KR200262510Y1 - Hydraulic press control Structure of Hydraulic Floor Hinge - Google Patents

Abstract

The present invention relates to a hydraulic floor hinge, which is coupled to the lower end of the swing door to control the opening of the fluid movement passage to control the rotational movement of the door, and can be opened and closed only when the piston is retracted from the compression of the cylinder The first hydraulic valve and the second hydraulic valve which opens and closes only when the piston advances to the compression section of the cylinder, and the second hydraulic pressure adjusting screw pressurizing the elastic member from the second hydraulic valve at the hydraulic floor hinge that controls the operation of the actuators. 2, the hydraulic pressure control structure of the hydraulic floor hinge that can be operated smoothly opening and closing without mechanical force by adjusting the operating pressure of the hydraulic valve.

Description

Hydraulic press control structure of hydraulic floor hinge

The present invention relates to a hydraulic floor hinge, and more specifically, in the hydraulic floor hinge coupled to the lower end of the swing door to control the rotational movement of the door, the second hydraulic valve which can be opened and closed only when the door is closed while the piston is advanced to the compression part of the cylinder. It relates to a hydraulic control structure of the hydraulic floor hinge that can be opened and closed smoothly without mechanical forces by adjusting the operating pressure of the second hydraulic valve with a second hydraulic control screw for pressing the elastic member in the.

In general, the floor hinge is a device that is installed in the swing door that is rotated open and close to return the door to the closed state so that the door is automatically closed even if no additional force is applied when the door is opened. Such a floor hinge is typically formed in a casing with the fluid inside the casing and the casing is sealed. The floor hinge is connected to the lower part of the door to control the rotational motion of the door by the hydraulic action in the spring and the casing. do.

1 is a side cross-sectional view showing the configuration of a conventional hydraulic floor hinge, Figure 2 is a perspective view showing the configuration of a conventional hydraulic floor hinge, Figure 3 is a plan view showing the internal structure of a conventional hydraulic floor hinge.

Conventional hydraulic floor hinge as shown in the drawing has a piston access passage 20, the front of which is open on one side of the cylinder 10 and the rear is blocked, and is opened in one side of the cylinder 10 to the piston access passage ( The fluid passage is formed to have a fluid passage for controlling the fluid to flow in and out 20 properly, the fluid passage is larger in the side wall surface 21 of the piston access passage 20 toward the rear wall surface 23 toward the rear wall surface 23. Discharge grooves 30 cut into smaller cross sections, discharge inlets 40 which are partially drilled rearward from the rear wall surface 23 of the piston entry passage 20, and the upper surface 11 of the cylinder 10. And a lower pressure portion of the cylinder 10, which is drilled down from a predetermined depth so as to communicate with the discharge inlet 40 and the hydraulic adjusting screw 51 screwed therein so as to be movable. Bored in (12) and the hydraulic adjustment hole (50) It is formed to constitute a discharge outlet 60 communicated with.

The conventional hydraulic floor hinge configured as described above, as shown in the figure, the hinge shaft 2, the control cam 3, the piston 5, the piston rod 6, the spring ( 7) and is installed in conjunction with each operating part consisting of the fluid (8) and the like, when the door (D) is opened and closed to cooperate with each operating part organically to control the opening and closing state of the door.

That is, as shown in FIG. 3, when the user opens the door D, the hinge shaft 2 rotates while the control cam 3 at the lower end of the hinge shaft 2 rotates to open the piston rod 6. And the piston (5) retreat from the piston access passage (20), at this time, in the piston valve (5a) the valve is opened only when the piston (5) retracts, so that the fluid (8) flows into the piston entry passage (20) The piston 5 quickly retracts so that the door D can be opened.

On the other hand, when the piston 5 enters the interior of the piston access passage 20 by the spring force of the spring 7 when the door is closed, the fluid 8 inside the access passage is mostly discharged in the early and middle periods. Exit through the), the entry of the piston (5) proceeds to the end of the discharge groove 30, when the discharge groove 30 is completely closed by the piston (5) from then to the discharge inlet 40 and the hydraulic control Passed through the hole 50 and the discharge outlet 60 in sequence to be discharged to the outside.

