KR20140005538U - Apparatus for mixing and pouring of filler for rail construction of concrete slab track - Google Patents

Abstract

The present invention relates to a mobile filling material pouring apparatus and a pouring apparatus for railway construction, and more particularly, to a mobile filling material pouring apparatus and a pouring apparatus for a slab track railway construction capable of being mounted on a vehicle or a train. According to the present invention, a mobile filling material pouring and pouring apparatus includes a lower support plate having a wheel capable of running on a track or a road; A water tank for storing water fixed to the lower support plate; A first reservoir for storing a non-shrinkage composition comprising cement fixed to the lower support plate; A second reservoir for storing a non-shrinkage composition comprising cement fixed to the lower support plate; A metering tank for supplying and discharging the non-shrinking composition from the reservoir; A mixing tank for mixing the non-shrinkage composition discharged from the metering and discharging tank and the water supplied from the water tank; And a pump for pumping and discharging the non-shrinkage mortar mixed in the mixing tank.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a movable filler composition and a casting device for railroad track construction,

More particularly, the present invention relates to a movable filler mixing and pouring apparatus for a railway slab track construction mounted on a vehicle or a train, and more particularly, to a movable filler mixing and pouring apparatus for railway construction.

The railroad industry is constantly evolving as an alternative to green growth and traffic growth due to industrial development. Conventionally, a railway track, a railroad track, a track bed ballast, and a gravel roadway have been installed in the railway track. Recently, a slab railway has been installed to solve or solve various drawbacks of the gravel railway track There is a trend.

The gravel railway track has the advantage of distributing the load transmitted through the rail through the rail evenly to the ground when the train is operated. However, if the period of use is prolonged, the gravel is broken or worn due to the load of the train. Therefore, even though the initial installation cost is relatively low, it is not only costly and time-consuming to maintain, but also has a problem of stability of train operation. In order to solve these problems of the gravel roadway, an on-site concrete piercing orbit has been developed and started to be used from the tunnel section.

This orbit has a higher initial cost than the gravel trajectory, but it has a high stiffness of the orbit, which reduces the maintenance effort due to the damage or deformation of the train due to the load. However, since the orbit of the concrete placed on the site is installed by the method of installing the concrete after the formwork is installed on the site, problems such as complicated installation and long construction period are recognized. In addition, if the track structure is damaged, it is necessary to take the relatively long time, such as demolishing the track structure, re-construction and concrete curing, after stopping the train operation.

Recently, precast slab tracks have been developed to improve the above problems and are being technologically improved. The precast slab track is constructed by prefabricating a concrete slab panel in the factory, transporting it to the site, assembling it on a prefabricated bedrock and concrete base layer. Unlike the on-site concrete pavement, the standardized concrete slab panel can be produced in the factory through strict quality control. Therefore, the panel is excellent in quality, and the complicated and time-consuming construction and installation of the formwork in the field, concrete pouring and curing Since the process is dramatically reduced, the construction period can be shortened.

Furthermore, the precast slab track can be restarted in a short time due to the replacement of the standardized panel, and the curing process is not necessary, so that the train can be quickly restarted in the event of a breakage. Therefore, the inconvenience of the passenger can be reduced, and the maintenance cost and operating loss can be minimized, thereby reducing the overall cost. In short, precast slab track system is an orbital laying method which can improve the economical efficiency by facilitating the high quality of the product, the improvement of the construction speed, the environment friendliness, and the maintenance by mechanized construction after the factory.

In this precast slab track method, a panel is fixed in place on a base layer, and a non-shrinkage mortar composition in which a non-shrinkage composition and water are mixed as a main component is filled and solidified between the panel and the base layer . However, since the non-shrinkage mortar composition starts to solidify immediately when the non-shrinkage composition is mixed with water, there is a possibility that the shrinkage mortar composition becomes solid during transportation if the production factory of the shrinkage mortar composition is excessively separated from the construction site.

In order to solve this problem, there has been used a method of constructing a production factory for a large number of non-shrinkage mortar compositions along a railroad construction section, but there has been a problem that it is difficult to avoid an increase in construction costs.

