JP6533667B2 - Tank trailer - Google Patents

Description

  The present invention relates to a tank trailer, and more particularly to a tank trailer that can eliminate the need for updating and maintenance of storage tanks.

  Liquefied gas such as liquefied petroleum gas (LPG) is transported from a base such as an import base or a refinery to a filling place using a mobile storage facility (tank trailer etc.) and temporarily stored in a storage tank of the filling place. The liquefied gas stored in the storage tank of the filling station is filled into a container, and the container is transported to the consumer (Patent Document 1). In order to improve the earthquake resistance and disaster prevention of filling stations, it is urgently necessary to renew aging storage tanks in recent years.

Patent No. 2968766 (FIG. 6 etc.)

  However, in order to improve the earthquake resistance and disaster prevention of the filling station and maintain the condition, mobile storage that carries liquefied gas into the filling station and fills the storage tank with liquefied gas in addition to updating and maintenance of the storage tank Maintenance of equipment (tank trailer etc.) is also required. That is, there is a problem that updating and maintenance of the storage tank and maintenance of the mobile storage facility are required in order to improve the earthquake resistance and the disaster prevention of the filling station and maintain the state.

  The present invention has been made to solve the problems described above, and it is an object of the present invention to provide a tank trailer that can eliminate the need for storage renewal and maintenance.

In order to achieve this object, the tank trailer according to claim 1 comprises a tank filled with liquefied gas, and in the case of being towed by a tractor, the tank comprises a first liquid port to which the liquefied gas is supplied; A gas port through which the vaporized gas is discharged with the supply of the liquefied gas from the first liquid port, and a second liquid port through which the liquefied gas charged therein is sent out by connecting a pump ; A liquid pipe connected to the second liquid port, an emergency shut-off valve disposed on the liquid pipe, a bypass pipe bypassing the emergency shut-off valve and communicating with the liquid pipe, and a relief disposed on the bypass pipe And the emergency shutoff valve is constituted by a ball valve .

  The tank trailer according to claim 2 is the tank trailer according to claim 1, wherein the tank is a recovery port through which a portion of the liquefied gas delivered from the second liquid port to the pump is circulated and recovered from the pump Is equipped.

  The tank trailer according to claim 3 is the one according to claim 1 or 2, wherein the tank is connected to the downstream side of the pump and at least a part of the liquefied gas discharged from the pump is returned. Have a mouth.

  The tank trailer according to claim 4 is the one according to claim 2 or 3, wherein the gas port is shared with the recovery port or the return port.

  The tank trailer according to a fifth aspect is the one according to any one of the first to fourth aspects, wherein the second liquid port is shared with the first liquid port.

  A tank trailer according to any one of claims 1 to 5, further comprising a liquid level detection device for detecting the position of the liquid level of the liquefied gas filled in the tank, wherein the tank is An inner diameter larger than the first small diameter portion and the second small diameter portion, which is located between the cylindrical first small diameter portion and the second small diameter portion located on both sides in the axial direction and the first small diameter portion and the second small diameter portion. And the horizontal axis is set to be inclined downward from the side where the tractor is connected to the opposite side, and the second liquid port has the large diameter. The liquid level detection device detects the position of the liquid level of the large diameter portion.

  A tank trailer according to claim 7 is the one according to claim 6, wherein the liquid level detection device transmits a detection signal regarding the position of the liquid level to an alarm device installed at the installation location of the tank.

  The tank trailer according to claim 8 is the one according to any one of claims 1 to 7, wherein the tank is set to be placed horizontally and is provided with a tilt adjusting mechanism for adjusting the tilt of the axial center of the tank with respect to a horizontal surface. ing.

  The tank trailer according to claim 9 is the one according to any one of claims 1 to 8, wherein the pump is installed with respect to the tank.

Tank trailer according to claim 10, wherein, in the as described in any one of claims 1 to 9, emergency shut-off valve is opened and closed on the basis of the compressed air supplied from the location of the tank.

Tank trailer according to claim 11, wherein, in the as described in any one of claims 1 to 9, emergency shut-off valve is opened and closed on the basis of the compressed air supplied from the air tank installed in the tank.

According to the tank trailer of the first aspect, the liquefied gas is supplied to the tank from the first liquid port, and the vaporized gas is discharged from the gas port with the supply of the liquefied gas from the first liquid port. Thus, the tank is filled with liquefied gas. The tank filled with the liquefied gas is towed by a tractor and separated from the tractor, whereby the tank is installed at an arbitrary place. By connecting a pump to the second liquid port of the tank, the liquefied gas filled inside is delivered to the outside. That is, the liquefied gas can be stored instead of the storage tank at any place where the tractor is disconnected, and the liquefied gas can be delivered to the outside of the tank as needed. According to this tank trailer, storage can be made unnecessary. As a result, it is possible to eliminate the need for updating and maintenance of the storage tank.
Since the relief valve is disposed on the bypass pipe bypassing the emergency shutoff valve disposed on the liquid pipe connected to the second liquid port, excessive load (pressure) is prevented from acting on the liquid pipe and the pump, It protects the pump and prevents the liquid piping from bursting.
The emergency shutoff valve is separated from the second liquid port and disposed in the liquid pipe, so that the pipe resistance of the second liquid port and the liquid pipe can be reduced. Since the emergency shutoff valve is constituted by a ball valve, the pressure loss of the emergency shutoff valve can be reduced. As a result, the effective suction capacity (NPSH) of the pump can be easily secured, so that a general purpose pump having a relatively high capacity can be adopted, and the amount of residual liquid can be reduced by efficiently sucking in the liquefied gas in the tank. .

