KR101373716B1 - Hydraulic cylinder apparatus provided with diaphragm ring type cushion member - Google Patents

Abstract

Hydraulic cylinder device provided with a cushion member in the form of an aperture ring according to the present invention, the hollow formed cylinder; A rod slidably installed in the cylinder; A piston fixed to one end of the rod and slidable in contact with the inner circumferential surface of the cylinder; A piston nut fixed to the rod while supporting one surface of the piston to prevent the piston from being separated from the rod; And a head cover fixed to one end of the cylinder and provided with a flow path for supplying pressure oil to the piston from the outside, wherein the hydraulic cylinder device is formed at one end of the rod and has an outer diameter greater than a portion to which the piston is coupled. A cushion guided portion formed small; An aperture ring coupled to an outer circumference of the cushion induction part so as not to be separated from the cushion induction part, and formed in a ring shape spaced apart from an outer circumferential surface of the cushion induction part; A spring having one end supporting the diaphragm ring and the other end arranged to be supported by the piston nut to apply elastic restoring force away from the piston; And an entrance groove provided in the head cover to receive the cushion induction part, wherein the entrance groove is connected to the flow path.

Description

Hydraulic cylinder apparatus provided with diaphragm ring type cushion member

The present invention relates to a hydraulic cylinder device, and more particularly to a cushion structure that mitigates the impact between the rod and the head cover during rod compression operation.

Hydraulic cylinder devices are generally mechanical devices that generate a large force using a small amount of oil using the principle of Pascal. Hydraulic cylinder devices are widely used in various industries.

The hydraulic cylinder device is a mechanical device that can work outside by the extension or compression of the rod by the hydraulic pressure applied to the piston. However, in general, the hydraulic cylinder device is provided with a cushion structure that prevents the main parts from being damaged by collision of the end of the rod or the piston and the head cover when the rod is in compression operation. An example of such a cushion structure is disclosed in Korean Patent Laid-Open Publication No. 2007-0063205.

1 shows the structure of a conventional hydraulic cylinder device. Referring to Figure 1, a brief description will be given of the cushion operating principle of a conventional hydraulic cylinder device.

Referring to FIG. 1, the hydraulic cylinder device 1 includes a rod 3 and a piston 4 slidably installed in a cylinder 2 in which a hollow is formed. In the hydraulic cylinder device 1, a head cover 5 having a flow path 6 through which hydraulic oil (oil) flows in and out is fixed to one end of the cylinder 2. In addition, the cushion plunger 7 is provided as a shock absorbing structure for preventing the end of the rod 3 from suddenly colliding with the head cover 5 when the rod 3 is in compression operation. The cushion plunger 7 is coupled to the end of the rod 3 in a floatable state by a stop ring 8. The head cover 5 has an entry groove 9 through which the cushion plunger 7 can enter, and the entry groove 9 is connected to the flow path 6. When the cushion plunger 7 enters the entry groove 9, a space in which oil can flow in the entry groove 9 is reduced, and the rod 3 is connected to the head cover 5 by the pressure. A sudden collision is prevented. In addition, a separate orifice is provided between the hollow part of the cylinder 2 and the flow path 6 so that the reaction force of the cushion plunger 7 enters the entrance groove 9 so as not to generate excessive reaction force. have. A check valve 11 is provided at a portion connecting the orifice 10 and the flow path 6. The check valve 11 serves to smoothly expand the operation by supplying sufficient oil to the piston 4 during the extension operation of the rod (3).

However, since the conventional hydraulic cylinder device 1 having the above-described structure cannot be configured to have a large diameter of the cushion plunger 7 in reality, the cross section of the rod 3 side and the head cover 5 side when the cushion is operated. The difference in cross-sectional area is so large that the cushion feeling is not smooth and rough. In addition, since the conventional hydraulic cylinder device 1 has to configure the cushion plunger 7 in a floating form, it is difficult to assemble the cushion plunger 7 in a large cylinder, which is likely to cause a problem of assembly failure. In addition, since the check valve 11 is added, there is a problem in that the number of parts is increased and manufacturing cost is high and productivity is deteriorated.

