KR102188807B1 - a functional bridge lifting lock device and the bridge lifter using thereof - Google Patents

Abstract

The present invention relates to a bridge upper structure lifting lock device for maintaining an upper structure of a bridge and, more specifically, to a bridge lifting lock device and a bridge lifting apparatus using the same, wherein, after the bridge is lifted by using the bridge lifting apparatus in order to repair the bridge, the upper structure thereof or the like, the bridge lifting lock device fixes a load applied to the bridge lifting apparatus to prevent the bridge or the upper structure thereof from falling. The present invention provides a functional lifting lock device (200) configured to include a lower fixing unit (210), an upper fixing unit (220) and a fixing adjustment unit (230). The lower fixing unit (210) is configured to include a lower fixing unit body portion (211) and a lower fixing unit screw thread portion (212). The upper fixing unit (220) is configured to include an upper fixing unit body portion (221) and an upper fixing unit screw thread portion (222). The fixing adjustment unit (230) is configured to include a main body portion (231), a screw portion (232) and a rotation actuating portion (233). In addition, the present invention provides a bridge lifting apparatus (100) configured to include: one or two or more functional lifting lock devices; and a hydraulic pump (110) and a lifting jack (120).

Description

A functional bridge lifting lock device and the bridge lifter using the same

The present invention relates to a bridge upper structure lifting lock device for maintenance and repair of a bridge superstructure, and more specifically, a bridge after raising a bridge using a bridge lifting device to repair a bridge or its upper structure, etc. It relates to a bridge lifting lock device that fixes a load acting on the lifting device to prevent a bridge or its upper structure from descending, and a bridge lifting device using the same.

In general, bridge structures have live loads due to the characteristics of the bridge, such as the length and transverse direction of the bridge (bridge axis direction, bridge axis perpendicular direction) due to frequent passage of vehicles or trains and temperature changes.

Accordingly, as shown in FIG. 1A, a bridge support 50 is installed so as to be installed on a bridge substructure (pier, abutment) to support the bridge upper structure (slab) and absorb the new construction of the bridge upper structure.

Such a bridge support 50 is fixed by an anchor 52 to the concrete support 51 installed on the upper surface of the bridge substructure, and a hemispherical groove 53 is formed on the upper central surface of the lower plate 54, a brass bearing plate ( 55), oilless bridge bearings including the upper plate 56 can be used according to the purpose.

However, since these bridge supports (50, bridge support) act as a medium to transfer loads between the bridge upper structure and the bridge substructure, the bridge support that has been used up to its endurance life as time elapses will eventually require repair or replacement. It becomes necessary.

Therefore, conventionally, a hydraulic jack was simply installed on the upper surface of the lower structure to raise the upper structure, and then repair work of the bridge support was performed by repairing the bridge support or replacing a new bridge support.

Since such work of raising the upper structure of the bridge must be continuously raised during the period of repair and replacement of the bridge support, hydraulic jacks must be installed continuously during the construction period.

However, the problem at this time is that even during this period, since the upper structure of the bridge is constantly being expanded and constructed in the direction of the bridge axis, a lifting device with the function of the bridge support was required even during the period of raising the upper structure of the bridge.

Thus, as shown in Figure 1b, such a pulling device is introduced.

The lower lifting device is a combination of two types of lifting devices, and the lower cylinder 1, the hydraulic pipe 1a, the safety hook 2, the upper cylinder 3, the piston 4 and the turning rod ( It consists of 4a).

The piston 4 is a lifting device capable of mechanically adjusting the height of the lifting by using a screw groove without using hydraulic pressure when no load is applied, and the lower and upper cylinders 1 and 3 are It is a method of using the hydraulic pressure injected through the pipe (1a), but the safety ring (2) is attached to the conventional hydraulic pulling device.

Therefore, compared to the conventional hydraulic pulling device, it can be applied by adjusting the height of the pulling using the piston 4 even when the mold space is large, and the pulling portion that may occur due to a decrease in hydraulic pressure or the like during long-term pulling of the upper structure. Various accidents caused by the descending of can be prevented by using the safety hook (2). That is, a thread is formed on the inner surface of the safety ring (2) in the shape of a ring or ring with a circular hole in the center, and the thread on the inner surface of the safety ring is screwed with a thread formed on the outer surface of the upper cylinder (3). Adjust the height of the pull by raising the piston (4) by the rotation of the bar and the turning rod (4a), and to further increase the height of the pull, raise the height of the upper cylinder and safety hook by supplying hydraulic pressure. When the upper structure is raised for a long period of time, it is a safety that is screwed with the threads on the outer surface of the cylinder to prevent the descending of the raised part due to the decrease in hydraulic pressure due to the long period of time.