  According to the tank trailer of claim 2, in the tank, a part of the liquefied gas delivered to the pump from the second liquid port is circulated and recovered from the pump to the recovery port. Since the liquefied gas is easily vaporized, a part of the liquefied gas is heated by the pump and vaporized, which may cause cavitation or gas accumulation. In order to prevent this, it is possible to suppress the occurrence of cavitation or gas accumulation that adversely affects the pump by circulating a part of the liquefied gas and collecting it from the pump to the recovery port. Thereby, in addition to the effect of claim 1, there is an effect that the durability of the pump can be improved.

  According to the tank trailer of claim 3, the tank has a return port connected to the downstream side of the pump, and at least a portion of the liquefied gas discharged from the pump is returned to the return port. As a result, even when the demand for liquefied gas sent to the outside of the tank fluctuates, the minimum discharge of the pump can be secured. Therefore, in addition to the effect of claim 1 or 2, there is an effect that the continuous operation of the pump can be prevented.

  According to the tank trailer of claim 4, since the gas port is shared with the recovery port or the return port, parts constituting the recovery port or the return port, piping connected to the recovery port or the return port, and It is possible to eliminate the need for a space where piping is provided. Therefore, in addition to the effect of claim 2 or 3, there is an effect that the number of parts can be reduced and the space saving property can be improved.

  According to the tank trailer of claim 5, since the second liquid port is shared with the first liquid port, parts constituting the first liquid port or the second liquid port, and the first liquid port or the second liquid The piping connected to the mouth can be eliminated. Therefore, in addition to the effect of any one of claims 1 to 4, there is an effect that the number of parts can be reduced and the space saving property can be improved.

  According to the tank trailer of Claim 6, the position of the liquid level of the liquefied gas with which the tank was filled is detected by the liquid level detection apparatus. The tank has cylindrical first and second small diameter portions located on both sides in the axial direction, and an inner diameter larger than the first small diameter portion and the second small diameter portion between the first small diameter portion and the second small diameter portion. A cylindrical large diameter portion is formed. Since the tank is set to a horizontal position in which the axis is inclined downward toward the rear side of the vehicle, the center of gravity when the tractor is connected as compared with the case where the tank is arranged so that the axis is horizontal. You can lower the height. Therefore, there is an effect that it is possible to improve the stability of the tank trailer pulled by the tractor against falling.

  In addition, since the large diameter portion is set to have a larger inner diameter than the first small diameter portion and the second small diameter portion, the position of the liquid surface of the large diameter portion is detected by the liquid level detection device. The position of the liquid surface can be detected until the remaining amount (filling amount) of the liquefied gas becomes smaller than when the position of the liquid surface of the second small diameter portion is detected by the liquid level detection device. Furthermore, since the second liquid port is formed in the large diameter portion, the liquefied gas can be sent out from the second liquid port even when the remaining amount of the liquefied gas decreases. Therefore, in addition to the effect of any one of claims 1 to 5, an effect of reducing the amount of liquefied gas remaining inside without being discharged outside while improving stability against falling of a tank trailer pulled by a tractor is achieved. is there.

  According to the tank trailer of the seventh aspect, the liquid level detection device transmits a detection signal regarding the position of the liquid level to the alarm device installed at the installation location of the tank. At the installation site of the tank, the position of the liquid level is detected based on the detection signal, and in addition to the effect of claim 6, an operation such as stopping the pump can be performed, and the pump can be prevented from running idle. effective.

  According to the tank trailer of the eighth aspect, the tank is set to be placed horizontally, and the inclination adjustment mechanism adjusts the inclination of the axial center of the tank with respect to the horizontal surface. Thus, the height of the second liquid port with respect to the surface around the second liquid port can be adjusted, and therefore, in addition to the effect of any one of claims 1 to 7, it remains inside without being sent out from the second liquid port. Has the effect of reducing the amount of liquefied gas that

  According to the tank trailer of claim 9, the pump is installed relative to the tank. Therefore, in addition to the effect of any one of claims 1 to 8, an effect that the liquefied gas can be sent out by operating the pump installed for the tank even in the place where the pump is not disposed is there.

According to a tank trailer according to claim 10, emergency shutoff valve, because they are opened and closed on the basis of the compressed air supplied from the location of the tank, in addition to the effects of any one of claims 1 9, in the event of an emergency There is an effect that stable remote control can be performed.

