KR100894299B1 - Multiple purpose shock absorber - Google Patents

Abstract

An object of the present invention is to provide a multipurpose shock absorber, the configuration of the present invention is provided so as to be able to move forward and backward in the cylinder 10, the interior of the cylinder 10 to eliminate the internal space of the cylinder (10) A piston valve 20 partitioned into a first chamber 12 and a second chamber 14, a first check valve 40 mounted to the piston valve 20 and opened toward the first chamber 12; And a first spring check valve 50 mounted to the piston valve 20 at an outer position of the first check valve 40 to open toward the second chamber 14, and the cylinder 10. A body valve 30 installed in the second chamber 14 to form a compression chamber 16 at a position opposite to the piston valve 20, and mounted to the body valve 30 in the direction of the second chamber 14; The second check valve 60 is opened to the body valve 30 in the outer position of the second check valve 60 in the direction of the compression chamber 16 The second spring check valve 70 is opened to the pre-piston 80, and the compression chamber 16 and the first chamber 12 are installed so as to be able to move forward and backward in the compression chamber 16. It characterized in that it comprises a hydraulic pressure supply valve installed on the outside of the cylinder (10).

The present invention in the operation of pulling and pushing the weight for the health of the body, by adopting the principle of the shock absorber, which is a kind of hydraulic cylinder instead of the weight, the desired weight and suitable for the physical ability of the person exercising exercise It is effective to select the momentum and exercise. Also, it is a multipurpose shock absorber that can be used in various fields such as shock absorber for automobile shock absorber and shock absorber for building earthquake absorption (vibration absorption). To provide a shock absorber, and to provide a multi-purpose shock absorber configured to control the hydraulic manually and electrically controlled.

In addition, the present invention can be widely used in a variety of fields as described above, the important core functions are composed of a combination of gas, fluid and hydraulic cylinder, in particular, when applied to the warmth mechanism from the young to the elderly at will Provides the effect of adjusting the use.

In addition, the present invention provides the effect of performing the function of a safe exercise equipment given to the self-maintenance function that can be stopped in place at the time of exercise stop without risk of falling, such as weight, further narrow space Even men and women of all ages can expect the effect to exercise safely.

Shock Absorber, Weight, Hydraulic Cylinder, Flow, Control, Safety, Linear Solenoid Valve

Description

Multi purpose shock absorber

The present invention relates to a versatile shock absorber, and more specifically, to exercise physical health by adopting the principle of a shock absorber, which is a kind of hydraulic cylinder, in place of weights such as barbells or dumbbells used in a conventional gymnasium. It is configured to control hydraulic pressure manually so that it can be controlled electronically so that any man and woman of all ages can exercise safely. In addition, shock absorber or shock absorber (vibration absorption) which is a shock absorber for automobiles can be used. The present invention relates to a multipurpose shock absorber that can be used for a wide range of applications such as shock absorbers.

Conventionally, a multipurpose shock absorber using a hydraulic cylinder has been provided and used. In the case of such a conventional multipurpose shock absorber, when a heavy force is applied, that is, the adjustment is set to "0", the flow is prevented from flowing. If it is, the O-ring or oil seal, etc., which prevents the oil from being broken and broken, there is a risk that can lead to a big accident during the movement, and the hydraulic cylinder has a disadvantage that the oil is leaking out properly. In particular, when applied to the exercise equipment, there is a inconvenience that the exercise person must adjust the exercise force only roughly.

The present invention is to solve the above problems, an object of the present invention is to electronically select the desired force by operating the control valve between the voltage 0 ~ 5V and the current 0 ~ 1.3A, the voltage and current In conversion, the spool of the electric linear solenoid moves to open the pipeline, and the oil flows through the appropriately opened orifice pipeline, and when the movement stops, the body stops in that state and the exercise equipment is forced to the human body. Since it stops without any action, it is to provide a new shock absorber of a new configuration that can ensure the safety during exercise.

In addition, the present invention is to provide a manual multi-purpose shock absorber in another embodiment, the object of the present invention to safely enjoy the exercise using hydraulic pressure instead of the conventional exercise method using a weight.

