KR102331788B1 - Linear scale magnetization protection for controlling hydraulic cylinder position - Google Patents

Abstract

The present invention is to provide a linear scale anti-magnetization bush system for controlling the position of a hydraulic cylinder, the configuration of the present invention is a cylinder tube 20; a ram 26 slidably coupled to the inside of the cylinder tube 20; a linear scale 30 mounted on the cylinder tube 20; and a bush 40 provided between the coupling portion of the linear scale 30 and the cylinder tube 20, wherein the cylinder tube 20 has a front cover 22 and a rear cover ( 24) is coupled, the rear cover 24 has a bush seating groove at an outer end thereof, the linear scale 30 is coupled to the bush seating groove, and the bush seating groove and the linear scale 30 ), characterized in that the bush 40 is interposed between the front end.

Description

Linear scale magnetization protection for controlling hydraulic cylinder position

The present invention relates to a linear scale anti-magnetization bush system for controlling the position of a hydraulic cylinder, and more particularly, a new configuration that can prevent the hydraulic oil of the hydraulic cylinder from leaking and prevent the magnetic force of the magnet for detecting the position of the linear scale from weakening It relates to a linear scale anti-magnetization bush system for controlling the position of a hydraulic cylinder of

In general, gunpowder is used for a variety of purposes, such as for blasting or flashing. In this case, a process of dehydrating impurities such as moisture and organic matter from the raw material of gunpowder is required to make gunpowder for manufacturing explosives or flash bombs.

In order to dehydrate impurities such as moisture from the gunpowder raw material, a dehydrator for the manufacture of gunpowder is used. Gunpowder fuel is filled in a plurality of baskets provided in the turntable of the dehydrator for producing explosives, and the turntable is rotated to press the raw material for the gunpowder several times by means of a press, thereby dehydrating moisture and the like.

On the other hand, in the press, a press plate is coupled to a ram that moves forward and backward by a hydraulic cylinder, and a linear scale is provided on the cylinder body of the hydraulic cylinder, and the ram of the hydraulic cylinder advances to press the gunpowder raw material filled in the basket of the turntable. By pressing the plate, impurities such as moisture and oil (oil component) are dehydrated from the raw material of the gunpowder. A linear scale is required because it is necessary to sense how much the ram of the hydraulic cylinder is lowered. A linear scale is needed so that you can see how much pressure the gunpowder presses on the press plate and how much the gunpowder is pressed and the impurities are dehydrated. Of course, the hydraulic cylinder combined with the linear scale is employed in various fields such as a press device in addition to being used for the manufacture of gunpowder.

However, when a linear scale for position control is applied to a conventional hydraulic cylinder, there is a problem in that hydraulic oil leaks during hydraulic action of the hydraulic cylinder, and the magnetic force of the linear scale position sensing magnet is weakened due to magnetization.

In addition, due to the weakening of the magnetic force of the magnet, the linear scale cannot properly sense to what extent the ram (piston) of the hydraulic cylinder has advanced, and thus a sensing error occurs.

Conventionally, the packing is pinched at the part where the linear scale is coupled to the cylinder tube of the hydraulic cylinder and the packing is damaged. When hydraulic fluid leaks, it pollutes the surrounding environment and adversely affects devices such as dehydration equipment for manufacturing gunpowder.

Korean Patent No. 10-1861447 (registered on May 18, 2018) Korean Patent Registration No. 10-1233858 (Registered on February 08, 2013)

It is an object of the present invention to provide a linear scale anti-magnetization bush system for controlling the position of a hydraulic cylinder of a new configuration that can prevent the hydraulic fluid of the hydraulic cylinder from leaking and the magnetic force of the magnet for sensing the linear scale position is weakened. .

According to the present invention for solving the above problems, a cylinder tube; a ram slidably coupled to the inside of the cylinder tube; a linear scale mounted on the cylinder tube; There is provided a linear scale anti-magnetization bush system for controlling the position of a hydraulic cylinder, characterized in that it includes; a bush provided between the linear scale and the coupling part of the cylinder tube.

The cylinder tube is configured such that a front cover and a rear cover are respectively coupled to a front end and a base end of the cylinder tube. and the bush is interposed between the front end of the linear scale.

