RU2097476C1 - Moving gear used to push span structures of bridge - Google Patents

Abstract

FIELD: construction industry, building of beam bridges. SUBSTANCE: moving gear has base which upper part carries working table with polished surface, sliding support which lower part is fitted with hydraulic power modules and jacks made fast to it. Transfer pedestals manufactured in the form of vertical jacks are placed in symmetry on both ends of base and sliding support is joined to base by means of horizontal jacks. In process of operation span structure is held off on sliding support with the aid of jacks. After this hydraulic power modules forming oil cushion between sliding support and table are switched on. Horizontal hydraulic cylinders move span structure on. EFFECT: increased functional reliability and efficiency of moving gear. 2 cl, 3 dwg

Description

 The invention relates to the field of construction of predominantly girder bridges constructed using a slide method.

A device is known for sliding the bridge spans located on the head of the support and working on the principle of moving goods in suspension on an air cushion. This device allows you to reduce the frictional force when sliding superstructures in relation to the known mechanical device [1]
However, the equipment of this device is cumbersome, requiring the installation of long gutter-shaped guides and a busy system for collecting fluid leaks. In addition, this equipment is capable of transporting structures of constant weight, while the reaction on the supports when sliding superstructures varies over time over a wide range.

A transfer device for sliding bridge spans is known, comprising a base with a sliding support located on it, horizontal hydraulic cylinders connected by rods and a sliding support, and hydraulic jacks rigidly mounted on it [2]
This device works with reloading elements mounted separately from it on supports, which leads to the separate installation of this equipment, while it is also cumbersome, which, in turn, does not allow to reduce the installation time of the device and increase the productivity of the equipment when sliding.

 The purpose of the invention is to increase productivity by reducing resistance to movement, which allows to reduce the weight and dimensions of the equipment and combine it into one unit, the installation of which takes much less time than its counterparts. This is achieved by the fact that in the known transfer device for sliding bridge spans 2, the base of the device is equipped with reloading stands symmetrically installed at its ends, made in the form of vertical hydraulic jacks and a work table with a polished surface located in its upper part, while the sliding support is provided with located in its lower part, hydraulic power modules, each of which is installed coaxially with a hydraulic jack, and compensation is placed in front of the sliding support functional elements, while the cases of horizontal hydraulic cylinders are pivotally connected to the base.

 Each power module is made in the form of a housing with a cavity in its lower part and a groove located around the perimeter of the housing, in which a movable sealing element is placed, and the groove space above the sealing element and the cavity are communicated with each other and with the pump station, while the compensation elements are made in the form additional hydraulic power modules.

 In FIG. 1 shows a transfer device for sliding bridge spans; figure 2 is the same, a top view; in Fig.3 hydraulic power module in section.

 The transfer device has a base 1, a horizontal working table 2, made of planed steel sheet coated with a thin polished stainless steel sheet. A rigid welded frame 3 is mounted on the surface of the table 2, inside which the power hydraulic modules 4 and the leveling hydraulic jacks 5, mounted coaxially to the modules 4, are tightly fixed. The eyelets of the hydraulic cylinder rods are pivotally fixed on both sides of the frame. hydraulic modules are equipped with peripheral flexible sealing elements 7 and open working cavities 8. in contact with the polished surface of the table 2. On the rods 9 hydrod On the spherical thrust bearings, support shoes 10 are mounted on top of spherical thrust bearings, on which the span 11 is supported. Standard hydraulic jacks 12 are symmetrically installed at both ends of the transfer device, also equipped with spherical thrust bearings and base plates 13, and compensation frames are placed on the front frame in the direction of sliding elements made in the form of additional hydraulic power modules 14 to ensure its guaranteed horizontalness and final ascent to the oil darling.

 The equipment is driven from a two-line pumping station and a block of electro-hydraulic equipment and is controlled from a pulse of remote manual or automatic control, which are also located on the head of the support and are not shown conditionally.

 In the initial position, the span is resting above the pore on the base plates of standard jacks 12, for which their rods are extended to the required height by the pumping station. Hanging the span on an oil cushion, the operator produces a command from the remote control. The corresponding electromagnets of the distributors are turned on, the station pumps enter the operating mode, the filling of the lower cavities of the hydraulic jacks 5 begins, their rods 9 rise up to contact with the span and raise it to a predetermined height, tearing 13 load-bearing pedestals made in the form of jacks 12 from the base plates. During this period, due to the mutual communication of the lower cavities of all hydraulic jacks 5, the load is automatically balanced from the span side to all rods 9 both longitudinally and transversely direction. This ensures uniform loading of the span along the entire length of the bearing area and the equality of support reactions on this support in the transverse direction. Then the filling of the cavities 8 of the modules 4 and their ascent on the oil layer begin. As each module 4 ascends to the required height, its sensors give commands to automatically stop the flow of fluid into the cavity 8, while monitoring the tightness of each module using special peripheral seals 7 pressed against the table 2 by oil pressure. The final elevation of the span to the oil cushion and the leveling of the frame 3 are controlled by additional power modules 14, also rigidly fixed on the frame and create a moment that prevents forward skew arising from the movement of the support.

 The superstructure span is made by pushing installations from the slipway. During this period, the frame 3 with lifting devices with reduced friction slides on the oil cushion formed by the reactive oil pressure in the cavities 8, which are closed from external leaks by the seals 7 of the power modules 4.

 At the end of the next stroke, the sliders for a certain step size of the cavity of the modules are connected to the tank of the pump unit and lowered to the surface of the table 2, and the rods of the hydraulic jacks 5 are forcibly retracted downward. As a result, the span is lowered onto the base plates of standard jacks. By giving a command to the operator, the hydraulic cylinders 6 are also driven, also powered by the pump station, which return the frame to its original position, after which they automatically stop.

 Then the technological cycle of the movement of the span can be repeated. If necessary, the operator in manual mode can adjust the height of the lifting rods of the jacks 12, the magnitude of the forward and reverse.

Claims (3)

 1. A transfer device for sliding bridge spans, containing a base with a sliding support located on it, horizontal hydraulic cylinders connected by rods and a sliding support and hydraulic jacks rigidly mounted on it, characterized in that the base is equipped with load-bearing stands symmetrically mounted at its ends, made in the form vertical hydraulic jacks, and a work table with a polished surface located in its upper part, while the sliding support is provided with lower parts of it by hydraulic power modules, each of which is installed coaxially with a hydraulic jack, and compensation elements are placed in front of the sliding support, while the cases of horizontal hydraulic cylinders are pivotally connected to the base.  2. The device according to p. 1, characterized in that each hydraulic power module is made in the form of a housing with a cavity in its lower part and a groove located along the perimeter of the housing, while the movable sealing element is located in the groove, and the groove space above the sealing element and the cavity communicated with each other and with the pumping station.  3. The device according to p. 1, characterized in that the compensation elements are made in the form of additional hydraulic power modules.

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