In addition, the present invention is not only applied to the above-described sports equipment, but also for automobile shock absorber shock absorbers, building earthquake absorber (vibration absorber) shock absorbers, bildong automatic door (rotary) shock absorbers, mechanical shock absorber shock absorbers, airplanes and industrial applications. It can be used as an accurate force absorbing shock absorber, tank foam shock absorbing shock absorber, reservoir dam and breakwater shock absorbing shock absorber, fireproof automatic door shock absorber, and as a broad range of shock absorbers in other fields.

According to the present invention for solving the above problems, the cylinder 10 and the inside of the cylinder 10 is installed so as to be forward and backward so that the internal space of the cylinder 10 is the first chamber 12 and the second A piston valve 20 partitioned into the chamber 14, a first check valve 40 mounted to the piston valve 20 and opened toward the first chamber 12, and the first check valve 40 The first spring check valve 50 and the second chamber 14 of the cylinder 10, which is mounted to the piston valve 20 in the outer position of the c) and open in the direction of the second chamber 14, A body valve 30 forming the compression chamber 16 at a position opposite to the piston valve 20, and a second check valve mounted to the body valve 30 and opened in the direction of the second chamber 14; 60 and a second spring check valve 70 mounted to the body valve 30 at an outer position of the second check valve 60 to open toward the compression chamber 16. And a free piston 80 installed in the compression chamber 16 so as to be moved forward and backward, and a hydraulic supply valve installed outside the cylinder 10 so as to be opened in both directions of the compression chamber 16 and the first chamber 12. There is provided a multipurpose shock absorber characterized in that the configuration, including.

According to the present invention, the hydraulic supply valve may be provided with a manual multi-use shock absorber consisting of a manual throttle valve (90).

In addition, according to the present invention, the hydraulic pressure supply valve is composed of a linear solenoid valve 100, the linear solenoid valve 100 is connected to the electric regulator 110, the voltage set in the electric regulator 110 An electric multipurpose shock absorber may be provided that is configured to adjust the opening and closing degree of the linear solenoid valve 100 in response to a value.

In addition, a display device 120 is connected to the electric motor adjusting device 110, and may be configured to convert the voltage value set in the electric motor adjusting device 110 into a kinetic force for display.

According to the embodiment of the present invention, a multipurpose shock absorber having the following effects may be provided.

Conventional shock absorber has only a method of controlling the hydraulic pressure only by the manual throttle valve, but when the manual throttle valve is blocked, there is a problem that the oil seal is broken and the hydraulic oil leaks, but the present invention has a check valve with a spring. Is added to prevent bursting, and digitally quantifies the force to be exercised so that the user can visually check and exercise the internal taper throttle valve inside the linear solenoid valve so that the user can exercise as needed. It is an invention that has the effect of exercising the exercise by adjusting the necessary force at will, and furthermore, the basic science is applied to improve the efficiency of the exercise and manage the physical fitness.

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

1 is a cross-sectional view of a multipurpose shock absorber according to an embodiment of the present invention, FIG. 2 is a hydraulic circuit diagram of the multipurpose shock absorber shown in FIG. 1, and FIG. 3 is a cross-sectional view of a multipurpose shock absorber according to another embodiment of the present invention. 4 is a hydraulic circuit diagram of the multipurpose shock absorber shown in FIG. 3, FIG. 5 is an exploded perspective view of a piston valve which is a main part of the present invention, and FIG. 6 is an exploded perspective view of a body valve which is another main part of the present invention.

In the illustrated multipurpose shock absorber of the present invention, the cylinder 10 and the inside of the cylinder 10 are installed so as to be moved forward and backward so that the internal space of the cylinder 10 may be the first chamber 12 and the second chamber 14. Piston valve 20 is divided into the first, the first check valve 40, which is mounted to the piston valve 20 to open in the direction of the first chamber 12, and the outside of the first check valve 40 A first spring check valve 50 mounted to the piston valve 20 in the position and open in the second chamber 14 direction, and installed in the second chamber 14 of the cylinder 10. A body valve 30 forming the compression chamber 16 at a position opposite to the 20, a second check valve 60 mounted to the body valve 30 and opened toward the second chamber 14; A second spring check valve 70 mounted to the body valve 30 at an outer position of the second check valve 60 and opened toward the compression chamber 16; It comprises a free piston 80 installed in the chamber 16 so as to be able to move forward and backward, and a hydraulic supply valve installed outside the cylinder 10 to open in both directions of the compression chamber 16 and the first chamber 12. do.

