JP2010037843A - Screed and method for testing gas sealability of the screed - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a screed and a method for testing gas sealability of the screed which enable economical test of gas sealability in a shorter time with a simple structure. <P>SOLUTION: The most upstream opening and closing valve 21 and the most downstream opening and closing valves 27-30 are installed respectively at one end of the most upstream end of a gas supply pipe 16 of the screed 5 in the gas flow direction T and the other end of the most downstream end in the gas flow direction T, and pressure detecting means 31-34 for detecting gas pressure in the gas supply pipe 16 are installed between the most upstream opening and closing valve 21 opening and closing the gas supply pipe 16 and the most downstream opening and closing valves 27-30. Before starting paving work, the most upstream opening and closing valve 21 is opened to supply fuel gas from a gas cylinder 15 into the gas supply pipe 16, and when the indicated pressures of the pressure detecting means 31-34 become a predetermined pressure, the most upstream opening and closing valve 21 is closed, and the gas sealability is evaluated based on the presence of a decrease in the indicated pressures of the pressure detecting means 31-34. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a screed device for a paving machine that spreads the paving material while heating, and a gas sealability inspection method for the screed device.

  2. Description of the Related Art Conventionally, paving machines such as asphalt finishers, repavers, and remixers are equipped with a screed device that spreads and mixes a composite material (paving material) on a road surface (for example, see Patent Document 1). The screed device includes a screed body in which a base plate for spreading and leveling the composite material is integrally provided on the screed frame, and a heating device for heating the base plate to substantially the same temperature as the composite material. ing.

  The heating device is connected to the gas cylinder, the burner integrally attached to the screed frame, the blower for sending air toward the side of the burner, the gas cylinder and the burner, and fuel gas such as LPG is supplied from the gas cylinder. And a gas supply pipe for supplying to the burner. Further, the gas supply pipe includes a regulator for reducing the primary pressure of the gas cylinder and supplying fuel gas to the burner, and a temperature for opening and closing the gas supply pipe according to the temperature of the base plate (supply / stop of fuel gas to the burner). A control on-off valve is provided. When the temperature control on / off valve is opened and fuel gas is supplied from the gas cylinder to the burner, it is ignited by the spark plug, and high-temperature combustion gas is blown onto the upper surface of the base plate as well as blown by the blower. Heated.

By heating the base plate uniformly in this way, the composite material on the road surface does not cool down and adhere to the base plate while being in contact with the base plate. It becomes possible. Further, the opening / closing operation of the temperature control on / off valve is controlled by a controller (control means). When the base plate is heated to a predetermined temperature by the burner, the controller controls the temperature based on the detection result of the temperature sensor. The on-off valve is controlled to close, and the supply of fuel gas is stopped. When the temperature of the base plate decreases, the controller controls to open the temperature control on / off valve, fuel gas is supplied to the burner, and the base plate is heated again to a predetermined temperature.
JP-A-8-239804

  By the way, in the conventional screed device, for example, a gas detection sensor is provided inside the screed frame and the fuel gas sealability can be inspected by this gas detection sensor. Therefore, it has been desired to be able to perform an economical gas seal inspection.

  In view of the above circumstances, an object of the present invention is to provide a screed device and a gas seal property inspection method for a screed device that can perform an economical gas seal property inspection in a shorter time with a simple configuration. And

  In order to achieve the above object, the present invention provides the following means.

  The screed apparatus according to claim 1, further comprising: a screed body in which a base plate for spreading and leveling a paving material is provided integrally with the screed frame; and a heating apparatus for heating the base plate. The heating device includes a gas cylinder, a burner integrally attached to the screed frame, one end connected to the gas cylinder and the other end connected to the burner, and a gas supply pipe for supplying fuel gas from the gas cylinder to the burner. The gas supply pipe is provided with a most upstream side opening / closing valve for opening and closing the gas supply pipe and a most downstream side opening / closing on one end side on the most upstream side in the gas flow direction and the other end side on the most downstream side in the gas flow direction. And a pressure detecting means for detecting the gas pressure in the gas supply pipe is provided between the most upstream side opening / closing valve and the most downstream side opening / closing valve. To.

