KR20100130448A - An oilpressure-type floor hinge apparatus for door - Google Patents

Abstract

PURPOSE: A hydraulic floor hinge device for opening and closing a door, which can supply buffer force, is provided to reduce maintenance and repair costs and effort by reducing a size and simplifying a structure. CONSTITUTION: A hydraulic floor hinge device for opening and closing a door comprises a floor hinge housing(101), a cylinder member(110), a piston unit(120), a cam unit(130) and an elastic control unit(140). The cylinder member is installed in the inner structure of the housing. The piston unit is installed inside the cylinder member to move up and down.

Description

Hydraulic floor hinge device for door opening and closing {AN OILPRESSURE-TYPE FLOOR HINGE APPARATUS FOR DOOR}

The present invention relates to a hydraulic hinge device for opening and closing a door, and in detail, a door opening / closing that is installed at an entrance of a building to provide a buffering force so that a swinging door (glass door) is opened and closed at a constant speed by a hydraulic action. It relates to a hydraulic floor hinge device for.

In general, a door (including a glass door) installed at the entrance of a building is pivotally installed (ie, a swing type), and the top and bottom of one side thereof are rotatably installed in a building or a door frame installed in the building. In the case of the door that is opened and closed in this way, when a separate door fixing device or a door opening / closing shock absorber is not installed, a situation in which the door is easily opened, closed or shaken even by a slight external force such as wind power may occur.

When the door is opened and closed arbitrarily by an external force, the possibility of a safety accident such as a person crashing into the door and colliding cannot be excluded, and the door itself has a problem such as being damaged or broken due to a collision. In particular, such a safety accident, failure, breakage, etc. may cause more serious results when the door is a glass door to which tempered glass is applied.

To this end, for doors, especially glass doors installed in the entrance and exit, so-called floor hinge devices are widely used in the floor of the entrance of the building to provide a cushioning force so that the swing opening / closing operation of the glass door is naturally and slowly maintained.

1 is an exemplary view for explaining the structure applied to the floor hinge device for opening and closing the glass door. In FIG. 1, at least one glass door 12 made of tempered glass is installed inside the door frame 10 fixed to the wall of the doorway so as to be opened and closed by swinging (ie, opening and closing). The glass door 12 has a rotary shaft rotatably coupled to the door frame 10 on the upper side thereof, and a floor hinge installed at the bottom of the entrance of the building so as to support the lower end of the glass door 12 in a rotatable manner. 16) is installed.

By the way, when the floor hinge 16 is installed on the entrance floor of a building, most of the floor hinges are dug to a predetermined width and depth so that the rotary support structure 17 of the floor hinge 16 is embedded. Therefore, the installation work is very complicated and cumbersome problem.

Therefore, as a simple structure, as well as the development of a floor hinge device that is easy to install, while also being able to stably control the opening and closing speed of the glass door 12, the glass door 12 is easily opened and closed by external force such as wind power, for example. There has been a demand for the development of a floor hinge device that can cushion the operation.

In consideration of the above, the development of a hydraulic floor hinge device having a shock absorbing function to prevent a sudden opening and closing operation of the glass door and to operate slowly has been made actively in consideration of the above points. In the case of the hinge device, the number of parts, the structure is complicated, the manufacturing cost increases, there is a limit in reducing the size, and when the failure occurs, the problem that the separation and repair work is not easy.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object thereof is to provide an improved hydraulic floor hinge device for door opening and closing, which is simple in structure, can be reduced in size, and easy to maintain.

The door opening and closing hydraulic floor hinge device of the present invention for achieving the above object, in the door opening and closing hydraulic floor hinge device for supporting the opening and closing of the door, is installed to be buried inside the door chassis coupled to the lower end of the door. A housing; A cylinder member having a cylinder unit in which a hydraulic medium is received, the cylinder member being installed in the housing; A piston unit installed in the cylinder to be reciprocated and having a movement passage for movement of the hydraulic medium; The upper end is rotatably installed on the cylinder member rotatably in a state passing through the cylinder portion, and the lower end is fixed to the bottom of the building in which the door is installed, and has a semicircular shape for moving the piston member when the door is turned. A cam unit having a cam portion; And an elastic control unit installed inside the cylinder part to elastically pressurize the piston unit to one side and adjust elasticity.