By rotating the ring so that the safety ring is placed on the lower cylinder (1), there is provided an impression device capable of preventing the descent of the impression portion by screwing and preventing danger.

1C is a view showing another example of a support device for raising a girder according to the prior art, and shows that it can be installed corresponding to the gradient of the girder.

That is, the support device for raising a girder according to the prior art includes a lower cylinder 51 that is supplied with a fluid from the outside through a hydraulic pipe, and an upper and a lower cylinder in which a vertical motion is controlled by the hydraulic pressure of the supplied fluid, A lower lifting device including a cylinder 53; A lubricating surface is formed on the upper part, and a spherical body 55 with a rubber pad and solid lubricant interpolated to relieve impact and local stress from the upper structure, and the upper plate and the spherical body directly interviewed with the bridge structure to be raised or lowered. Consisting of a bearing part 56 including a lubricating plate and a solid lubricant for reducing friction between the spherical plate with the lubricating surface bonded to the lower surface to enable free rotation by interviewing the lubricating surface of It is equipped with an upper support device.

At this time, the upper cylinder 53 has a thread formed on the inner surface as well as the outer surface thereof, and the safety device has a safety ring 52 in which the thread of the inner surface is screwed with the thread of the outer surface of the upper cylinder, and has a shape of a ring as a whole. The lower lifting device is further provided with a piston 54 that is thread-coupled with a thread on the inner surface of the upper cylinder 53 and moves up and down by the rotation of the turning rod.

Accordingly, it can be seen that the upper cylinder 53 is raised and lowered by hydraulic pressure, and is made to be manually lifted and lowered by the piston 54, and the support part 56 is capable of rotating according to the gradient at the bottom of the girder.

Therefore, it can be seen that the conventional support device for girder lifting can raise the girder by adjusting the gradient, but depending on the site, there are cases where it is necessary to use a hydraulic jack with a large number of capacity. There was a limit of being inefficient.

As shown in Fig. 1d, in order to solve the above problem, Patent Registration No. 10-1885159 (raising jack for gradient adjustment and automatic bridge lifting control system using the same) is "installed on the bridge substructure 300 to provide the girder 200 As for raising, including a hydraulic jack 110 and an impression jack fixing device 120,

First, the hydraulic jack 110 includes a body part 111 and a hydraulic cylinder 112 that is elevated from the inside of the body part 111, and hydraulic pressure is supplied through a separate hydraulic line. Accordingly, the hydraulic jack 110 serves to raise the girder 200 as the hydraulic cylinder 112 by hydraulic pressure rises,

The lifting jack fixing device 120 includes a hydraulic jack housing 121 and an outer housing 122, and allows the girder 200 to be raised by using a hydraulic jack 110 that does not have a threaded portion formed on the outer circumferential surface thereof. While serving, it serves to fix the hydraulic jack 110 to the girder 200 on the bridge substructure 300 while maintaining the raised state of the girder 200,

Accordingly, the hydraulic jack housing 121 is a hollow member that is inserted and installed downward from the top of the body 111 of the hydraulic jack 110, as shown in FIG. 2A. A thread is formed on the outer circumferential surface, and the upper surface is formed by the hydraulic jack housing top surface 121b. To be blocked, but the hydraulic jack housing upper surface (121b) is formed with a central hole (H) so that the hydraulic cylinder (112) can operate through, and the bottom surface is an impression jack for gradient adjustment formed of an open cylindrical body portion (121a) (100)" has been suggested.

The above-described prior art and prior art have the following structural problems.

As shown in FIG. 2, the bridge impression apparatus 100 includes a hydraulic pump 110, an impression jack 120, and a support 130.

The above-described hydraulic pump 110 refers to a device or means for supplying hydraulic pressure to the hydraulic jack 120 and is installed on the bottom part 2.

The hydraulic jack 120 is also referred to as an impression jack and refers to a device or means for lifting the upper structure 1 (hereinafter referred to as “bridge”) of a bridge with hydraulic pressure supplied from a hydraulic pump. The hydraulic jack 20 is installed on the upper end of the bridge to raise the bridge.

The support part 130 is a device that supports the upper structure 1 of the bridge, and the upper part has a flat shape, so that it supports the upper structure 1 of the bridge.

In addition, the lower end of the support 130 has a convex hemispherical structure, so it is supported and bound to the upper end 121 of the hydraulic jack, and the upper end of the hydraulic jack also has a concave hemispherical structure. It is to be well coupled with the lower end of the support 130.