According to a tank trailer according to claim 11, emergency shutoff valve is opened and closed on the basis of the compressed air supplied from the air tank installed in the tank. Therefore, in addition to the effect of any one of claims 1 to 9, there is an effect that the emergency shutoff valve can be operated even when the compressed air is not supplied from the installation location of the tank.

It is a side view of a tank trailer in a 1st embodiment of the present invention. It is a piping system diagram of a tank trailer. It is a piping system diagram of a tank trailer in a 2nd embodiment. It is a piping system diagram of the tank trailer in 3rd Embodiment. It is a piping system diagram of a tank trailer in a 4th embodiment.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the attached drawings. FIG. 1 is a side view of a tank trailer 1 according to a first embodiment of the present invention. As shown in FIG. 1, the tank trailer 1 is a vehicle (tank semi-trailer in the present embodiment) which is towed by a tractor T. The tank trailer 1 includes a horizontally disposed tank 2 filled with liquefied gas such as liquefied petroleum gas (LPG) and liquefied natural gas (LNG), and a traveling device 3 attached to the tank 2. Supported by the wheels 4 of the vehicle. The tank trailer 1 is towed by the tractor T by being connected to the connecting portion T2 provided on the frame T1 of the tractor T, and the tank 2 is conveyed in the axial direction.

  The tank 2 is disposed such that the axis O is inclined rearward, and the center of gravity G of the tank trailer 1 (the center of gravity of the tractor T and the tank trailer 1) to which the tractor T is connected is lower than the axis O of the tank 2 Set to position. The height of the center of gravity G (center of gravity height) is H. Since the center of gravity height H can be made lower by arranging the tank 2 backward as compared with the case where the tank 2 is arranged so that the axis O is horizontal, the fall of the tank trailer 1 to which the tractor T is connected is Can improve the stability against

  The tank 2 is located at the front end side of the tank 2, that is, the first small diameter portion 11 located on the tractor T side and supported by the frame T1, and the second small diameter located on the rear end side of the tank 2 and supported by the traveling device 3. Part 12, a large diameter part 13 located between the first small diameter part 11 and the second small diameter part 12, a first inclined part 14 connecting the first small diameter part 11 and the large diameter part 13, and a second A second inclined portion 15 connecting the small diameter portion 12 and the large diameter portion 13 is provided.

  The first small diameter portion 11 and the second small diameter portion 12 are respectively formed in a cylindrical shape with an inner diameter D1, and the large diameter portion 13 is formed in a cylindrical shape with an inner diameter D2. The inner diameter D2 of the large diameter portion 13 is the first small diameter portion 11 And it is formed larger than the internal diameter D1 of the 2nd small diameter part 12 (D1 <D2). In addition, the first inclined portion 14 and the second inclined portion 15 are formed in a truncated cone shape in which the diameter increases from the first small diameter portion 11 and the second small diameter portion 12 toward the large diameter portion 13.

  The large diameter portion 13 is disposed concentrically with the first small diameter portion 11, the second small diameter portion 12, the first inclined portion 14 and the second inclined portion 15, and between the frame T1 of the tractor T and the traveling device 3 The inner diameter D2 is uniformly enlarged with respect to the axial center O. As a result, the volume of the tank 2 can be expanded while suppressing the center of gravity G of the tank 2 from rising, and the stability of the tank trailer 1 can be secured. Furthermore, by arranging the first small diameter portion 11 and the second small diameter portion 12 and the large diameter portion 13 concentrically, even when liquefied gas is charged into the tank 2 in a high pressure state, stress concentration is suppressed to be a tank The strength of 2 can be secured.

  The tank trailer 1 delivers the liquefied gas from the tank 2 to the lower part of the tank 2 and the loading operation box 5 in which a valve operated when filling (loading) the liquefied gas is disposed. A connection control box 6 in which valves and the like to be operated are disposed. The loading operation box 5 is disposed on the side of the first small diameter portion 11 of the tank 2, and the connecting operation box 6 is disposed on the side of the second small diameter portion 12 of the tank 2. In the tank 2, the support leg 7 is disposed on the side of the first small diameter portion 11 opposite to the second small diameter portion 12 in which the traveling device 3 is disposed, with the large diameter portion 13 interposed therebetween.

  The support leg 7 is a member for supporting the front end side (the first small diameter portion 11 side) of the tank 2 with respect to the ground surface. The support leg 7 in the present embodiment is configured to be extensible and contractible so that the inclination of the axial center O of the tank 2 with respect to the horizontal surface can be adjusted. By adjusting the length of the support leg 7 while bringing the lower end portion of the support leg 7 into contact with the ground surface, the inclination of the axial center O of the tank 2 with respect to the horizontal surface is adjusted.

