KR20200038163A - Screed attachment of excavator arm for screeding pile of asphalt concrete - Google Patents

Abstract

The present invention relates to an asphalt concrete stack screeding device for an installation in an arm of an excavator, which is provided to lay a pile of asphalt concrete placed on a road surface along a screeding route to be paved in a predetermined width and a predetermined height. The screeding device includes: a screeding device body mounted on an arm of an excavator or a bucket of the excavator; a screeding height determining plate mounted on the screeding device body and determining a screeding height of the pile of the asphalt concrete by coming into contact with the pile of the asphalt concrete in screeding; and screeding width determination plates mounted on the screeding device body and determining the screeding width of the pile of the asphalt concrete as a vertical end is in contact with the pile of the asphalt concrete on both sides of the screeding height determination plate and a horizontal end is in contact with the road. The screeding device body includes: a screeding unit vertical to a screeding direction on which the screeding height determination plate and the screeding width determination plates are mounted; and screeding side units forming a U-shape with the screeding unit in the screeding direction by individually extending from positions, which are separated from a center line of the screeding direction in the screeding unit to both sides, to the front side of the screeding direction at a right angle or at an obtuse angle to the screeding direction, wherein the screeding side units guide the pile of the asphalt concrete to be laid to the screeding unit while coming into contact with the road when the pile of the asphalt concrete is laid. The screeding unit is in contact with the screeding height determination plate and the screeding width determination plates when laying the pile of the asphalt concrete, thereby supporting the screeding height determination plate and the screeding width determination plates in the screeding direction.

Description

Ascon pile stacker for mounting excavator arm {SCREED ATTACHMENT OF EXCAVATOR ARM FOR SCREEDING PILE OF ASPHALT CONCRETE}

The present invention is mounted on an excavator for pavement pavement, the asphalt concrete stacking installation device (attachment) for mounting an excavator arm capable of laying a pile of asphalt concrete (pile of asphalt concrete) already distributed on the road surface along a laying path at a constant height and width. Hereinafter referred to as "the laying machine".

In the field of pavement, excavators were used for crushing work to crush roads, excavating work to dig the ground, loading work to transport soil, and stopping work to clear the ground.

In the conventional pipeline construction (waterworks pipe, sewage pipe, rainwater pipe, gas pipe, electric power pipe, optical cable pipe, etc.), after the pipe was buried, the auxiliary base material was backfilled to the surface according to the level difference of the crushed road surface. For example, after the pipeline construction of the 1,000M section, the asphalt concrete layer is wrapped. At this time, the auxiliary base material, which had been temporarily backfilled, was blown out by matching the height of the road surface to be laid, and then laid out with asphalt. After that, the road surface is compacted evenly with rollers, compacts, and rammers, and then temporarily packed. After compaction, asphalt emulsion is sprayed.

When an Ascon vehicle (usually a 25-ton vehicle, sometimes a 15-ton vehicle) comes, leave the proper distance and divide the 6 to 7-minute Ascon pile along the laying path and get off. In the conventional pipeline construction (waterworks pipe, sewage pipe, rainwater pipe, gas pipe, electric power pipe, optical cable pipe, etc.), after the pipe was buried, the auxiliary base material was backfilled to the surface according to the level difference of the crushed road surface. If the pipeline buried construction is scheduled for a certain period, it will be temporarily packed with ascon base layer packaging on the same day or a few days later. At this time, the backing surface of the auxiliary base material is compacted with an excavator compaction plate, and the auxiliary base material that has been temporarily backfilled is set to the desired height for temporary packaging and then taken out. After digging, the road surface of the auxiliary base material is compacted with a roller, compact, or rammer. Apply the primer for the base layer (asphalt emulsion, RSC-3) to the compacted road surface. Subsequently, the asphalt truck is transported with asphalt packaging material (25 tons or 15 tons), divided into 6 to 7 times to unload the asphalt piles on the laying path, and repeats temporary installation and stopping operations several times with an excavator bucket or wheel loader to repeat the existing asphalt packaging surface. After proper alignment, compact the asphalt concrete compaction equipment (combi roller, etc.) to complete the temporary packaging.

In the present invention, "ascon pile" means ascon to be laid in advance along the laying path, and "laying layer" means a layer having a constant laying height and laying width of the laying asphalt stack by the presenter. A large tire excavator (0.6m3W, narrow road 0.3m3W) should be laid slightly and uniformly in the width to be paved. When paving roads that have already been paved for pipeline construction, not paving the entire road, and laying the desired pipes or cables after laying them along the laying path, the finisher used for asphalt pavement has a wide installation width. Not suitable for small ascon packaging.

When the installation is over, the first compaction is made on the way to the tires of a large tire excavator. Next, you have to cut out the thick part and fill it with the thin part, and then lay the surface flat again. Then, it is compacted with a combi roller.

Excavators have been used for laying asphalt piles using buckets mounted on excavator arms in the temporary pavement of conventional asphalt, due to the limitations of the attachment. However, since the bucket mounted on the excavator arm was mounted for digging the ground, it took a lot of time and was difficult to install precisely in the installation work to install at a certain height and width. In the case of the finisher, as the asphalt is directly supplied from the dump truck, the width of the left and right is adjusted while the amount of laying is adjusted, so that a large load is not applied to the upper and lower left and right mounting plates. On the other hand, in the case of laying ascon piles for temporary pavement after pipeline construction, as the ascon piles previously placed on the laying work path need to be pulled with an excavator, a large load is placed on the left and right sides of the snow plate and the snow plate.

Japanese Unexamined Patent Publication No. JP2007-132156 relates to a screed device for a packaging machine having a placement device for adjusting the amount of a mixture supplied to a screed plate by strike-off. In the screed device of the packaging machine, the packaging material is supplied to the installation plate by performing a strike-off consisting of a rotating body in a sequential rotation or reverse rotation along the packaging material supply direction to the installation plate by a driving means. At this time, by controlling the rotation speed of the strike-off by the driving means, the amount of the packaging material supplied to the installation plate can be adjusted. Therefore, the amount of the packaging material supplied to the installation plate can be easily changed and adjusted even during construction by the packaging machine, but there is no device for adjusting the width of the left and right installation.