As shown in Fig. 2b, the reason why the lower end of the support 130 has a convex hemispherical structure and the upper end of the hydraulic jack has a concave hemispherical structure is that the upper structure 1 of the bridge is at the bottom 2 ), because it is a structure that cannot achieve complete equilibrium, that is, the upper structure (1) of the bridge can be formed diagonally with respect to the bottom (2). It can be said that it is for raising it with a hydraulic jack while supporting it.

In this way, when the upper structure (1) of the bridge is raised with a hydraulic jack, it is usually raised by 1 to 5 mm, and generally by 3 to 4 mm.The hydraulic jack is continuously receiving a load from the upper structure (1) of the bridge. As the pulling force is received by the hydraulic pump 110, a hydraulic jack fixing device 140 is provided to perform a function of fixing the hydraulic jack.

The hydraulic jack fixing device 140 has a structure that is coupled with a screw thread formed on the outside of the hydraulic jack 120, and has a feature of moving to the upper or lower portion of the hydraulic jack 120 through rotation.

In this way, the hydraulic jack fixing device 140 rotates after the hydraulic jack raises the upper structure 1 of the bridge, and is brought into contact with and mounted on the upper surface 111 of the hydraulic pump 110. The hydraulic jack 120 performs a function of stopping the force applied to the hydraulic pump 110 by the load.

As shown in Figure 2c, the function of holding the load of the upper structure 1 of the bridge by the hydraulic jack 120 is a thread 141 formed on the hydraulic jack fixing device 140 and a thread 122 formed on the hydraulic jack 120 This is possible because) is caught on each other and supports the applied force.

However, each screw thread having a function of acting by interlocking the screw thread 141 formed on the hydraulic jack fixing device 140 and the thread 122 formed on the hydraulic jack 120 is applied to the heavy load of the upper structure (1) of the bridge. As a result, a phenomenon in which the hydraulic jack 120 is struck downward due to wear or damage occurs, thereby causing a problem in that the function of lifting and fixing the upper structure 1 of the bridge is deteriorated.

In addition, the hydraulic jack fixing device 140 should be used that fits the thread of the hydraulic jack 120, but it is not compatible with the hydraulic jack 120 of various sizes, so the convenience of use that cannot be used for other hydraulic jacks 120 is remarkably. Falling problems arise.

The present invention was conceived to solve the problems of the prior art and the prior art, and the hydraulic jack of the bridge lifting device descends, which is not affected by time and load even after the upper structure of the bridge is raised with the bridge lifting device. It is intended to provide a functional bridge lifting lock device with a function of preventing and a bridge lifting device using the same.

In addition, even if the upper structure (1) and the floor (2) of the bridge are not completely parallel in the conventional technology, after the upper structure (1) of the bridge is raised, the conventional support part 130 is used. Even when the hydraulic jack 120 is not allowed to descend, there are many problems in which the support function of the impression fails due to the difference in the load acting to the left and right of the thread formed on the support part. Aims to provide a functional bridge lifting lock device that completely solves this problem and a bridge lifting device using the same.

In particular, the present invention is to provide a functional bridge lifting lock device and a bridge lifting device using the same that can be used in all weather in the size and radius of various bridge lifting devices and hydraulic jacks accordingly.

The present invention in order to solve the above problems and needs,

It provides a functional lifting lock device 200 comprising a lower fixing part 210, an upper fixing part 220, and a fixed adjustment part 230.

In addition, in the present invention, the lower fixing part 210 includes a lower fixing part body part 211 and a lower fixing part threaded part 212,

The upper fixing part 220 is configured to include an upper fixing part body part 221, an upper fixing part threaded part 222,

The fixed adjustment unit 230 provides a functional lifting lock device 200, characterized in that it comprises a body portion 231, a screw portion 232, and a rotation operation portion 233.

In addition, the present invention provides a bridge lifting device 100 comprising one or two or more of the above-described functional lifting lock device and comprising a hydraulic pump 110 and an impression jack 120.

The functional bridge lifting lock device according to the present invention has the effect of remarkably preventing the hydraulic jack of the bridge lifting device from descending with a function that is not affected by the load for a long time and even after lifting the upper structure of the bridge with the bridge lifting device.

In addition, the functional bridge lifting lock device according to the present invention exhibits functions and effects that can be used in all weather without being affected by the size and radius of various bridge lifting devices and hydraulic jacks accordingly.

In addition, even if the upper structure (1) and the floor (2) of the bridge are not completely parallel in the conventional technology, after the upper structure (1) of the bridge is raised, the conventional support part 130 is used. Even when the hydraulic jack 120 does not descend, there are many problems in which the support function of the impression fails due to the difference in the load acting to the left and right of the thread formed on the support part. The functional bridge lifting lock device according to the invention exhibits functions and effects that can be well applied even when the upper structure (1) and the floor (2) of the bridge are not completely parallel.