  The tank 2 is provided with a ring-shaped locking portion 8 at a predetermined position. The locking portion 8 is a portion to which one end side of a lashing member (not shown) such as a lashing wire is fixed, and the other end side of the lashing member is a fixing member (not shown) such as an anchor bolt fixed to the ground surface. Fixed to the The tank trailer 1 separated from the tractor T is fixed to the ground surface of the filling station to be stopped by fixing the lashing member to the locking portion 8. As a result, it is possible to prevent the tank trailer 1 from moving or tipping over due to an earthquake or wind and flood damage (for example, tsunami, storm surge, river flooding, tornado, etc.).

  Next, the piping system of the tank trailer 1 will be described with reference to FIG. FIG. 2 is a piping system diagram of the tank trailer 1. FIG. 2 shows a state where the pump P on the filling station side is connected to the tank trailer 1 parked at the filling station.

  As shown in FIG. 2, in the tank trailer 1, a first liquid port 21, a gas port 22, a second liquid port 24 and a return port 25 are formed at the bottom of the large diameter portion 13 (see FIG. 1) of the tank 2. In the tank 2, the liquid level detection device 27 is disposed at the bottom of the large diameter portion 13, and the safety valve 29 is disposed at the top. The second liquid port 24 and the liquid level detection device 27 are provided on the rear side (the traveling device 3 side) from the center in the axial direction of the large diameter portion 13.

  The first liquid port 21 is an opening for allowing the liquefied gas to flow into the tank 2 when the tank 2 is filled with the liquefied gas, and one end of a first liquid pipe 31 is connected. The coupling 32 is connected to the other end of the first liquid pipe 31, and the first liquid source valve 33 for opening and closing the first liquid pipe 31 is disposed between the first liquid port 21 and the coupling 32. . The first liquid port 21 is provided with an emergency shutoff valve 34 for opening and closing the first liquid port 21.

  The gas port 22 is an opening for pushing out the vaporized gas in the tank 2 along with the supply of the liquefied gas from the first liquid port 21, and the vent pipe 23 is connected. The vent pipe 23 is a pipe having one end connected to the gas port 22 and the other end extending toward the top of the tank 2, and the gas port 22 communicates with the gas phase portion of the tank 2 by the vent pipe 23. One end of a gas pipe 35 is connected to the gas port 22. The coupling 36 is connected to the other end of the gas pipe 35, and a gas main valve 37 for opening and closing the gas pipe 35 is disposed between the gas port 22 and the coupling 36. The gas port 22 is provided with an emergency shutoff valve 38 for opening and closing the gas port 22. The gas port 22 also has a function as a recovery port through which a part of the liquefied gas delivered to the pump P from the second liquid port 24 (described later) is circulated and recovered.

  The second liquid port 24 is an opening for delivering the liquefied gas filled in the tank 2, and one end of a second liquid pipe 39 is connected. The coupling 40 is connected to the other end of the second liquid pipe 39, and a second liquid source valve 41 for opening and closing the second liquid pipe 39 is disposed between the second liquid port 24 and the coupling 40. . In the second liquid pipe 39, the emergency shutoff valve 42 is disposed between the second liquid port 24 and the second liquid source valve 41. An upstream pipe P1 of a pump P (in this embodiment, a centrifugal type) is connected to the coupling 40.

  The emergency shutoff valve 42 is a valve for opening and closing the second liquid pipe 39, and in the present embodiment, is constituted by a ball valve, and is opened and closed by the drive unit 43. The drive unit 43 is driven by the shutoff valve operating device 44. The shutoff valve operating device 44 is a device for switching the emergency shutoff valve 42 from the open state to the closed state by driving the drive unit 43 when the air pressure inside is changed. Further, the shutoff valve operating device 44 is configured to be able to simultaneously send an operation signal to the air / oil pressure converter 56 (described later) simultaneously with sending an operation signal to the drive unit 43.

  The second liquid pipe 39 is connected to a bypass pipe 45 which communicates between the second liquid port 24 and the emergency shutoff valve 42 and between the second liquid source valve 41 and the emergency shutoff valve 42. A relief valve 46 is disposed in the bypass pipe 45.

  The return port 25 is an opening connected to the downstream side (downstream pipe P2) of the pump P, and is an opening for returning at least a part of the liquefied gas discharged from the pump P to the tank 2. The pipe 26 is connected to the return port 25. The pipe 26 is a pipe whose one end is connected to the return port 25 and the other end is extended toward the top of the tank 2, and the return port 25 communicates with the gas phase portion of the tank 2 by the pipe 26. One end of a return pipe 47 is connected to the return port 25. Coupling 48 is connected to the other end of the return pipe 47, and between the return port 25 and the coupling 48, the return pipe 47 can be opened and closed to adjust the flow rate, and a return source valve 49 that can be closed is disposed. Ru. The return port 25 is provided with an emergency shutoff valve 50 for opening and closing the return port 25.

