the lower pivot so that the friction control screw hole protrudes from the lower pivot outside of the lower pivot, that is, at a position farther from the hinge, and the friction control screw hole can be formed at that position.

The friction end may be formed so as not to impede the longitudinal movement of the movable block without passing through the horizontal partition. For this purpose, the friction end may be formed in a curved shape such as a hemisphere or round.

The positioning device of the present invention enables stable positioning without shaking or rattling the door during the process of installing the door and adjusting the position of the lower pivot.

The position control device of the present invention limits the movement of the moving block, but adjusts the friction or resistance to enable initial setting suitable for the operator's convenience.

Figure 1 is a diagram for explaining an example of use of a lower pivot position adjusting device according to an embodiment of the present invention.
Figure 2 is a diagram for explaining a cross section of a lower pivot position adjusting device and a lower frame according to an embodiment of the present invention.
Figure 3 is a diagram for explaining the coupling relationship of the lower pivot position adjusting device of Figure 2.
FIG. 4 is a diagram for explaining the operating mechanism of the lower pivot position adjusting device of FIG. 2.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings, but the present invention is not limited or limited by the embodiments. For reference, in this description, the same numbers refer to substantially the same elements, and under the above rules, content written in other drawings may be cited and explained, and content deemed obvious to those skilled in the art or repeated may be omitted.

Figure 1 is a diagram for explaining an example of use of a lower pivot position adjusting device according to an embodiment of the present invention, and Figure 2 is a diagram illustrating a cross section of a lower pivot position adjusting device and a lower frame according to an embodiment of the present invention. FIG. 3 is a diagram for explaining the coupling relationship of the lower pivot position adjusting device of FIG. 2, and FIG. 4 is a diagram for explaining the operating mechanism of the lower pivot position adjusting device of FIG. 2.

Referring to Figures 1 to 4, the position adjusting device 100 according to this embodiment may be integrally coupled with the lower pivot 30. The lower pivot 30 is a part of the floor hinge that is coupled to the lower hinge body 40 buried in the floor, and is located at the lower part of the door 10.

The door 10 is coupled to the lower hinge body 40 around the hinge axis by the lower pivot 30. In general, a square-shaped hinge axis protrudes from the lower hinge body 40, and the lower pivot 30 has a A square-shaped hole that can be coupled to a square-shaped hinge shaft may be provided. A plurality of screw holes that can be coupled to the door may be formed in the lower pivot 30.

The position adjusting device 100 includes a fixed block 110, a moving block 120, an adjusting bolt 130, and a friction adjusting screw 140.

The fixed block 110 is fixed to the bottom of the horizontal bulkhead 22 within the lower frame 20 of the door 10, and is centrally located in response to the longitudinal direction of the lower frame 20 or the moving direction of the movable block 120. A hole 112 may be formed.

The movable block 120 is movably mounted along the bottom of the horizontal bulkhead 22 in the lower frame 20 in response to the fixed block 110, and is connected to the lower pivot 30 using bolts 34, etc. Can be combined as one. Additionally, a screw hole 122 located on a concentric axis with the central hole 112 of the fixed block 110 may be formed in the moving block 120.

The fixed block 110 and the moving block 120 are aluminum extrusions and can be used by cutting the same extrusion to the required length. However, so that the adjustment bolt 130 can freely rotate within the fixing block 110, the central hole 112 may be formed larger through processing such as boring, and may be formed to be larger through processing such as boring, corresponding to the thread of the adjustment bolt 130. The movable block 120 may additionally undergo internal thread processing on the screw hole 122.

The fixing block 110 may be formed with a fixing screw hole for fixing a screw to the horizontal partition 22 in a direction perpendicular to the central hole 112, and a fastening screw 32 penetrating the horizontal partition 22. It can be fixed to the horizontal partition wall 22 through.

A pivot screw hole may be further formed in the movable block 120 for coupling with the lower pivot 30 and may be fixed by a bolt 34, but the pivot screw hole does not need to penetrate the movable block 120. , the bolt 34 also does not pass through the moving block 120.

Referring to FIG. 4, the adjustment bolt 130 may include a screw rod passing through two blocks, a bolt head 132, an intermediate locking portion, and a washer.

The screw rod is screwed to the screw hole 122 of the moving block 120 and can freely rotate in the central hole 112 of the fixed block 110. In this embodiment, screw threads are formed throughout the screw rod, and the central hole 112 is formed to have a relatively large size compared to the screw rod. However, in some cases, the screw rod inserted into the central hole may not have a screw thread, and it is also possible to form a screw thread only on one end of the screw rod coupled to the moving block 120.

The bolt head 132 is integrally coupled to the other end of the screw rod on the outside of the fixing block 110, and in this embodiment, a cross-shaped groove is formed in the cross screwdriver, but a flat screwdriver or hex wrench is used in response to other fastening tools. It may be formed in a shape corresponding to the back.

The middle locking portion may be located at a distance away from the bolt head 132 corresponding to the width of the fixing block 110 and integrally fixed to the screw rod. As in this embodiment, a nut can be used as an intermediate locking part, and the nut can be fixed to the screw rod by welding or punching. In this embodiment, washers are provided on the bolt head 132 and the middle locking portion to reduce friction between the fixing block 110 and the bolt head 132 and the fixing block 110 and the middle locking portion.

