KR100706173B1 - A Door Hinge - Google Patents

Abstract

The present invention can simply adjust the strength of the restoring force of the compression spring by changing the initial compression degree of the compression spring simply by turning the power adjustment bolt by inserting a wrench, the door can adjust the opening and closing speed of the door by adjusting the flow of oil It's about the hinge.

Hinge, oil, resilience, spring

Description

Initial compression degree adjustment structure of door hinge compression spring {A Door Hinge}

1 is a schematic cross-sectional view of one embodiment of the present invention.

2 is an exploded coupling diagram of an embodiment of the present invention.

3A to 3C are partial detailed views of one embodiment of the present invention.

4 and 5 are partial details of one embodiment of the present invention.

<Description of Major Symbols in Drawing>

1: Mounting plate 3: Hollow Shanghai copper member

15: compression spring 19: power adjustment bolt 27: hollow turning member

28: hollow stopper 29: hollow spring compression member

30: housing 40: locking jaw

41: bolt portion 42: cutting surface

43: protruding jaw 44: turning hole

The present invention relates to a door hinge. More specifically, the present invention relates to a door hinge that automatically closes an open door in a sliding door.

In the conventional door hinge, the hinge shaft fixed to the door frame and the door hinge coupled to the door are coupled by the torsion spring, and when the door is opened, the torsion spring is twisted by the rotational movement. To close. However, the torsion spring has a problem that increases the manufacturing cost of the door hinge because the unit cost is higher than the general compression spring.

The present invention, by using the restoring force of the compression spring by converting the rotational movement on the rotating shaft to linear movement when the door is opened and closed, the restoring force of the compression spring in the door hinge configured to automatically close the door without using expensive torsion springs Its purpose is to be able to easily adjust the power of.

According to the present invention, when the door is opened, the mounting plate 1 coupled to the door rotates and the compression spring 15 in the door hinge housing 30 is compressed to rotate the mounting plate in the opposite direction by the restoring force of the compressed compression spring. The initial compression degree adjustment structure of the door hinge to automatically close the door, the power adjustment bolt 19 is penetrated through the hollow stopper 28 coupled to one end of the housing 30, one end of the power adjustment bolt inside the hollow stopper The locking jaw 40 is formed on one side of the outer circumferential surface of the power adjusting bolt so that the locking jaw is caught by the hollow stopper to prevent the power adjusting bolt from being separated and the bolt of the power adjusting bolt inserted into the hollow stopper. A spiral rib is formed on at least a portion of the outer circumferential surface of the portion 41, and the spiral rib is formed on the inner circumferential surface of the hollow spring compression member 29 in contact with the compression spring. The line ribs are helically coupled, the outer circumferential side of the hollow spring compression member is cut to form a cutting surface 42, and a protruding jaw for preventing the spring compression member from rotating together with the power adjustment bolt on one side of the housing inner circumferential surface. (43) is formed, when the power adjustment bolt is rotated while the hollow spring compression member 29 is caught by the protruding jaw 43 to prevent rotation, the spiral rib of the outer circumferential surface of the power adjustment bolt moves up and down By the initial compression degree of the compression spring 15 is adjusted to adjust the magnitude of the restoring force applied to the door relates to the initial compression degree adjustment structure of the door hinge compression spring, characterized in that.

Here, one end of the power adjustment bolt is projected to the outside of the hollow stopper, it is preferable that the hollow turning member 27, which is formed with at least one turning hole 44 on the outer peripheral surface is fixedly coupled.

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

1 is a schematic cross-sectional view of one embodiment of the door hinge of the present invention, Figure 2 is an exploded coupling. The door hinge of the present invention is composed of a mounting plate 1 coupled to the door and rotating together when the door is opened and closed, a door hinge housing 30 coupled to the mounting plate and axially rotating, and various parts formed inside the housing. It is buried in the bottom is fixed and is operated in a structure coupled to the hinge shaft coupled to the housing.