An object of the present invention is to provide a hydraulic cylinder device that is devised to solve the above problems, the structure is simple, the cushion performance is good, the manufacturing cost is reduced and productivity is improved.

Hydraulic cylinder device with a cushion member in the form of an aperture ring according to an embodiment of the present invention to achieve the above object, the hollow formed cylinder;

A rod slidably installed in the cylinder;

A piston fixed to one end of the rod and slidable in contact with the inner circumferential surface of the cylinder;

A piston nut fixed to the rod while supporting one surface of the piston to prevent the piston from being separated from the rod; And

In the hydraulic cylinder device including; a head cover is fixed to one end of the cylinder and provided with a flow path for supplying pressure oil to the piston from the outside,

A cushion guide part formed at one end of the rod and having an outer diameter smaller than a portion at which the piston is coupled;

An aperture ring coupled to an outer circumference of the cushion induction part so as not to be separated from the cushion induction part, and formed in a ring shape spaced apart from an outer circumferential surface of the cushion induction part;

A spring having one end supporting the aperture ring and the other end being supported by the piston nut to apply an elastic restoring force away from the piston; And

An entrance groove provided in the head cover to accommodate the cushion induction part;

The entry groove is characterized in that it is connected to the flow path.

It is preferable that the aperture ring is not separated from the cushion guide part by a stop ring coupled to the stop ring coupling groove formed on the cushion guide part.

Preferably, the head cover includes an aperture ring engaging portion formed concave to receive a portion of the aperture ring at a portion in contact with the aperture ring.

The aperture ring has a taper portion formed in a tapered shape on an outer circumferential surface of a portion accommodated in the aperture ring coupling portion,

It is preferable that the aperture ring coupling portion has a shape corresponding to the tapered portion.

Preferably, the spring has a larger outer diameter as it approaches the piston nut from the aperture ring.

The aperture ring is preferably provided with a spring support groove coupled to one end of the spring so that the spring can be stably supported.

Hydraulic cylinder device according to the present invention by integrally forming a cushion guide portion to act as a cushion plunger to the rod and adjust the cushion filling through the aperture ring, the hydraulic cylinder with a simple structure, good cushioning performance, reduced manufacturing costs and improved productivity Provide the effect of providing the device.

1 is a view for explaining the cushion structure of a conventional hydraulic cylinder device.
2 is a view for explaining the cushion structure of the hydraulic cylinder device according to an embodiment of the present invention.
3 is a view illustrating an extended state of the hydraulic cylinder device illustrated in FIG. 2.
4 is a view showing the shape of the stop ring shown in FIG.
5 is a view showing the shape of the aperture ring shown in FIG.

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

2 is a view for explaining the cushion structure of the hydraulic cylinder device according to an embodiment of the present invention. 3 is a view illustrating an extended state of the hydraulic cylinder device illustrated in FIG. 2. 4 is a view showing the shape of the stop ring shown in FIG. 5 is a view showing the shape of the aperture ring shown in FIG.

2 to 5, the hydraulic cylinder device 100 (hereinafter, referred to as a “hydraulic cylinder device”) equipped with a cushioning member in the form of an aperture ring according to a preferred embodiment of the present invention includes a cylinder 110 and a rod ( 120, a cushion guide part 122, a piston 130, a piston nut 140, an aperture ring 160, a spring 170, and a head cover 150.

The cylinder 110 may generally be manufactured by a casting method of a metal material to have a hollow portion therein. The hollow part is formed in the longitudinal direction of the cylinder 110. The hollow part is formed to penetrate the cylinder 110. Openings are formed at both ends of the cylinder 110. The cylinder 110 may be made of a material such as carbon steel.

The rod 120 is disposed inside the cylinder 110 and is slidably installed in the cylinder 110. One end of the rod 120 may be exposed to the outside of the cylinder 110. The rod 120 is a rod-shaped member. In general, the cross section of the rod 120 is circular. One end of the rod 120 is located in the cylinder 110. The other end of the rod 120 is exposed to the outside of the cylinder 110. That is, the rod 120 is installed to reciprocate in the longitudinal direction of the cylinder 110. That is, the rod 120 is slidably installed in the hollow cylinder.

