JP2008190143A - Screed apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem with conventional screed apparatuses wherein strike-off cannot be heated uniformly due to unevenness between a portion to which hot air guided to a pipe or a duct and delivered in the strike-off is blown sufficiently so that it is well heated and a portion not heated well. <P>SOLUTION: The base part and the front part inside the strike-off 17 in the screed apparatus 5 are provided with induction coils 18, 19 having a width substantially equal to the length of a screed plate 13. When a high-frequency current is supplied to the induction coils 18, 19, an induced current is generated in the strike-off 17. By this induced current, Joule heat is generated in the strike-off 17, and the strike-off 17 is induction-heated uniformly at a predetermined temperature independently from heating of the screed plates 13L, 13R by hot air generators 22L, 22R. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a screed device including a strike-off that adjusts the supply amount of paving material supplied to a tamper edge.

  Conventionally, this type of screed device is provided in a paving machine such as an asphalt finisher. A paving machine equipped with this screed device transports a paving material such as an asphalt heating mixture charged into the hopper backward from the hopper by a conveyor provided on the bottom surface of the hopper and drops it onto the road surface. Spread on the road. The screed device is provided with a tamper device that compacts the pavement material wound on the road surface, and the tamper edge is moved up and down by driving the tamper motor to compact the pavement material. The supply amount of the pavement material supplied to the tamper edge is adjusted by strike-off, and the pavement material compacted by the tamper edge is spread and leveled by a screed plate. At this time, the strike-off and the screed plate are heated by a heating device to prevent the pavement and the like from adhering to the strike-off and the screed plate, and the pavement surface is smoothly ironed.

In the conventional screed devices disclosed in Patent Document 1 and Patent Document 2, air is heated by a burner (combustor) using LPG such as propane gas or light oil as a fuel, and the heated air is blown onto a screed plate by a blower. As a result, the screed plate is heated. Further, the strike-off is heated by guiding the hot air that has heated the screed plate into the strike-off using a pipe or a duct.
JP 2001-11816 (see paragraph [0006] and FIG. 7) Japanese Patent No. 2872049 (see paragraphs [0018] to [0021] and FIG. 5)

  However, the strike-off in the above-described conventional screed devices disclosed in Patent Document 1 and Patent Document 2 is sufficient in that there is a portion where hot air that is guided to a pipe or duct and is sent into the strike-off is sufficiently blown. There are places that cannot be sprayed. For this reason, in the conventional screed device, unevenness occurs between a portion where hot air is sufficiently blown and heated well and a portion where it is not heated so much, and the strike-off cannot be uniformly heated.

  In the conventional screed device, the strike-off is heated with hot air. To adjust the heat-off temperature of the strike-off, the combustion amount of the burner and the wind power of the blower are adjusted and guided to the pipe or duct. This is done by adjusting the temperature of the hot air sent out. However, it is difficult to finely adjust the strike-off heating temperature by this adjustment, and the strike-off temperature control is not easy.

  The conventional screed apparatus has a structure in which the hot air once heated the screed plate is then guided into the strike-off by a pipe or duct to heat the strike-off. For this reason, in order to sufficiently heat the strike-off at the tip of the screed plate to such an extent that the paving material in contact with the strike-off is not attached, the screed plate must be heated more than necessary. Therefore, the screed plate may be overheated, and the screed plate may be distorted or the components around the screed plate may be damaged by heat. Further, since the screed plate is heated more than necessary, the amount of fuel consumed, such as propane gas, increases.

  The present invention has been made to solve such a problem, and a tamper device that moves a tamper edge up and down by a driving means to compact a road surface on which the pavement material has been wound, and a supply amount of the pavement material supplied to the tamper edge. In a screed apparatus, comprising: a screed plate that adjusts the strike-off, a screed plate that spreads the road surface compacted by a tamper edge, and a screed plate heating means that heats the screed plate. And a strike-off heating means for heating the strike-off by converting electric energy into heat energy. The strike-off heating means includes, for example, a resistance heating device that generates Joule heat disposed on the inner surface of the strike-off, and an induction heating device that generates and heats an induction current in the strike-off.

  According to this configuration, the strike-off is heated by converting the electric energy into the heat energy by the strike-off heating means including a resistance heating device or an induction heating device. Therefore, the strike-off in the screed device of this configuration is provided with the strike-off heating means at the location to be heated, so that the location where the hot air is not sufficiently blown in the strike-off of the conventional screed device is sufficiently heated. become. As a result, the strike-off in the screed device of this configuration is uniformly heated by the strike-off heating means.