Korean Patent Application Publication No. KR10-2002-0084941 relates to a laying machine that wraps pavement materials of each pavement in a certain width and thickness according to the width of the road when paving small roads such as sidewalks, trails, and bicycle roads. It consists of a main body frame, a moving frame, a vibrating device, a guide device, a horizontally moving hydraulic cylinder, a vertically moving hydraulic cylinder, an intermediate fixed hydraulic cylinder, a hydraulic supply device, and a generator. It is guided by a traction device such as a tractor along a boundary stone or a temporary seat installed on both sides of the road, and the width of the material input section can be adjusted according to the width of the road to be laid. It can be freely adjusted and the packaging material is evenly compacted by the vibration device. The laying machine described in Korean Patent Application Publication No. KR10-2002-0084941 adjusts the amount of material to be laid according to the laying width, so that input and laying of the laying material is performed at the same time. Does not take a large load. Even during construction by the packaging machine, the amount of packaging material supplied to the installation plate can be easily changed and adjusted, but when asking a pile of asphalt concrete already laid on the laying path while laying it, there is no means to adjust the width of the left and right, so it is mounted on the excavator. Unsuitable for

Japanese Patent Publication JP H11-264110 provides a road laying machine that can perform the opening of an extended screed in a short time and can be simplified. As the asphalt mixture is compacted, a pair of left and right is disposed behind the traveling direction of the main screed paving the road surface to regulate the movement of the asphalt mixture to the shoulder side from the outside of the expansion screed that substantially expands the compaction range of the main screed. The side plate is moved forward from the stretch screed side to the shoulder side by means of a side plate moving means to form a gap for opening the stretch screed between the stretch screed and the side plate, and an expansion screed is opened at the gap. This structure is mounted on the excavator arm because the main screed to determine the height of the installation and the site plate to determine the width of the expansion and the screed are connected by a telescopic screed so that the side plate is moved to determine the width of the installation. When laying and laying the piles of ascons pre-positioned on the laying work path with the screed and side plates, it cannot withstand the high loads continuously applied to the new screeds and side plates from the contacting ascon piles and the ground.

 When digging the ground with a bucket mounted on an excavator arm, when laying a pile of asphalt concrete previously laid in the laying work path with an excavator, such as a heavy load between the long blade and the side of the bucket, a conventional finisher or screed The structure between the laying part and the laying side of the device did not have sufficient durability to lay the pile of laid asphalt.

In the past, the laying work of the ascon pile previously laid along the laying path in the pipeline construction has been carried out using the bucket mounted on the excavator arm, and the ground contact portion of the bucket forms an efficient form for digging the ground. There was a problem in that it took a long time to install the pre-positioned asphalt concrete pile, and it was impossible to precisely match the installation height and width.

When the mounting plate and the laying side part installed in a conventional finisher or other packaging machine is mounted on an excavator, the load applied to the laying plate and the laying side part can be withdrawn when the asphalt concrete pile placed in the laying path is towed to the laying plate and the laying side part. Since it did not have a structure, the present invention is mounted on an excavator to provide sufficient durability between the laying part and the laying side part of the laying machine, and at the same time, it is possible to install a pile of asphalt concrete previously laid on the laying path at a constant laying height and laying width. The necessity of a gun was raised.

The present invention exerts a height adjusting device and a width adjusting device on the front part of the laying machine, thereby improving the efficiency of laying asphalt packaging and minimizing the economic burden of purchasing equipment in preparation for purchasing the mini-finisher equipment currently in use. Furthermore, it is an object of the present invention to provide a desirable installation structure as a spreader capable of increasing a limited amount of installation of asphalt than in the case of packaging ascon using a conventional excavator bucket flattening operation and small-scale finisher equipment within a limited time.

In one embodiment of the present invention, an ascon pile stacker for mounting an excavator arm for laying a pile of asphalt concrete previously placed on a road surface along a laying path to be packaged at a constant height and width, wherein the laying machine is mounted on an excavator arm or an excavator bucket and installed An aerator body receiving a traction force capable of laying a pile of asphalt concrete in a traveling direction from an excavator; A laying height determining plate which is mounted to the horizontal end of the road surface side of the laying machine main body to be movable up and down and determines the laying height of the stack of asphalt as it comes into contact with the stack of asphalt; And horizontal width ends of the laying machine main body, which are horizontally mounted on both sides, wherein vertical edges perpendicular to the road surface of each of the width-width crystal plates contact the pile of asphalt concrete, and horizontal ends of the width-width crystal plates are In contact with, the laying width determining plates for determining the laying width of the ascon dummy, including: the laying body is vertical to the direction in which the laying proceeds, and the laying portion contacting the laying height crystal plate at the horizontal end of the road surface side of the laying body; And the installation parts extending at a right angle or an obtuse angle with the installation parts forward from the points spaced apart on both sides from the center line of the installation direction to form a "c" shape with the installation parts in the installation progress direction, thereby forming a pile of ascons to be laid. Containing side guides to the laying part; including, the laying height determining plate determines the laying height of the pre-positioned ascon pile along the laying path to be packed with asphalt, and the laying width determining plates of the laying part are pre-positioned along the laying path to be paved with asphalt Determine the laying width of the dummy, and the laying parts and laying side parts of the main body are fixed to each other firmly (without moving) or integrally withstand each other to withstand the load of the asphalt concrete pile to be installed by the traction force and the frictional force in contact with the road surface. It is composed.

In another embodiment of the present invention, all or part of the height-determining plate is in contact with the installation portion of the installation machine body in parallel with the installation portion to receive the traction of the installation machine body in the direction of installation, and each of the installation width determination plates Alternatively, a portion of the main body is in contact with at least one of the main body and the side of the main body in parallel with the main body to receive the traction force of the main body in the direction of installation.