  The screed device according to claim 2 is the screed device according to claim 1, wherein the heating device includes a plurality of burners, and the gas supply pipe includes a plurality of branch pipes connected to the other ends of the burners. Each of the plurality of branch pipes of the gas supply pipe is provided with a most downstream side open / close valve on the other end side, and opens and closes the branch pipe to the branch portion side on one end side to selectively supply fuel gas to each burner. For this purpose, a channel selection opening / closing valve is provided, and pressure detecting means is provided between the channel selection opening / closing valve and the most downstream opening / closing valve of each branch pipe.

  The screed device according to claim 3 is the screed device according to claim 1 or 2, wherein the most upstream side on-off valve and the most downstream side on-off valve, or the most upstream side on-off valve and the most downstream side on-off valve and channel selection are selected. And a control means for controlling the opening / closing operation of the on-off valve.

  The screed device according to claim 4 is the screed device according to any one of claims 1 to 3, further comprising a control device connected to the pressure detection device and an alarm device connected to the control device. While the side open / close valve and the most downstream side open / close valve are closed, the pressure detecting means detects a decrease in the gas pressure in the gas supply pipe, and the control means receiving the detection result from the pressure detecting means outputs an operation signal. The alarm device is configured to issue an alarm.

  The gas seal property inspection method for the screed device according to claim 5 is a method for inspecting the gas seal property of the screed device according to any one of claims 1 to 4, wherein before the pavement operation is started, When the most upstream side on-off valve and the most downstream side on / off valve are closed, the uppermost stream side on / off valve is opened and fuel gas is supplied from the gas cylinder into the gas supply pipe. When the indicated pressure of the pressure detecting means becomes a predetermined pressure The most upstream side on-off valve is closed, and the gas sealing performance is evaluated based on the presence or absence of a decrease in the indicated pressure of the pressure detecting means.

  In the screed device according to claim 1, before starting the pavement work, the most upstream side on-off valve and the most downstream side on-off valve are opened from the state where the most upstream side on-off valve and the most downstream side on-off valve are closed, and fuel gas is introduced into the gas supply pipe from the gas cylinder When the indicated pressure of the pressure detecting means reaches a predetermined pressure, the most upstream side on-off valve is closed. And based on the presence or absence of the fall of the instruction | indication pressure of this pressure detection means, it becomes possible to confirm the gas-sealing property of a gas supply pipe | tube. Thus, with respect to the conventional screed device, the most upstream side opening / closing valve and the most downstream side opening / closing valve are provided on one end side and the other end side of the gas supply pipe, and between the most upstream side opening / closing valve and the most downstream side opening / closing valve. With a simple configuration in which the pressure detecting means is provided, it is possible to perform an economical gas seal inspection in a shorter time.

  In the screed device according to claim 2, from the state where the most upstream side open / close valve and the channel selection on / off valves and the most downstream side open / close valves of all the branch pipes are closed, for example, the most upstream side open / close valve and one By opening the channel selection opening / closing valve of the branch pipe, the fuel gas can be supplied only from the gas cylinder to the gas flow path (gas supply line, channel) for supplying the fuel gas to the burner connected to the branch pipe. Then, by closing the most upstream side on-off valve and confirming the indicated pressure of the pressure detecting means provided in this branch pipe, it becomes possible to inspect the gas sealability of this gas flow path. Similarly, the channel selection on / off valves of the other branch pipes are opened to supply fuel gas to the other gas flow paths, and the most upstream side on / off valves are closed to sequentially detect the pressures provided on the respective branch pipes. By confirming the command pressure of the means, it becomes possible to inspect the gas sealing performance for each gas flow path for supplying the fuel gas from the gas cylinder to each of the plurality of burners. As a result, the most upstream side opening / closing valve is provided on one end side of the gas supply pipe, and the channel selection opening / closing valve, the most downstream side opening / closing valve and the pressure detection means are provided in each branch pipe. An economical gas sealability test can be performed.

  4. The screed device according to claim 3, further comprising control means for controlling an opening / closing operation of the most upstream side opening / closing valve and the most downstream side opening / closing valve, or the most upstream side opening / closing valve, the most downstream side opening / closing valve, and the channel selection opening / closing valve. Accordingly, for example, the most upstream side opening / closing valve, the most downstream side opening / closing valve, and the channel selection opening / closing valve can be opened / closed according to, for example, a button operation by an operator. This makes it possible to easily and efficiently inspect the gas sealing performance as compared with the case of manually opening and closing each on-off valve.