Here, the cylinder member, the cylinder body is formed so that the cylinder portion is open to one end; A door engaging portion formed from an upper end of the cylinder body such that one end of the door is fitted into the door; A cap member coupled to an open end of the cylinder portion to prevent leakage of the hydraulic medium inside the cylinder portion; And a cam unit coupling portion formed to communicate with the cylinder portion at a lower end of the cylinder body such that the cam unit is rotatably coupled to the cam unit.

The piston unit may include: first and second pistons disposed to be spaced apart from each other, each having a hydraulic medium passage hole penetrating both ends; And a pair of connecting members connecting the first and second pistons to be spaced apart from each other, the cam unit of the cam unit being interposed between the first and second pistons to pivot the door. In operation, the first and second pistons may be moved by a cam operation relative to the cam portion.

In addition, the inner space of the cylinder portion is divided into a first space portion, a second space portion and a third space portion from one side to the other side, the first space portion and the third space portion are provided on both sides of the piston unit, respectively, The second space portion may be provided between the first and second pistons, and the cylinder body may have a hydraulic medium moving passage connecting the first and third space portions.

In addition, the elastic control unit is installed in the first space portion to elastically press the piston unit toward the third space portion, the elastic control unit is compression-deformed by the movement of the piston unit during the swing operation of the door. It is good.

In addition, the elastic control unit, the elastic member is installed inside the cap portion to support the piston unit elastically; A movable plate installed between the elastic member and the cap member to support one end of the elastic member and to be movable; And an elastic adjustment member screwed to the cap member, one end of which is installed to be in contact with the movable plate through the cap member, and moves the movable plate toward the elastic member according to the screwing degree of the elastic adjustment member. It is good to be able to adjust the degree of elasticity of the elastic member to move or move away.

In addition, the cam unit, the upper end is rotatably connected to the cylinder body through the cylinder portion, the lower end is projected out of the cylinder body is fixed to the support surface of the door, the semi-circular cam portion in the center portion A camshaft; A bearing member rotatably supporting the camshaft relative to the cylinder body; And protruding from the position corresponding to the cam portion of the camshaft to the outer circumferential surface of the camshaft, contacting the second piston to provide frictional force in a rotational motion relative to the piston unit of the camshaft, and rotating in the opposite direction. It is preferable to include; an interference member to suppress the.

In addition, the interference member is screwed to the cam portion is preferably installed so that the height can be adjusted from the outer periphery of the cam portion.

In addition, the door opening and closing hydraulic floor hinge device according to another aspect of the present invention for achieving the above object, in the door opening and closing hydraulic floor hinge device for supporting the opening and closing of the door, the door is coupled to the lower end of the door A housing installed buried in the chassis; A cylinder member having a cylinder unit in which a hydraulic medium is received, the cylinder member being installed in the housing; A piston unit installed in the cylinder to be reciprocated and having a movement passage for movement of the hydraulic medium; The upper end is rotatably installed on the cylinder member rotatably in a state passing through the cylinder portion, and the lower end is fixed to the bottom of the building in which the door is installed, and has a semicircular shape for moving the piston member when the door is turned. A cam unit having a cam portion; And an elastic control unit installed inside the cylinder part to elastically pressurize the piston unit to one side and adjust elasticity. The semi-circular cam part cuts the center of the camshaft to set the maximum point of force. When the cutting surface is in contact with the piston member, the operation of the piston member is stopped, and the idling surface is separated from the piston member.

According to the hydraulic floor hinge device for opening and closing the door of the present invention, it is possible to prevent the safety accident and breakage due to the sudden operation of the door by buffering when the door is rotated by using the hydraulic pressure to operate slowly.

In addition, by forming the cylinder portion integrally formed in the floor hinge housing and directly coupled to the door, it is possible to reduce the overall size, it is possible to reduce the cost by reducing the number of parts.

In addition, since the configuration of the piston unit is also simple, assembleable and disassembled, there is an advantage in that maintenance is convenient.

In addition, by providing an elastic control unit that can adjust the elastic force of the elastic member for applying elasticity to the piston unit, it can be used to adjust the elasticity in a long time use so that the swing operation of the door can be stabilized.