1 is a cross-sectional view of a manual multi-use shock absorber that is an embodiment of the present invention, Figure 2 is a hydraulic circuit diagram of the manual multi-use shock absorber shown in FIG.

1 and 2, the passive multipurpose shock absorber of the present invention is installed in the cylinder 10 and in the cylinder 10 so as to be movable forward and backward so that the internal space of the cylinder 10 may be formed in the first chamber 12 and the first chamber. A piston valve 20 partitioned into two chambers 14, a first check valve 40 mounted to the piston valve 20 and open toward the first chamber 12, and the first check valve 40 The first spring check valve 50 which is mounted to the piston valve 20 at an outer position of the valve and is opened in the direction of the second chamber 14, and which is installed in the second chamber 14 of the cylinder 10. A body valve 30 forming the compression chamber 16 at a position opposite to the 20, a second check valve 60 mounted to the body valve 30 and opened toward the second chamber 14; And a second spring check valve 70 mounted to the body valve 30 at an outer position of the second check valve 60 to open toward the compression chamber 16 and forward and backward to the compression chamber 16. Install And a hydraulic supply valve installed outside the cylinder 10 to open in both directions of the compression chamber 16 and the first chamber 12, wherein the hydraulic supply valve is a manifold 6. It consists of a manual throttle valve 90 is installed to open in both directions of the compression chamber 16 and the first chamber 12 of the cylinder (10) through.

The first check valve 40 and the arc-shaped through-hole 42 is formed in an elastic plate shape. As shown in FIG. 5, the first check valve 40 is formed by a washer 21a, a retainer 24a, a leaf spring 24b, a step retainer 24c, a valve washer 24d and a nut 24e. It is installed on one side of the piston valve 20 (that is, the surface facing the first chamber 12 of the cylinder 10), the second check valve 60 is an elastic plate formed with an arc-shaped through-hole 62 As shown in FIG. 6, the other side of the body valve 30 (ie, the cylinder 10) is formed by the pin 34a, the washer 34b, the suction spring 34c, and the retainer 34d. On the side facing the compression chamber 16).

The first check valve 40 and the second check valve 60 are configured in the shape of an elastic plate formed with arc-shaped through holes 42 and 62, respectively, so that the first check valve 40 and the second check valve 60 can be bent by hydraulic pressure inside the cylinder 10. .

In addition, the first spring check valve 50 is formed in an elastic plate shape that covers the second hydraulic communication passage 22b passing through the piston valve 20, so that the first chamber 12 of the cylinder 10 The hydraulic communication path 22 is opened while being bent in the direction of the second chamber 14 by the hydraulic pressure.

At this time, the hydraulic communication path 22 is formed to be inclined toward the other surface from one surface of the piston valve 20, the first spring check valve 50 to the hydraulic communication path 22 on the other surface of the piston valve (20). To cover.

In addition, the second spring check valve 70 is configured in the shape of an elastic plate covering the orifice hole 32 penetrating the body valve 30, by the hydraulic pressure of the second chamber 14 of the cylinder 10 The hydraulic pressure is supplied to the compression chamber 16 through the orifice hole 32 while being bent in the direction of the compression chamber 16.

In other words, as shown in FIG. 5, the hydraulic communication passage 22 is a pair of first hydraulic communication passage 22a and a second hydraulic communication passage formed so as to be inclined from one surface of the piston valve 20 to the other surface. 22b, the first check valve 40 covers the first hydraulic communication passage 22a on one surface of the piston valve 20, and the first spring check valve 50 includes a piston. The other side of the valve 20 covers the second hydraulic communication passage 22b.

A hole 33 and an orifice hole 32 are formed in the body valve 30, and the second check valve 60 covers the hole 33 on one surface of the body valve 30, and a second spring check valve. The 70 is formed in an elastic plate shape that covers the orifice hole 32 on the other side of the body valve 30, the second spring check valve 70 by the hydraulic pressure of the second chamber 14 of the cylinder 10 ) Is bent toward the compression chamber 16 so that the hydraulic pressure is supplied to the compression chamber 16 through the orifice hole 32.