The housing is in the form of a hollow tube. The hollow stopper 28 is coupled to the upper side of the housing, and the compression spring 15 is placed below the hollow stopper. On the lower side of the compression spring is placed a spring support member 13 for applying a force to the compression spring or to receive a force from the compression spring, and the lower side of the spring support member 13 with a steel ball 12 between the hollow up and down moving member ( 3) is placed, the check valve 9 is coupled to the inside of the upper and lower hollow member (3). The first oil passage 46 and the second oil passage 47 are formed in the check valve, and the steel balls 11 are inserted into the second oil passage. The steel ball 12 between the lower side of the spring support member 13 and the upper side of the hollow up and down member 3 acts like a bearing to prevent wear during rotation. The check valve 9 is placed on the hollow shankdong member 3 and the hollow up and down moving member has a spiral rib 50 formed on at least a portion of the outer circumferential surface thereof and a gear portion 52 formed in the longitudinal direction on the inner circumferential surface (FIG. 3C). Shown in the figure). Figure 3a is a plan view of an embodiment of a hollow shankdong member, Figure 3b is a view showing a state in which the hinge shaft is fitted to the hollow shankdong member and Figure 3c is a partial cutaway view. As shown in the figure, the gear portion may be formed of a plurality of longitudinally formed grooves formed in a sawtooth shape. The spiral rib 50 formed on the outer circumferential surface may be constituted by four rows of screws as shown in FIG. 3C.

The hollow fixing tube 4 in which the spiral rib 54 is formed on the inner circumferential surface is fixedly coupled to the housing 30. The hollow fixing tube 4 and the housing are fixedly coupled with a pin or the like. The spiral rib 54 formed on the inner circumferential surface of the hollow fixing tube is formed to have a structure that meshes with the spiral rib 50 formed on the outer circumferential surface of the hollow shank moving member.

The housing 30 has a mounting plate 1 coupled to an opposite side to which the hollow stopper 28 is coupled. As shown in FIG. 2, a screw 56 and a mounting plate 1 formed on one side of the inner circumferential surface of the housing 30 are provided. Screws 58 formed on one side of the can be simply coupled by screwing. It is preferable to adjust the opening and closing speed of the door by filling the inside of the housing, in which case the O-rings 5, 10 and 20 to prevent oil leakage and steel balls 8 and 12 to reduce friction during rotation. Auxiliary coupling parts, etc. are required, but these can be variously modified and can be used or omitted as necessary.

The gear part 60 is formed in the upper outer peripheral surface of the hinge shaft 2 fixed to the bottom surface of the part in which the door is installed. This gear portion meshes with the gear portion 52 formed on the inner circumferential surface of the hollow shank moving member 3. Figure 3c illustrates this. The gear part 52 of the inner circumferential surface of the hollow shank moving member 3 is engaged with the gear part 60 of the hinge shaft 2 which is fixed so that the hollow shank moving member cannot be rotated. Only linear motion is possible.

The movement of the housing, the hollow fixing tube, the hollow up and down member when the door is opened and closed will be briefly described. When the door is opened, the mounting plate 1 rotates together with the door, and the housing 30 coupled to the mounting plate also rotates together. Then, the hollow fixing tube 4 fixedly coupled to the housing also rotates together. Then, since the spiral rib 54 of the inner circumferential surface of the hollow fixing tube and the spiral rib 50 formed on the outer circumferential surface of the hollow shandong copper member 3 are engaged, when the hollow anchor tube is rotated, the hollow shandong member is rotated as the spiral rib of the hollow anchor tube is rotated. As you climb the ribs, you will have a straight line upward. This is because the hollow shank-dong member 3 is coupled to the gear part of the hinge shaft outer circumferential surface fixed to the bottom by the gear part of the inner circumferential surface, and thus cannot be rotated. As the hollow shandong moving member moves upward, the compression spring 15 is pressed upward, thereby compressing the compression spring. In other words, when the mounting plate 1 rotates as the door is opened, the housing 30 coupled thereto rotates, and the hollow fixed tube 4 coupled to the housing rotates, and the hollow shank member engaged with the spiral rib of the hollow fixed tube moves upward. By this, the compression spring 15 is compressed.