The bush is characterized in that the linear scale is configured to accurately measure the movement stroke of the ram moving in the cylinder tube.

A linear scale coupling hole having a threaded portion on an inner circumferential surface is provided at an outer end of the rear cover, and a coupling shaft having a threaded portion on an outer circumferential surface is provided at the front end of the linear scale, and the coupling shaft of the linear scale is connected to the linear scale coupling hole is coupled by the screw parts, and the bush is interposed between the front end of the linear scale and the outer end of the rear cover.

The bush is seated in a bush seating groove formed at the outer end of the rear cover, and the bush is provided with shaft insertion holes communicating on both sides, and the coupling shaft of the linear scale passes through the shaft insertion hole to pass the rear cover. It characterized in that it is coupled by the screw parts to the linear scale coupling hole of the.

It is characterized in that both surfaces of the bush are in close contact with the bush seating groove at the outer end of the rear cover and the front end of the linear scale.

A packing is interposed between the inner surface of the bush and the outer end of the rear cover to prevent leakage of hydraulic oil inside the cylinder tube due to the bush and the packing.

A packing is interposed between the outer circumferential surface of the rear cover and the inner circumferential surface of the cylinder tube.

One end of the ram is disposed to face an inner end of a rear cover provided in the cylinder tube, and a magnet is provided at one end of the ram.

A bush is provided between the inner surface of the magnet and one end of the ram, and the bush prevents the magnetic force of the magnet from being lost to the surrounding metal, thereby causing the linear scale to measure the magnetic force of parts other than the magnet. To prevent this, the linear scale is characterized in that it is configured to precisely measure the movement stroke of the ram, and to extend the life.

The bush is characterized in that the life of the magnet is extended by preventing the magnetic force of the magnet from being lost to other parts.

A bush is provided between the inner surface of the magnet and one end of the ram, and the bush is configured to prevent the magnetic force of the magnet from being lost to the surrounding metal, thereby extending the lifespan.

The front cover provided at the front end of the cylinder tube is provided with a ram guide hole communicating on both sides, the ram is slidably coupled to the ram guide hole, and a packing is interposed between the ram guide hole and the outer circumferential surface of the ram characterized by being

A plurality of packing grooves are provided on the inner peripheral surface of the ptont cover, and the packing is seated in the packing groove to seal between the inner peripheral surface of the front cover and the outer peripheral surface of the ram.

A piston block part is provided on the outer circumferential surface of the ram, the first hydraulic chamber and the second hydraulic chamber are secured between the outer circumferential surface of the ram and the inner circumferential surface of the cylinder tube based on the piston block part, the first hydraulic chamber and the second hydraulic chamber 2 It is characterized in that the ram is configured to move forward and backward according to the hydraulic hydraulic oil circulation to the hydraulic chamber.

According to the present invention, a cylinder tube; a ram slidably coupled to the inside of the cylinder tube; a linear scale mounted on the cylinder tube; a bush provided between the linear scale and the coupling part of the cylinder tube; the cylinder tube is configured such that a front cover and a rear cover are coupled to a front end and a base end, respectively, and the rear cover has a bush seating groove at the outer end is provided, the linear scale is coupled to the bush seating groove, the bush is interposed between the bush seating groove and a front end of the linear scale, and one end of the ram is inside the rear cover provided in the cylinder tube disposed to face the end, a magnet is provided at one end of the ram, a bush is provided between an inner surface of the magnet and one end of the ram, and the bush is fixed to one end of the ram by a fastener, , The fastener is provided with a linear scale anti-magnetization bush system for position control of a hydraulic cylinder, characterized in that it is composed of a non-ferrous metal.

A packing groove is provided on the inner surface of the bush interposed between the bush seating groove of the rear cover and the front end of the linear scale, and the packing is seated in the packing groove, and the bush seating groove of the rear cover is the packing. and configured to seal between the bush.

The bush interposed between the inner surface of the magnet and one end of the ram is made of a non-ferrous metal.