In another embodiment of the present invention, the main body of the installation machine extends in a direction opposite to the direction of the installation progress from the rear side or the rear side of the installation side, and at least one of the rear side portion and the rear side portion is installed on both sides of the rear side portion or the rear side portion. Further comprising a protruding plate having a length higher than the height from the road surface, at least one of the protruding plates and the rear wall portion through which the width of the crystal width plate is penetrated and movable in the left and right directions, the through groove opened in a direction perpendicular to the road surface ( through grooves, or the main body of the installation machine is opened in a direction perpendicular to the road surface so that the installation width determining plate is in contact with the installation front part on one side and the installation side parts on the other side can penetrate the installation side parts and move left and right. It has a through groove.

In another embodiment of the present invention, the laying height determining plate is attached on the laying front part which is the laying direction front side of the laying section or the laying rear section which is the rear direction of the laying section, and determines the laying height of the pile of ascons previously placed along the laying path to be packed with ascon, The laying width determining plates of the laying parts are attached one by one on the left and right sides of the laying front part or the laying front part of the laying part opposite to the laying front part or the laying rear part to which the laying height determining plate is attached, and laying of the pile of asphalt concrete previously laid along the laying path to be packed with asphalt. Determine the width, or both the height of the laying plate and the width of the laying plates are attached in front of the laying front part to determine the laying height and laying width of the ascon pile previously laid along the laying path to be packed with asphalt.

In another embodiment of the present invention, the height-determining plate is fixed to be height-adjustable by a movable actuator mounted on the front-side part of the installation part, which is the front-side part of the installation part, or the rear-side part, which is the rear side of the installation part, and the width-of-coverage determining plates are respectively installed The left and right mounting widths are fixed adjustable by the left and right moving actuators mounted on the negative or rear mounting parts.

In another embodiment of the present invention, the installation front surface portion in front of the installation direction of the installation portion is in contact with the installation height determination plate to support the installation height determination plate at the back of the installation progress direction of the installation height determination plate during installation, and the installation front surface portion is the amount of the installation height determination plate Equipped with guide rails to guide the movement up and down at the end, and the rear surface of the installation section, which is the rear side of the installation section, is in contact with each of the installation width determining plates on both sides, and the installation rear surface is capable of moving left and right moving width determining plates respectively. The guide rails on the horizontal ends of the horizontal widths of the widths of the widths are not contacted with the road surface, and the guide rails for the widths of the widths of the widths of the crystals support the widths of the widths of the widths.

In another embodiment of the present invention, at least one of the installation part and the installation side part extends in a direction opposite to the installation progress direction from the rear part or the installation side parts on both sides of the installation rear part or the installation side parts, and the height from the road surface of the installation width determining plate Further comprising a protruding plate having a higher length, the contact surface of the rear surface portion in contact with the installation width determining plate or the contact surface of the installation side portions and the contact surface of the protruding plates in contact with the installation width determining plate penetrate the width of the crystal width plates and move in the left and right directions Where possible, through grooves are opened in a direction perpendicular to the road surface.

In another embodiment of the present invention, when laying an ascon dummy, further comprising a laying width line pointer indicating a laying width line in front of the laying progress direction of the laying section, and a laying width line indicated by the laying width line pointer in front of the laying width determining plates. Is associated with the snowfall width specified by the snowfall decision.

In one embodiment of the present invention, the distance between the laying width line and the laying center line indicated by the laying width line pointer in front of the laying width determining plates is greater than the distance between the laying width determining plate and the laying center line.

In another embodiment of the invention, the laying width line pointer is a metal bar or metal rod, or an optical pointer.

In another embodiment of the present invention, when laying ascon dummy, a snow width line detection sensor mounted on the top or snow side of the snow main body so as to detect the snow width line in the forward direction of the snow laying part; And a controller for controlling the height of the laying height determining plate and the laying width of the laying width determining plate, the controller receiving a detection signal from the laying width line detection sensor, using the detection signal as an input signal, and setting the input signal. The actuators to the left and right are controlled so that the width of the installation width determining plates follows the input signal compared to the value of the installation width of the determination plates.

In another embodiment of the present invention, the laying front portion and the laying side portion may be integrally formed through sheet metal, welding, or casting production.

The present installation machine is detachably attached to the excavator arm and is mountable in the same way as the excavator bucket fixing device, and is installed on both sides of the installation height determining unit provided on the installation unit and the installation unit to determine the width of the pile of asphalt concrete to be installed. By the laying width determining unit, the width and height of the laying of ascon dummy in the site conditions can be adjusted and adjusted according to the site conditions before or during construction.

The structure in which the laying part of the laying machine body contacts both the laying height determining plate and the laying width determining plates to support both the laying height determining plate and the laying width determining plates in the direction of laying is mounted on the excavator arm Since the retainer retains the supporting force of the main body, the loader withstands the load generated by continuously dragging and dropping the asphalt pile previously placed on the laying path and the load caused by friction generated by contacting the road surface with the tongue side parts extending from the tongue part. It provides stiffness and durability.

In addition, even if the direction of the laying path is slightly changed according to the movement of the excavator by attaching the laying width line pointer, it is possible to install while preventing the laying path from deviating, and the height and width of the laying is increased by the integral configuration of the laying section and the laying side sections. It is possible to install the remaining ascon piles that have been laid and fit inside the laying machine along the laying path of the ascon piles.

Even if the excavator with a bucket or a small wheel loader temporarily installs in a slightly irregular state in a small paving section, moving the ascon dummy loader for mounting an excavator arm completes the installation uniformly, thereby irregularly flattening the pavement compaction surface in the conventional way. It is possible to overcome and reduce the construction cost due to construction supplementation, and improve the economical efficiency and rapid long-distance pavement construction by improving the completion distance by 2 ~ 3 times of the existing pavement construction, so that the smooth running of the car passing through the road can be achieved. It can be guaranteed faster than the method.

The present invention is in addition to the crushing work to crush roads, excavation work to dig the ground, loading work to transport soil, stop work to clear the ground, etc. Ascon pile stacker is mounted on the excavator arm of the ascon pile placed on the pavement path to a certain height and width to expand the working range of the excavator.