In addition, the functional bridge lifting lock device having a function according to the present invention and the bridge lifting device using the same have the effect of stably performing the lifting of the bridge.

1 is a configuration diagram of a conventional bridge raising device.
Figure 2b and Figure 2c is an embodiment of the locking device in the bridge impression device.
Figure 1d is a configuration diagram of an improved bridge lifting device of the prior art.
Figure 2 and Figure 2b is a configuration and implementation of the conventional bridge lifting device and hydraulic jack fixing device.
Figure 2c is a working view of the hydraulic jack fixing device in the conventional bridge lifting device.
Figure 3 is a coupling structure diagram of the lifting lock device according to the present invention.
Figure 3b is a detailed structural diagram of the lifting lock device according to the present invention.
Figure 4 is a front structural view of the lower fixing portion of the lifting lock device according to the present invention.
Figure 4b is a side cross-sectional view of the lower fixing portion of the lifting lock device according to the present invention.
Figure 4c is a perspective structure diagram of the lower fixing portion of the impression lock device according to the present invention.
Figure 5 is a front structural view of the upper fixing portion of the lifting lock device according to the present invention.
Figure 5b is a side cross-sectional view of the upper fixing portion of the lifting lock device according to the present invention.
Figure 5c is a perspective view of the upper fixing portion of the impression lock device according to the present invention.
Figure 6 is a detailed structural diagram of the fixed adjustment unit of the impression lock device according to the present invention.
Figure 6b is a side structural view of the fixed adjustment unit of the lifting lock device according to the present invention.
7 is a structural diagram and an implementation diagram of a bridge lifting device including the lifting lock device according to the present invention (when the upper structure of the bridge and the floor are parallel).
7B is a structural diagram and an implementation diagram of a bridge lifting device including an lifting lock device according to the present invention (when the upper structure and the floor of the bridge are not parallel).
Figure 7c is a structural diagram and an implementation diagram of the lifting lock device according to the present invention (if the upper structure and the bottom of the bridge are not parallel structure).

Hereinafter, the present invention will be described in detail with reference to the drawings.

The present invention provides a functional impression lock device 200 comprising a lower fixing part 210, an upper fixing part 220, and a fixed adjustment part 230.

The functional lifting lock device 200 of the present invention refers to performing a function of preventing the hydraulic jack of the bridge lifting device from being lowered after the bridge lifting device raises the upper structure of the bridge.

In addition, the present invention provides a bridge lifting device 100 comprising one or two or more of the above-described functional lifting lock device 200 and including a hydraulic pump 110 and an impression jack 120.

As shown in FIG. 2, the bridge impression apparatus 100 includes a hydraulic pump 110, an impression jack 120, and a support 130.

The above-described hydraulic pump 110 refers to a device or means for supplying hydraulic pressure to the hydraulic jack 120 and is installed on the floor 2 (a structure that supports the upper structure 1 of a pier or bridge).

The hydraulic jack 120 is also referred to as an impression jack and refers to a device or means for lifting the upper structure 1 (hereinafter referred to as “bridge”) of a bridge with hydraulic pressure supplied from a hydraulic pump. The hydraulic jack 20 is installed on the upper end of the bridge to raise the bridge.

The support part 130 is a device that supports the upper structure 1 of the bridge, and the upper part has a flat shape, so that it supports the upper structure 1 of the bridge.

In addition, the lower end of the support 130 has a convex hemispherical structure, so it is supported and bound to the upper end 121 of the hydraulic jack, and the upper end of the hydraulic jack also has a concave hemispherical structure. It is to be well coupled with the lower end of the support 130.

As shown in Fig. 2b, the reason why the lower end of the support 130 has a convex hemispherical structure and the upper end of the hydraulic jack has a concave hemispherical structure is that the upper structure 1 of the bridge is at the bottom 2 ), because it is a structure that cannot achieve complete equilibrium, that is, the upper structure (1) of the bridge can be formed diagonally with respect to the bottom (2). It can be said that it is for raising it with a hydraulic jack while supporting it.

In this way, when the upper structure (1) of the bridge is raised with a hydraulic jack, it is usually raised by 1 to 5 mm, and generally by 3 to 4 mm.The hydraulic jack is continuously receiving a load from the upper structure (1) of the bridge. As the pulling force is received by the hydraulic pump 110, a hydraulic jack fixing device 140 is provided to perform a function of fixing the hydraulic jack.