  The liquid level detection device 27 is a device for detecting the position of the liquid level of the liquefied gas filled in the tank 2, and a tubular liquid level sensor 28 extending toward the top of the tank 2 is connected. The liquid level detection device 27 includes an output circuit (not shown) that processes and outputs the detection result detected by the liquid level sensor 28.

  The recovery pipe 51 is a pipe for circulating a part of the liquefied gas drawn from the second liquid port 24 to the pump P and recovering it from the gas port 22 to the tank 2. One end of the recovery pipe 51 is connected to the gas pipe 35 between the gas port 22 and the gas main valve 37, and the coupling 52 is connected to the other end. The recovery pipe 51 is provided with a recovery source valve 53 capable of adjusting the flow rate by opening and closing the recovery pipe 51.

  The emergency shutoff valves 34, 38, and 50 are valves that are opened and closed by oil pressure. In the present embodiment, the emergency shut off valves 34, 38, and 50 are formed of globe valves, and hydraulic pipes 54 and 54a are connected. The hydraulic pipes 54, 54a are pipes for transmitting the hydraulic pressure to the emergency shutoff valves 34, 38, 50, and the three-way valve 55 is disposed. The hydraulic piping 54 is provided with a hydraulic stop valve 55a, and an air-hydraulic converter 56 is connected to an end. The air-hydraulic pressure converter 56 is a device for converting the air pressure into the hydraulic pressure, and is connected to the first air pipe 57 and the second air pipe 59 (described later) via the shutoff valve operating device 44.

  The shutoff valve operating device 44 that operates the opening / closing of the emergency shutoff valve 42 is connected to the air tank 58 via the first air pipe 57. The air tank 58 is a tank for storing compressed air supplied to an air brake (not shown) of the tank trailer 1. Further, a second air pipe 59 is connected to the shutoff valve operating device 44. The second air pipe 59 is connected to a joint 60 fixed to the connection operation box 6. The joint 60 is a member to which the joint 62 of the air pipe 61 connected to an air pressure source (not shown) installed at the filling station is connected. By connecting the joints 60 and 62, air pressure is introduced from the filling station to the shutoff valve operating device 44. Since the shutoff valve operating device 44 sends an operation signal to the pneumatic / hydraulic converter 56 as described above, the emergency shutoff valves 38, 42, 50 can be remotely controlled from the filling station side.

  The electric wiring 63 is connected to the liquid level detection device 27. The electrical wiring 63 is a wiring for supplying power to the liquid level detection device 27 from the filling station side and transmitting a detection signal to the filling station side. The electrical wiring 63 is connected to a connector 64 fixed to the connection operation box 6. The connector 64 is a member to which the connector 66 electrically connected to the alarm device 65 installed at the filling station is connected. By connecting the connectors 64 and 66 to each other, the alarm device 65 installed at the filling station can acquire the detection result output from the liquid level detection device 27.

  Next, a method of filling liquefied gas using the tank trailer 1 will be described. The tank trailer 1 is towed by the tractor T in a state where the first liquid main valve 33, the gas main valve 37, the second liquid main valve 41, the return main valve 49 and the recovery main valve 53 are closed, and the import base and oil production It is transported to the base of At the base, the air tank 58 or the compressor (not shown) of the tractor T is connected to the air-hydraulic converter 56, and setting of the three-way valve 55 opens the emergency shutoff valves 34, 38. A fluid hose and a gas hose (both not shown) extending from the base are connected to the couplings 32 and 36, respectively, and the first fluid main valve 33 and the gas main valve 37 are opened.

  The liquefied gas fed from the base via the liquid hose and the coupling 32 flows through the first liquid pipe 31 and enters the tank 2 from the first liquid port 21. The vaporized gas in the tank 2 is discharged from the aeration pipe 23 and the gas port 22 as the liquefied gas flowing into the tank 2 increases, is sent to the base side through the gas piping 35 and the coupling 36, and is recovered. Ru. Thus, the tank 2 is filled with liquefied gas at the base.

  The tank trailer 1 filled with the liquefied gas into the tank 2 is towed by the tractor T and transferred to the filling station. After the support legs 7 are grounded, the tractor T is disconnected and the tank trailer 1 is parked at the filling station. After the support leg 7 is expanded and contracted to adjust the inclination of the axial center O of the tank 2, the tank trailer 1 is fixed by the locking portion 8 to the ground surface of the filling station using a lashing member (not shown). Ru.

  In the filling station, a joint 62 of an air pipe 61 extending from the filling station is connected to the joint 60, and a connector 66 extending from the filling station is connected to the connector 64. The setting of the three-way valve 55 enables remote control of the emergency shutoff valves 38, 42, 50 from the filling station side via the air-hydraulic pressure converter 56, and filling the detection result of the liquid level output from the liquid level detection device 27. It can be acquired by the office side (alarm device 65). The air pressure is introduced from the air pipe 61 to the shutoff valve operating device 44, whereby the emergency shutoff valves 38, 42, 50 are opened.