1 is a view illustrating an operation of laying a pile of asphalt concrete previously placed on a road surface along a laying path according to an embodiment of the present invention.
2A is a side perspective view of an ascon dummy laying machine according to an embodiment of the present invention.
2B is a rear perspective view of an ascon dummy laying machine according to an embodiment of the present invention.
Figure 2c shows the maximum height (MH) and the maximum width (MW) of the installation part groove of the ascon dummy laying machine according to an embodiment of the present invention.
Figure 2d shows the laying height (D), the laying width (D), the laying width (W), and the maximum width (MW) of the laying part groove defined by the laying height determining plate of the ascon dummy laying machine according to an embodiment of the present invention do.
3A is a rear perspective view of an ascon dummy laying machine according to an embodiment of the present invention.
Figure 3b shows the rear of the ascon dummy laying machine according to an embodiment of the present invention, the protrusion plate attached to the rear laying portion, and the protrusion plate groove of the protrusion plate.
Figure 3c shows the attached width of the mounting plate and the left and right actuators of the rear installation of the asphalt cone dummy laying machine according to an embodiment of the present invention.
3D is another embodiment of a snow height determining plate and a snow width determining plate attached to an ascon dummy laying machine according to an embodiment of the present invention.

1 is an embodiment of laying a pile of asphalt as previously laid along the laying path according to the present invention.

In the present invention, the "ascon pile 8" refers to the asphalt concrete to be laid by the laying machine according to the present invention, which is placed by pre-distributing the asphalt concrete along the laying path 6. In the dump truck, the asphalt concrete is pre-divided along the laying path 6 and unloaded to temporarily lay the asphalt pile 8 along the laying path 6. In the present invention, "temporary laying" means that a pile of asphalt concrete 8 is pre-stacked on the laying route 6 for laying with a certain height and width along the laying route 6 using an excavator or the like from a dump truck that has brought asphalt. it means. Temporarily laid ascon pile 8 has a peak shape in which the center of the asphalt laying path 6 is the highest and the height is lower toward the width of the path, a curvature is formed along the laying path 6 and continues to the end of the laying path 6. . The temporarily laid ascon pile 8 having the peak curvature is laid by the laying layer 4 having a certain height and width by the laying device according to the present invention, and the laying of asphalt concrete layer 4 is laid on the laying path passed by the laying machine. ) Is formed, and the laid ascon laying layer 4 is compacted ascon packed into a certain height and width by a combi roller, which is an ascon paving compaction equipment, so that it is the same height as the existing existing ascon paving parts that are not shredded. Fit.

2A is a side perspective view of an ascon dummy laying machine according to the present invention. A snow loader is mounted on an excavator arm or an excavator bucket, and is mounted on the horizontal end of the road surface side of the snow main body 10 and the snow main body 10 to be movably mounted on the horizontal end of the snow main body 10 when receiving traction power capable of laying a pile of asphalt. It is installed to be horizontally movable on both sides of the horizontal height end of the laying height determining plate 22 that determines the laying height (H) of the ascon dummy 8 in contact with the ascon dummy 8, and the road surface side of the laying machine body 10. And includes the laying width determining plates 32 to determine the laying width of the ascon pile 8, the vertical end of both sides of the main body 10 is in contact with the ascon pile 8 and the horizontal end is in contact with the road surface do.

The aerator body 10 includes an arm mounting portion 12 of an excavator. In another embodiment, the aerator body 10 may include a bucket mounting portion (not shown) that can be mounted to the bucket of the excavator. The excavator mounting portion 12 has the same shape as the arm mounting portion of the bucket so that the excavator arm can be mounted in such a way that the excavator arm is mounted with the bucket. The arm mounting portion 12 of the laying machine may also have a different size of the arm mounting portion according to the size of the excavator. The arm mounting portion 12 is not limited to the size of the excavator and may include a variable arm mounting portion to be mounted on all sizes of excavators. In another embodiment, the excavator body 10 may be mounted on an excavator bucket. In this case, the mounting portion may be mounted using at least one of a clamping mechanism and a screw coupling means, and a metal cable so as to be firmly attached to the bucket. Preferably, the mounting portion of the main body may have a shape coupling portion having the same shape as a fork-shaped bending portion that is mounted against the inner plane of the bucket.

2B is a rear perspective view of an ascon dummy laying machine according to the present invention. The laying part 14 has a laying front part 20 which contacts the asphalt concrete pile 8 in the laying direction, and a laying back surface part 30 which is the opposite surface of the laying front part 20. The main body 10 is extended vertically or curved from the top of the main body 10 in which the arm or bucket mounting portion is located, and extends to the road surface, and the main height determining plates 22 and main width determining plates 32 are mounted. The installation part 14 perpendicular to the installation progress direction and the installation part extending in a right angle or an obtuse angle with the installation part 14 forward from the points spaced apart from both sides from the center line of the installation direction of the installation part and extending at a right angle or an obtuse angle, respectively (14) and "c" shaped, ascon dummy (8) when laying, while laying in contact with the road surface, the ascon pile to be laid includes the laying side portions (31) to guide the laying portion (14).

The laying side part 31 functions to collect the asphalt concrete pile 8 toward the laying width of the laying path 6 and guide the asphalt concrete pile to be laid along the laying path 6 toward the laying part 14. The laying side portion 31 prevents the crumbs from the asphalt pile 8 laid by the laying portion 14 from being left around the asphalt concrete layer laid by the laying machine, that is, around the asphalt road. In one embodiment, the installation side portions 31 form a right angle to the installation portion 14. Since the installation side portions 31 are parallel to the traveling direction of the installation machine when they form a right angle with the installation portion 14, it is possible to reduce the area of contact with the road surface than when the obtuse angle with the installation portion 14 is achieved.

When laying the ascon dummy, the installation part contacts the installation height determining plates and the installation width determining plates to support the installation height determining plates and the installation width determining plates in the direction of installation. All or part of each of the width of the installation plates is in contact with at least one of the installation portion and the installation side portion of the installation machine body parallel to the installation portion to receive the traction force of the installation machine body in the direction of installation. The laying part of the main body of the laying machine may be in contact with the laying height determining plates and the laying width determining plates to transmit the traction force capable of laying the stack of asphalt concrete in the installing direction in the laying height determining plates and laying width determining plates.