The hydraulic jack fixing device 140 has a structure that is coupled with a screw thread formed on the outside of the hydraulic jack 120, and has a feature of moving to the upper or lower portion of the hydraulic jack 120 through rotation.

In this way, the hydraulic jack fixing device 140 rotates after the hydraulic jack raises the upper structure 1 of the bridge, and is brought into contact with and mounted on the upper surface 111 of the hydraulic pump 110. The hydraulic jack 120 performs a function of stopping the force applied to the hydraulic pump 110 by the load.

As shown in Figure 2c, the function of holding the load of the upper structure 1 of the bridge by the hydraulic jack 120 is a thread 141 formed on the hydraulic jack fixing device 140 and a thread 122 formed on the hydraulic jack 120 This is possible because) is caught on each other and supports the applied force.

However, each screw thread having a function of acting by interlocking the screw thread 141 formed on the hydraulic jack fixing device 140 and the thread 122 formed on the hydraulic jack 120 is applied to the heavy load of the upper structure (1) of the bridge. As a result, a phenomenon in which the hydraulic jack 120 is struck downward due to wear or damage occurs, thereby causing a problem in that the function of lifting and fixing the upper structure 1 of the bridge is deteriorated.

In addition, the hydraulic jack fixing device 140 should be used that fits the thread of the hydraulic jack 120, but it is not compatible with the hydraulic jack 120 of various sizes, so the convenience of use that cannot be used for other hydraulic jacks 120 is remarkably. Falling problems arise.

The present invention has been devised to solve the above-described problem, and provides a functional lifting lock device 200 comprising a lower fixing part 210, an upper fixing part 220, and a fixing adjustment part 230.

As shown in Figure 3, the functional lifting lock device 200 of the present invention has a configuration in which the fixed adjustment unit 230 is inserted between the lower fixing portion 210 and the upper fixing portion 220 is used.

As shown in FIG. 4, the lower fixing part 210 of the present invention performs a function of contacting and supporting the upper surface part 111 or the bottom part 2 of the hydraulic pump 110, and by the fixed adjusting part 230 It refers to a device or means that performs a function of ascending or descending in response to the upper fixing part 220.

The lower fixing part 210 is configured to include a lower fixing part body part 211 and a lower fixing part threaded part 212.

The lower fixing body 211 is a part that forms the body of the lower fixing body and performs a function of being contacted and supported by the upper surface 111 of the hydraulic pump 110 by receiving the load of the upper structure 1 of the bridge. It means a device or structure.

Accordingly, the lower end portion 211-1 of the lower fixing portion main body 211 is preferably formed in a flat shape as it performs a function of being contacted and supported by the upper surface portion 111 of the hydraulic pump 110.

As shown in FIGS. 4 and 4B, the lower fixing part main body part 211 has a lower part 211-1, a front part 211-2, a rear part 211-3, and side parts 211-4 on both sides. ).

The technical feature of the present invention is in the structure of the lower fixing part 210 described above, in which the height LD1 of the front part is formed lower than the height LD2 of the rear part, and the difference between the heights (LG1) is formed. It is characterized by being.

The height LD1 of the front part means the height between the point where the thread of the threaded part starts and the bottom surface.

In addition, the height LD2 of the rear portion refers to a height between the end of the thread of the threaded portion and the bottom surface.

It is effective that the difference (LG1) between the heights of the front portion and the rear portion is formed of about 0.5 to 50 mm, preferably about 1 to 4 mm.

The lower fixing portion threaded portion 212 of the present invention is formed inside the body portion of the lower fixing portion, and is preferably formed in a concave shape.

In addition, the lower fixing portion threaded portion 212 is characterized in that it is formed to be concave while having a height difference (LG1) from the height (LD1) of the front portion to the height (LD2) of the rear portion as described above.

The structure in which the lower fixing part threaded part 212 is concave is preferably formed in a circular structure, and accordingly, the fixing control part 230 is later provided with the upper fixing part 220 and the lower height. Even if inserted between the tops 210, the fixed adjustment unit 230 prevents separation and functionally increases or narrows the gap between the lower fixing unit 210 and the upper fixing unit 220 while the fixed adjustment unit 230 rotates. Function.

The upper fixing part 220 of the present invention is characterized in that it is formed in the same structure as the lower fixing part 210 described above.

As shown in FIG. 3, when the lower fixing part 210 is rotated 180 degrees, the structure of the upper fixing part 220 is obtained.

The upper fixing part 220 of the present invention performs a function of ascending or descending by the action on the fixed adjustment part 230 supported by the lower fixing part 210, and the lower surface part 1 of the upper structure 1 of the bridge It means a device or means that performs a function of being contact-supported by -1).