  An upstream pipe P1 for sucking the liquefied gas by the pump P is connected to the coupling 40 from the filling station side. The pump P discharges the liquefied gas sucked from the upstream pipe P1 from the downstream pipe P2. Pump P performs lubrication and cooling of the bearings and cooling of a motor (not shown) that drives pump P using a portion of the liquefied gas sucked into pump P (hereinafter referred to as "recirculation fluid"). . The circulating fluid having cooled the bearings, etc. is recovered to the gas phase portion of the tank 2 from the recovery pipe P3 connected to the coupling 52. Further, a return pipe P4 branched from the downstream pipe P2 is connected to the coupling 48.

  Since the filling station side can acquire the detection result (liquid level information) of the liquid level of the tank 2 by the alarm device 65, the remaining amount of liquefied gas in the tank 2 can be grasped based on the liquid level information. If the remaining amount of liquefied gas in the tank 2 can be grasped, an empty container is left by the liquefied gas remaining in the tank 2 of the tank trailer 1 which is stopped in relation to the number (volume) of containers (empty containers) requiring filling. The filling station can determine whether it can be filled or not.

  As a result of the judgment, if the remaining amount of liquefied gas in the tank trailer 1 which has been parked is insufficient, the filling station side will call for another tank trailer to fill the empty container with the liquefied gas. You can take In addition, since the operation of the pump P can be stopped when the remaining amount of liquefied gas in the tank trailer 1 decreases, the pump P can be prevented from running idle and the pump P can be prevented from being damaged in advance. .

  As described above, when filling the liquefied gas from the tank trailer 1 connected with the base side to the container (not shown), the downstream pipe P2 is connected to the container, and the second liquid source valve 41, the return source valve 49 and the recovery The pump P is operated with the main valve 53 opened. The liquefied gas in the tank 2 is sucked by the pump P and filled in the vessel from the upstream pipe P1 to the downstream pipe P2. In the past, liquefied gas was temporarily stored in a storage tank from a mobile storage facility (tank trailer etc.), and then the container was filled with liquefied gas, whereas according to the tank trailer 1, the storage tank is used. The container can be filled directly with liquefied gas. Since the liquefied gas does not need to be stored again in the storage tank, the storage tank can be made unnecessary. By using the tank trailer 1, it is not necessary to update the old storage tank, and since the storage tank is not updated, maintenance of the storage tank can be unnecessary.

  Further, in the tank trailer 1, the circulating fluid that has performed cooling of the pump P is recovered from the gas port 22 via the recovery pipe 51 and the gas pipe 35, and returned to the gas phase portion of the tank 2 from the vent pipe 23. As a result, the occurrence of cavitation and gas accumulation in the pump P and piping can be suppressed. That is, the circulating fluid (liquefied gas) is likely to be heated and vaporized due to the heat transfer of the motor and the sliding heat of the bearing of the pump P. When the circulating fluid, which has been heated, is allowed to flow through the pump P or the downstream pipe P2, cavitation or gas accumulation may occur due to vaporization of the circulating fluid. According to the tank trailer 1, this can be prevented, and by collecting the circulating fluid from the pump P to the gas port 22, the occurrence of cavitation or gas accumulation that adversely affects the pump P can be suppressed. As a result, the durability of the pump P can be improved.

  In the tank trailer 1, the gas port 22 is also used as a recovery port for recovering the circulating fluid which has cooled the pump P etc. Therefore, the tank trailer 1 is connected to parts such as an emergency shutoff valve constituting the recovery port and the recovery port. It is possible to eliminate the need for the necessary piping and the space where the piping is disposed. Therefore, the number of parts can be reduced and the space saving can be improved.

  In the tank trailer 1, at least a part of the liquefied gas discharged from the downstream pipe P <b> 2 is returned from the return pipe P <b> 4 to the return port 25 via the coupling 48. Here, when the liquefied gas in the tank 2 is sucked using the pump P and filled in a container having a smaller volume than the volume of the tank 2, the demand amount of the liquefied gas discharged from the pump P fluctuates. Even in such a case, since the tank trailer 1 is provided with the return port 25, at least a part of the liquefied gas discharged from the downstream pipe P2 (the surplus when the demand changes) is coupled It is returned into the tank 2 from the return port 25 through 48. As a result, even when the demand amount of the liquefied gas sent to the outside of the tank 2 fluctuates, the minimum discharge amount of the pump P can be secured. Thus, the continuous operation of the pump P can be prevented from being disturbed. Furthermore, if the pump P is frequently turned on and off, gas accumulation tends to occur in the piping, but the return port 25 can be made not to affect the continuous operation of the pump P (frequently on and off operation is not performed) It is possible to reduce the possibility of gas accumulation in the piping.

  If an abnormal situation such as the outflow of liquefied gas occurs during the filling operation, the pressure of the air pipe 61 extending from the filling station side is reduced to operate the drive unit 43 by the shutoff valve operating device 44. The emergency shutoff valves 38, 42, 50 can be closed. According to the tank trailer 1, the emergency shutoff valves 38, 42, 50 can be remotely controlled from the filling station side as described above.