In addition, by forming a semi-circular cam portion on the cam shaft of the cam unit, it is possible to guide the piston unit to be reciprocated while reducing the maximum width size of the cam shaft. Therefore, it is possible to reduce the overall length of the piston unit is water, it is possible to reduce the weight and size of the product by reducing the overall size and weight of the floor hinge device.

Hereinafter, a hydraulic floor hinge device for opening and closing a door according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2, 3, 4, 5, 6 and 7, the hydraulic floor hinge device 100 for door opening and closing according to an embodiment of the present invention, the bottom of the door 12 (particularly glass door) It is embedded in the door chassis 18 to be installed so as not to be exposed to the outside.

Here, the door 12 is a swing door in which the opening and closing operation is performed by the pivoting operation, and the floor hinge device 100 is installed at a lower one side position corresponding to the rotation center of the door 12. A door chassis 18 is installed at the bottom of the door 12 as shown in FIGS. 2 and 3.

The upper frame of the door 12 is provided with a rotating shaft 30 rotatably supported in the building.

The floor hinge device 100 includes a floor hinge housing 101, a cylinder member 110 installed inside the housing 101, a piston unit 120 installed inside the cylinder member 110, and A cam unit 130 installed in the housing 101 to be interlocked with the piston unit 120 and an elastic control unit 140 coupled to the cylinder member 110 is provided.

The housing 101 is installed inside the door chassis 18 and has an inner space 102 for accommodating the cylinder member 110, the piston unit 120, and the elastic control unit 140.

The cylinder member 110 includes a cylinder body 112 having a cylinder portion 111 formed therein, a cap member 113 coupled to an open end of the cylinder portion 111, and the cylinder portion 111. It has a cam unit coupling portion 115 (see Fig. 6) formed at the bottom of the housing body 112 in communication with.

The cylinder part 111 is divided into a first space part 111a, a second space part 111b and a third space part 111c from one side to the other direction. The first space portion 111a and the third space portion 111c are provided at both sides with the piston unit 120 interposed therebetween, and the second space portion 111b is the first and second portions of the piston unit 120. It is formed between the piston (121, 122). A hydraulic medium moving passage 116 is formed in the housing body 112 to allow the hydraulic medium of the third space 111c to move to the second space 111b. The hydraulic medium movement path 116 is connected to the control passage 117 communicated to the outside of the housing body 112. The control valve 118 for adjusting the hydraulic pressure using the control passage 117 and the movement path 116 is installed to the depth of the cylinder body 112. By rotating the control valve 118 to adjust the coupling depth, it is possible to adjust the amount of the hydraulic medium to be moved through the movement path (116).

The first space 111a is coupled to the elastic control unit 140. Therefore, the piston unit 120 is elastically pressed toward the third space portion 111c by the elastic control unit 140.

The cap member 113 is coupled to be inserted into the first space portion 11a of the cylinder body 112 to close the cylinder portion 111. The cap member 113 is provided with the elastic control unit 140.

The piston unit 120 is installed to reciprocate in the cylinder part 111, and the first and second pistons 121 and 122 and the first and second pistons 121 and 122 formed to be spaced apart from each other by a predetermined distance from each other. It has a pair of connecting portion 123 for connecting.

The first piston 121 is located between the first and second space parts 111a and 111b, and the second piston 122 is located between the second and third space parts 111b and 111c. The first piston 121 has a hydraulic medium passage hole 121a so as to pass through the center thereof. The hydraulic medium of the first and second spaces 111a and 111b may be moved in both directions when the piston unit 120 reciprocates through the hydraulic medium through hole 121a.

The second piston 122 is also provided with a hydraulic medium through hole 122a for communicating the second and third space portions 111b and 111c. The hydraulic medium of the second space portion 111b is moved to the third space portion 111c through the hydraulic medium passage hole 122a and moves in the opposite direction, that is, the second space portion 111b in the second space portion 111c. The check valve 124 for blocking the movement of the hydraulic medium to the () is installed in the hydraulic medium through-hole (122a). The check valve 124 is moved in the through hole (122a) and the opening and closing ball (124a) for selectively opening and closing the passage hole (122a) according to the moving position, and the hole selectively closed by the opening and closing ball (124a) And a valve member 124b and a mesh member 124c and a cover member 124d that are coupled to the expansion part 122b extended in the through hole 122a. The cover member 124d is coupled from the outside of the second piston 122 to prevent separation of the mesh member 124c, the opening / closing member 124b, and the open ball 124a.