The upper fixing part 220 is configured to include an upper fixing part main body part 221 and an upper fixing part threaded part 222.

The upper fixing body part 221 is a part forming the body of the upper fixing part, and means a device or structure that directly receives the load of the upper structure 1 of the bridge and transmits the load to the lower fixing part.

Therefore, the upper surface portion (221-1) of the upper fixing body portion (221) is preferably made of a flat shape as it performs a function of being contacted and supported by the lower surface portion (1-1) of the upper structure (1) of the bridge. It is desirable.

As shown in FIGS. 5 and 5B, the upper fixing part main body 211 has an upper surface part 221-1, an upper front part 221-2, an upper rear part 221-3, and an upper part formed on both sides. It is configured to include a side portion (221-4).

The technical feature of the present invention is in the structure of the upper fixing portion 220, wherein the height of the upper front portion (UD1) is formed lower than the height of the upper rear portion (UD2), and the difference in height (UG1) is formed. It is characterized by the structure.

The height UD1 of the upper front portion refers to the height between the point where the thread of the upper fixing portion threaded portion 222 starts and the extension line of the upper surface.

In addition, the height UD2 of the upper rear portion refers to the height between the point where the thread of the upper fixing portion thread ends and the extension line of the upper surface.

It is effective that the difference (UG1) between the heights of the upper front portion and the upper rear portion is 0.5 to 50 mm, preferably 1 to 4 mm.

The upper fixing part threaded part 222 of the present invention is formed inside the upper fixing part main body part, and is preferably formed in a concave shape.

In addition, the lower fixing portion threaded portion 212 is characterized in that it is formed to be concave while having a height difference (LG1) from the height (LD1) of the front portion to the height (LD2) of the rear portion as described above.

The structure in which the upper fixing portion threaded portion 222 is concavely formed is preferably formed in a circular structure, and accordingly, the fixing adjustment unit 230 later becomes the upper fixing portion 220 and the lower height. The function of preventing the separation of the fixed adjustment unit 230 even if inserted between the tops 210 and increasing or narrowing the gap between the lower fixing portion 210 and the upper fixing portion 220 while the fixed adjustment portion 230 rotates functionally Will perform.

When the fixed adjustment part 230 of the present invention is inserted between the upper fixing part 220 and the lower fixing part 210 and rotated, the gap between the upper fixing part 220 and the lower fixing part 210 It performs the function of widening or narrowing the upper part 220 and the lower part 210 to fix the upper surface part 111 or the floor part 2 of the upper structure 1 and hydraulic pump 110 of the bridge. It means a device or means that performs a function.

The fixed adjustment part 230 of the present invention includes a body part 231, a screw part 232, and a rotation operation part 233.

As shown in FIG. 6, the body part 231 is a part that forms the entire body of the fixed adjustment part 230 and refers to a structure or device that performs a function of transmitting rotational force to the screw part 232.

As shown in Fig. 3, the screw portion 232 is formed on the body portion 231 and a screw thread is formed, and is coupled to the upper fixing portion threaded portion 222 and the lower fixing portion threaded portion 212 to adjust fixed When the part 230 rotates, the upper fixing part 220 and the lower fixing part 210 are rotated by meshing the threads of the upper fixing part 222 and the lower fixing part 212 and the screw part 232. It performs a function of widening or narrowing the gap between them.

As shown in Figure 6, the screw portion 232 is characterized in that the front portion diameter (B1) is formed smaller than the rear portion diameter (B2), between the upper fixing portion 220 and the lower fixing portion 210 When the combined fixed adjustment unit 230 is rotated, a function of widening or narrowing the gap between the upper fixing part 220 and the lower fixing part 210 is performed.

The rotation operation unit 233 refers to a structure or device that performs a function of rotating the body unit by receiving a rotational force.

The rotation operation unit 233 is formed or attached to the body unit 231 and performs a function of receiving power from an object or equipment that transmits power, such as a driver or a wrench.

As shown in FIG. 3, the rotation operation unit 233 may have a structure in which a groove is formed in the main body, and a power transmission means such as a driver or a wrench is applied thereto to perform a function of rotating the main body.

The technical feature of the present invention is that it is used in combination in a structure in which the fixing adjustment part 230 is inserted between the lower fixing part 210 and the upper fixing part 220.

According to the present invention, after raising the upper structure 1 of the bridge using the bridge lifting device 100, the lifting lock device 200 of the present invention is applied to the upper structure 1 and the hydraulic pump ( It is installed between the upper surface or the bottom (2) of 110) and operates the fixed adjustment unit 230 to fix the bridge lifting device 100, thereby preventing the upper structure 1 of the raised bridge from descending. Will be performed.