On the other hand, if left still after the door is opened by the compressed compression spring (15) the hollow shankdong member (3) is forced downward and the hollow shankdong member is forced to move downward. Then, since the spiral rib 50 of the outer peripheral surface of the hollow shankdong member and the spiral rib 54 of the hollow fixed tube are engaged, the hollow fixed tube which is not movable up and down is rotated. Hollow fixing tube (4) is coupled to the housing so that it is impossible to move up and down will be rotated when the hollow shankdong moving member moves downward. Naturally, when the hollow fixing tube rotates, the housing 30 fixedly coupled thereto rotates, and the mounting plate 1 fixedly coupled to the housing rotates together, thereby automatically closing the door.

Now, the configuration of the present invention for adjusting the power of the compression spring and the configuration of the present invention for adjusting the opening and closing speed of the door through the oil flow.

As shown in FIGS. 1 to 3, the power adjusting bolt 19 is inserted into the hollow plug 28 coupled to the upper side of the housing. The O-ring 20 is coupled between the outer circumferential surface of the power adjusting bolt and the inner circumferential surface of the hollow stopper to prevent oil from leaking outside the hollow stopper. The hollow stopper may be coupled to the housing by screwing the screw formed on the outer circumferential surface of the hollow stopper to the screw formed on the inner circumferential surface of the uppermost side of the housing as shown. A locking jaw 40 is formed at one side of the outer circumferential surface of the power adjusting bolt 19 to prevent the power adjusting bolt from being separated by being caught at the bottom of the hollow stopper. The power adjusting bolt is formed of a thick head and a thin bolt portion 41. That is, a spiral rib 62 is formed on at least a portion of the outer circumferential surface of the portion inserted into the hollow stopper to form a bolt portion. The hollow spring compression member 29 is formed on the inner circumferential surface of the spiral rib 45 coupled to the spiral rib 62 so as to be engaged with each other between the spiral ribs. On the other hand, the upper side of the power adjustment bolt is coupled to the hollow turning member 27 formed with at least one turning hole 44 on the outer peripheral surface. The hollow turning member may be firmly fixed to the power adjusting bolt by a pin (not shown) or the like. Preferably, a screw is formed on the upper side of the power adjusting bolt protruding outside the hollow stopper, that is, the head of the head, and a screw is formed on the inner circumferential surface of the hollow turning member 27 to be firmly coupled to each other by screwing.

By such a configuration, the power adjustment bolt can be easily forcibly rotated by inserting a wrench or the like into the turning hole 44 on the outer circumferential surface of the hollow turning member. When the power adjustment bolt rotates, the hollow spring compression member 29 coupled to the spiral rib of the outer circumferential surface of the bolt portion of the power adjustment bolt is rotated together with the power adjustment bolt or move up and down. However, one side of the outer circumference of the hollow spring compression member is cut to form a cutting surface 42, and a protruding jaw 43 is formed on one side of the inner circumference of the housing to prevent the spring compression member from rotating together with the power adjusting bolt. The hollow spring compression member is prevented from rotating due to the protruding jaw. Therefore, when the power adjustment bolt is rotated, the hollow spring compression member 29 moves up and down on the helix rib of the outer circumferential surface of the power adjustment bolt. By the projection chin 43, the hollow spring compression member is prevented from being bitten by the power adjustment bolt. By this action, the spring compression member is forced up and down the spiral rib 62 by forcibly rotating the power adjustment bolt from the outside to adjust the initial compression of the compression spring and the power of the spring.

When the hollow turning member is rotated through the wrench by the above-described mechanism, the hollow spring compression member moves up and down, thereby changing the initial compression of the compression spring. For example, turning the power adjustment bolt to move the hollow spring compression member downward to compress the compression spring will increase the restoring force of the compression spring in the future. The compression spring therefore exerts a stronger force, making it suitable for opening and closing heavy doors. Therefore, when used in light doors, the spring compression member is moved upward to release the compression spring by rotating the power adjustment bolt, and in the case of heavy doors, the power compression bolt is rotated to move the spring compression member downward to tighten the compression spring. It is possible to easily adjust the strength of the restoring force to close the door by freely adjusting the initial compression of the compression spring.