The pair of connecting portions 123 are formed to be spaced apart from each other to allow the cam unit 130 to pass through the gap therebetween. The pair of connecting portions 123 may be connected to the first and second pistons 121 and 122 spaced apart from each other by a predetermined distance, and may be integrally formed with the first and second pistons 121 and 122. In addition, the left and right lengths L1 of the space formed between the pair of connecting portions 123 are larger than the distance L2 between the first and second pistons 121 and 122. To this end, a stepped portion 121b is formed to be stepped in part from a side facing the second piston 122 of the first piston 121. The stepped portion 121b is formed at a position higher than the medium passage hole 121a.

According to the configuration, when the piston unit 120 is moved in the direction B1 in the state of FIG. The hydraulic medium of the three space portion 111c moves to the second space portion 111b only through the hydraulic medium moving passage 116. On the contrary, when the piston unit 120 moves in the direction B2 in the state of FIG. 6, the outlet of the hydraulic medium moving passage 116 is blocked by the second piston 122 and the check valve 124 is opened as shown in FIG. 7. As a result, the hydraulic medium of the second space 111b is moved to the third space 111c through the hydraulic medium through hole 122 of the second piston 122a. In addition, the hydraulic medium of the first space 111a is moved to the second space 111b through the hydraulic medium passage hole 121a of the first piston 121.

As the piston unit 120 reciprocates from side to side, the hydraulic medium in the cylinder portion 111 is moved, thereby acting as a buffer.

The cap member 113 is coupled to the open side of the cylinder 111 to seal the open portion of the cylinder 111. The cap member 113 may be screwed to one side of the cylinder portion 111.

The elastic control unit 140 is an elastic member 141 installed inside the cap member 113, a movable plate 142 that is installed to be movable in the cap member 113, and a movable plate 142. It is provided with an elastic adjustment member 143 to adjust the position of the.

The movable plate 142 is installed between the elastic member 141 and the inner surface of the cap member 113, is supported by the elastic control member 143 is moved in the left and right directions.

The elastic control member 143 is coupled to be seated in the coupling groove 113a formed at the end of the cap member 113, it is screwed to the end of the cap member 113. The end of the elastic control member 143 is installed to pass through the end of the cap member 113 to contact the movable plate 142 inside the cap member 113. Therefore, by rotating the elastic control member 143 to adjust the length of the end protruding into the cap member 113, the position of the movable plate 142 can be adjusted, by adjusting the position of the movable plate 142 The elastic force of the elastic member 141 can be adjusted.

In FIG. 6 and 7, reference numeral 144 denotes a sealing member installed between the elastic control member 143 and the inside of the coupling groove 113a.

As described above, by installing the elastic control unit 140 including the elastic member 141, the movable plate 142 and the elastic control member 143, the elastic force of the elastic member 141 may be lowered with use for a long time. In this case, by changing the position of the movable plate 142 by adjusting the coupling degree of the elastic control member 143, it is possible to adjust the elastic force of the elastic member 141.

The cam unit 130 is rotatably installed on the cylinder body 112 so as to cross the cylinder portion 111 and the cam shaft 131 is rotatable with respect to the cylinder body 112. It is provided with a bearing member 133 to be supported.

On the lower side of the cylinder body 112, a cam unit coupling portion 115 to which the bearing member 133 is coupled is formed, and the bearing member 133 is press-fitted and coupled. The cam shaft 131 has a fixed coupling portion 131a, a bearing coupling portion 131b, a cam portion 131c, a guide portion 131d, and a rotation shaft portion 131e from the lower end to the upper end.

The fixed coupling portion 131a is coupled to a bottom portion or a door frame that supports the door 12 so that the door 12 is rotatably installed and supported, and is formed in a non-circular cross-sectional shape. The fixed coupling portion 131a is fixedly coupled to the other support, so that the piston unit 120 and the cylinder member 110 are rotated with respect to the camshaft 131 so that the door 12 is opened and closed. .

The bearing 133 is coupled to the bearing coupling portion 131b, so that the cam shaft 131 can be rotatably connected to the cylinder body 110.