According to the present invention, according to the present invention, a cylinder tube; a ram slidably coupled to the inside of the cylinder tube; a linear scale mounted on the cylinder tube; a bush provided between the linear scale and the coupling part of the cylinder tube; the cylinder tube is configured such that a front cover and a rear cover are coupled to a front end and a base end, respectively, and the rear cover has a bush seating groove at the outer end is provided, the linear scale is coupled to the bush seating groove, the bush is interposed between the bush seating groove and a front end of the linear scale, and one end of the ram is inside the rear cover provided in the cylinder tube disposed to face the end, a magnet is provided at one end of the ram, a bush is provided between an inner surface of the magnet and one end of the ram, and the bush is disposed in a bush seating groove formed at the outer end of the rear cover. is seated, the bush is provided with shaft insertion holes communicating on both sides, the coupling shaft of the linear scale passes through the shaft insertion hole, and the bush has a tapered portion in the shaft insertion hole, and the tapered portion and the There is provided a linear scale anti-magnetization bush system for controlling a position of a hydraulic cylinder, characterized in that a packing is interposed between the outer peripheral surfaces of the coupling shaft.

The linear scale anti-magnetization bush system for controlling the position of a hydraulic cylinder according to the present invention has an effect of preventing hydraulic pressure from leaking from the hydraulic cylinder by having a bush, and due to hydraulic oil leakage and weakening of the magnet in the application of the linear scale to the hydraulic cylinder By compensating for the lowering of the position detection ability, it is effective in extending the service period of the position control function in the use of hydraulic cylinders. The reason for using the bush in the linear scale for controlling the position of the hydraulic cylinder is that the linear scale accurately measures the stroke of the piston rod of the hydraulic cylinder and to extend the lifespan by preventing the magnetic force from being lost due to the magnetic force of the magnet being lost to the surrounding metal. The purpose of the present invention is to faithfully achieve the purpose of accurately measuring the stroke of the piston rod of the hydraulic cylinder by appropriately employing the bush, and to prevent the case where the magnetic force of the magnet is lost and the lifespan is shortened. It is effective enough to achieve.

In addition, the bush prevents the magnetic force of the magnet from going to the cylinder tube and the ram, which is other places nearby, and the linear scale prevents an error in measuring the magnetic force of parts other than the magnet, so the linear scale accurately measures the moving stroke of the ram. has the effect of

1 is a perspective view showing a state in which a linear scale anti-magnetization bush system for controlling the position of a hydraulic cylinder according to the present invention is mounted on a dewatering equipment for manufacturing gunpowder;
2 is a perspective view showing the main part of the present invention;
3 and 4 are cross-sectional views showing the structure of the present invention.
5 is a side view of the bush which is the main part of the present invention;
6 is a cross-sectional view showing a modified embodiment of the bush which is the main part of the present invention;
7 is a side view of a magnet which is another main part of the present invention;
8 is a front view of FIG. 7
9 is an enlarged cross-sectional view showing a state in which a magnet and a bush, which are main parts of the present invention, are fixed to the ram by a fastener;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by referring to the accompanying drawings and the following detailed description. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the components from other components, and the essence, order, or order of the components are not limited by the terms. For example, when a component is described as being "connected", "coupled" or "connected" to another component, the component may be directly connected or connected to the other component, but between each component. It will be understood that another component may be “connected,” “coupled,” or “connected.”

Referring to the drawings, the linear scale anti-magnetization bush system for controlling the position of a hydraulic cylinder of the present invention includes a cylinder tube 20, a ram 26 slidably coupled to the inside of the cylinder tube 20, and the cylinder tube ( 20 ) and a bush 40 provided between the linear scale 30 and the coupling portion between the linear scale 30 and the cylinder tube 20 . The coupling portion between the linear scale 30 and the tube is a portion of the coupling shaft 32 provided in the linear scale 30 and the linear scale coupling hole 25 of the rear cover 24 provided in the cylinder tube 20, wherein the The bush 40 is interposed between the front end of the linear scale 30 and the inner end of the rear cover 24 . In addition, a magnet 52 and a bush 40 are coupled to the ram 26 . The present invention is supported by the upper panel 12 of the dewatering equipment 10 for the production of gunpowder is installed in the vertical direction. The present invention is arranged on the basket of the dewatering equipment for the manufacture of gunpowder. At this time, it should be understood that the present invention is employed as an example to be employed in the dehydration equipment for the manufacture of gunpowder, and the present invention can be universally employed in various other fields such as a press device as well as dehydration equipment for the manufacture of gunpowder. On the other hand, the cylinder tube 20, the front cover 22, the rear cover 24, and the ram 26, which are the main parts in the present invention, are hydraulic cylinders.