In the state where the floor hinge is installed, the lower pivot 30 is fixed so as to be integrated with the position adjusting device 100. When the installer rotates the bolt head 132, since one end of the screw rod is connected to the screw hole 122 of the movable block 120 by a screw connection, the movable block 120 moves forward or forwards according to the rotation of the screw rod. It is possible to move backwards, and through this process, the installer can finely adjust the distance between the moving block 120 and the fixed block 110.

The moving block 120 is formed to be longer than the lower pivot 30, and the friction adjustment screw hole 126 of the moving block 120 may be exposed outside the lower pivot 30, that is, at a position farther away from the hinge. there is. The friction adjustment screw 140 may be mounted through the friction adjustment screw hole 126.

The friction adjustment screw 140 is formed to penetrate the moving block 120 up and down, and may include a friction end 142 in close contact with the bottom of the horizontal partition 22. The friction end 142 can be maintained in close contact with the bottom surface of the horizontal partition 22 without penetrating the horizontal partition 22. To this end, the friction end 142 may be formed in a hemispherical, round shape, etc.

The operator can adjust the height at which the friction end 142 protrudes between the horizontal bulkhead 22 and the moving block 120 by adjusting the friction adjustment screw 140, and adjusting the height to adjust the height relative to the lower frame 20. The movement of the moving block 120 may be restricted.

With the fixed block 110 fixed to the lower frame 20, the operator can easily adjust the positions of the moving block 120 and the lower pivot 30 by a simple operation of turning the bolt head 132. The entire door may shake or rattle due to clearance between the block 120 and the lower frame 20.

However, in this embodiment, the friction adjustment screw 140 can increase the friction or resistance between the horizontal partition 22 and the moving block 120, and the lower frame ( 20), the movement of the moving block 120 may be restricted.

Even after the friction or resistance of the moving block 120 is increased by the friction adjustment screw 140, the user or worker turns the bolt head 132 of the adjustment bolt 130 exposed on the fixed block 110 side to move the moving block ( 120) can be adjusted without shaking.

A rail portion 24 may be further formed in the lower frame 20 to guide the longitudinal movement of the movable block 120, and the movable block 120 remains coupled to the rail portion 24 and maintains the lower frame 20. It is possible to slide and move along the frame 20.

The rail portion 24 may be formed during the process of extrusion molding the core of the lower frame 20, and the movable block 120 is not only fixed by the adjustment bolt 130 but also bound by the rail portion 24. The status quo can be maintained.

In particular, while adjusting the gap between the horizontal bulkhead 22 and the moving block 120 with the friction adjustment screw 140, the gap between the rail part 24 and the moving block 120 can also be adjusted, resulting in a more stable coupling relationship. By forming, the moving block 120 can slide more stably.

For reference, the horizontal bulkhead 22 and the rail portion 24 cannot be designed to form an interference fit with the moving block 120, and since smooth slide movement must be allowed without the friction adjustment screw 140, shaking may occur. There is no choice but to do so. However, when the friction adjustment screw 140 lifts the movable block 120 from the horizontal partition 22, the rail portion 24 may also restrict the movement of the movable block 120.

Referring to FIG. 3, the friction adjustment screw hole 126 through which the friction adjustment screw 140 passes may be formed at an eccentric position away from the center of the moving block 120. The lever principle can be used by lifting the movable block 120 in an eccentric position, and the range of clearance is larger than when formed in the center of the movable block 120, allowing for fine adjustment.

A plurality of protrusions formed in the longitudinal direction may be provided on the surface of the horizontal partition 22 that contacts the movable block 120. Due to the protrusion, the movable block 120 and the horizontal bulkhead 22 can maintain line contact, and the movable block 120 can be moved with a small friction force even under a high load. This may also form a protrusion formed in the longitudinal direction corresponding to the friction end 142.

As described above, the present invention has been described with reference to preferred embodiments, but those skilled in the art can make various modifications and changes to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You will understand that you can do it.

10: door 20: lower frame
30: lower pivot 100: position adjusting device
110: fixed block 120: moving block
130: adjustment bolt 140: friction adjustment screw

Claims (5)

In the lower pivot position adjustment device for mounting the lower pivot of the floor hinge to the lower frame of the door,
a fixing block fixed to the bottom of the horizontal partition formed in the lower frame and having a central hole;
a movable block movably mounted along the bottom of the horizontal bulkhead and having a screw hole located concentric with the central hole;
an adjustment bolt penetrating the fixing block and having one end screwed to the screw hole; and
It includes a friction adjustment screw that penetrates the moving block up and down and includes a friction end that is in close contact with the bottom surface of the horizontal partition,
The lower pivot is fixed to the moving block and can be adjusted in position together with the moving block,
The friction end of the friction adjustment screw does not penetrate the horizontal bulkhead and remains in close contact with the bottom surface of the horizontal bulkhead, and the friction end protrudes between the horizontal bulkhead and the moving block to adjust the height of the lower portion. Lower pivot positioning device, characterized in that limiting movement of the moving block relative to the frame.
According to paragraph 1,
A rail portion corresponding to the moving block is formed in the lower frame,
The moving block is a lower pivot position adjusting device, characterized in that the moving block slides along the longitudinal direction of the lower frame along the rail portion.
According to paragraph 1,
A lower pivot position adjusting device, characterized in that the friction adjustment screw hole through which the friction adjustment screw passes is formed at an eccentric position away from the center of the moving block.
According to paragraph 3,
The moving block is formed to be longer than the lower pivot, and the friction adjustment screw hole is located outside the lower pivot.
According to paragraph 1,
A lower pivot position adjusting device, wherein the friction end is formed in a curved shape.

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