The cam part 131c is formed to have a diameter equal to or less than that of the bearing coupling part 131b, and preferably has a diameter corresponding to the gap L2 between the first and second pistons 121 and 122. It is formed to have. However, the cam part 131c has the cam surface S1 (cutting surface) formed so that the cross-sectional shape may have semi-circle shape. Therefore, the maximum distance between the cam surface S1 and the outer circumferential surface S2 of the cam portion 131c is 1/2 or less of the diameter of the cam portion 131c. The cam surface S1 is formed between the bearing coupling portion 131b and the guide portion 131d, and the height h1 is greater than the thickness t1 from the step portion 121b of the first piston 121 to the outer diameter. It is largely formed.

The guide part 131d is interposed between the connecting part 123 so that the cam shaft 131 may be relatively rotated at the center of the cylinder unit 120 when the cam shaft 131 and the cylinder unit 120 are rotated relative to each other. Guide to help. In addition, the rotation shaft portion 131e is coupled to the shaft support groove in the cylinder 111 so that the cam shaft 131 is rotatable with respect to the cylinder body 110, and supports the shaft to be stably rotated without shaking.

In addition, the cam portion 131c limits the relative rotation direction and the rotation angle between the camshaft 131 and the piston unit 120, and prevents free rotation when no force is applied in each of the states of FIGS. 6 and 7. The interference member 135 is installed to protrude to the outer circumferential surface S2 opposite to the cam surface S1. To this end, the cam portion 131c has a screw hole 131f to which the interference member 135 is screwed. The interference member 135 has an engaging portion 135a having a screw line formed on its outer circumference so as to be screwed into the screw hole 131f at one end thereof, and an interference that is selectively contacted with an end surface of the second piston 122 at the other end and interfered therewith. It has a portion 135b. As described above, the coupling depth with the screw hole 131f may be adjusted by having the coupling portion 135a at one end of the interference member 135, and thus, the second piston 122 may be adjusted by adjusting the protrusion height of the interference member 135b. ), The degree of interference (friction) can be adjusted. As shown in FIGS. 8A and 8B, the interference part 135b is formed to be symmetrically with respect to the virtual reference line L3 connecting the center of the interference part 135 at the center of the camshaft 131.

The interference portion 135b of such a configuration is such that when the camshaft 131 is rotated relative to the piston unit 120 in the A1 direction as shown in FIG. 8C, a small friction force may be applied to the second piston 122. Rotates in contact. That is, when an external force is applied, the camshaft 131 and the piston unit 120 are freely rotated in the direction A1 by being formed to have a contact area (friction force) that can be sufficiently overcome by the external force. Allow to be rotated by external force.

On the other hand, when the camshaft 131 is moved in the A2 direction in the state as shown in FIG. 8B, the interference part 135b prevents the cam shaft 131 from being rotated due to interference with the first piston 121. It can be rotated further in this A3 direction, but only rotated when an external force is applied to the second piston 122. Accordingly, the camshaft 131 is rotated about 90 degrees to about 120 degrees in the A4 direction and the A3 direction in the state of FIG. 8D, and rotates in the direction A1 in the state of FIG. 8B, and the angle is 90 degrees or less in the A2 direction. Can be controlled to rotate.

When the piston unit 120 is rotated with respect to the cam shaft 131 in the state as shown in FIG. 8D, since the cam portion 131c of the cam shaft 131 is semi-circular, the cam surface S1 is connected to the first piston 121. The piston unit 120 may be moved from the state of FIG. 7 to the state of FIG. 6 to be in close contact. That is, by forming the cam portion 131c in a semi-circular shape, it is possible to provide a space in which the piston unit 120 can be moved by the radial width reduced in the width direction, so that the piston unit 120 with respect to the cam shaft 131 The cam surface S1 of the cam part 131c faces or shifts the first piston 121 according to the rotational position of the cam unit 131c to allow the piston unit 120 to reciprocate.