The cylinder tube 20 is configured in a tubular shape having a space therein. The cylinder tube 20 is configured in a circular tube shape.

The cylinder tube 20 is provided with a front cover 22 and a rear cover 24 . The front cover 22 is provided with a flange portion. A fastener 56 such as a bolt passing through the flange is tightened to the front end of the cylinder tube 20 so that the front cover 22 is coupled to the front end of the cylinder tube 20 . The front cover 22 is provided with a ram guide hole communicating on both sides. The ram guide hole is provided in the center of the front cover 22 . The rear cover 24 is also provided with a flange portion, and a fastener 56 such as a bolt passing through the flange portion of the rear cover 24 is tightened to the proximal end of the cylinder tube 20 so that the rear cover 24 is a cylinder. It is coupled to the proximal end of the tube (20). A bush seating groove is provided at an outer end of the rear cover 24 . The bush seating groove is provided in the center of the rear cover 24 .

The linear scale 30 is coupled to the bush seating groove of the rear cover 24 . The bush 40 is interposed between the bush seating groove of the rear cover 24 and the front end of the linear scale 30 . The bush 40 has a structure interposed between the front end of the linear scale 30 and the bush seating groove of the rear cover 24 in a state where it is seated in the bush seating groove of the rear cover 24 .

A linear scale coupling hole 25 having a threaded portion is provided at an outer end of the rear cover 24 on an inner circumferential surface. The bush seating groove is configured in a groove shape extending from the center of the rear cover 24 to the outside by a predetermined area, and the linear scale coupling hole 25 is provided in the center of the bush seating groove.

A coupling shaft 32 is provided at the front end of the linear scale 30 . The coupling shaft 32 has a shaft shape having a threaded portion on its outer circumferential surface. The coupling shaft 32 protrudes from the front end of the linear scale 30 . The coupling shaft 32 of the linear scale 30 is coupled to the linear scale coupling hole 25 of the rear cover 24 by the screw parts.

The bush 40 is configured so that the linear scale 30 accurately measures the movement stroke of the ram 26 moving in the cylinder tube 20 . The bush 40 is interposed between the front end of the linear scale 30 and the outer end of the rear cover 24 . The bush 40 is provided with shaft through-holes communicating on both sides, and the coupling shaft 32 of the linear scale 30 passing through the shaft through-hole of the bush 40 is connected to the rear cover 24 by the screw parts. is coupled to the linear scale coupling hole 25 of the The linear scale 30 is coupled to the rear end of the cylinder tube 20 , and the bush 40 is pressed with a constant pressure between the bottom of the bush seating groove of the rear cover 24 and the front end of the linear scale 30 . In this state, the structure is interposed between the front end of the linear scale 30 and the rear cover 24 of the cylinder tube 20 . That is, both surfaces of the bush 40 are press-contacted to the bush seating groove of the outer end of the rear cover 24 and the front end of the linear scale 30 . Preferably, the bush 40 interposed between the outer end of the rear cover 24 and the front end of the linear scale 30 is made of non-ferrous metal. For example, the bush 40 may be made of stainless steel, which is a non-ferrous metal.

A packing PK is interposed between the inner surface of the bush 40 and the outer end of the rear cover 24 . A plurality of packing grooves 42 are provided in the form of concentric circles on the inner surface of the bush 40 , and the packing PK is seated in the plurality of packing grooves 42 . The packing PK seals between the inner surface of the bush 40 and the outer end of the rear cover 24 of the cylinder tube 20 . A packing (PK) is interposed between the inner surface of the bush (40) and the outer end of the rear cover (24), and the hydraulic oil inside the cylinder tube (20) leaks due to the bush (40) and the packing (PK). achieve the goal of preventing it from happening.

In addition, a packing PK is interposed between the outer circumferential surface of the rear cover 24 and the inner circumferential surface of the cylinder tube 20 . A packing groove is provided in the rear cover 24, and the packing PK is seated in the packing groove, so that the packing PK seals between the outer circumferential surface of the rear cover 24 and the inner circumferential surface of the cylinder tube 20 do.