  Further, the strike-off heating means controls the heating current for the strike-off by controlling the energization current. Since this energization current in the strike-off heating means can be finely adjusted, the screed device of this configuration adjusts the temperature of the hot air by adjusting the burner combustion amount and the wind power of the blower to perform the strike-off. Compared with the conventional screed apparatus which heats, the temperature management of strike-off becomes easy.

  Further, in the screed device of this configuration, the strike-off is heated independently of the screed plate by the strike-off heating means, and is heated without passing through the screed plate as in the conventional screed device. For this reason, in the screed device of this configuration, the screed plate is not overheated when the strike-off is heated, and the screed plate may be distorted or the components around the screed plate may be damaged by heat as in the past. Disappears. Further, since the screed plate is not heated more than necessary as in the prior art, the consumption of fuel such as propane gas can be suppressed.

  As described above, the screed apparatus of the present invention is provided with the strike-off heating means at the location to be heated, so that the strike-off is uniformly heated by the strike-off heating means. Further, since the strike-off heating means controls the energizing current that can be finely adjusted to adjust the heating temperature of the strike-off, the strike-off temperature management becomes easy. In addition, since the strike-off is heated independently of the screed plate by the strike-off heating means, the screed plate is not overheated, the screed plate may be distorted, and the components around the screed plate may be damaged by heat. Disappear. Moreover, consumption of fuel such as propane gas can be suppressed.

  Next, the best mode for carrying out the present invention will be described.

  FIG. 1 is a partially broken side view showing an outline of the configuration of an asphalt finisher 1 provided with a screed device 5 according to the best mode.

  The asphalt finisher 1 is provided with a hopper 2 on which the asphalt heating mixture k is loaded at the front of the vehicle body. A conveyor 3 for conveying the asphalt heating mixture k loaded on the hopper 2 is provided at the lower part of the vehicle body behind the hopper 2, and a screw spreader 4 is provided at the lower part of the vehicle body further behind the conveyor 3. The screw spreader 4 has screw blades formed on the outer periphery of the screw shaft, and as the screw shaft rotates at a constant speed, the screw blades turn and are supplied from the conveyor 3 and fall on the road surface R. Is spread in the width direction of the road surface R. A screed device 5 is provided at the rear of the vehicle body to spread the spread asphalt heating mixture k and smooth the paved surface. The asphalt finisher 1 travels to the left in the figure, which is the traveling direction, by the pair of front drive wheels 6L and 6R and the pair of rear drive wheels 7L and 7R, and pulls the screed device 5. An operation unit 8 is provided at the driver's seat at the top of the vehicle body, and an operation lever, an operation switch, and the like for operating the screed device 5 are provided in the operation unit 8.

  FIG. 2 is a side view for explaining the outline of the configuration of the front lower portion of the screed device 5.

  The screed device 5 is provided with a screed plate 13 supported by the frame 12 below the screed frame 11 and a tamper device 14 for compacting the road surface. The tamper device 14 includes a tamper motor in a housing 15 attached to the screed frame 11, and the tamper edge 16 is moved up and down along the front end surface of the screed plate 13 by driving the tamper motor. A strike-off 17 is provided on the front side of the tamper edge 16 to adjust the amount of the asphalt heating mixture k supplied to the tamper edge 16 by changing the attack angle α. Inductive coils 18 and 19 are provided on the inner bottom surface and front surface of the strike-off 17. The induction coils 18 and 19 constitute strike-off heating means for heating the strike-off 17 by converting electric energy into heat energy independently of heating the screed plate 13 by a screed plate heating means described later. A deflector 20 is provided on the front side of the strike-off 17. Excess asphalt heating mixture k supplied to the screed plate 13 is sent back to the screw spreader 4 by the deflector 20.

  3A is a cross-sectional view taken along the line IIIa-IIIa in FIG. 2 along the line IIIa-IIIa. FIG. 3B is a cross-sectional view taken along the line IIIb-IIIb in FIG. It is arrow sectional drawing of strike-off 17 which was made.

  As shown in FIG. 2A, the screed plate 13 is configured by including two screed plates 13L and 13R on the left and right, and the frame 12 is also configured by a plurality of frames 12L and 12R. The screed plates 13L and 13R are supported by the frames 12L and 12R, respectively. On the screed plates 13L and 13R between the pair of frames 12L and between the pair of frames 12R, ducts 21L and 21R each having a hollow rectangular parallelepiped shape are provided. Hot air generators 22L and 22R each composed of a burner and a blower are provided at the upper right end of the duct 21L and the upper left end of the duct 21R. The burner uses propane gas as fuel, and the hot air generated by the combustion of the burner is guided into the ducts 21L and 21R by the blower provided at the upper part of the burner to heat the screed plates 13L and 13R. The hot air that has heated the screed plates 13L and 13R is then discharged to the outside from the exhaust port 23 (see FIG. 2) provided at the left end portion of the duct 21L and the right end portion of 21R. The ducts 21L and 21R and the hot air generators 22L and 22R constitute screed plate heating means for heating the screed plates 13L and 13R.