In the above, the discharge groove 30 for providing the initial and middle air discharge passages of the fluid 8 is formed in a cross section which is larger toward the opening part 22 and toward the rear wall surface 23, so that the piston 5 enters the entrance. Since the passage amount of the fluid 8 is adjusted while the opening is gradually reduced in size, the closing speed of the door is initially fast and gradually slows.

In addition, the discharge inlet 40, the hydraulic control hole 50 and the discharge outlet 60 is finely adjusted so that the fluid (8) little by little in the state that the door is almost closed, it operates gradually when the door is completely stopped. It plays the role of making it possible.

That is, the conventional hydraulic floor hinge is configured to close the door by gradually slowing the closing speed as the door automatically closes, so there is no problem when the door is opened and closed slowly, but once the door is closed to open the door in the opposite direction, the door is closed again. If you try to open in the direction of the door is closed while the door is slowly operating because the user pushes the door with a strong force to rotate, there was a problem that the mechanical force on the floor hinge.

In addition, when the door is closed, some mechanisms have been proposed to prevent the mechanical force applied to the hydraulic floor hinge by opening and closing the valve only when there is a strong force of the user, but this also prevents the operation of the valve to control the speed of closing the door. If the door closing speed is too slow because it is not properly controlled, the hydraulic floor hinge may not only give mechanical pressure to the hydraulic floor hinge, but if the door closing speed is too fast, there may be a risk of a safety accident.

The present invention is devised to solve the above problems, when the door is closed, the user closes smoothly when the force is applied, but controls the closing speed so that the user can be smoothly closed without considering mechanical safety. It is to provide a hydraulic control structure of the hydraulic floor hinge as far as possible.

1 is a side cross-sectional view showing the configuration of a conventional hydraulic floor hinge.

2 is a perspective view showing the configuration of a conventional hydraulic floor hinge.

3 is a plan view showing the internal structure of a conventional hydraulic floor hinge.

Figure 4 is a perspective view showing the configuration of the hydraulic floor hinge according to an embodiment of the present invention.

5 is an exploded perspective view showing the configuration of a hydraulic floor hinge according to an embodiment of the present invention.

6 is a perspective view showing a hydraulic control structure of the hydraulic floor hinge according to an embodiment of the present invention.

7 is a plan sectional view showing a hydraulic control structure of the hydraulic floor hinge according to the embodiment of the present invention.

8 is a cross-sectional view showing the structure of the hydraulic control unit according to an embodiment of the present invention.

9 is a cross-sectional view showing another state of FIG. 8.

-Explanation of symbols for the main parts of the drawings-

140: hinge axis 150: second casing

160: piston 161: first hydraulic control valve

161a: steel ball 170: spring

180: fluid 200: fluid movement control unit

210: first fluid flow path 220: first external opening

230: fluid movement adjusting screw 300: second hydraulic control valve

310: second fluid movement passage 320: second external opening

330: steel ball 340: elastic member

350: Hydraulic adjusting screw

The present invention for realizing the above object accommodates the actuators and the fluid to the inside, and the fluid movement control unit for adjusting the opening degree of the fluid movement passage, and can be opened and closed only when the piston is reversed in the compression portion of the cylinder A hydraulic floor hinge for controlling the operation of actuators by a first hydraulic valve and a second hydraulic valve which can be opened and closed only when the piston is advanced to the compression part of the cylinder, wherein the second hydraulic valve has a compression part and a fluid receiving part of the cylinder. It is formed so as to communicate, and forms a second outer opening that is opened on one side to the outside to block the valve inward, the elastic member for pressing the steel ball and fastened to the second outer opening to move up and down of the elastic member The second hydraulic pressure adjusting screw for adjusting the pressing force is characterized in that it is formed so as to be sequentially inserted.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In addition, this embodiment is not intended to limit the scope of the present invention, but is presented by way of example only.

4 is a perspective view showing the configuration of the hydraulic floor hinge according to an embodiment of the present invention, Figure 5 is an exploded perspective view showing the configuration of a hydraulic floor hinge according to an embodiment of the present invention.