The ram 26 is slidably coupled to the inside of the cylinder tube 20 . The ram 26 is configured in a bar shape of a certain length. One end of the ram 26 is disposed to face the inner end of the rear cover 24 provided in the cylinder tube 20 . A magnet 52 is provided at one end of the ram 26 . In addition, a bush 54 is provided between the inner surface of the magnet 52 and one end of the ram 26 . A bush 54 is provided between the inner surface of the magnet 52 and one end of the ram 26 so that the bush 52 prevents the magnetic force of the magnet 52 from being lost to the surrounding metal, thereby extending the lifespan. will make it That is, in the linear scale anti-magnetization bush system for controlling the position of the hydraulic cylinder of the present invention, the life of the hydraulic cylinder, which is a main part, is extended. In this case, the peripheral metal means the cylinder tube 20 and the ram 26, which are main parts of the hydraulic cylinder.

A concave groove portion 27 is provided at one end of the ram 26 , and a bush 40 is seated and coupled to the concave groove portion 27 . The bush 54 is provided with fastener holes communicating on both sides. As the fastener 56 passing through the fastener hole of the bush 54 is tightened into the fastener coupling hole extending inward from the bottom of the concave groove portion 27 of the ram 26, the bush 54 becomes the ram 26 ) has a structure coupled to the concave groove portion 27 provided at one end. At this time, the fastener coupling hole of the ram 26 is composed of a hole having a threaded part on the inner peripheral surface, and the fastener 56 is composed of a bolt having a threaded part on the outer peripheral surface while having a head part, and the fastener 56 is a bush ( 54) and is fastened to the fastener coupling hole of the ram 26 by the screw parts, so that the bush 40 can be seated and coupled to the concave groove portion 27 of the ram 26. . Preferably, the bush 40 is made of a non-ferrous metal. For example, the bush 40 may be made of stainless steel, which is a non-ferrous metal. In addition, the fastener 56 is also made of a non-ferrous metal. For example, the fastener 56 is also made of stainless steel, which is a non-ferrous metal.

The magnet 52 is coupled to the bush 54 in a state in which it enters the concave groove portion 27 of the ram 26 . In a state in which the magnet 52 is in contact with the bush 54 , the magnet 52 is coupled to the bush 54 by the fastener 56 . In a state where one side of the magnet 52 is in contact with one side of the bush 54, a fastener 56 such as a bolt passes through a fastener through-hole communicating on both sides of the magnet 52 and is formed in the bush 54. The magnet 52 is coupled to the bush 54 by being tightened in the fastener hole. The fastener 56 is composed of a bolt having a head part and a threaded part on the outer circumferential surface, and the fastener hole of the bush 40 is composed of a threaded hole having a threaded part on the inner circumferential surface. By being tightened to the bush 54 , it may be configured to be fixed to one end of the ram 26 while the magnet 52 is in contact with the bush 54 . On the other hand, the fastener 56 passes through the fastener through hole of the magnet 52 and the fastener hole of the bush 54 and is tightened into the fastener engaging hole formed inside the ram 26 so that the magnet 52 is It may be configured to be coupled to one end of the ram 26 while in contact with the bush 54 . At this time, the fastener coupling hole of the ram 26 is composed of a hole having a threaded part on the inner peripheral surface, and the fastener 56 is composed of a bolt having a threaded part on the outer peripheral surface while having a head part, and the fastener 56 is a bush ( 54) and is tightened to the ram 26 by the screw parts, so that the bush 54 is seated in the concave groove part 27 of the ram 26 and the magnet 52 is also attached to the ram 26. It can be coupled to one end of the ram 26 in a state of being seated in the concave groove portion 27 of the. The magnet 52 has a structure fixed to one end of the ram 26 while physically separated from the ram 26 by a bush 54 in the middle. At this time, the fastener 56 for coupling the magnet 52 to the bush 54 and the ram 26 is also made of non-ferrous metal. For example, the fastener 56 for coupling the magnet 52 to the bush 54 and the ram 26 may be made of stainless steel, which is a non-ferrous metal. Preferably, the outer diameter of the magnet 52 is smaller than the inner diameter of the concave groove portion 27 of the ram 26 so that the outer peripheral surface of the magnet 52 is spaced a certain distance from the inner wall of the concave groove portion 27 of the ram 26 . It is configured to secure the space. Even by the space, the magnet 52 is physically spaced apart from the ram 26 . Accordingly, since the magnetic force of the magnet 52 is lost through the ram 26 and the magnetic force is weakened, a stroke sensing error of the ram 26 due to the linear scale 30 is prevented.