According to the floor hinge device 100 according to the embodiment of the present invention having the above configuration, the camshaft 131 is fixed to the bottom of the facility, the cylinder body 110 is fixed to the door 12. Accordingly, when the door 12 is pivoted, the cylinder body 110 is rotated about the cam shaft 131, and the piston in the cylinder portion 111 is caused by relative cam movement between the pistons 121 and 122 and the cam portion 131c. The unit 120 moves from the state of FIG. 6 to the state of FIG. 7 to compress the elastic member 140. That is, the piston unit 120 and the cam shaft 131 is relatively rotated step by step from the state of Figure 8b to the state of Figure 8d, the piston unit 120 is moved. At this time, the hydraulic medium of the first space portion 111a is moved to the second space portion 111b through the through hole 121a of the first piston 121, and the hydraulic medium of the second space portion 111b is moved. It passes through the through hole 122a of the second piston 122 and is forcibly pushed into the third space 111c to be moved. In this case, since the hydraulic medium moving passage 116 is blocked due to the movement of the second piston 122, the hydraulic medium is moved into the third space 111c to prevent the door 12 from turning rapidly. It works.

When the door 12 is opened at an approximately 90 degree angle, the interference member 135 is positioned to face the end surface of the second piston 122 to provide frictional force during rotation, so that the door 12 is easily operated by hydraulic pressure. It can be prevented from turning and closing.

When the door 12 is pivoted in the opposite direction by applying an external force to the door 12 in the state of FIG. 7, the camshaft 131 and the piston unit 120 in the state of FIGS. 8C and 8B are again in the state of FIG. 8D. While relatively rotating, the piston unit 120 is moved to the state of FIG. Then, the hydraulic medium moving passage 116 is opened according to the movement of the second piston 122 in the right direction, and the passage hole 122a is closed. Therefore, the hydraulic medium of the third space 111c is moved to the second space 111b through the hydraulic medium moving passage 116, and the hydraulic medium of the second space 111b is the first piston 121. As it moves to the first space portion (111a) through the through hole (121a) of the to act as a buffer so that the sudden turning operation of the door 12 does not occur.

In the case of the floor hinge device of the present invention having the above-described configuration, the number of parts thereof is smaller than that of the conventional art, and the configuration is simple, so that the production can be performed at low cost and small size.

In addition, when the parts are broken, the cam unit 130 and the piston unit 120 can be easily separated and assembled, and thus, there is an advantage of easy troubleshooting, parts replacement, and the like.

In addition, by forming the shape of the cam portion 131c of the camshaft 131 in a semicircular shape, the entire maximum width of the camshaft 131 can be reduced, so that the length of the piston unit 120 can be made to a minimum. Therefore, there is an advantage that can reduce the size of the entire device and the weight.

In addition, as described above, since the position of the movable plate 142 supporting the elastic member 141 installed in the cap member 113 coupled to the cylinder chamber 111 may be adjusted, the elastic force of the elastic member 141 may be adjusted. There is an advantage that can be used by adjusting appropriately. Therefore, even when the elastic force of the elastic member 141 is lowered during long time use, by further pushing the movable plate 142 into the cylinder chamber 111, it is possible to correct the elastic force of the elastic member 141 is weakened. Therefore, the piston unit 120 can be stably operated while maintaining a constant elastic force of the elastic member 140 even when used for a long time.

1 is a view for explaining a conventional floor hinge device.

2 is a view showing a door installed in the hydraulic floor hinge device for opening and closing the door according to an embodiment of the present invention.

Figure 3 is an exploded perspective view of the hydraulic floor hinge device for opening and closing the door shown in FIG.

4 is a sectional view showing the piston unit shown in FIG.

5 is a longitudinal cross-sectional view of the cam unit shown in FIG.

6 and 7 are each a cross-sectional view for explaining the hydraulic floor hinge device for opening and closing the door according to an embodiment of the present invention for each operation state.

8A is a front view of the camshaft shown in FIG.

8b to 8d are each a plan view showing the rotation state of the cylinder unit with respect to the camshaft step by step.