  The strike-off 17 has a width of the same length as the screed plate 13, and has a screed plate on the inner bottom surface as shown in FIG. 5A and on the inner front surface as shown in FIG. The induction coils 18 and 19 are provided with a width substantially the same as 13. These induction coils 18 and 19 are connected to an AC generator (not shown). An induction current is generated in the strike-off 17 by supplying a high-frequency current from the AC generator to the induction coils 18 and 19. Then, Joule heat is generated in the strike-off 17 by this induction current, and the strike-off 17 is induction-heated to a predetermined temperature.

  According to the present embodiment, the strike-off 17 is heated by converting the electric energy into heat energy by the induction coils 18 and 19 as described above. Therefore, according to the screed device 5 of the present embodiment, the strike-off 17 is provided with the induction coils 18 and 19 at the location to be heated, so that the hot air is not sufficiently blown in the strike-off of the conventional screed device. , Become fully heated. As a result, the strike-off 17 in the screed device 5 of the present embodiment is uniformly heated by the induction coils 18 and 19.

  The induction coils 18 and 19 adjust the heating temperature of the strike-off 17 by controlling the energization current. Since this energization current in the induction coils 18 and 19 can be finely adjusted, the screed device 5 of the present embodiment adjusts the temperature of the hot air by adjusting the burner combustion amount and the blower wind force. Compared to a conventional screed device that heats the strike-off, the temperature management of the strike-off 17 is facilitated.

  Further, in the screed device 5 of the present embodiment, the strike-off 17 is heated independently of the screed plate 13 by the induction coils 18 and 19, and is heated without the screed plate 13 as in the conventional screed device. For this reason, in the screed device 5 of the present embodiment, the screed plate 13 is not overheated when the strike-off 17 is heated, and the screed plate 13 is distorted or the components around the screed plate 13 as in the prior art. There is no risk of damage due to heat. Further, since the screed plate 13 is not heated more than necessary as in the prior art, the consumption of fuel such as propane gas can be suppressed.

  In the above embodiment, the case where the induction heating device including the induction coils 18 and 19 is used as the strike-off heating means for heating the strike-off 17 has been described. However, the present invention is not limited to this. For example, a configuration using a resistance heating device made of nichrome wire or the like that generates Joule heat when an electric current is passed may be used as the strike-off heating means.

  In the above embodiment, the screed plate heating means for heating the screed plate 13 is configured to burn propane gas with a burner and blow hot air, but the present invention is not limited to this. For example, as with the strike-off heating unit, an electric heating device that heats the screed plate 13 by converting electric energy into heat energy may be used.

  In the above embodiment, the case where the screed device according to the present invention is applied to a screed device in an asphalt finisher has been described, but the present invention is not limited to this. For example, the present invention can also be applied to a screed device of a road surface layer regenerator such as a remixer or a repuber. Even in this case, the same operation and effect as the above-described embodiment can be obtained.

It is a partially broken side view which shows the asphalt finisher provided with the screed apparatus by one Embodiment of this invention. It is a side view explaining the outline of the structure of the front lower part of the screed apparatus shown in FIG. (A) is a cross-sectional view of the screed device broken along the IIIa-IIIa break line in FIG. 2, and (b) is a cross-sectional view of the strike-off broken along the IIIb-IIIb break line in FIG. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 5 ... Screed device 13, 13L, 13R ... Screed plate 14 ... Tamper device 16 ... Tamper edge 17 ... Strike-off 18, 19 ... Inductive coil 21L, 21R ... Duct 22L, 22R ... Hot air generator

Claims (3)

A tamper device that moves the tamper edge up and down by driving means to compact the road surface on which the pavement material is wound, a strike-off that adjusts the supply amount of the pavement material supplied to the tamper edge, and a road surface compacted by the tamper edge. In a screed device comprising a screed plate for spreading and screed plate heating means for heating the screed plate,
A screed apparatus comprising: a strike-off heating unit that converts electric energy into heat energy to heat the strike-off independently of the screed plate heating by the screed plate heating unit.   The screed device according to claim 1, wherein the strike-off heating unit includes a resistance heating device that generates Joule heat disposed on an inner surface of the strike-off.   The screed device according to claim 1, wherein the strike-off heating means includes an induction heating device that generates and heats an induction current in the strike-off.

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