One end of the rod 120, the cushion guide portion 122 is formed. The cushion induction part 122 is formed to have an outer diameter smaller than a portion to which the piston 130 to be described later is coupled. The cushion guide part 122 performs a role similar to that of the cushion plunger provided in the conventional hydraulic cylinder device. Since the cushion guide part 122 is integrally formed with the rod 120, a separate assembly process is not required. Thus, the structure is simplified. The outer circumferential surface of the cushion induction part 122 is provided with a stop ring coupling groove 124. The stop ring coupling groove 124 is a portion to which the stop ring 126 to be described later is coupled. The stop ring coupling groove 124 is formed in a circumferential shape along the outer circumferential surface of the cushion induction part 122. The stop ring 126 is coupled to the stop ring coupling groove 124. The stop ring 126 is a member of "C" shape as shown in FIG. The stop ring 126 may be coupled to or separated from the stop ring coupling groove 124 by appropriately applying an external force using an elastic deformation. The outer diameter of the stop ring 126 is greater than the size of the outer diameter of the cushion guide portion 122 in a state coupled to the stop ring engaging groove 124.

The piston 130 is fixed to one end of the rod 120. The piston 130 is arranged to be slidable in contact with the inner circumferential surface of the cylinder 110.

The piston nut 140 is fixed to the rod 120 while supporting one surface of the piston 130. In general, the piston nut 140 is screwed to the rod 120, and is configured so as not to be separated from the rod 120 by a fixing pin 142 in some cases. That is, the piston nut 140 serves to prevent the piston 130 from being separated from the rod 120.

The head cover 150 is fixed to one end of the cylinder 110. The head cover 150 may be fixed to the cylinder 110 by welding, screwing, forcing or the like. The head cover 150 includes a flow path 152, an entrance groove 154, and an aperture ring coupling part 156.

The flow path 152 is a flow path for supplying pressure oil to the piston 130 disposed inside the cylinder 110 from the outside of the head cover 150. The entry groove 154 is connected to or formed as part of the flow path 152. The entrance groove 154 is a portion for receiving the cushion guide part 122. Therefore, the entrance groove 154 is disposed in the longitudinal direction of the rod 120, and is disposed coaxially with the rod 120. One end of the entry groove 154 is connected to the cylinder 110 and the other end is connected to the flow path 152. The aperture ring coupling part 156 is provided on the head cover 150. More specifically, the aperture ring coupling portion 156 is recessed to receive a portion of the aperture ring 160 at a portion in contact with the aperture ring 160.

The aperture ring 160 is a ring-shaped member as shown in FIG. The aperture ring 160 is coupled to the outer circumference of the cushion induction part. The inner diameter of the inner circumferential surface of the aperture ring 160 is larger than the outer diameter of the cushion guide part 122. In addition, the size of the inner diameter of the inner peripheral surface of the aperture ring 160 is smaller than the size of the outer diameter of the stop ring 126. Therefore, the aperture ring 160 is not separated from the cushion guide part by engaging the stop ring 126. In addition, a gap is formed between the outer circumferential surface of the cushion guide part 122 and the inner circumferential surface of the aperture ring 160. The gap formed between the aperture ring 160 and the cushion guide part 122 plays a key role in softening the cushion filling during the compression operation of the rod 120. The aperture ring 160 has a spring support groove 164 coupled to one end of the spring 170 so that the spring 170 to be described later can be stably supported. The aperture ring 160 includes a taper portion 162 formed in a tapered shape on an outer circumferential surface of a portion accommodated in the aperture ring coupling portion 156. The tapered portion 162 may be easily understood with reference to the drawing shown in FIG. 5. The head cover 150 has a shape corresponding to the tapered portion 162. That is, the aperture ring coupling part 156 provided on the head cover 150 is provided with a shape corresponding to the taper part 162 as shown in FIG.