  Further, since the air tank 58 is connected to the shutoff valve operating device 44, the air pressure is introduced from the air tank 58 to the shutoff valve operating device 44 even if the air pressure is not introduced into the shutoff valve operating device 44 from the filling station side. Thus, the emergency shutoff valves 38, 42 and 50 can be opened.

  The emergency shutoff valve 42 is configured by a ball valve. Therefore, the pressure loss of the emergency shutoff valve 42 can be smaller than that of a general emergency shutoff valve. The emergency shutoff valve 42 is separated from the second liquid port 24 and disposed in the second liquid pipe 39, so that the pipe resistance of the second liquid port 24 and the second liquid pipe 39 can be reduced. As a result, the pump P can be efficiently suctioned, and the effective suction capacity (NPSH) of the pump P can be easily secured. Therefore, a general-purpose pump P having a relatively high capacity can be employed, and the amount of residual liquid can be reduced by efficiently sucking the liquefied gas in the tank 2.

  Here, when the emergency shutoff valve 42 is closed and the second liquid source valve 41 is closed, the second liquid pipe 39 between the emergency shutoff valve 42 and the second liquid source valve 41 is sealed. . Then, the internal pressure is increased by sunlight or the like, and the second liquid pipe 39 may be ruptured. In order to prevent this, when the pressure of the second liquid pipe 39 between the emergency shutoff valve 42 and the second liquid source valve 41 is increased, the relief valve 46 is operated and the valve is opened. Thereby, the pressure can be released from the bypass pipe 45 into the tank 2. As a result, it is possible to prevent an excessive load (pressure) from acting on the second liquid pipe 39 and to prevent the second liquid pipe 39 from being ruptured.

  The relief valve 46 also operates when the pressure in the first liquid pipe 39 between the pump P and the emergency shutoff valve 42 increases after the emergency shutoff valve 42 is closed. Pressure can be released from the bypass pipe 45 into the tank 2 by operating the relief valve 46 and opening it. As a result, it is possible to prevent the load (pressure) from acting on the pump P and to protect the pump P.

  Here, the position of the liquid surface of the large diameter portion 13 whose inner diameter is set to be larger than the first small diameter portion 11 and the second small diameter portion 12 is detected by the liquid level detection device 27. The position of the liquid surface can be detected until the remaining amount (filling amount) of the liquefied gas becomes smaller than when the position of the liquid surface of the small diameter portion 12 is detected by the liquid level detection device 27.

  Furthermore, since the second liquid port 24 is formed in the large diameter portion 13, the remaining amount of liquefied gas is smaller compared to the case where the liquid port is formed in the first small diameter portion 11 or the second small diameter portion 12 Until then, the liquefied gas can be sent out from the second liquid port 24. Therefore, the amount of liquefied gas remaining inside the tank 2 without being sent out can be reduced.

  Furthermore, the second liquid port 24 and the liquid level detection device 27 are provided on the rear side (the traveling device 3 side) with respect to the axial center of the large diameter portion 13. Therefore, the inclination of the axial center O of the tank 2 is set such that the axial center O of the tank 2 is inclined backward (the axial center O is inclined downward as it goes backward in the axial direction of the tank 2 (the traveling device 3 side)). As compared with the case where the inclination of the axial center O of the tank 2 is set such that the axial center O of the tank 2 is inclined forward, the liquid from the second liquid port 24 is liquefied until the remaining amount of liquefied gas becomes smaller. Gas can be pumped out.

  The support leg 7 is configured to be extendable and contractable so that the inclination of the axial center O of the tank 2 can be adjusted. Therefore, even when the ground surface of the filling station is inclined forward with respect to the tank trailer 1, the height of the support leg 7 is adjusted, and the second liquid port 24 and the liquid level detection device 27 are provided. The tank 2 can be inclined to the rear side. As a result, the amount of liquefied gas remaining in the tank 2 without being delivered can be reduced without being affected by the topography of the filling station and the like.

  Next, a second embodiment will be described with reference to FIG. In the first embodiment, the first liquid port 21 for supplying liquefied gas to the tank 2 and the second liquid port 24 for delivering liquefied gas from the tank 2 are separately provided, and are communicated with the gas piping 35. The case where the recovery piping 51 to be provided is provided has been described. On the other hand, in the second embodiment, the liquid port for supplying the liquefied gas to the tank 2 and the liquid port for transmitting the liquefied gas from the tank 2 are shared, and the recovery pipe 51 is omitted. explain. In addition, about the part same as the part demonstrated in 1st Embodiment, the same code | symbol is attached | subjected and the following description is abbreviate | omitted. FIG. 3 is a piping system diagram of the tank trailer 71 in the second embodiment. FIG. 3 illustrates a state where the pump P on the filling station side is connected to the tank trailer 71 parked at the filling station.