  5. The screed device according to claim 4, wherein the pressure detecting means detects a decrease in the gas pressure in the gas supply pipe with the most upstream side opening / closing valve and the most downstream side opening / closing valve closed, and the alarm device blinks the alarm light. The alarm is issued by sounding the alarm buzzer. Accordingly, it is possible to perform an economical gas seal inspection in a shorter time with a simple configuration in which a control unit connected to the pressure detection unit and an alarm device connected to the control unit are provided.

  6. The gas sealability inspection method for a screed device according to claim 5, wherein before the pavement operation is started, the most upstream side on-off valve and the most downstream side on-off valve are opened from the state where the most upstream side on-off valve and the most downstream side on-off valve are closed, Gas is supplied into the gas supply pipe, and when the indicated pressure of the pressure detection means reaches a predetermined pressure, the most upstream side on-off valve is closed. And based on the presence or absence of the fall of the instruction | indication pressure of this pressure detection means, it becomes possible to confirm the gas-sealing property of a gas supply pipe | tube. Thus, with respect to the conventional screed device, the most upstream side opening / closing valve and the most downstream side opening / closing valve are provided on one end side and the other end side of the gas supply pipe, and between the most upstream side opening / closing valve and the most downstream side opening / closing valve. With a simple configuration in which the pressure detecting means is provided, it is possible to perform an economical gas seal inspection in a shorter time.

  Hereinafter, a screed device and a gas sealability inspection method for a screed device according to an embodiment of the present invention will be described with reference to FIGS. 1 to 6. Here, the present embodiment relates to a main screed and an extension screed (screed device) of an asphalt finisher.

  Asphalt finisher (paving machine) 1 includes a hopper 2, a feeder conveyor 3, a spreader 4, and a screed device 5 as shown in FIGS. 1 (a) and 1 (b). . The asphalt finisher 1 travels forward, conveys the composite material (paving material) in the hopper 2 disposed at the front part of the vehicle body to the rear part of the vehicle body by the feeder conveyor 3, and the spreader 4 performs the vehicle width direction. Spread almost evenly and lay on the road surface. Then, the mixed material on the road surface diffused by the spreader 4 is spread and smoothed while being pressed by the screed device 5. In this way, the asphalt finisher 1 sequentially drives forward while driving the feeder conveyor 3, the spreader 4, and the screed device 5 so that the road surface can be paved.

  In the present embodiment, as shown in FIG. 2, the screed device 5 includes a screed body 6 and a heating device (burner device) 7, and the screed body 6 presses the mixture on the road surface. A base plate 8 for leveling and a screed frame 10 to which the base plate 8 is integrally attached so as to form a combustion chamber 9 between the base plate 8 are provided.

  The heating device 7 is connected to a plurality of burners (four burners 11, 12, 13, and 14 in this embodiment), a gas cylinder 15 that stores a fuel gas such as LPG, the gas cylinder 15, and the burners 11 to 14. And a gas supply pipe 16 for supplying fuel gas from the gas cylinder 15 to the burners 11 to 14.

  The plurality of burners 11 to 14 are integrally attached to the upper end side of the screed frame 10 at a predetermined interval, and are arranged so that the flame S faces the inside of the combustion chamber 9 and thus the upper surface of the base plate 8. Further, the heating device 7 is provided with a blower 17 for supplying air toward the side surfaces of the burners 11 to 14. And the heating apparatus 7 can heat the base plate 8 uniformly by supplying the high temperature combustion gas which generate | occur | produces by burning the fuel gas with each burner 11-14 into the combustion chamber 9 with the ventilation from the blower 17. It is configured as follows. Further, the screed frame 10 is provided with a flame detection sensor 18 for detecting the flame S of each burner 11 to 14, a temperature sensor (not shown) for detecting the temperature of the base plate 8, a gas detection sensor (not shown), and the like. Yes.

  On the other hand, the gas supply pipe 16 includes a plurality of branch pipes (four branch pipes 16a, 16b, 16c, and 16d in the present embodiment) having one end connected to the gas cylinder 15 and the other ends connected to the burners 11-14. The fuel gas can be supplied from the gas cylinder 15 to each burner 11-14.