6 is a perspective view showing a hydraulic control structure of the hydraulic floor hinge according to an embodiment of the present invention, Figure 7 is a cross-sectional view showing a hydraulic control structure of the hydraulic floor hinge according to an embodiment of the present invention.

In addition, Figure 8 is a cross-sectional view showing the structure of the hydraulic control unit according to an embodiment of the present invention, Figure 9 is a cross-sectional view showing another state of FIG.

As shown here, the hydraulic floor hinge consists of a first casing 120, a first casing cover 130, and a second casing 150 to accommodate a plurality of components and actuators and the operation of the actuator on one side. Form a hydraulic control to adjust the.

That is, the lower portion of the first casing 120 is rotated and supported in the inner side thereof, and the upper portion thereof is partially exposed through the hinge shaft through hole 131 of the first casing cover 130, and the lower portion of the door, which is not shown in the drawing, is exposed. The hinge shaft 140 to be connected to the control shaft 145 is formed integrally with the hinge shaft 140 and rotates together with the hinge shaft 140. The second casing 150 is provided at one side. The side opening portion 151 is formed to be coupled to the side opening portion 122 of the first casing 120 and includes a cylinder 152 inward.

In addition, the cylinder 152 is inserted and installed to operate the piston 160, the one end is connected to the control cam 145 of the hinge shaft 140 and the other end is connected to the piston 160 is connected to the piston 160 Install rod 165.

A first hydraulic valve 161 is formed on the front side of the piston 160 to allow the fluid 180 to move in only one direction.

In addition, one end of the spring 170 is supported by the side opening 122 of the first casing 120 while the spring 170 is fitted to the piston rod 165, and the other end of the spring 170 is connected to the piston 160.

The first casing 120 accommodates fluids with the respective actuators and forms the upper opening 121 and the side opening 122, respectively.

The first casing cover 130 includes a hinge shaft through-hole 131 to cover the first casing 120 to seal the actuators received inward, and to allow the hinge shaft 140 to protrude through.

The first casing cover 130 is formed in a circular shape, and a threaded portion 132 is formed on the outer circumferential surface thereof. In addition, the upper opening 121 of the first casing 120 is also formed in a circular shape according to the shape of the first casing cover 130 while the screw 132 of the first casing cover 130 is fastened to the inner circumferential surface thereof. The threaded portion 124 is formed so that the first casing cover 130 is screwed onto the first casing 120.

Accordingly, the coupling of the first casing 120 and the second casing 150 forms a screw hole 126 in the peripheral portion 125 of the side opening 122 of the first casing 120 and the second casing. (150) A screw hole 155 corresponding to the screw hole 126 of the first casing 120 is formed in the peripheral portion 154 of the side opening 151, and the screw is screwed through the screw hole 155. 126 to make it.

That is, the first casing 120 and the second casing 150 are coupled to each other, and the first casing cover 130 is screwed into the upper opening 121 to form a hydraulic floor hinge.

The present invention is a hydraulic floor hinge configured as described above, the first hydraulic valve 161 that can be opened and closed only when the piston 160 is reversed from the compression unit 152a of the cylinder 152 to one side of the piston 160 And a fluid movement adjusting part 200 for controlling the opening degree of the fluid movement passage on one side of the second casing 150. This is the same to or similar to the prior art. However, in the present invention, the piston 160 is formed by further adding a second hydraulic valve 300 to one side of the second casing 150, which can be opened and closed only when advancing to the compression part 152a of the cylinder 152. And it is formed to control the opening and closing of the second hydraulic valve (300).

That is, the first hydraulic valve 161 is formed in the piston 160, the fluid 180 in the cylinder 152 is moved only in one direction from the fluid receiving portion 152b to the compression portion 152a. Form as possible. That is, when the piston 160 moves backward while the door is opened, the steel balls 161a accommodated therein open the first hydraulic valve 161 by the pressure of the fluid 180 and the fluid 180 receives the fluid. When the piston 160 moves forward toward the compression unit 152a, the pressure of the fluid 180 causes the steel ball 161a to move to the compression unit 152a from 152b. Pressurized to block the hydraulic valve 161, the fluid 180 is not movable.