The spring 170 is disposed between the piston nut 140 and the aperture ring 160. The spring 170 is fitted to the cushion guide part 122. More specifically, one end of the spring 170 supports the aperture ring 160. On the other hand, the other end of the spring 170 is supported by the piston nut 140. The spring 170 is a compression coil spring is employed. Thus, the spring 170 exerts an elastic restoring force toward the aperture ring 160 away from the piston 130. Preferably, the spring 170 has a larger outer diameter as it approaches the piston nut 140 from the aperture ring 160. The spring 170 has a tapered structure as a whole so that the force acting on the aperture ring 160 effectively works while the rod 120 is extended.

Hereinafter, the operation and effect of the hydraulic cylinder device 100 having the above-described configuration will be described in detail with reference to a process of compressing and extending the hydraulic cylinder device 100 as an example.

The hydraulic cylinder device 100 shown in FIG. 2 shows a state in which the rod 120 is almost compressed. 3 shows an extended state of the hydraulic cylinder device 100. The behavior that occurs when the rod 120 is compressed from the extended state as shown in FIG. 3 to the state shown in FIG. 2 will now be described in detail. In the state in which the rod 120 is extended, the cushion guide part 122 is completely separated from the entrance groove 154, and the aperture ring 160 is in close contact with the stop ring 126. It is supported by the spring 170. In this state, when the oil passage 152 of the head cover 150 is opened and the hydraulic oil is leaked to the outside and the hydraulic oil is supplied to the rod cover 180, the piston 130 moves toward the head cover 150. Since the piston 130 and the rod 120 are integrally coupled, the cushion guide part 122 approaches the entrance groove 154 as the piston 130 moves toward the head cover 150. Since the cushion induction part 122 starts to be accommodated in the entry groove 154, the amount of pressure oil flowing out toward the flow path 152 through the entry groove 154 decreases rapidly, thereby reducing the pressure of the rod 120. Reaction force occurs. In addition, as the cushion guide part 122 is gradually accommodated in the entrance groove 154, the aperture ring 160 contacts the head cover 150. More specifically, the taper portion 162 of the aperture ring 160 is coupled to the aperture ring coupling portion 156. In this state, the aperture ring 160 may no longer move toward the head cover 150. However, the cushion guide part 122 is moved until it hits the wall formed inside the entrance groove 154. In this process, the aperture ring 160 is pushed toward the piston nut 140 by the elastic deformation of the spring 170. However, since there is a gap between the inner circumferential surface of the aperture ring 160 and the cushion guide part 122, the pressure oil existing inside the cylinder 110 passes between the aperture ring 160 and the cushion guide part 122. By passing through the entry groove 154 may move to the flow path (152). In this process, the gap formed between the aperture ring 160 and the cushion guide part 122 serves as an orifice, thereby softening the cushion filling. That is, the gap between the inner circumferential surface of the aperture ring 160 and the cushion guide part 122 serves as an orifice and a check valve provided in the conventional hydraulic cylinder device. In addition, the cushion guide part 122 formed integrally with the rod 120 performs the same function as the conventional cushion plunger.

Meanwhile, the process of changing from the compressed state shown in FIG. 2 to the stretched state shown in FIG. 3 is as follows.

The pressure oil introduced into the flow path 152 from the outside exerts pressure on the aperture ring 160 through the entry groove 154. The aperture ring 160 is in contact with the head cover 150 by the spring 170. At this time, the spring ring 170 is compressed by the applied pressure oil, and the aperture ring 160 is connected to the head cover 150. Separated from. Now, the pressure oil introduced through the flow path 152 and the entrance groove 154 pushes the piston 130 in the direction in which the piston 130 extends through the gap between the aperture ring 160 and the head cover 150. Accordingly, the rod 120 moves in a direction away from the head cover 150 together with the piston 130. When the cushion induction part 122 is completely out of the entrance groove 154, the pressure applied to the normal piston 130 is increased to perform normal stretching operation. In addition, the aperture ring 160 is restored to a state in which it is in close contact with the stop ring 126 by being pressed by the spring 170. In this process, the gap formed between the aperture ring 160 and the cushion induction part 122 serves as a check valve installed in the conventional hydraulic cylinder device so as to be a smooth operation during the initial stretching operation.