As shown in Fig. 3b, when the impression lock device 200 of the present invention is coupled in a structure in which the fixing adjustment unit 230 is inserted between the lower fixing part 210 and the upper fixing part 220, the coupling rear part is combined. The point that the height (H1) and the height (H2) of the coupling front portion remain the same even when the fixed adjustment unit 230 is rotated to widen and narrow between the lower fixing portion 210 and the upper fixing portion 220 , H1=H2 is a technical feature.

When the upper structure (1) of the bridge is raised by the bridge raising device 100 by the structural function of the present invention, the upper surface part (221-1) of the body part 221 of the upper fixing part is the upper structure (1) of the bridge. ) Of the lower surface portion (1-1) is in full contact and the lower end portion (211-1) of the main body portion 211 of the lower fixing portion is entirely on the upper surface portion 111 or the bottom portion (2) of the hydraulic pump 110 By performing the function of being supported by contact, the efficiency of completely fixing the upper structure (1) of the raised bridge so that it does not descend is remarkably improved.

As shown in Figure 7, the impression lock device 200 of the present invention may be used in one or two or more, and when used in two or more, the fixing force is further enhanced.

In particular, the lifting of the upper structure (1) of the bridge is a very important problem as the work is carried out on the pier, so the safety of the work is very important. The effect of remarkably increasing the stability appears.

In particular, as shown in Fig. 2b, there are many cases where the upper structure 1 and the floor 2 of the bridge are not completely parallel, and after the upper structure 1 of the bridge is raised, the conventional support ( Even when the hydraulic jack 120 is not lowered by using 130), there are many problems in that the support function of the impression fails because the thread of the support part is well damaged due to the difference in load acting to the left and right of the thread formed on the support part. Will occur.

As described below, the present invention has functions and effects that completely solve the problems of the prior art and the prior art.

As shown in FIG. 7, the lifting lock device 200 of the present invention is a lifting lock device installed on the left side of the bridge lifting device 100 when the upper structure 1 and the floor 2 of the bridge are parallel. The height of 200) and the height of the lifting lock device 200 installed on the right side act equally, so that the upper structure 1 of the raised bridge is stably fixed to the left and right so as not to descend.

In addition, as shown in Figures 7b and 7c, the lifting lock device 200 of the present invention is on the left side of the bridge lifting device 100 when the upper structure 1 and the bottom part 2 of the bridge are not parallel. Even when the height (S1) and the height (S2) on the right side are different, the upper fixing part 220 naturally rotates along the axis of the fixed adjustment part 230, and the lower surface part (1- The effect of accurately adhering to and raising the surface line of 1) is shown, and the effect is very well applied even when the upper structure (1) and the floor (2) of the bridge are not parallel.

The material of the lower fixing part 210, the upper fixing part 220, and the fixing control part 230 of the functional lifting lock device 200 of the present invention is made of steel, which is very advantageous for durability and stability.

In particular, the material of the above-described steel is preferably made of carbon steel, and more preferably, the use of high-strength steel exhibits excellent effects on durability and stability.

As an example of the above-described high-tensile steel, in wt%, C: 0.20 to 0.40%, Si: 0.10 to 0.35%, Mn: 0.4 to 1.2%, Al: 0.001 to 0.055%, Cr: 0.6 to 1.1%, Mo: 0.10 to 0.38%, Ni: 0.1~1.5%, P: 0.001~0.015%, S: 0.001~0.010%, Ca: 0.001~0.003%, Cu 0.001~0.01%, the remaining Fe and other unavoidable impurities. .

The above impurities are limited to the range of 0.02% or less nitrogen and 0.003% or less oxygen.

By including an additive to the high-tensile steel as described above, the hardness of the high-tensile steel is increased to increase the fixing force of the functional lifting lock device 200 (that is, the function of preventing the lock device from being crushed by the load of the pier) to be settled down.

The additives described above may be mixed in an amount of 0.0001 to 0.0005 parts by weight to 100 parts by weight of carbon.

The above-described additive refers to a mixture in which V (vanadium), Nb (nebium), Ti (titanium), K (potassium), and Mg (magnesium) are mixed.

The above additives are V (vanadium) 100 parts by weight, Nb (navyum) 80 to 200 parts by weight, Ti (titanium) 50 to 150 parts by weight, K (potassium) 50 to 120 parts by weight, Mg (magnesium) 10 to 50 It is formed by mixing parts by weight.

The present invention increases the strength and workability of the high-tensile steel by including natural functional additives to the high-tensile steel, thereby remarkably improving the workability and durability of the high-tensile steel.

The natural functional additive is preferably mixed with 0.001 to 0.005 parts by weight of carbon 100 parts by weight.