In addition, the fluid movement adjusting unit 200 formed at one side of the second casing 150 has a first fluid movement passage 210 for communicating the compression unit 152a and the fluid receiving unit 152b of the cylinder 152. ) Is formed, the first outer opening 220 is formed on one side of the first fluid movement passage 210 to the outside to adjust the opening and closing degree of the first fluid movement passage 210 inward. It is formed to fasten the fluid movement adjusting screw 230.

And, the second hydraulic valve 300 is formed on one side of the second casing 150 to be located near the fluid movement control unit 200, the compression unit 152a and the fluid receiving of the cylinder 152 A second fluid movement passage 310 is formed to communicate the portion 152b, and a second external opening 320 is formed at one side of the second fluid movement passage 310 to the outside to open the valve. Hydraulic adjustment screw for locking the steel ball 330, the elastic member 340 for pressing the steel ball 330 and the second outer opening 320 to move up and down to adjust the pressing force of the elastic member 340 ( 350 is formed to be inserted sequentially.

Here, the second fluid movement passage 310 has a small inner diameter at the compression portion 152a side and a large inner diameter at the fluid receiving portion 152b side, so that the fluid 180 may have a compression portion 152a at the fluid receiving portion 152b. When moving to the steel ball 330 blocks the second fluid movement path 310 to prevent the fluid from moving, on the contrary the fluid is moved only from the compression unit 152a to the fluid receiving unit 152b The fluid is movable to the two-fluid flow passage 310.

That is, when the door is opened and the piston 160 moves backward from the compression unit 152a of the cylinder 152, the second fluid movement passage 310 is blocked, and the piston 160 is closed by the cylinder 152 as the door is closed. The second fluid movement path 310 is openable only when advancing to the compression unit 152a. However, the steel ball 330 is pressed by the elastic member 340, the pressing force of the elastic member 340 to the depth of tightening by the vertical movement of the hydraulic adjustment screw 350 is fastened to the second outer opening 320 It is formed to regulate. Therefore, the second fluid movement passage 310 is opened only when the pressure of the fluid 180 is greater than the pressure of the elastic member 340. At this time, the hydraulic adjustment screw 350 is screwed and inserted while moving up and down. Since it is possible to adjust the degree, it is possible to reduce the pressure applied to the steel ball of the elastic member 340.

Referring to the operation of the present invention is as follows.

Basically, the fluid movement adjusting unit 200 operates in the same manner both when the door is opened and when the door is closed, thereby controlling the movement amount of the fluid 180 to slowly open and close the door. That is, the hinge shaft 140 rotates as the door opens and closes, so that the compression unit 152a and the fluid receiving unit 152b of the cylinder 152 whenever the piston 160 moves forward or backward in the cylinder 152. The fluid 180 moves between the first fluid movement passage 210, and a movement adjusting screw fastened to the first external opening 220 opened outwardly from one side of the first fluid movement passage 210. 230 to block the part of the first fluid movement passage 210 by the fastening degree to adjust the amount of movement of the fluid 180 so that the piston 160 is not fast forward or backward so that the door rotates slowly It works.

However, when the door is opened, the first hydraulic valve 161 is opened, and the second hydraulic valve 300 operates to shut off.

That is, when the door is opened, the piston 160 is reversed, which causes the piston 160 to pressurize the fluid 180 in the fluid receiving part 152b so that the fluid 180 controls the fluid movement control part 200. It moves from the fluid receiving portion (152b) to the compression portion (152a), and additionally the steel ball (161a) accommodated in the first hydraulic valve 161 by the pressure of the fluid 180 to the first hydraulic valve (161) The fluid 180 moves more quickly from the fluid receiving portion 152b to the compression portion 152a by being separated from the blocked position. Therefore, when the door is opened, the first hydraulic valve 161 is operated to open so that the door is opened quickly. However, in the second hydraulic valve 300, the fluid 180 presses the steel ball 330 which blocks the second fluid movement passage 310 in a direction of blocking, so that the fluid 180 is not opened and does not operate.