On the other hand, Figures 3 and 4 show an electric multipurpose shock absorber which is another embodiment of the present invention, the electric multipurpose shock absorber is a hydraulic supply valve is composed of a linear solenoid valve 100, the linear solenoid valve 100 is electric adjustment The device 110 is connected and configured to adjust the opening and closing degree of the linear solenoid valve 100 in response to the voltage value set in the electric regulator 110.

In addition, a display device 120 is connected to the electric control device 110, and converts and displays the voltage value set in the electric control device 110 into exercise force, thereby visualizing the force that the exerciser is currently exercising. Added a function to check.

On the other hand, according to the present invention, a plurality of the first spring check valve 50 and the second spring check valve 70 is arranged to overlap.

Hereinafter, with reference to the accompanying drawings will be described the operation of the present invention of the above configuration.

In the manual type currently used in the prior art, only the manual throttle valve 90 exists and the check valves 40 and 60 and the spring-loaded check valves, that is, the first spring check valve 50 and the second spring check valve 70 are If the cylinder is completely blocked and operated, the cylinder 10 may burst due to overload or the oil seal may be destroyed.

By the way, according to the manual multi-use shock absorber of the present invention according to Figs. 1 and 2, when the exerciser grabs the handle (not shown) connected to the rod and pulls the piston valve, the manual throttle valve 90 (exactly speaking) , The flow rate reduced through the ball valve is converted into a force to feel the force is small for humans to feel, and the fluid passed through the lower cap 34 (shown in Figures 1 and 3) The free piston (80) is pushed to fill the compression chamber (16) filled with nitrogen (N2) gas, and the remaining hydraulic oil pushes the second check valve 60 of the body valve 30 again to the cylinder 10. It enters into the second chamber 14 to achieve an equilibrium.

At this time, when the manual throttle valve (90) is locked at any time, a person pulls the rod and the piston valve (20) due to the inertia force to continue to move, and the hydraulic oil in the first chamber (12) of the cylinder (10) has no place to escape. As a result, the first spring check valve 50 is moved to the cylinder 10 while beating the elastic force of the first spring check valve 50 mounted on the piston body (that is, the force of the first spring check valve 50 having a leaf spring shape). Since it is bent in the direction of the second chamber 14 of), the oil pressure of the first chamber 12 is released to the second chamber 14, it is possible to prevent the oil seal burst and leakage, which is the present invention It is a feature of the versatile shock absorber.

Meanwhile, the operating principle of the electric multipurpose shock absorber of the present invention shown in FIGS. 3 and 4 is the same as the manual multipurpose shock absorber of FIG. 1 described above, but instead of the manual throttle valve 90, the linear solenoid valve 100 is It is attached so that the digital value can be visually confirmed through the display device 120. In other words, Figure 3 and Figure 4 is a feature of the invention that it is possible to adjust the movement force by electric (electronic).

Referring to the electric multipurpose shock absorber of FIGS. 3 and 4, when a person pulls the rod 18 and the piston valve 20 to exercise, the hydraulic oil filled in the first chamber 12 of the cylinder 10 Pass the manifold (6) and the automatic tapered throttle valve in the linear solenoid valve (100), when the momentum is fully opened at 5V, the hydraulic pressure flows in the no-load state, the person who does not have any resistance Pulling exercise equipment will occur.

At this time, the flowing hydraulic pressure exits the manifold 6 again and enters the compression chamber 16 to push out the free piston 80, and the remaining oil passes through the second check valve of the body valve 30 to the cylinder 10. It is introduced into the second chamber 14 of the, while maintaining the equilibrium while filling the volume of the rod 18 and the piston valve 20 which is coming out. At this time, the piston valve 20, which was in motion when the electric regulator 110 was blocked with "0" V, was stopped because the automatic tapered throttle valve 102 (shown in FIG. 4) was completely blocked.