A ram guide hole communicating on both sides is provided in the front cover 22 provided at the front end of the cylinder tube 20, and a ram 26 is slidably coupled to the ram guide hole, and the ram guide hole and the ram A packing (PK) is interposed between the outer peripheral surfaces of (26). A plurality of packing grooves are provided on the inner peripheral surface of the front cover 22 , and the packing PK is seated in the packing groove to seal between the inner peripheral surface of the front cover 22 and the outer peripheral surface of the ram 26 . Since a packing groove is provided on the outer circumferential surface of the ram 26 so that the packing PK is seated in the packing groove, the packing PK is interposed between the ram guide hole of the front cover 22 and the outer circumferential surface of the ram 26 . becomes the structure.

In addition, a piston block portion 26PB is provided on the outer peripheral surface of the ram 26 . The piston block portion 26PB has a larger outer diameter than the other portions. One end of the piston block portion 26PB faces the inner surface of the rear cover 24 of the cylinder tube 20 so that one end of the ram 26 faces the inner surface of the rear cover 24, The magnet 52 and the bush 54 are provided at one end of the piston block 26PB, so that the bush 54 and the magnet 52 are provided at one end of the ram 26 .

A first hydraulic chamber is secured between a part of the outer circumferential surface of the ram 26 and the inner circumferential surface of the cylinder tube 20 based on the piston block portion 26PB of the ram 26, and one end of the ram 26 and the cylinder A second hydraulic chamber is secured between the inner peripheral surface of the tube 20 and the inner surface of the rear cover 24 . The ram 26 moves forward and backward according to the hydraulic hydraulic oil circulation to the first hydraulic chamber and the second hydraulic chamber. When the hydraulic pressure enters through the first port provided in the cylinder tube 20 and the hydraulic pressure is released to the second port provided in the cylinder tube 20 , the ram 26 moves backward in the cylinder tube 20 , and the cylinder When the hydraulic pressure is discharged through the first port provided in the tube 20 and the hydraulic pressure enters the second port provided in the cylinder tube 20 , the ram 26 advances to come out of the cylinder tube 20 . As the ram 26 moves, the magnet 52 and the bush 54 also move, so that the sensors provided in the linear scale 30 sense the moving distance of the magnet 52 and the movement stroke of the ram 26 . will sense

The linear scale anti-magnetization bush system for hydraulic cylinder position control according to the present invention applies a double O-ring, that is, a new BUSH (40) to which a double packing (PK) is applied, for preventing hydraulic oil leakage during hydraulic action, and a linear scale (30) In order to prevent the weakening of the magnetic force of the magnet 52 for position sensing, a new BUSH 54 is applied.

Therefore, the present invention has the effect of preventing the hydraulic pressure from leaking from the hydraulic cylinder by providing the bush 40, preventing the hydraulic hydraulic oil from leaking and polluting the surrounding environment by the hydraulic hydraulic oil. It prevents the case of adversely affecting the dehydrator for the manufacture of gunpowder.

In addition, a packing groove 42 is provided on the inner surface of the bush 40 interposed between the bush seating groove of the rear cover 24 and the front end of the linear scale 30, and the packing ( PK) is seated, and the packing PK seals between the bush seating groove of the rear cover 24 and the bush 40, thereby more reliably preventing the hydraulic oil from leaking inside the hydraulic cylinder.