The above-described natural functional additives are 100 parts by weight of Nabokja, 10 to 40 parts by weight of Maekmundong, 110 to 150 parts by weight of Saengjihwang, 50 to 80 parts by weight of Jibuja, 100 to 150 parts by weight of Baekchul, 10 to 30 parts by weight of Sanjoin, 80 to 120 parts of Wiryeongseon Parts by weight, 80 to 120 parts by weight of Cheonodu, 10 to 30 parts by weight of Gosam, 10 to 30 parts by weight of Samae, 80 to 120 parts by weight of Seontoe, 10 to 30 parts by weight of half, 80 to 120 parts by weight of turmeric, 50 to 80 parts by weight of Chungo It means a composition extracted by mixing parts.

The present invention acts to significantly increase the acid resistance and corrosion resistance of the high-tensile steel by further mixing natural reinforcing additives with the high-tensile steel.

It is preferable to mix 1 to 3 parts by weight of the natural reinforcing additive of the present invention based on 100 parts by weight of carbon.

The natural reinforcing additive of the present invention is 100 parts by weight of Gosam, 80 to 120 parts by weight of gyomaek, 80 to 120 parts by weight of Omae, 110 to 150 parts by weight of self-cultivation, 80 to 120 parts by weight of branch, 30 to 55 parts by weight, neck 30 to It refers to a composition extracted by mixing 55 parts by weight, 50 to 80 parts by weight of the heel, and 50 to 80 parts by weight of the mold.

As a method of extracting the natural functional additive and the natural depressant additive of the present invention, 75 to 85% [mass%] ethanol 1000 parts by weight is added to 100 parts by weight of the mixed raw material, followed by reflux extraction for 2 to 4 hours, and the filtrate Can be extracted by decompression and concentration using a rotary evaporator.

Such an extract may be extracted in a powder form of about 5 to 25 parts by weight based on 100 parts by weight of the mixed raw material, and it is preferable to add the extract in a powder form.

The present invention provides a functional impression lock device 200 made of the above configuration and function.

In addition, the present invention is composed of a functional lifting lock device (200 includes one or two or more) consisting of the above-described configuration and function, and is configured to include a hydraulic pump 110, an impression jack 120 to significantly increase the function of the upper structure of the bridge. It provides an improved bridge impression device 100.

The present invention is a useful invention for the industry to produce, manufacture, sell, distribute, and research bridge raising devices.

In particular, the present invention is a useful invention in the industry of producing, manufacturing, sales, distribution, research of the lifting lock device for fixing the hydraulic jack of the bridge lifting device.

Lower fixing part 210, upper fixing part 220, fixed adjustment part 230,
Functional impression lock device 200,
Hydraulic pump 110, impression jack 120, support unit 130, hydraulic jack fixing device 140,
Bridge raising device 100,

Claims (3)

Consisting of including a lower fixing part 210, an upper fixing part 220, a fixed adjustment part 230,
The lower fixing part 210 is configured to include a lower fixing part body part 211 and a lower fixing part threaded part 212,
The upper fixing part 220 is configured to include an upper fixing part body part 221, an upper fixing part threaded part 222,
The fixed adjustment unit 230 includes a body portion 231, a screw portion 232, and a rotation operation portion 233,
It has a structure in which a fixed adjustment part 230 is inserted between the lower fixing part 210 and the upper fixing part 220,
The screw part 232 of the fixed adjustment part 230 has a front part diameter (B1) smaller than a rear part diameter (B2),
The screw portion 232 of the fixing adjustment portion 230 is formed on the body portion 231 and has a screw thread, so that it is combined with the upper fixing portion threaded portion 222 and the lower fixing portion threaded portion 212 When the fixing control unit 230 rotates, the upper fixing portion 220 and the lower fixing portion (220) and the lower fixing portion are rotated by meshing the threads of the upper fixing portion screw thread portion 222 and the lower fixing portion screw thread portion 212 and the screw portion 232 210) A functional lifting lock device, characterized in that it performs a function of increasing or narrowing the gap between the bridges and the hydraulic jack of the bridge lifting device from lowering after the bridge lifting device raises the upper structure of the bridge ( 200).
The method of claim 1,
The lower fixing portion threaded portion 212 is formed in a concave shape inside the lower fixing portion body portion 211,
The upper fixing portion threaded portion 222 is a functional impression lock device 200, characterized in that formed in a concave shape inside the upper fixing portion body portion 221.
One or two or more of the functional lifting lock device of claim 1 or 2 is included, and the bridge lifting device 100 is configured to include a hydraulic pump 110, an impression jack 120.

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