  The gas supply pipe 16 has a regulator 20 and two on-off valves 21 between one end connected to the gas cylinder 15 and one end (branch portion 16e) of the first branch pipe 16a connected to the first burner 11 at the other end. , 22 are provided. The regulator 20 is provided in the immediate vicinity of the gas cylinder 15. The two on-off valves 21 and 22 are electromagnetic valves that open and close the gas supply pipe 16. One of the on-off valves 21 is the most upstream side on-off valve, and one end side (the gas cylinder 15 side) on the most upstream side in the gas flow direction T. ) And downstream of the regulator 20 in the gas flow direction T. The other on-off valve 22 is a temperature control on-off valve, and is provided downstream of the most upstream side on-off valve 21 in the gas flow direction T (on the branching portion 16 e side).

  Further, the branch pipes 16b, 16c, and 16d that branch on the downstream side in the gas flow direction T from the first branch pipe 16a are, in order from the upstream side in the gas flow direction T, the second branch pipe 16b that has the other end connected to the second burner 12. The third branch pipe 16 c has the other end connected to the third burner 13, and the fourth branch pipe 16 d has the other end connected to the fourth burner 14.

  The first to fourth branch pipes 16a to 16d are provided with two on-off valves 23 to 26 and 27 to 30 and pressure detection means 31 to 34 such as a pressure gauge and a pressure sensor, respectively. The two on-off valves 23 to 26 and 27 to 30 provided in the branch pipes 16a to 16d are electromagnetic valves for opening and closing the branch pipes 16a to 16d (gas supply pipe 16), and one of the on-off valves 23 to 26 is provided. The channel selection opening / closing valve is provided on one end side (upstream side in the gas flow direction T, branching portions 16e, 16f, 16g, 16h side) of the branch pipes 16a to 16d. These channel selection opening / closing valves 23 to 26 open and close gas flow paths (gas supply lines L1 to L4, channels) for supplying fuel gas from the gas cylinder 15 to the burners 11 to 14 connected to the branch pipes 16a to 16d. The fuel gas is selectively supplied to each burner 11-14. Further, the open / close valves 27 to 30 in the other direction are the most downstream open / close valves and are provided on the other end side (the gas flow direction T most downstream side, the burners 11 to 14 side).

  Further, each of the pressure detection means 31 to 34 is for detecting the gas pressure in the branch pipes 16a to 16d (in the gas supply pipe 16). The channel selection opening / closing valves 23 to 26 and the most downstream side opening / closing valve. 27 to 30 (between the most upstream opening / closing valve 21 and the most downstream opening / closing valve 27-30).

  In the present embodiment, a controller (control means) 35 for controlling the opening / closing operation of each on-off valve 21 to 30 and the drive of the blower 17 is provided. Furthermore, the pressure detection means 31 to 34 and the alarm device 36 are connected to the controller 35. Then, the controller 35 receives the detection results from the pressure detection means 31 to 34, outputs an operation signal to the alarm device 36 based on the detection results, and flashes an alarm light or sounds an alarm buzzer. The alarm device 36 is controlled to emit.

  The controller 35 is connected to each flame detection sensor 18 and a temperature sensor (not shown), and controls the temperature control on-off valve 22 to be closed when the flame detection sensor 18 does not detect the flame S. The supply of the fuel gas to the burners 11 to 14 is stopped. Further, the opening / closing operation of the temperature control on / off valve 22 is controlled in accordance with the temperature of the base plate 8 detected by the temperature sensor, and the supply of fuel gas to the burners 11 to 14 and, consequently, the temperature of the base plate 8 are controlled.

  Next, a method for inspecting the gas sealability of the screed device 5 having the above-described configuration will be described, and the operation and effect of the screed device 5 of this embodiment and the gas sealability inspection method for the screed device 5 will be described.

  In the present embodiment, the gas sealability inspection of the screed device 5 is performed before the start of the paving work. In the gas sealability inspection of the screed device 5, first, as shown in FIG. 3, for example, an operation signal is output from the controller 35 in response to an operator's button operation or the like, and all the on-off valves 21 to 30 are closed. From the state, the temperature control on-off valve 22 and the channel selection on-off valve 23 of the first branch pipe 16a are opened. At the same time, the most upstream side opening / closing valve 21 is opened, and the common gas supply line L0 from the gas cylinder 15 to the channel selection opening / closing valves 23-26 of the branch pipes 16a-16d and the channel selection of the first branch pipe 16a are selected. Fuel gas is supplied to the first gas supply line L1 from the on-off valve 23 to the most downstream on-off valve 27. At this time, the primary pressure of the gas cylinder 15 is reduced by the regulator 20, and the gas pressure in the common gas supply line L0 and the first gas supply line L1 rises according to the reduced secondary pressure. Then, when the indicated pressure of the pressure detection means 31 provided in the first branch pipe 16a becomes a predetermined pressure (secondary pressure of the regulator 20), the controller 35 that receives the detection result from the pressure detection means 31 The most upstream side open / close valve 21 is closed.