In addition, if a metal is attached to the circumference of the magnet 52, a phenomenon in which the magnetic force of the magnet 52 is lost (magnetization phenomenon) occurs, and a stroke sensing error of the ram 26 by the linear scale 30 occurs. In the present invention, the magnetic force of the magnet 52 is physically separated by the bush 40 between the magnet 52 and the ram 26 between the ram 26 and the cylinder tube 20 through which the magnetic force of the magnet 52 passes. This prevents the ram 26 and the cylinder tube 20 from being taken away (lefting phenomenon), thereby preventing the magnetic force sensing error of the magnet 52 caused by the linear scale 30 and removing the ram 26 from the cylinder tube 20 Prevents the occurrence of a stroke error of That is, when the linear scale 30 is applied to the hydraulic cylinder, it is effective in extending the service period of the position control function in using the hydraulic cylinder by compensating for the decrease in position detection ability due to hydraulic oil leakage and weakening of the magnet 52 . In other words, the magnetic force of the magnet 52 can be maintained homogeneously for a longer period by the bush 54 to prevent the magnetic force sensing error of the magnet 52 by the linear scale 30 and from the cylinder tube 20 This is to prevent the occurrence of a stroke error of the RAM 26 .

In particular, since the fastener 56 for fixing the magnet 52 to the ram 26 is made of a non-ferrous metal, the magnetic force of the magnet 52 is more reliably prevented from being stolen by the fastener 56 . , it more reliably prevents the magnetic force sensing error of the magnet 52 by the linear scale 30 and more reliably prevents the occurrence of a stroke error of the ram 26 in the cylinder tube 20 .

In addition, the bush 54 interposed between the magnet 52 and the ram 26 is also made of copper or stainless steel, which is a non-ferrous metal, so that the magnetic force of the magnet 52 is lost toward the ram 26. 54), thus preventing a sensing error of the linear scale 30 due to a decrease in the magnetic force of the magnet 52.

In addition, the bush 54 prevents the magnetic force of the magnet 52 from going to another place, thereby preventing the linear scale 30 from not accurately measuring the measurement distance of the ram 60 . In other words, the bush 54 prevents the magnetic force of the magnet 52 from going to the cylinder tube 20 and the ram 26, which are other places in the vicinity, so that the linear scale 30 is Since an error in measuring the magnetic force of other parts is prevented, the linear scale 30 can measure the movement stroke of the ram 26 very precisely, while extending the lifespan. The bush 54 prevents the magnetic force of the magnet 52 from being lost to other parts, and in particular, extends the life of the magnet 52 . Extending the life of the magnet 52 is extending the life of the hydraulic cylinder employing the linear scale 30 . The function or effect of the bush 40 also has the same function or effect as that of the bush 52 to which the magnet 52 is in contact.

In addition, the bush 54 is seated in the bush seating groove formed at the outer end of the rear cover 24, and the bush 54 is provided with shaft through-holes communicating on both sides, and a linear scale ( 30) is passed through the coupling shaft 32, and the bush 54 is provided with a tapered portion 55 in the shaft through hole, and a packing (PK) between the tapered portion 55 and the outer peripheral surface of the coupling shaft 32 . ) is interposed.

Therefore, the coupling shaft 32 of the linear scale 30 is passed through the shaft through hole of the bush 40 and screwed into the linear scale coupling hole 25 formed in the rear cover 24 of the cylinder tube 20. In the process of coupling, etc., the packing (PK) is pinched between the coupling shaft 32 and the shaft through-hole of the bush 40 and is prevented from being torn, thereby preventing the packing (PK) from being damaged. It also prevents hydraulic fluid from leaking inside the hydraulic cylinder.

Terms such as "include", "compose" or "have" described above mean that the corresponding component may be inherent unless otherwise stated, so it does not exclude other components. It should be construed as being able to further include other components. All terms including technical and scientific terms have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs, unless otherwise defined. Commonly used terms such as terms defined in the dictionary should be interpreted as being consistent with the contextual meaning of the related art, and are not interpreted in an ideal or excessively formal meaning unless explicitly defined in the present invention.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Therefore, since the embodiments described above are provided to fully inform those of ordinary skill in the art to which the present invention pertains the scope of the invention, it should be understood that they are exemplary in all respects and not limiting, The invention is only defined by the scope of the claims.