Korean Patent No. 1129533 issued to Daemyung Industrial Co., Ltd. discloses a mobile asphalt mixing plant. This mobile plant is realized by loading the mixing plant horizontally on its own, transporting it vertically, and mixing it in a place where construction is required. Such a device has a problem that the plant for mixing is required to stand upright every time the construction section is changed, and there is a risk that the mixing plant standing on the vehicle falls over.

Also, since such a mixing plant uses a bucket elevator for conveying the raw material, there is a problem that it is not suitable for mixing a product such as an unshrinkable filler which is required to be precisely mixed in order to ensure high fluidity.

A problem to be solved in this invention is to develop a mobile non-shrinkage mortar composition production apparatus and to provide a new mobile equipment capable of manufacturing a mortar composition at a construction site by transporting a raw material of the mortar composition.

A problem to be solved in the present invention is to make a non-shrinkage mortar of precise composition used for slab track railway construction in a narrow space of a track vehicle or a trailer.

In order to solve the above problems,

A lower support plate with a wheel capable of driving a track or road;

A water tank for storing water fixed to the lower support plate;

A first reservoir for storing a non-shrinkage composition comprising cement fixed to the lower support plate;

A second reservoir for storing a non-shrinkage composition comprising cement fixed to the lower support plate;

A metering tank for metering and discharging the non-shrinking composition from the reservoir;

A mixing tank for mixing the non-shrinkage composition discharged from the metering and discharging tank and the water supplied from the water tank; And

A pump for pumping and discharging the non-shrinkage mortar mixed in the mixing tank;

Shrinkage mortar filling material and a pouring device.

In the present invention, the first reservoir and the second reservoir are formed in the shape of a silo, and the upper part is formed with a storage tank such as a cylinder or a square passage, and the lower part is formed with a tapered part that becomes narrower as it goes downward. The first reservoir and the second reservoir are equipped with a vibrator to prevent the non-shrinkage composition from staying inside the reservoir.

A first transfer conduit is formed between the first reservoir and the second reservoir, and the non-shrinkage composition stored in the first reservoir is transferred to the second reservoir. The first conveying line is connected from the lower end of the inclined portion of the first reservoir to the upper end of the inclined portion of the second reservoir, and the screw conveyor for conveying the non-shrinkable composition is embedded, Lt; / RTI >

A second transfer conduit is formed between the second reservoir and the metering tank to transfer the non-shrinkage composition stored in the second reservoir to the metering tank. The second conveying line is connected from the lower end of the inclined portion of the second reservoir to the upper end of the weighing and discharging tank, and a screw conveyor for conveying the non-shrinking composition is incorporated, so that the non-shrinking composition of the second reservoir is transferred to the weighing and discharging tank. The second conveyance line may be formed of two or more conduits for smooth conveyance at steep slopes from the lower end of the second reservoir to the upper portion of the metering drains.

In the present invention, the weighing and discharging vessel is in the form of a funnel-like funnel under an upper limit, a non-shrinking composition is introduced into the upper end of the second conveying line, a lower outlet is formed with a discharge screw for controlling the discharge amount by rotation, The non-shrinkable composition is discharged in a fixed amount while rotating at the speed The discharge screw is installed to be upwardly inclined so as to eliminate voids inside the screw so that accurate quantification can be achieved.

At the lower end of the metering and discharging tank, there is formed a mixing tank for mixing the water introduced from the water tank and the non-shrinkage composition discharged from the metering tank to discharge the mixed non-shrinking mortar. The mixing tank is a continuous mixing type, and the non-shrinking mortar is continuously discharged by mixing water with the flowing non-shrinking composition.

At the lower end of the mixing tank, a pump tank for pumping the non-shrinkage mortar discharged from the mixing tank is formed. The pump set comprises a pump reservoir for storing the non-shrinkage mortar and a pump for pumping the shrinkage mortar stored in the pump reservoir.

When the device according to the present invention is used, it is possible to solve the problem that the non-shrinkage mortar solidifies while being transferred from the production site to the construction site. Accordingly, the problem of installing a blending plant for producing a non-shrinkage mortar at a place close to the construction site has been solved. In particular, a large amount of non-shrinkage composition can be stored in the two reservoirs, so that a work section that can be constructed by one dispatching becomes long.