  Then, the indication pressure of the pressure detecting means 31 of the first branch pipe 16a that detects the gas pressure in the common gas supply line L0 and the first gas supply line L1 does not decrease after a certain time has passed. It is evaluated that the gas sealing performance of the common gas supply line L0 and the first gas supply line L1 is reliable.

  On the other hand, when the command pressure of the pressure detecting means 31 of the first branch pipe 16a decreases, the controller 35 that has received the detection result of the gas pressure drop from the pressure detecting means 31 outputs an operation signal, and the alarm device 36 An alarm is generated by blinking an alarm light or sounding an alarm buzzer. Thereby, it is easily and reliably notified to the operator that the gas sealing performance of the gas supply pipe 16 is not sufficient.

  As described above, when the gas sealing performance of either the common gas supply line L0 or the first gas supply line L1 is not sufficient, an operation signal is output from the controller 35 in response to the operator's button operation or the like. The side opening / closing valve 21 is opened, and fuel gas is supplied to the common gas supply line L0 and the first gas supply line L1. Then, when the command pressure of the pressure detection means 31 of the first branch pipe 16a reaches a predetermined pressure, an operation signal is output from the controller 35, the most upstream side on-off valve 21 is closed, and the first branch pipe 16a The channel selection opening / closing valve 23 is closed. That is, the common gas supply line L0 and the first gas supply line L1 are blocked.

 In this state, the command pressure of the pressure detection means 31 of the first branch pipe 16a indicates only the gas pressure in the first gas supply line L1, and this command pressure decreases after a certain period of time, and again When the warning light blinks or the alarm buzzer sounds, it is determined that the gas sealing performance of the first gas supply line L1 is not sufficient. Further, if the command pressure of the pressure detecting means 31 of the first branch pipe 16a does not decrease after a certain time has elapsed, it is determined that the gas sealing performance of the common gas supply line L0 is not sufficient.

  When it is determined (evaluated) that the gas sealing performance of the common gas supply line L0 and the first gas supply line L1 is reliable by the above operation, an operation signal is output from the controller 35 as shown in FIG. The most upstream side open / close valve 21 and the channel selection open / close valve 24 of the second branch pipe 16b are opened. Thereby, in addition to the common gas supply line L0 and the first gas supply line L1, the fuel gas is supplied from the gas cylinder 15 to the second gas supply line L2, and the gas pressure in the second gas supply line L2 increases. At this time, the controller 35 opens the most upstream side opening / closing valve 21 and the channel selection opening / closing valve 24 of the second branch pipe 16b, and closes the channel selection opening / closing valve 23 of the first branch pipe 16a that has been inspected. In this way, the fuel gas may be supplied only to the common gas supply line L0 and the second gas supply line L2.

  When the command pressure of the pressure detection means 32 of the second branch pipe 16b that detects the gas pressure in the common gas supply line L0 and the second gas supply line L2 does not decrease after a certain time has elapsed, It is evaluated that the gas sealing performance of the second gas supply line L2 is reliable.

  On the other hand, when the indicated pressure of the pressure detecting means 32 of the second branch pipe 16b decreases, the controller 35 that has received the detection result of the gas pressure drop from the pressure detecting means 32 outputs an operation signal, and the alarm device 36 An alarm is generated by blinking an alarm light or sounding an alarm buzzer. Thus, as in the case of the inspection of the first gas supply line L1, the operator is easily and surely informed that the gas sealing performance of the gas supply pipe 16 is not sufficient.

  In this case, the most upstream side opening / closing valve 21 is opened again in response to the operator's button operation, etc., and the fuel gas is supplied again to the common gas supply line L0 and the second gas supply line L1, and the most upstream side The on / off valve 21 and the channel selecting on / off valve 24 of the second branch pipe 16b are closed. By shutting off the common gas supply line L0 and the second gas supply line L2 in this way, the command pressure of the pressure detecting means 32 of the second branch pipe 16b shows only the gas pressure in the second gas supply line L2. It will be. For this reason, when the indicated pressure decreases and the warning light blinks again or the alarm buzzer sounds, it is determined that the gas sealing performance of the second gas supply line L2 is not sufficient. In addition, when the indicated pressure of the pressure detecting means 16b of the second branch pipe 16b does not decrease, it is determined that the gas sealing performance of the common gas supply line L0 is not sufficient.