In one embodiment, the laying height determining plate is attached on the laying front part which is the installation direction of the laying section or the rear mounting section which is the rear direction of the laying section, and determines the laying height of the stack of ascons previously placed along the laying path to be packed with asphalt. All or part of the installation height determining plate may be in contact with the installation part of the main body in parallel with the installation part to receive the traction force of the main body in the direction of installation. When all of the installation plate of the installation height is in contact with the installation part of the main body in parallel with the installation part, the installation height crystal plate is moved to the maximum height and completely overlaps the installation part to receive the traction force of the installation body in the direction of installation. It is the case. In another embodiment, the laying part may be configured such that the laying height determining plate and the laying width determining plate are both positioned in front of the laying front part in the installation progression direction. In this case, the installation part can directly transmit the traction force to one of the installation height decision plate and the installation width decision plate, and indirectly transmit the traction force to the other of the installation height decision plate and the installation width decision plate located further forward.

2B to 3B show an embodiment in which the laying height determining plate is attached on the laying front part of the laying part. The laying height determining plate 22 of the laying part 14 is movable up and down, and the laying height determining plate 22 is configured to be mounted to be movable in the installation height direction by contacting the laying front part 20. The front part of the installation is in contact with the installation height determining plate to support the installation height determining plate at the rear of the installation progress direction of the installation height determining plate during installation. The front part of the installation is provided with guide rails that guide vertical movement to both ends of the installation height determining plate. The laying front part 20 includes a flange protruding to form a height determining plate guide rail 24 through which the laying height determining plate 22 can move up and down. The installation width determining plates 32 are configured to contact the rear installation portion 30 and be movably mounted in the installation width direction. The rear part of the laying part, which is the rear side of the laying direction of the laying part, makes contact with each of the laying width determining plates on both sides, and the laying rear part does not contact the road surface of the horizontal ends of the laying width determining plates so that the laying width determining plates can be moved left and right, respectively. The guide rails are provided at the horizontal ends. The guide rails for the snowfall width determining plates support the snowfall width determining plate behind the snowfall width determining plate. The installation rear surface portion 30 includes a flange to form the installation width guide plate 34 on which the installation width determining plate 32 can move left and right.

Figure 2c shows the maximum height (MH) and the maximum width (MW) of the installation part groove of the asphalt concrete pile laying machine according to the present invention. In one embodiment, the laying part 14 has a laying part groove, preferably a rectangular laying part groove 21, opened in the direction of the road surface at an end contacting the road surface at an end contacting the pile of asphalt concrete. The installation part groove has a horizontal end that is horizontal to the road surface and defines a maximum installation height of the installation height determining plate, and vertical ends that define a maximum installation width of the installation width determining plates perpendicular to the road surface at both sides of the horizontal end. The installation part groove 21 defines a maximum installation height (MH) and a maximum installation width (MW) of the asphalt concrete pile 8 to be installed. The laying height determining plate 22 configured to adjust up and down to fit the laying height H contacts the laying front part 20 or the laying back part 30 of the laying part 14 and adjusts the laying width W from side to side. The installation width determining plate 32 configured to contact the installation height determining plate 22 is in contact with the installation front part 20 or the installation rear surface part 30 or the installation front part 20 located on the opposite side of the installation rear part 30. Since it can be, the installation part groove 21 is positioned between the installation height determining plate 22 and the installation width determining plate 32. In another embodiment, when the laying height determining plate 22 and the laying width determining plates 32 are configured to be positioned in front of the laying portion, the laying height determining plate 22 and the laying width determining plate 32 are installed in the direction of laying. In order, all can be placed in front of the installation groove 21.

Figure 2d shows the laying height (H), the laying width (W) defined by the laying width determining plate of the ascon dummy laying machine according to the present invention, the maximum width (MW) of the laying unit groove. The laying height (H) is determined by considering the height lowered by compaction to be the same as the height of the surrounding asphalt when compacting after laying a certain height. Since the height compacted after compaction is determined according to the viscosity and temperature of the packed asphalt, the height of the laid layer is constantly determined according to the condition of the asphalt. The laying height H is determined while the laying height determining plate 22 moves up and down and is limited to the maximum height MH of the laying section groove 21.

The laying width W is determined so that the lowered layer can accurately fill the asphalt width when compacted with a roller in consideration of the crushing width of the asphalt crushed by the crusher. Ascon laying layer 4 laid at a certain height and width protrudes above the crushed ascon paving width, so it is generally determined to be 1-5 cm less to the left and right than the ascon paving width. The laying width is determined according to the laying path 6 width because the laying path 6 may be curved and the crushing width to be crushed may be irregular. The installation width W is determined while the installation width determining plate 32 is moved from side to side and is limited to the maximum width (MW) of the installation part groove 21.

The installation side portions 31 extend in the form of a letter “c” and the installation portion 14 toward the installation direction from points spaced wider than the installation path width from the center line of the installation portion 14. The center line of the installation portion 14 The spaced distance of the installation side portions 31 from is greater than or equal to half of the installation width W. Therefore, the half distance of the installation width W is spaced apart of the installation side portions 31 from the center line of the installation portion 14 The distance can be maximized.

In one embodiment, the laying front part 20 and the laying height determining plate 22, and the laying rear part 30 and the laying width determining plate 32 may be coupled to each other by fastening means. The fastening means may be screws or clamps. When the installation height determining plate 22 is located on the rear installation portion 30 and the installation width determining plate 32 is located on the installation front portion 20, the installation front portion 20, the installation width determining plate 32, and the installation rear portion 30 and the installation height determining plate 22 may be coupled to each other by fastening means.