 As described above, the cushion induction part 122 and the diaphragm ring 160 perform the action performed by the conventional cushion plunger, the orifice and the check valve, and thus the structure is simpler than the conventional hydraulic cylinder device. Since the number of components to be performed is reduced, the manufacturing cost is reduced and the productivity of the hydraulic cylinder device with remarkable productivity is improved. In addition, by varying the interval between the inner peripheral surface of the aperture ring and the outer peripheral surface of the cushion guide portion can be adjusted cushioning. The realization of such an operation can be realized simply by manufacturing various sizes of the inner circumferential surface of the aperture ring. In addition, the hydraulic cylinder device according to the present invention has the effect of alleviating the cushion initial inlet impact and end impact that can occur in the conventional cushion plunger structure to improve cushion filling. In addition, since the cushion guide portion is not a floating type but a fixed structure, the impact can be reduced by reducing the difference in cross-sectional area as compared with the conventional cushion plunger structure.

As described above, the hydraulic cylinder device according to the present invention employs a cushion member in the form of an aperture ring, and thus, a hydraulic cylinder device having a simple structure, good cushioning performance, reduced manufacturing cost, and improved productivity can be provided as compared with a conventional hydraulic cylinder device. Can be.

While the present invention has been described with reference to the preferred embodiments, it is to be understood that the invention is not to be limited by the example, and various changes and modifications may be made without departing from the spirit and scope of the invention.

100: hydraulic cylinder device with a cushion member in the form of an aperture ring
110: cylinder 120: rod
122: cushion guide portion 124: stop ring engaging groove
126: stop ring 130: piston
140: piston nut 142: fixing pin
150: head cover 152: euro
154: entrance groove 156: aperture ring coupling
160: aperture ring 162: tapered portion
164: spring support groove 170: spring
180: rod cover

Claims (6)

A cylinder in which the hollow part is formed;
A rod slidably installed in the cylinder;
A piston fixed to one end of the rod and slidable in contact with the inner circumferential surface of the cylinder;
A piston nut fixed to the rod while supporting one surface of the piston to prevent the piston from being separated from the rod; And
In the hydraulic cylinder device including; a head cover is fixed to one end of the cylinder and provided with a flow path for supplying pressure oil to the piston from the outside,
A cushion guide part formed at one end of the rod and having an outer diameter smaller than a portion at which the piston is coupled;
An aperture ring coupled to an outer circumference of the cushion induction part so as not to be separated from the cushion induction part, and formed in a ring shape spaced apart from an outer circumferential surface of the cushion induction part;
A spring having one end supporting the diaphragm ring and the other end arranged to be supported by the piston nut to apply elastic restoring force away from the piston; And
An entrance groove provided in the head cover to accommodate the cushion induction part;
The entrance groove is provided with a cushion member in the form of an aperture ring, characterized in that connected to the flow path,
And the diaphragm ring is not separated from the cushion induction part by a stop ring coupled to the stop ring engaging groove formed in the cushion induction part. delete The method of claim 1,
The head cover is provided with a diaphragm ring engaging portion formed to be recessed to receive a portion of the aperture ring in contact with the aperture ring; Hydraulic cylinder device with a cushion member in the form of an aperture ring. The method of claim 3,
The aperture ring has a taper portion formed in a tapered shape on an outer circumferential surface of a portion accommodated in the aperture ring coupling portion,
The aperture ring coupling portion is provided with a cushion member in the form of an aperture ring, characterized in that provided with a shape corresponding to the tapered portion. The method of claim 1,
The spring is a hydraulic cylinder device with a cushion member in the form of an aperture ring, characterized in that the outer diameter is formed larger as the piston nut closer to the piston nut. The method of claim 1,
The aperture ring is a hydraulic cylinder device with a cushion member in the form of an aperture ring, characterized in that it has a spring support groove coupled to one end of the spring so that the spring can be stably supported.

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