  Subsequently, when it is determined that the gas sealing performance of the second gas supply line L2 is reliable, the second gas supply line L2 is sequentially checked as shown in FIG. The gas sealability of the third gas supply line L3 and the fourth gas supply line L4 is inspected as shown in FIG. As described above, by sequentially checking the gas sealing properties of the first gas supply line L1, the second gas supply line L2, the third gas supply line L3, and the fourth gas supply line L4 including the common gas supply line L0. Before starting the pavement work, the gas sealability of all the pipes (gas supply pipes 16) of the heating device 7 is confirmed, and when the gas sealability is not sufficient, the occurrence location is specified.

  Then, when it is confirmed that the gas sealing performance of the entire gas supply pipe 16 is reliable, the pavement work is started. During the pavement work, an operation signal is output from the controller 35 by an operator's button operation, etc., all the on-off valves 21 to 30 are opened, fuel gas is supplied from the gas cylinder 15 to the burners 11 to 14, and ignition is performed by the spark plug. Is done. At the same time, the blower 17 is driven, and high-temperature combustion gas is blown onto the upper surface of the base plate 8 through the combustion chamber 9 of the screed frame 10 together with the air blown from the blower 17, and the base plate 8 is uniformly heated. At this time, the flame detection sensor 18 and the gas detection sensor are attached, so that the gas sealability during pavement work can be confirmed (inspected).

  Here, at the time of pavement work, the base plate 8 may be heated by some of the burners 11 to 14 without heating the base plate 8 by all the burners 11 to 14, and the mixed material on the road surface may be spread and leveled. In this case, the controller 35 selectively opens the channel selection on-off valves 23 to 26 of some branch pipes 16a to 16d (closes some of the channel selection on-off valves 23 to 26), and selects the selected channel. The fuel gas is supplied to the burners 11 to 14 to perform the paving work.

  And as mentioned above, in addition to the time of pavement work, the gas sealability of the gas supply pipe 16 of the heating device 7 can be inspected before the start of the pavement work, so that economical gas sealability can be inspected in a shorter time. Thus, the base plate 8 can be suitably heated to perform the paving work.

  Accordingly, in the screed device 5 and the screed device gas sealing property inspection method of the present embodiment, the gas supply pipe 16 is provided with the most upstream side open / close valve 21, the most downstream side open / close valves 27-30, and the pressure detecting means 31-34. Before starting the pavement work, the fuel gas is supplied from the gas cylinder 15 into the gas supply pipe 16 and the presence or absence of a decrease in the indicated pressure of the pressure detecting means 31 to 34 is confirmed. Can be inspected.

  As a result, according to the screed device 5 and the screed device gas sealing property inspection method of the present embodiment, the most upstream side on-off valve 21 and the most upstream side open / close valve 21 on the one end side and the other end side of the gas supply pipe 16 are compared with the conventional screed device. In addition to providing the downstream opening / closing valves 27 to 30, the pressure detection means 31 to 34 are provided between the most upstream opening / closing valve 21 and the most downstream opening / closing valves 27 to 30. It becomes possible to inspect the gas sealability.

  Further, in the screed device 5 of the present embodiment, the channel selection opening / closing valves 23 to 26, the most downstream side opening / closing valves 27 to 30 and the pressure detection means 31 to 34 are provided in the branch pipes 16 a to 16 d of the gas supply pipe 16. By providing, it becomes possible to selectively supply the fuel gas from the gas cylinder 15 to the gas supply lines (gas flow paths, channels) L0 to L4. And it becomes possible to test | inspect the gas-sealing property for every gas supply line L0-L1 by confirming the instruction | indication pressure of the pressure detection means 31-34 provided in each branch pipe 16a-16d sequentially. . Thereby, when the gas sealing performance of the gas supply pipe 16 is not sufficient, it becomes possible to easily identify the occurrence location, and the most upstream side on-off valve 21 is provided on one end side of the gas supply pipe 16, Each branch pipe 16a to 16b is provided with a channel selection opening / closing valve 23 to 26, a most downstream side opening / closing valve 27 to 30 and a pressure detection means 31 to 34, so that an economical gas sealing property can be achieved in a shorter time. An inspection can be performed.