Meanwhile, the speed adjusting bolt 18 is coupled to the head of the power adjusting bolt 19. 6 shows a schematic diagram of this. On the outer circumferential side of the head of the speed adjustment bolt, a recessed part is formed, and the ring 22 and the E ring (stop ring) 26 are inserted into this part and then inserted into the hollow of the power adjustment bolt. The end of the inner circumferential surface of the power adjustment bolt is configured in a data form as shown in the figure to insert the ring and the E ring. The E ring serves to prevent separation of the ring 22. Thereafter, the speed adjusting bolt 18 is coupled to the power adjusting bolt by bending the uppermost end of the inner circumferential surface of the power adjusting bolt to the inside by a punching operation. O-ring 20 is coupled between the inner circumferential surface of the power adjustment bolt and the outer circumferential surface of the head of the speed adjustment bolt to prevent leakage of oil.

The speed adjusting bolt is composed of a head portion and a leg portion 70 extending to one end thereof. The leg portion has a narrow elongated plate shape as shown in a partial detail view of FIG. 1. A spiral rib 75 is also formed on the inner circumferential surface of the bolt portion of the power adjusting bolt. The spiral rib 75 is coupled to the spiral rib 76 formed on the outer circumferential surface of the adjustment valve holder 17. The adjusting valve holder 17 is cut in the longitudinal direction from the upper side as shown in the partial detailed view of FIG. 1 so that the leg portion 70 of the speed adjusting bolt can be inserted into this portion. Meanwhile, the speed adjusting rod 14 is inserted into the adjustment valve holder and coupled thereto. A concave portion 78 is formed at the upper end of the speed adjusting rod 14 so that the speed adjusting rod is simply coupled to the adjusting valve holder by inserting it into the adjusting valve holder and punching. One end of the head of the speed adjusting bolt is preferably coupled to the turning member 23 so as to easily turn the speed adjusting bolt from the outside. As shown, the turning member 23 may be coupled by the washer 25 and the screw 24.

By rotating the speed adjusting bolt as described above, the opening / closing speed of the door, in particular the speed of closing the door, is adjusted according to the principle described below. It is preferable that the housing is filled with oil to prevent sudden opening and closing of the door. That is, the door is closed smoothly by the resistance of the oil. To this end, a hollow up and down moving member 3 is placed on the lower side of the spring support member 13 with a steel ball 12 therebetween, and a check valve 9 is coupled to the inside of the hollow high moving member. Two oil passages are formed in the check valve. That is, the 1st oil path 46 of the center part and the 2nd oil path 47 which exist in the side slightly from the center are formed. The steel ball 11 is inserted into the second oil passage 47 and a steel ball drop preventing washer (not shown) may be coupled to prevent the steel ball 11 from being separated. The steel ball 12 between the lower side of the spring support member 13 and the upper side of the hollow up and down member 3 acts like a bearing to prevent wear during rotation. The check valve 9 is formed on the hollow shankdong member 3.

The second oil passage 47 is divided into a narrow part of the upper side and a wide part of the lower side, and the steel balls 11 are inserted and coupled to the wide part, and the check valve moves in contact with the hollow shank-dong member 3.

The steel ball 11 inserted into the check valve acts as follows to close the door gently. In the usual state, the steel ball is lowered due to its own weight. While the door is opened and the hollow spring moving member 3 moves upward, the compression spring is compressed, and as shown in FIG. 4, the oil on the upper side of the housing is transferred to the second oil passage 47 and the first oil of the check valve 9. The door is opened while moving downward through the oil passage 46. Steel ball 11 is in the lower side and the oil passage above the steel ball is open. On the other hand, while the door is closed, the hollow shankdong member moves linearly downward, and the check valve 9 also moves downward, so that the oil in the space below the check valve exits to the upper side so that the door can be closed. However, in this case, the steel ball 11 in the check valve is moved upward by the pressure of the oil to be moved upward to block the second oil passage 47, and the oil between the check valve and the hinge shaft as shown in FIG. 5A. May be moved through the first oil passage 46. However, the speed adjusting rod 14 has the cut portion 80 cut in the middle as shown, so that when the cut portion is positioned in the first oil passage 46 in the check valve as shown in FIG. Due to the relatively wide flow port, the oil moves smoothly and the closing speed of the door is high. On the other hand, when the door is gradually closed and the check valve is further moved downward, as shown in FIG. 5B, the check valve is moved below the incision, and the first oil passage is narrowed gradually, so that the flow of oil is slow and the door is closed. Will be lowered. Thus, when the door is closed, it is prevented from closing rapidly. In order to smoothly flow the oil, it is preferable to form a space 82 as shown in FIG. 3B between the gear portion formed in the longitudinal direction on the outer peripheral surface of the hinge shaft 2 and the gear portion formed on the inner peripheral surface of the hollow shank moving member 3. .