In addition, if only a storage tank capable of storing the non-shrinkable composition on the ground and loading it on the moving device according to the present invention is installed, there is no need to install a separate mixing plant for producing a non-shrinking mortar, .

1 is a side view of a device for producing a mobile shrink-free mortar composition according to the present invention.
2 is a plan view of the apparatus for producing a mobile shrink-free mortar composition according to the present invention.
FIG. 3 is a diagram for filling a non-shrinkable composition in a device for producing a mobile shrink-free mortar composition according to the present invention as seen from a ground-type reservoir.

Hereinafter, the present invention will be described in detail by way of examples. The following examples are intended to illustrate the present invention in detail and are not intended to limit the present invention.

As shown in FIG. 1, in the apparatus A for manufacturing a movable shrinkable mortar according to the present invention, a lower support plate 100 having wheels 10 for railway tracks, which can travel to a construction site along a rail, is formed do. When the rail installation is not completed to the installation site, the lower support plate 100 may be a trailer that is moved by a truck.

A water tank 110 for storing water is installed on the lower support plate 100. The water tank 110 may have a rectangular parallelepiped shape or a cylindrical shape and may be fixed to the lower support plate 100 by bolting or welding.

In addition, a first reservoir 120 for storing a non-shrinkage composition containing cement is disposed on one side of the water tank 110 on the lower support plate 100. The first storage tank 120 is formed with a first storage tank 121 having a rectangular parallelepiped shape at its upper portion and a first inclined portion 122 formed at a lower portion thereof with a rectangular funnel shape becoming narrower downward. (120) is fixed to the lower support plate (100) by means of a first support frame (123) which supports the lower edge of the rectangular corner of the first storage tank (121).

In addition, a second reservoir 130 for storing a non-shrinkage composition containing cement is disposed on the upper side of the lower support plate 100, beside the first reservoir 120. The second storage tank 130 is formed with a second storage tank 131 having a rectangular parallelepiped shape at its upper portion and a second inclined portion 132 having a narrower downward shape in the form of a rectangular funnel. (130) is fixed to the lower support plate (100) by a second support frame (133) that supports the lower edge of the rectangular corner of the second storage tank (131).

In addition, a weighing and discharging tank 140 for receiving and discharging the non-shrinking composition from the second storage tank 130 is positioned on the upper side of the lower supporting plate 100, beside the second storage tank 130. The weighing and discharging tank 140 has a funnel shape and is fixed to the lower supporting plate 100 by a third supporting frame 143 that supports the edge of the weighing and discharging tank 140. At the lower end of the metering and discharging tank 140, a discharge pipe 141 having a screw for controlling the rotational speed is formed. The discharge pipe 141 is disposed upward at the lower end of the metering and discharging tank 140 and is disposed at an angle of about 30 ° so that the non-shrinking composition can move upward without slipping.

 The second inclined portion 132 of the second reservoir 130 is connected to the lower end of the first inclined portion 122 of the first reservoir 120 so as to move the non-shrinkage composition stored in the first reservoir to the second reservoir. A first conveying line 124 communicating with the upper end of the first conveying path 124 is formed.

A screw 125 rotating by a motor is housed in the first conveyance pipe 124 and the non-shrinkage composition is conveyed by the rotation of the screw 125. The first conveying line 124 maintains the inclination degree of about 30 degrees so that the non-shrinking composition does not slip and can be conveyed upward to the second reservoir by the rotation of the screw 125. [

The second slope part 132 of the second reservoir 130 is provided at the lower end of the second slope part 132 so as to transport the non-shrinkage composition stored in the second reservoir to the upper part of the metering / A second conveying path 135 is formed. The second conveying line 135 is composed of two conduits, and a screw conveyor (not shown) by screws is incorporated therein to move the non-shrinking composition. The second conveyance line is arranged in parallel to prevent a decrease in the conveyance amount due to the steep slope.