When the power regulator opens the voltage to 5V and stops the pulling motion, and starts pushing the rod and the piston again, the first check valve 40 for compression of the piston valve 20 is opened and the first chamber 12 is opened. Since the internal hydraulic pressure rises toward the compression chamber 16 of the cylinder 10 and at the same time the volume of the rod and the piston valve 20 is pushed in, the volume increases, so that the first chamber 12 of the cylinder 10 is increased. The hydraulic pressure inside was again passed through the automatic taper throttle valve 102 of the linear solenoid valve 100 through the manifold 6 to push the free piston 80 and replenished oil in the compression chamber 16 again. Enters the cylinder 10 and cycles repeatedly.

Accordingly, the conventional mechanism applied to the hydraulic cylinder 10, when the flow valve is clogged when the phenomenon occurs, but in the present invention, in order to solve this problem, the piston valve 20 and the body valve 30 is a safety valve The function of the check valves 40 and 60 is prevented from bursting. The hydraulic supply valve, that is, the manual type throttle valve 90 and the electric type taper throttle valve 102 of the linear throttle valve 100 are provided. When blocked, the spring check valve (50, 70) is opened to provide an effect that can act as a safety valve.

In addition, in the prior art, the person who wants to exercise has been sensibly adjusting the exercise force by turning the handle, but in the present invention, in order to solve this problem, an automatic tapered throttle valve 102 is built into the electronic (electric) linear solenoid and digitally installed. If the user wants to exercise by the exercise force, for example, 100kgf, by converting the digital input of 100kgf corresponding to 1V, the effect of automatically checking the 100kgf displayed on the display device 120 by the eye and exercising To provide.

By controlling the opening and closing degree of the linear solenoid valve 100, converting the amount of exercise into a force, converting the converted exercise force to digital to display on the display device 120 will be a feature of the electric multipurpose shock absorber.

On the other hand, Figure 5 is an exploded perspective view of the piston valve 20, which is the main part of the present invention, according to the piston valve 20 shown in Figure 5, by moving the piston valve 20 to the end of the rod as shown in the figure When a person presses (pushes) the piston valve 20, the first check valve 40 is opened so that hydraulic pressure can be passed freely, and when lifted (pull), the first check valve 40 C) is clogged and suddenly clogged, the first spring check valve (50) of the disk type safety valve bends toward the second chamber (14) of the cylinder (10) and the oil pressure escapes to prevent the oil seal from bursting. This is an invention which makes a characteristic of this invention.

In addition, Figure 6 is an exploded perspective view of the body valve 30, which is another main part of the present invention, explaining the function of the body valve 30 shown in Figure 6, when pulling the piston valve 20 (tension) While the second check valve 60 is opened to supply the hydraulic pressure from the compression chamber 16 toward the second chamber 14, while the piston valve 20 is pushed (when compressed), the second check valve 60 ) And the hydraulic pressure passing through the orifice hole 32 having a diameter of 0.5 mm causes the disk-type second spring check valve 70 to be bent toward the compression chamber 16, thereby opening the orifice hole 32 and bursting. To prevent. At this time, the free piston 80 is pushed back while compressing the charged nitrogen gas while the piston valve 20 and the rod 18 is pushed into the cylinder 10 inside direction (that is, the body valve 30 direction) increases It is to achieve the equilibrium by absorbing the volume to be, which is a feature of the present invention.

On the other hand, the present invention has been described in the embodiment applied to the exercise shock absorber, but in addition to the shock absorber shock absorber for automobiles, the shock absorber shock absorber, building earthquake absorption (vibration absorption) shock absorber, bildong automatic door (rotary) Shock absorbers, mechanical shock absorbing shock absorbers, accurate force absorbing shock absorbers for aircraft and industrial applications, tank foam shock absorbing shock absorbers, reservoir dams and breakwater shock absorbing shock absorbers, fire door automatic shock absorbers, and other It can be used as shock absorber.

The performance of the present invention is that the same force acts in exactly the symmetrical compression and tension, it is possible to implement a safer and more reliable shock absorber.

In addition, the function of the present invention can be attached to the manual adjustment and the automatic adjustment function of the above uses, it will be said that the features of the present invention in this respect.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

1 is a cross-sectional view of a multipurpose shock absorber according to an embodiment of the present invention

2 is a hydraulic circuit diagram of the multipurpose shock absorber shown in FIG.