20. Cylinder tube 22. Front cover
24. Rear cover 25. Linear scale coupling hole
26. RAM 26PB. piston block
27. Concave groove 30. Linear scale
32. Combined shaft 40. Bush
42. Packing groove 52. Magnet
54. Bush 56. Fastener

Claims (12)

cylinder tube 20;
a ram 26 slidably coupled to the inside of the cylinder tube 20;
a linear scale 30 mounted on the cylinder tube 20;
A bush 40 provided between the coupling part of the linear scale 30 and the cylinder tube 20;
The cylinder tube 20 is configured such that a front cover 22 and a rear cover 24 are coupled to a front end and a base end, respectively, and the rear cover 24 is provided with a bush seating groove at an outer end thereof, and the bush seating groove is coupled to the linear scale 30, and the bush 40 is interposed between the bush seating groove and the tip of the linear scale 30,
One end of the ram 26 is disposed to face the inner end of the rear cover 24 provided in the cylinder tube 20, and a magnet 52 is provided at one end of the ram 26,
A bush 54 is provided between the inner surface of the magnet 52 and one end of the ram 26 so that the bush 54 prevents the magnetic force of the magnet 52 from being lost to the surrounding metal. The linear scale 30 prevents an error in measuring the magnetic force of parts other than the magnet 52 , so that the linear scale 30 precisely measures the movement stroke of the ram 26 and extends the lifespan Linear scale anti-magnetization bush system for hydraulic cylinder position control, characterized in that it is configured to
delete According to claim 1,
The bush 40 is configured so that the linear scale 30 accurately measures the movement stroke of the ram 26 moving in the cylinder tube 20, and is configured to extend the lifespan. Scale anti-magnetization bush system.
According to claim 1,
The outer end of the rear cover 24 provided in the cylinder tube 20 is provided with a linear scale coupling hole 25 having a threaded portion on its inner circumferential surface, and the front end of the linear scale 30 has a threaded portion on its outer circumferential surface. A shaft 32 is provided, the coupling shaft 32 of the linear scale 30 is coupled to the linear scale coupling hole 25 by the screw parts, and the bush 40 is the linear scale 30 ), a linear scale anti-magnetization bush system for position control of a hydraulic cylinder, characterized in that it is interposed between the front end of the rear cover and the outer end of the rear cover (24).
5. The method of claim 4,
The bush 40 is seated in a bush seating groove formed at the outer end of the rear cover 24 of the cylinder tube 20, and the bush 40 is provided with shaft through-holes communicating on both sides, the shaft The hydraulic cylinder position control, characterized in that the coupling shaft 32 of the linear scale 30 passes through the through hole and is coupled to the linear scale coupling hole 25 of the rear cover 24 by the screw parts. Linear scale anti-magnetization bush system.
6. The method of claim 5,
Hydraulic pressure, characterized in that both surfaces of the bush (40) are configured to be in close contact with the bush seating groove at the outer end of the rear cover (24) provided in the cylinder tube (20) and the front end of the linear scale (30) Linear scale anti-magnetization bushing system for cylinder position control.
7. The method of claim 6,
A packing PK is interposed between the inner surface of the bush 40 and the outer end of the rear cover 24 , and the hydraulic pressure inside the cylinder tube 20 is caused by the bush 40 and the packing PK. Linear scale anti-magnetization bush system for hydraulic cylinder position control, characterized in that it is configured to prevent hydraulic oil from leaking.
According to claim 1,
A linear scale anti-magnetization bush system for hydraulic cylinder position control, characterized in that a packing (PK) is interposed between the outer peripheral surface of the rear cover (24) and the inner peripheral surface of the cylinder tube (20).
delete delete 4. The method of claim 3,
A plurality of packing grooves are provided on the inner peripheral surface of the ptont cover provided in the cylinder tube 20 , and the packing PK is seated in the packing groove, the inner peripheral surface of the front cover 22 and the outer peripheral surface of the ram 26 . Linear scale anti-magnetization bushing system for hydraulic cylinder position control, characterized in that it is configured to seal between them.
According to claim 1,
A piston block part 26PB is provided on the outer peripheral surface of the ram 26 , and a first hydraulic chamber is provided between the outer peripheral surface of the ram 26 and the inner peripheral surface of the cylinder tube 20 based on the piston block part 26PB. and a second hydraulic chamber are secured, and the ram 26 is configured to move forward and backward according to the hydraulic hydraulic oil circulation to the first hydraulic chamber and the second hydraulic chamber. system.

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