  Further, by providing a controller (control means) 35 for controlling the opening / closing operation of the most upstream side opening / closing valve 21, the most downstream side opening / closing valve 27-30, and the channel selection opening / closing valve 23-26, the button operation by the operator is performed. It is possible to open and close the on-off valves of the most upstream side on-off valve 21, the most downstream side on-off valves 27 to 30, and the channel selection on-off valves 23 to 26. This makes it possible to easily and efficiently inspect the gas sealing performance as compared with the case of manually opening and closing each on-off valve.

  Further, by providing a controller (control means) 35 connected to the pressure detection means 31 to 34 and the alarm device 36, the pressure detection means 31 to 31 with the most upstream side on-off valve 21 and the most downstream side on-off valves 27 to 30 closed. As the gas pressure in the gas supply pipe 16 decreases, an alarm is issued from the alarm device 36, so that the operator can easily and reliably be informed that the gas sealing performance is not sufficient. Thereby, it becomes possible to perform an economical gas sealing test in a shorter time with a simple configuration in which the controller 35 connected to the pressure detection means 31 to 34 and the alarm device 36 connected to the controller 35 are provided.

  As mentioned above, although one embodiment of the screed apparatus according to the present invention and the gas sealability inspection method for the screed apparatus has been described, the present invention is not limited to the above-described one embodiment, and may be appropriately selected without departing from the scope of the present invention. It can be changed. For example, in the present embodiment, the description has been given on the assumption that the paving machine is the asphalt finisher 1. However, the present invention is not limited to the asphalt finisher, and is applied to screed devices of other paving machines such as a repaver and a remixer. May be.

  In the present embodiment, the screed device 5 is provided with four burners 11 to 14, and the gas supply pipe 16 includes branch pipes 16 a to 16 d in order to supply fuel gas to the burners 11 to 14, respectively. However, in the present invention, it is not necessary to limit the number and arrangement of the burners 11 to 14 and the branch pipes 16a to 16d.

  Further, it is assumed that the most upstream side opening / closing valve 21 and the most downstream side opening / closing valves 27 to 30 are electromagnetic valves, and the opening / closing operation thereof is controlled by a controller (control means) 35. The valve 21 and the most downstream side open / close valves 27 to 30 may be cock valves that are manually opened and closed, and the gas supply pipe 16 may be inspected for gas sealing by opening and closing manually by an operator.

  In the present embodiment, before the pavement operation is started, the gas is supplied in the order of the common gas supply line L0, the first gas supply line L1, the second gas supply line L2, the third gas supply line L3, and the fourth gas supply line L4. The explanation was made on the assumption that the sealing performance was to be inspected. On the other hand, in the first stage of performing the gas sealability inspection, the channel selection on-off valves 23 to 26 of all the branch pipes 16a to 16d are opened to supply the fuel gas to all the gas supply lines L0 to L4 and The upstream side opening / closing valve 21 may be closed to inspect the gas sealability of the entire gas supply pipe 16. That is, the gas sealability of the entire gas supply pipe 16 (all the gas supply lines L0 to L4) may be inspected before the gas sealability inspection is performed for each of the gas supply lines L0 to L4 (see FIG. 6). State shown). In this case, when the gas supply pipe 16 is surely gas-sealable, the inspection can be completed by a single operation. Only when the gas-sealability is not sufficient, the gas supply lines L0 to L4 need to be inspected. Therefore, it is possible to efficiently perform the gas sealability inspection.

  Furthermore, in the screed device of the present invention, not only the gas sealing property is inspected based on the presence or absence of a decrease in the indicated pressure of the pressure detecting means 31 to 34, but when an abnormal pressure occurs due to, for example, a failure of the regulator 20, It is also possible to capture this abnormal pressure. For this reason, the screed device of the present invention can also inspect whether there is an abnormality in the fuel gas supply of the entire heating device 7 including the inspection of the gas sealing performance of the gas supply pipe 16.