On the other hand, when the door is closed, the first hydraulic valve 161 is shut off, and the second hydraulic valve 300 operates to open as necessary.

That is, when the door is closed, the piston 160 is advanced toward the compression unit 152a, which causes the piston 160 to pressurize the fluid 180 in the compression unit 152a and the fluid 180 receives the fluid. It moves to the unit 152b.

This means that the fluid 180 moves from the compression unit 152a to the fluid receiving unit 152b through the fluid movement adjusting unit 200. The amount of the fluid moving through the fluid movement adjusting unit 200 is small so that the piston (160) Because it works slowly, the door closes slowly.

However, in the second hydraulic valve 300, the fluid 180 is pressurized from the compression part 152a to the fluid receiving part 152b, and the fluid receiving body having a large inner diameter is formed in the steel ball 330 in the second fluid moving passage 310. Since the second hydraulic valve 300 is opened and the fluid 180 is movable, the pressure of the fluid is greater than the elastic force of the elastic member 340 holding the steel ball 330. The fluid is movable. Therefore, when the door is closed only by the force of the spring 170, the second hydraulic valve 300 does not operate, and when the user closes the door by applying force, the moving pressure of the fluid 180 is increased, so the fluid The pressure of the overcoming elastic force of the elastic member 340, the fluid 180 pushes the steel ball 330 and moves from the compression portion 152a to the fluid receiving portion 152b to smoothly rotate and close the door.

Meanwhile, the hydraulic control screw 350 is inserted into the second hydraulic control valve 300 by fastening the hydraulic control screw 350 to press the elastic member 340 while pressing the steel ball 330 while moving the hydraulic control screw 350 up and down. The pressing force of the elastic member 340 can be adjusted.

When the pressing force of the elastic member 340 is adjusted, the door is strongly closed by the user because the pressure of the fluid 180 that opens the second hydraulic control valve 300 by pushing the steel ball 330 can be adjusted. The second hydraulic control valve 300 can be adjusted to open only when it loses, and if necessary, the second hydraulic control valve 300 can be adjusted to open when a larger force or a smaller force is applied.

Therefore, the present invention made as described above, if the user pushes or pulls the door closed slowly, to close more quickly, the second hydraulic valve 300 is opened to make the door smoothly closed, but also by adjusting the degree of smooth closing It also eliminates mechanical strain on the hydraulic floor hinges.

As described above, the present invention is coupled to the lower end of the swing door to control the opening of the fluid movement passage to control the rotational movement of the door, the first hydraulic valve to operate when the door is opened, and when the door is closed In this case, the second hydraulic valve which operates only when necessary is provided, and the hydraulic floor hinge which controls the rotation of the door can adjust the operating pressure of the second hydraulic valve so that the user can close the door by pushing or pulling the door that is slowly closed. In this case, the second hydraulic valve is opened to allow the door to be smoothly closed, but the degree of smooth closing is also controlled, so that there is no mechanical force on the hydraulic floor hinge.

Therefore, the mechanical force does not follow, so that it is not easily broken, and as a result, the use durability is increased, as well as the opening and closing operation of the door is soft, and thus the convenience of use is increased.

Claims (1)

Opens and closes only when the piston 160 is retracted from the fluid movement control unit 200 and the compression unit 52a of the cylinder 152 to accommodate the actuators and the fluid inward, and to control the opening degree of the fluid movement passage. A hydraulic floor hinge that controls the operation of the actuators with a possible first hydraulic valve 161 and a second hydraulic valve 300 which can be opened and closed only when the piston 160 is advanced to the compression section 152a of the cylinder 152. In the hydraulic control structure of, The second hydraulic valve 300 is formed so that the compression portion 152a and the fluid receiving portion 152b of the cylinder 152 communicate with each other, and forms a second external opening 320 that is opened to one side to the outside thereof. The steel ball 330 to block the valve, the elastic member 340 for pressing the steel ball 330 and the second outer opening 320 to be movable up and down to adjust the pressing force of the elastic member 340 Hydraulic control structure of the hydraulic floor hinge, characterized in that the hydraulic pressure adjusting screw 350 is formed to be inserted sequentially.