3 is a cross-sectional view of the multipurpose shock absorber according to another embodiment of the present invention.

4 is a hydraulic circuit diagram of the multipurpose shock absorber shown in FIG.

5 is an exploded perspective view of a piston valve which is an essential part of the present invention;

6 is an exploded perspective view of a body valve which is another main part of the present invention;

Claims (14)

delete delete delete delete delete delete The cylinder 10 and the inside of the cylinder 10 are installed so as to be moved forward and backward to partition the inner space of the cylinder 10 into the first chamber 12 and the second chamber 14 and the first inside A first hydraulic communication passage 22a and a second hydraulic communication passage 22b communicating with the chamber 12 and the second chamber 14 are formed, and the first hydraulic communication passage 22a and the second hydraulic communication passage are formed. The furnace 22b is elastically formed with a piston valve 20 and an arcuate through-hole 42 formed to be inclined toward the other surface facing the second chamber 14 from one surface facing the first chamber 12. A first check valve 40 formed in a plate shape and covering the second hydraulic communication path 22b on one surface of the piston valve 20 and open in the direction of the first chamber 12; An elastic plate shape is formed to cover the second hydraulic communication passage 22b penetrating through 20. The second chamber 14 is opened by the hydraulic pressure of the first chamber 12 of the cylinder 10. To the first spring check valve 50 and the second chamber 14 of the cylinder 10 to be opened to the second hydraulic communication path 22b while being bent in a position opposite to the piston valve 20. The body valve 30 is formed in the compression chamber 16 and the body valve 30 formed with a hole 33 and an orifice hole 32, and an elastic plate shape having an arc-shaped through hole 62. The second check valve 60 covering the hole 33 on one side thereof and opening toward the second chamber 14 and the orifice hole 32 of the body valve 30. A second spring check valve 70 provided on the other surface of the valve 30 and opened toward the compression chamber 16, a free piston 80 provided in the compression chamber 16 so as to be movable forward and backward, and the compression Including a manual throttle valve (90) installed on the outside of the cylinder 10 to open the seal 16 and the first chamber 12 in both directions Multipurpose shock absorber characterized in that the configuration. delete delete delete delete delete delete The cylinder 10 and the inside of the cylinder 10 are installed so as to be moved forward and backward to partition the inner space of the cylinder 10 into the first chamber 12 and the second chamber 14 and the first inside A first hydraulic communication passage 22a and a second hydraulic communication passage 22b communicating with the chamber 12 and the second chamber 14 are formed, and the first hydraulic communication passage 22a and the second hydraulic communication passage are formed. The furnace 22b is elastically formed with a piston valve 20 and an arcuate through-hole 42 formed to be inclined toward the other surface facing the second chamber 14 from one surface facing the first chamber 12. A first check valve 40 formed in a plate shape and covering the second hydraulic communication path 22b on one surface of the piston valve 20 and open in the direction of the first chamber 12; An elastic plate shape is formed to cover the second hydraulic communication passage 22b penetrating through 20. The second chamber 14 is opened by the hydraulic pressure of the first chamber 12 of the cylinder 10. To the first spring check valve 50 and the second chamber 14 of the cylinder 10 to be opened to the second hydraulic communication path 22b while being bent in a position opposite to the piston valve 20. The body valve 30 is formed in the compression chamber 16 and the body valve 30 formed with a hole 33 and an orifice hole 32, and an elastic plate shape having an arc-shaped through hole 62. The second check valve 60 covering the hole 33 on one side thereof and opening toward the second chamber 14 and the orifice hole 32 of the body valve 30. A second spring check valve 70 provided on the other surface of the valve 30 and opened toward the compression chamber 16, a free piston 80 provided in the compression chamber 16 so as to be movable forward and backward, and the compression A linear solenoid valve 100 installed outside of the cylinder 10 to open in both directions of the seal 16 and the first chamber 12, Group versatile Shock absorber, characterized in that configured to include a linear solenoid valve an electric adjustment device 110 in response to a voltage value that is set is connected to 100, which control the opening degree of the linear solenoid valve 100.

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