Figure 3c shows the attached width of the mounting plate and the left and right actuators of the rear installation of the asphalt cone dummy laying machine according to the present invention. The laying width determining plate 32 may be moved by a left-right moving actuator that provides a driving force moving left and right. The laying height determining plate 22 can be moved by an up-and-down actuator that provides driving force to move up and down (see FIGS. 2B and 3D). The actuators are connected to the hydraulic pump of the excavator by hydraulic cables and can be adjusted by the controller. The actuator includes actuator bodies 27 and 37 to be mounted with actuators, and actuator drives 28 and 38 to be mounted to a driving target to be driven by the actuator. In one embodiment, the up and down actuator is equipped with an actuator body 27 mounted on the front face portion 20 and a drive portion 28 of the drive actuator mounted on the placement height determining plate 22 to move up and down. The left and right movement actuators can be moved left and right by mounting the actuator's main body (37) to the rear mounting section (30) and driving parts (38) of the actuator to the left and right mounting width determining plates (32). The rear mounting portion 30 may include an actuator shield 39 in front of the left and right moving actuators on the protruding plate 25 to protect the left and right moving actuators.

In one embodiment, the up-and-down movement actuators are hydraulic cylinders, and the piston rod of the hydraulic cylinder is the driving unit of the actuator. In another embodiment, the up and down movement actuators are hydraulic motors, and the rotating shaft of the hydraulic motor is the drive of the actuator. Since the driving actuators are mounted on the front part 20 or the rear part 30, respectively, once the height of the mounting height colon plate and the width of the laying width determining plate 32 are respectively determined, the mounting height mounted on the driving part A fixed force is provided so that the crystal plate 22 and the installation width crystal plate 32 do not move.

The actuators are connected to an actuator control unit that can be mounted on a laying machine or an excavator, and the vertical width or the horizontal width W is controlled by the control unit. The control unit may control the operator to manually adjust the left and right, and manually move the actuators vertically and horizontally through the control unit, or automatically adjust the actuators by sensors to adjust the installation height and the installation width.

The laying machine main body 10 may have the laying parts 14 and the laying side parts 31 integrally formed through sheet metal, welding, or casting. In addition, the installation part 14 and the installation side parts 31 can be fixed to each other firmly (not moving) by fastening device coupling such as bolt and nut coupling or screw coupling. The laying part 14 and the laying side part 31 of the main body 10 are firmly attached to each other so as to provide rigidity or durability sufficient to withstand the load caused by the friction of the asphalt road and the load of the asphalt pile on the laying path during laying. Can be fixed or integrally formed. The laying parts 14 and the laying side body 31 and the connecting surfaces of the laying machine body to the arm mounting part are suitable for laying while the laying parts 14 and laying sides 31 hold the pile of ascon along the laying path 6 Can have a curved curve.

Figure 3b shows the rear mounting portion of the ascon dummy laying machine according to the present invention, a protrusion plate attached to the rear laying portion, and a protrusion plate groove of the protrusion plate. The installation part 14 includes protrusions 25 extending substantially perpendicular to the road surface by a predetermined distance from both sides of the installation rear surface part 30 of the installation part 14 in a direction opposite to the installation progressing direction. The protruding plates are open in a direction perpendicular to the road surface to the portion where the protruding plates and the rear surface portion 30 are in contact with each other, and include the protruding plate through grooves 36 so that the installation width determining plates 32 pass through, and the installation width determining plate The 32 are movable from side to side and parallel to left and right while in contact with the installation front portion 20 and the protrusion plate through grooves 36. The protruding plates 25 provide a support force for the laying width determining plates 32 behind the laying width determining plates 32 when the laying width determining plates 32 are installed in the installation progressing direction.

3d shows an embodiment in which the laying height determining plate 22 is positioned on the rear mounting portion 30. In an embodiment in which the laying height determining plate is attached to the rear surface of the laying part and the laying width determining plates are attached to the laying front part, the laying front part 20 includes guide rails of the laying width determining plate, on both sides of the laying rear part 30. Positioned installation height determining plate guide rails 24 are connected to each other to form a "a" shaped guide rail 24 from the installation rear surface portion 30 so that the height installation height determining plate 22 can move up and down when viewed from the road surface direction. have. The laying width 31 is so that the laying width determining plate 32 is in contact with the laying front part 20 on one side and the laying side parts 31 on the other side can be moved left and right through the laying side parts 31 and move from side to side. It includes a through groove 26 opened in a direction perpendicular to the road surface. The installation width determining plates 32 pass through the through-grooves 26 in the installation side portion and are movable to both sides in parallel to the installation portion 14 from side to side. The "a" shaped guide rail 24 from the installation rear surface portion 30 provides support for the installation height determining plates 22 behind the installation height determining plate 22 when the installation height determining plate 22 is installed in the installation progressing direction . The "a" type guide rail 24 extends between the shanghai-dong actuator bodies 27 and is attached to the installation rear surface portion 30 to increase the support force for the installation height determining plate 22, and to the installation rear surface portion 30 It is possible to form a guide rail having an "E" shaped surface. As the driving means, the actuator of the up-and-down motion is mounted on the rear surface 30 of the actuator body 27 and the driving part 28 of the driving actuator is mounted on the height-determining plate 22 to move up and down. As the driving means, the left and right moving actuators are mounted with the main body 37 of the actuator mounted on the front face part 20 and the drive parts 38 of the actuator mounted on the left and right width determining plates 32 to move left and right. Since the left and right movement actuators come into contact with the pile of retained asphalt, the front and rear parts 30 may include an actuator shield in front of the left and right movement actuators to prevent the left and right movement actuators from contacting the asphalt pile.