<Description of Symbols for Main Parts of Drawings>

12. Door 100. Floor hinge device

110.Floor hinge housing 120.Piston unit

130. Cam unit 140. Elastic member

Claims (9)

In the hydraulic floor hinge device for opening and closing the door for supporting the opening and closing of the door, A housing buried in the door chassis coupled to a lower end of the door; A cylinder member having a cylinder unit in which a hydraulic medium is received, the cylinder member being installed in the housing; A piston unit installed in the cylinder to be reciprocated and having a movement passage for movement of the hydraulic medium; The upper end is rotatably installed on the cylinder member rotatably in a state passing through the cylinder portion, and the lower end is fixed to the bottom of the building in which the door is installed, and has a semicircular shape for moving the piston member when the door is turned. A cam unit having a cam portion; And And an elastic control unit installed inside the cylinder part to elastically pressurize the piston unit to one side and adjust elasticity. The method of claim 1, wherein the cylinder member, A cylinder body formed so that the cylinder portion is opened to one end; A door engaging portion formed from an upper end of the cylinder body such that one end of the door is fitted into the door; A cap member coupled to an open end of the cylinder portion to prevent leakage of the hydraulic medium in the cylinder portion; And And a cam unit coupling portion formed to communicate with the cylinder portion at a lower end of the cylinder body such that the cam unit is rotatably coupled to the hydraulic unit. The method of claim 2, wherein the piston unit, First and second pistons disposed to be spaced apart from each other, each having a hydraulic medium passage hole penetrating both ends; And a pair of connecting members connecting the first and second pistons and spaced apart from each other. The cam unit of the cam unit is interposed between the first and the second piston, the door opening and closing, characterized in that the movement of the first and second piston by the cam operation relative to the cam portion when the door swings. Hydraulic floor hinge device. The method of claim 3, The inner space of the cylinder part is divided into a first space part, a second space part and a third space part from one side to the other side, The first space portion and the third space portion are provided on both sides of the piston unit, the second space portion is provided between the first and the second piston, The hydraulic floor hinge device for door opening and closing, characterized in that the cylinder body is formed with a hydraulic medium moving passage connecting between the first and third space. The method of claim 4, wherein the first space portion is provided with the elastic control unit to elastically press the piston unit toward the third space portion, the elastic control unit to the movement of the piston unit during the swinging operation of the door. Hydraulic floor hinge device for opening and closing the door, characterized in that the compression deformation. The method of claim 4, wherein the elastic control unit, An elastic member installed inside the cap part to elastically support the piston unit; A movable plate installed between the elastic member and the cap member to support one end of the elastic member and to be movable; And an elastic adjustment member screwed to the cap member, one end of which is installed to contact the movable plate through the cap member. A hydraulic floor hinge device for door opening and closing, characterized in that the elasticity of the elastic member can be adjusted by moving the movable plate toward or away from the elastic member according to the screwing degree of the elastic control member. The method of claim 3, wherein the cam unit, An upper end rotatably connected to the cylinder body through the cylinder part, and a lower end protruding out of the cylinder body to be fixed to the support surface of the door, and a cam shaft having the semi-circular cam part at a central part thereof; A bearing member rotatably supporting the camshaft relative to the cylinder body; And It is installed to protrude to the outer circumferential surface of the cam portion at a position corresponding to the cam portion of the cam shaft, in contact with the second piston in the rotational motion relative to the piston unit of the cam shaft to provide a friction force, and to rotate in the opposite direction Door opening and closing hydraulic floor hinge device comprising a; interference suppressing member to suppress. The method of claim 7, wherein the interference member, The hydraulic floor hinge device for door opening and closing, characterized in that the screw is coupled to the cam portion so that the height can be adjusted from the outer periphery of the cam portion. In the hydraulic floor hinge device for opening and closing the door for supporting the opening and closing of the door, A housing buried in the door chassis coupled to a lower end of the door; A cylinder member in which a hydraulic medium is accommodated, and a cylinder member installed in the housing; A piston unit installed in the cylinder to be reciprocated and having a movement passage for movement of the hydraulic medium; The upper end is rotatably installed on the cylinder member rotatably in a state passing through the cylinder portion, and the lower end is fixed to the bottom of the building in which the door is installed, and has a semicircular shape for moving the piston member when the door is turned. A cam unit having a cam portion; And It is installed in the cylinder portion and elastically pressurizing the piston unit to one side, the elastic control unit for adjusting the elasticity; includes; The semi-circular cam portion cuts off the center of the camshaft to set the maximum point of force, and when the cutting surface is in contact with the piston member, the operation of the piston member is stopped, and the cutting surface is separated from the piston member. Hydraulic floor hinge device for opening and closing the door, characterized in that the idle of the door.

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