The speed adjusting rod 14 is coupled to the adjusting valve holder 17 and moved together. The adjusting valve holder is spirally coupled to the inner circumferential surface of the power adjusting bolt 19. When the speed adjusting bolt 18 is rotated, the power adjusting bolt rotates. The speed adjusting rod 14 is also vertically moved by moving up and down in a spiral rib. Therefore, since the height of the initial state of the speed adjusting rod can be changed, it becomes possible to determine whether the oil flow port of the first oil passage narrows from the moment of closing while the door is closed, thereby controlling the opening and closing speed of the entire door.

Speed adjusting rods can be manufactured simply. The speed adjusting rod is manufactured by cutting a plurality of speed adjusting rods side by side in a flat vise and milling them together because the rods are not tapered instead of the entire rod. Therefore, manufacturing cost is greatly reduced.

The present invention reduces the unit cost by converting the rotational movement on the rotating shaft into a linear movement when the door is opened and closed by not using an expensive torsion spring by using the compression restoring force of the compression spring, and furthermore, by inserting a wrench to adjust the power adjustment bolt By simply turning it, the initial compressibility of the compression spring can be changed, so that the power of the spring's restoring force can be easily adjusted, which can be adaptively used for doors of various weights.

On the other hand, the present invention has the effect of allowing the oil contained in the housing flow path to adjust the width of the oil flow path to close slowly and gently when the door is closed.

Claims (2)

When the door is opened, the mounting plate 1 coupled to the door rotates, and the compression spring 15 in the door hinge housing 30 is compressed to automatically close the door while the mounting plate rotates in the opposite direction by the restoring force of the compressed compression spring. In the initial compression degree adjustment structure of the door hinge One end of the power adjustment bolt is inserted into the inside of the hollow stopper through the hollow stopper 28 coupled to one end of the power adjustment bolt 19 by the housing 30, and the locking jaw 40 is disposed on one side of the outer circumferential surface of the power adjustment bolt. Is formed so that the locking step is caught by the hollow stopper to prevent the separation of the power adjustment bolt, the spiral rib is formed on at least a portion of the outer peripheral surface of the bolt portion 41 of the power adjustment bolt inserted into the hollow stopper, the spiral rib Spiral ribs formed on the inner circumferential surface of the hollow spring compression member 29 in contact with the compression spring is spirally coupled, One side of the outer circumference of the hollow spring compression member 29 is cut to form a cutting surface 42, and a protrusion for preventing the hollow spring compression member 29 from rotating together with the power adjustment bolt on one side of the inner circumferential surface of the housing. The jaw 43 is formed, When the power adjustment bolt is rotated, the hollow spring compression member 29 is caught by the protruding jaw 43 to prevent rotation, and moves up and down in a spiral rib of the outer circumferential surface of the power adjustment bolt, thereby causing the The initial degree of compression can be adjusted to adjust the magnitude of the restoring force applied to the door, characterized in that Initial compression degree adjustment structure of door hinge compression spring. The method of claim 1, One end of the power adjustment bolt protrudes to the outside of the hollow stopper, characterized in that the hollow turning member 27, which is formed with at least one turning hole 44 on the outer peripheral surface is fixedly coupled Initial compression degree adjustment structure of door hinge compression spring.

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