It is a figure showing a paving machine (asphalt finisher) concerning one embodiment of the present invention. It is a figure which shows the screed apparatus which concerns on one Embodiment of this invention. It is a figure which shows the state which is performing the gas-seal property test | inspection of a common gas supply line and a 1st gas supply line with respect to the screed apparatus which concerns on one Embodiment of this invention. It is a figure which shows the state which is performing the gas-seal property test | inspection of the 2nd gas supply line with respect to the screed apparatus which concerns on one Embodiment of this invention. It is a figure which shows the state which is performing the gas-seal property test | inspection of the 3rd gas supply line with respect to the screed apparatus which concerns on one Embodiment of this invention. It is a figure which shows the state which is performing the gas-seal property test | inspection of the 4th gas supply line (or all the gas supply lines, the whole gas supply pipe | tube) with respect to the screed apparatus which concerns on one Embodiment of this invention.

Explanation of symbols

1 Asphalt finisher (paving machine)
2 hopper 3 feeder conveyor 4 spreader 5 screed device 6 screed body 7 heating device 8 base plate 9 combustion chamber 10 screed frame 11 first burner (burner)
12 Second burner (burner)
13 Third burner (burner)
14 4th burner (burner)
15 Gas cylinder 16 Gas supply pipe 16a First branch pipe (branch pipe)
16b Second branch pipe (branch pipe)
16c 3rd branch pipe (branch pipe)
16d 4th branch pipe (branch pipe)
17 Blower 18 Flame detection sensor 20 Regulator 21 Uppermost flow side on-off valve 22 Temperature control on-off valve 23 Channel selection on-off valve 24 Channel selection on-off valve 25 Channel selection on-off valve 26 Channel selection on-off valve 27 Downstream side on-off valve 28 Most Downstream Open / Close Valve 29 Most Downstream Open / Close Valve 30 Most Downstream Open / Close Valve 31 Pressure Detection Unit 32 Pressure Detection Unit 33 Pressure Detection Unit 34 Pressure Detection Unit 35 Controller (Control Unit)
36 Alarm device L0 Common gas supply line L1 First gas supply line L2 Second gas supply line L3 Third gas supply line L4 Fourth gas supply line T Gas flow direction

Claims (5)

A screed device for a paving machine, comprising a screed body in which a base plate for spreading and leveling a paving material is provided integrally with the screed frame, and a heating device for heating the base plate,
The heating device includes a gas cylinder, a burner integrally attached to the screed frame, one end connected to the gas cylinder, the other end connected to the burner, and a gas supply pipe for supplying fuel gas from the gas cylinder to the burner. And
The gas supply pipe is provided with a most upstream side opening / closing valve and a most downstream side opening / closing valve for opening and closing the gas supply pipe at one end side on the most upstream side in the gas flow direction and the other end side on the most downstream side in the gas flow direction, and A screed device, characterized in that a pressure detecting means for detecting a gas pressure in the gas supply pipe is provided between the most upstream side opening / closing valve and the most downstream side opening / closing valve. The screed device according to claim 1,
The heating device includes a plurality of burners, and the gas supply pipe is configured to include a plurality of branch pipes connected to each burner at the other end,
Each of the plurality of branch pipes of the gas supply pipe is provided with a most downstream side open / close valve on the other end side, for selectively supplying fuel gas to each burner by opening and closing the branch pipe to the branch portion side on one end side. On / off valve for channel selection is provided,
A screed device characterized in that a pressure detecting means is provided between a channel selecting on-off valve and a most downstream on-off valve of each branch pipe. The screed device according to claim 1 or 2,
A screed device comprising control means for controlling the opening / closing operation of the most upstream side opening / closing valve and the most downstream side opening / closing valve, or the most upstream side opening / closing valve, the most downstream side opening / closing valve, and the channel selection opening / closing valve. The screed device according to any one of claims 1 to 3,
A control means connected to the pressure detection means, and an alarm device connected to the control means,
The pressure detection means detects a decrease in gas pressure in the gas supply pipe with the most upstream side open / close valve and the most downstream side open / close valve closed, and the control means that receives the detection result from the pressure detection means outputs an operation signal. A screed device, wherein the alarm device is configured to issue an alarm. A method for inspecting the gas sealability of the screed device according to any one of claims 1 to 4,
Before starting the paving work, open the most upstream side on-off valve from the state where the most upstream side on-off valve and the most downstream side on-off valve are closed, and supply the fuel gas from the gas cylinder into the gas supply pipe,
When the indicated pressure of the pressure detection means reaches a predetermined pressure, close the most upstream side open / close valve,
A gas sealability inspection method for a screed device, wherein gas sealability is evaluated based on the presence or absence of a decrease in the indicated pressure of the pressure detection means.

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