2B and 2C, the laying machine includes a laying width line pointer 42 indicating a laying width line in front of the laying progress direction of the laying section when laying ascon dummy. The laying width line pointer 42 extends from the top or the laying side parts 31 of the laying body 10 so as to indicate the laying width line so as to be movable from side to side in the installation progress direction of the laying section 14 when laying. It may be mounted on the mounting table (44). The laying width line pointer 42 is mounted so as to indicate the laying width line from side to side through a fixed position among positions moved from side to side or through rotation in place at the fixed position. An excavator equipped with a snow implementer moves along the installation direction from the front of the installation direction of the installation machine, and proceeds with the installation while adjusting the installation width determined by the installation width determining plate 32 of the installation machine so as not to deviate from the installation path 6. However, the operator adjusts the excavator and the laying machine along the laying path 6, but when laying, the laying width determining plate 32 is obscured by the pile of ascon being laid, so the laying width determining plate 32 moves visually along the laying width. I can't confirm that it is. Therefore, the installation width line pointer 42 protrudes from the installation side portions 31 or the top of the installation machine in front of the installation portion 14, and the installation width line through which the installation width determining plates 32 pass passes from the installation portion 14. It is installed to indicate in advance, and the laying width line pointer 42 is associated with the laying width determined by the laying width determining plate 32 and is configured to lead the laying width in front.

The distance between the laying width line pointer 42 and the laying center line is the same as the distance between the laying center lines of the laying width determining plates, or the distance between the laying width line pointer 42 and the laying center line is set to be different by a predetermined distance. The laying center line means the center line of the laying path, which is half the width of the laying path. The distance between the laying center line and the laying width determining plate may be determined to be smaller than the distance between the laying center line and the laying path width depending on the laying depth down the road surface and the temperature and viscosity of the ascon being laid. If the set width line pointer is set to indicate the set width line, the distance from the set center line to the set width width plates, that is, half of the set width is smaller than the distance from the set center line indicated by the set width line pointer to the set width line Is set. For example, when the distance from the laying center line to the laying width line pointer is 0.6 M, so that the total distance is 1.2 M, the distance from the laying center line to the laying width determining plate is 1 to 2.5 from the laying center line to the laying width line pointer. It is determined to be smaller than cm, so that the overall installation width can be determined from 1.15 to 1.18 M. Therefore, when installing the laying width line pointer 42, the worker does not visually check the laying path line passing by the laying gun, and the laying gun fits the laying path width through the laying width line pointer 42 indicating the laying width line. The laying layer 4 can be operated while visually checking that the laying layer 4 has a laying width smaller than the laying path width by 1 to 2.5 cm and is laid along the line. In another embodiment, the distance from the laying center line to the laying width determining plate is determined to be 1 to 5 cm smaller than the distance from the laying center line to the laying width line pointer, so that the total laying width may be determined to be 1.10 to 1.18 M.

The laying width line pointers 42 may be positioned one by one on the laying side to indicate the laying width on both sides of the laying side. Also, the laying width line pointer 42 may be in the form of a bar or rod, and may be an optical pointer. The optical pointer is mounted on the top or the side of the installation side of the front side of the main body 10 so that the optical pointer is movable from side to side or indicates the width of the side to side through rotation at a fixed position.

In another embodiment, the laying machine is provided with one or more of the laying body main body 10 of the laying side parts 31 or the upper part of the laying body 10 so as to detect the laying width line in the forward direction of the laying section of the laying section when laying ascon dummy, Alternatively, the installation width line detection sensor mounted on the mount 44 connecting the installation side parts 31, and a controller for controlling the installation height W of the installation height determining plate height H and the installation width W of the installation width determining plate Includes. The controller receives a detection signal from the laying width line detection sensor and adjusts the width of the laying width determining plate according to the detection signal. The laying width line detection sensor may be an infrared sensor, an ultrasonic sensor, or a vision sensor. In addition, any sensors suitable for detecting laying paths where a pile of asphalt is required or shredded can be used. The controller 19 may be mounted on the top of the snow implement, and may be mounted on the excavator driver's seat. In other embodiments, the controller 19 may be mounted in the driver's seat of a snow implement or excavator. The controller 19 receives a detection signal from a snow width line detection sensor, uses the detection signal as an input signal, and compares the input signal with the snow width value of the snow width determining plates 32 to determine the width of the snow width determining plates 32. The actuators to the left and right are controlled so that the width follows the input signal. The use of such a controller 19 automatically adjusts the laying path and laying width, so that the worker can more precisely follow the laying width than when manually operating the actuator, shorten the operation time, and improve the efficiency of night work. Can be increased.

In another embodiment, the controller 19 causes the snow width line detection sensor to detect a pre-marked snow path reference line spaced a predetermined distance from the snow width line instead of detecting the snow width line, and uses the spaced distance to accurately set the snow. You can calculate the width and control the left and right actuators. In this case, preferably, the path detection sensor may be mounted on the front edge (edge) of the installation side. In addition, the laying path reference line may be displayed at a position where the front edges of the laying side parts pass. As the laying side portions guide the pile of asphalt concrete toward the laying portion, the laying side portions of the laying machine can be erased when passing over the reference line of the laying path. If the temporary laying asphalt pile covers the laying path, it may be difficult to accurately detect the laying path, so it is possible to create a laying path reference line spaced a certain distance from the laying path without the asphalt cone. The laying path reference line may be marked with chalk or white paper, and may be marked with chalk, paint, or paint containing a material that the sensor is easy to detect.

In another embodiment, the controller 19 includes a storage device, and may store information about the laying path and the laying width by pre-scanning the laying path to be shredded or packaged without shredding before installation. The laying path scan may scan the laying path to be paved in advance by the excavator equipped with the laying machine before the asphalt cone is moved to the laying position, or marked as the path to be paved. Alternatively, the laying path may be transmitted to the controller 19 after the laying path is pre-scanned with a separate laying path location scanning device to transmit information regarding the laying path and laying width. Using the information regarding the laying path and the laying width, the controller 19 can control the left and right moving actuators according to the predetermined laying path and the laying width. The laying path scanning device may be an infrared sensor, an ultrasonic sensor, or a vision sensor that can be used as an image sensor or a laying width line detection sensor. In this scan operation, even if it is difficult to visually detect an accurate laying path because the laying path to be laid is temporarily covered with a pile of asphalt concrete, it is possible to lay the asphalt stack along the laying path with an accurate laying width.