Below the discharge metering tank 140, there is provided a mixing tank 150 capable of kneading and discharging water flowing from the water tank 110 and a non-shrinkage composition discharged in a fixed amount by rotation of the screw in the discharge metering tank 140, . At the lower end of the compounding tank 150, a compounding screw 151 is formed to mix the water and the non-shaking composition and discharge them continuously.

The lower portion of the compounding tank 150 includes a pumping reservoir 161 for pumping and discharging the produced shrinkage mortar and a pump 162 for pumping the same.

Construction using the movable shrinkable mortar production apparatus A shown in Figs. 1 and 2 is carried out as follows. The non-shrinkage composition prepared in the non-shrinkage composition production plant is transferred using a vehicle and stored in the storage space 200. A bucket elevator 210 is formed on one side of the storage space 200 so as to transfer the non-shrinkage composition discharged at the lower end of the storage space 200 to the upper portion of the storage space 200 to discharge the discharge pipe attached to the upper portion of the bucket elevator 210 Shrinkage mortar production apparatus A through the first storage tank 120 and the second storage tank 130 of the mobile shrink-free mortar production apparatus A. Shrinkage composition conveyed through the bucket elevator 210 is filled through the openings attached to the upper portions of the first storage tank 120 and the second storage tank 130.

 The movable shrinkage mallet production apparatus (A) filled with the non-shrinkable composition moves to a place where the precast slab track is installed along a track or a road. The non-shrinkage composition stored in the storage tank 131 of the second storage tank 130 and the storage tank 121 of the first storage tank 120 is transferred to the first transfer line 123 and the second transfer line 133 To the discharge metering tank 140 and discharges the metered amount to the top of the compounding tank 150 from the discharge metering tank 140. In the compounding tank 150, the water discharged from the water tank 110 is mixed with water so as to satisfy the high flowability of the non-shrinkage mortar. The mixture is discharged to the pumping storage tank 161 for pumping, Is filled in the space between the slab and the base layer through the discharge hose 163 attached to the front end of the pump 162 and solidified.

100: Lower support plate 110: Water tank
120: first storage tank 130: second storage tank
140: discharge metering tank 150: mixing tank
160: Pump tank

Claims (8)

A lower support plate that can be mounted on a vehicle capable of driving a track or a road;
A water tank for storing water fixed to the lower support plate;
A first reservoir for storing a non-shrinkage composition comprising cement fixed to the lower support plate;
A second reservoir for storing a non-shrinkage composition comprising cement fixed to the lower support plate;
A metering tank for supplying and discharging the non-shrinking composition from the reservoir;
A mixing tank for mixing the non-shrinkage composition discharged from the metering and discharging tank and the water supplied from the water tank; And
A pump for pumping and discharging the non-shrinkage mortar mixed in the mixing tank;
Characterized in that the mobile non-shrinkage mortar filler formulation and pouring device The method according to claim 1,
Wherein the first reservoir and the second reservoir are cylindrical or polygonal, and the lower portion is formed with an inclined portion that narrows downward. 3. The method of claim 2,
Wherein a first conveying line is formed in which the lower end of the inclined portion of the first reservoir and the upper end of the inclined portion of the second reservoir are communicated and a conveying screw is embedded in the first conveying line, Pouring device. 3. The method of claim 2,
Wherein two sloping sections are formed at the lower end of the second reservoir and two second conveyance conduits are connected to the upper ends of the metering drains at the respective discharge ports. The method according to claim 1,
The metering and emptying tank is in the form of a funnel-like funnel under the light pipe, a non-shrinking composition is introduced from the second conveying pipe at its upper end, and a discharge screw for regulating the amount of discharge by rotation is formed at the lower end discharging port. Wherein the molten metal is discharged. 6. The method of claim 5,
Wherein the discharge screw of the metering and discharging tank is installed to be inclined upwards. The method according to claim 1,
Wherein the compounding tank is a continuous mixing tank provided at the lower end of the metering tank and mixing the water introduced from the water tank and the non-shaking composition discharged from the metering tank and continuously mixing the mixed non-shaking mortar. Shrinkage mortar filling and pouring equipment. The method according to claim 1,
Wherein the first and second reservoirs are further equipped with a vibrator.

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