Claims (11)

An ascon pile stacker for mounting an excavator arm for laying a stack of ascons previously placed on a road surface along a path to be paved at a constant height and width, wherein the stacker is
An excavator body mounted on an excavator arm or an excavator bucket and receiving a traction force capable of laying an asphalt pile in the direction of installation, from the excavator body;
A laying height determining plate which is mounted to the horizontal end of the road surface side of the laying machine to be movable up and down and determines the laying height of the stack of asphalt as it comes into contact with the stack of asphalt; And
As the laying width determining plates mounted on both sides of the horizontal side of the road surface side of the main body, the vertical ends perpendicular to the road surface of each of the laying width determining plates contact the pile of asphalt concrete, and the horizontal end of the laying width determining plates is the road surface. And in contact with, to determine the laying width of the stack of asphalt concrete, including:
The main body of the aerator
A laying part which is perpendicular to the installation progressing direction and which comes into contact with the laying height determining plate at the horizontal end of the laying machine body; And
From the points spaced apart on both sides from the center line of the laying direction of the laying section, it extends at right angles or at an obtuse angle to the laying section, respectively, so as to form a “c” shape with the laying section in the direction of laying, so ascon piles are laid. Includes; laying side portions for guiding the pile of asphalt to be toward the installation portion,
The laying height determining plate determines the laying height of the pre-positioned asphalt cone along the laying path to be paved with asphalt, and the laying width determining plates of the laying section determine the laying width of the previously placed asphalt cone pile along the laying path to be paved with asphalt,
The laying parts and the laying side parts of the main body of the laying machine are fixed so as not to move with each other by bolt and nut coupling or screwing to withstand the load of the asphalt pile to be laid by the traction force and the frictional force contacting the road surface, Or integrally,
Ascon dummy laying machine for mounting excavator arms.
According to claim 1,
All or a part of the installation height determining plate is in contact with the installation part of the installation machine body in parallel with the installation part, and receives the traction force of the installation machine body in the direction of installation, and
All or part of each of the width of the snowboard width determining plates is in contact with one or more of the snowfalling section and the snowfall side of the snowfaller body in parallel with the snowfall section, and receives the traction force of the snowfaller body in the direction in which the snow is installed,
Ascon dummy laying machine for mounting excavator arms.

According to claim 1,
The main body of the laying machine extends in a direction opposite to the installation progressing direction from the rear side of the installation or the side of the installation on both sides of the rear side or the side of the installation, which is the rear side of the installation side, which is the rear side of the installation side, and extends in a direction opposite to the direction of the installation. Further comprising protrusions having a length higher than the height from the road surface,
At least one of the protruding plates and the rear surface portion to form through-holes through the grooves opened in a direction perpendicular to the road surface, through which the width-width crystal plates can penetrate and move in the left-right direction,
Ascon dummy laying machine for mounting excavator arms.
According to claim 1,
The main body of the laying machine is provided with through grooves opened in a direction perpendicular to the road surface so that each of the width-determining plates can be moved left and right through the laying side parts while contacting the laying side parts on one side and contacting the laying side parts on the other side. doing
Ascon dummy laying machine for mounting excavator arms.
According to claim 1,
The laying height determining plate is attached on the laying front part which is the installation direction of the laying part, or the laying rear part which is the rear direction of the laying part, and determines the laying height of the pile of ascons previously placed along the laying path to be packed with asphalt, and the laying width determining plates of the laying part are Determine the laying width of the pile of ascons previously placed along the laying path to be packaged by being attached one by one on the left and right sides of the laying front part or the laying front part which is opposite to the laying front part or the laying rear part to which the laying height determining plate is attached, or
Both the laying height determining plate and the laying width determining plates are configured to be positioned in front of the laying front part to determine the laying height and laying width of a stack of ascons placed in advance along the laying path to be packed with asphalt,
Ascon dummy laying machine for mounting excavator arms.
According to claim 1,
An up-and-down actuator mounted on the installation front part which is the installation direction front part of the installation part or the installation rear part part which is the rear direction in the installation direction; And the left and right movement actuators mounted to the front and rear parts of the installation;
The installation height determining plate is fixed to be adjustable in height by the up-and-down actuator,
The installation width determining plates are fixed to each other by adjusting the installation width by the left and right movement actuators,
Ascon dummy laying machine for mounting excavator arms.
According to claim 1,
The laying front part, which is in front of the laying direction of the laying part, comes into contact with the laying height determining plate to support the laying height determining plate at the back of the laying progress direction of the laying height determining plate during installation, and the installing front part moves up and down at both ends of the laying height determining plate It is provided with guide rails to guide this possible,
The rear part of the installation part, which is the rear side of the installation direction of the installation part, makes contact with each of the installation width determining plates on both sides thereof, and the installation rear part does not contact the road surface of the horizontal ends of the installation width determining plates so that the installation width determining plates can be moved left and right, respectively. Guide rails on the horizontal end portions, and the guide rails for the width determining plates support the width setting plates behind the width setting plates,
Ascon dummy laying machine for mounting excavator arms.
The method according to any one of claims 1 to 7,
When laying ascon dummy, further comprising a laying width line pointer indicating a laying width line in the forward direction of the laying progress of the laying section,
The laying width line indicated by the laying width line pointer in front of the laying width determining plates is associated with the laying width defined by the laying width determining plates,
Ascon dummy laying machine for mounting excavator arms.
The method of claim 8,
The distance between the laying width line and the laying center line indicated by the laying width line pointer in front of the laying width determining plates is greater than the distance between the laying width determining plate and the laying center lines,
Ascon dummy laying machine for mounting excavator arms.


The method of claim 8,
The installation width line pointer is a metal bar or a metal rod, or an optical pointer,
Ascon dummy laying machine for mounting excavator arms.
The method of claim 6,
When laying ascon dummy, one or more of the laying side parts of the main body or the upper part of the main body or the mounting side connecting the laying side parts so as to detect the laying width line in the forward direction of the laying part is installed. Detection sensor; And
Further comprising; a controller for controlling the shandong-dong actuator and the left-right movement actuator to adjust the height of the laying height determining plate and the laying width of the laying width determining plate;
The controller receives a detection signal from the laying width line detection sensor and adjusts the width of the laying width determining plate according to the detection signal,
Ascon dummy laying machine for mounting excavator arms.

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