  As shown in FIG. 3, in the tank trailer 71, a liquid port 72, a gas port 22 and a return port 25 are formed at the bottom of the large diameter portion 13 (see FIG. 1) of the tank 2. The liquid port 72 is an opening for flowing the liquefied gas into the tank 2 when the tank 2 is filled with the liquefied gas, and one end of the liquid pipe 73 is connected. A coupling 74 is connected to the other end of the liquid pipe 73, and a liquid source valve 75 for opening and closing the liquid pipe 73 is disposed between the liquid port 72 and the coupling 74. The liquid pipe 73 is connected with a bypass pipe 76 which communicates between the liquid port 72 and the emergency shutoff valve 42 and between the liquid source valve 75 and the emergency shutoff valve 42. A relief valve 77 is disposed in the bypass pipe 76. The couplings 36, 48, 74 and the like are disposed in the connection operation box 82 fixed to the tank 2.

  A hydraulic pipe 78 is connected to the emergency shutoff valves 38 and 50. The hydraulic piping 78 is a piping for transmitting the hydraulic pressure to the emergency shutoff valves 38, 50, the hydraulic stop valves 79, 80 are disposed, and the air-hydraulic pressure converter 81 is connected to the end. The air-oil pressure converter 81 is a device for converting air pressure into oil pressure, and is connected to the first air pipe 57 and the second air pipe 59. The air-hydraulic pressure converter 81 is operated by an operation signal sent from the shutoff valve operating device 44.

  Next, a method of filling liquefied gas using the tank trailer 71 will be described. First, with the liquid main valve 75, the gas main valve 37 and the return main valve 49 closed, the tank trailer 71 is pulled by the tractor T and transferred to a base such as an import base or a refinery. At the base, the air tank 58 or the compressor (not shown) of the tractor T is connected to the shutoff valve operating device 44 and the pneumatic hydraulic pressure converter 81, the hydraulic stop valve 79 is opened, and the hydraulic stop valve 80 is closed. 38, 42 are opened.

  A liquid hose and a gas hose (both not shown) extending from the base are connected to the couplings 74 and 36, respectively, and the liquid source valve 75 and the gas source valve 37 are opened. The liquefied gas fed from the base through the liquid hose and the coupling 74 flows through the liquid pipe 73 and flows into the tank 2 through the liquid port 72. The vaporized gas in the tank 2 is discharged from the aeration pipe 23 and the gas port 22 as the liquefied gas flowing into the tank 2 increases, is sent to the base side through the gas piping 35 and the coupling 36, and is recovered. Ru. Thus, the tank 2 is filled with the liquefied gas.

  The tank trailer 71 filled with the liquefied gas into the tank 2 is towed by the tractor T and transferred to the filling station. In the filling station, a joint 62 of an air pipe 61 extending from the filling station is connected to the joint 60, and a connector 66 extending from the filling station is connected to the connector 64. When the hydraulic stop valves 79 and 80 are opened, the emergency shutoff valves 38, 42 and 50 are opened via the shutoff valve operating device 44 and the pneumatic hydraulic pressure converter 81. Further, the upstream pipe P1 through which the liquefied gas is sucked by the pump P is connected to the coupling 74, the recovery pipe P3 is connected to the coupling 36, and the return pipe P4 is connected to the coupling 48.

  After the downstream pipe P2 is connected to the container, the pump P is operated with the liquid source valve 75, the gas source valve 37, and the return source valve 49 opened. The liquefied gas in the tank 2 is sucked by the pump P and filled in the vessel from the upstream pipe P1 to the downstream pipe P2. The circulating fluid which has performed cooling or the like of the pump P is returned to the gas phase portion of the tank 2 from the gas port 22 and the vent pipe 23 through the gas pipe 35. At least a portion of the liquefied gas discharged from the downstream pipe P2 is returned from the return pipe P4 to the return port 25 via the coupling.

  According to the tank trailer 71, the liquid port 72 through which the liquefied gas is supplied to the tank 2 at the base is shared with the liquid port through which the liquefied gas is delivered from the tank 2 in the filling station. As compared with the case where the first liquid port 21 and the second liquid port 24 are separately provided, components such as an emergency shutoff valve constituting one liquid port, piping connected to one liquid port, and The space where the piping is disposed can be eliminated. Therefore, the number of parts can be reduced and the space saving can be improved.

  Further, since the recovery piping 51 (see FIG. 2) for recovering the circulating fluid obtained by cooling the pump P and the like is omitted, the piping constituting the recovery piping 51 and the space where the recovery piping 51 is disposed are unnecessary. it can. Therefore, the number of parts can be reduced and the space saving can be improved.

  Next, a third embodiment will be described with reference to FIG. In the first and second embodiments, the case where the pump P is installed on the filling station side has been described. On the other hand, in the third embodiment, the case where the pumps 124 and 131 are fixed to the tank 2 will be described. The same parts as those in the first embodiment are given the same reference numerals, and the description thereof will be omitted. FIG. 4 is a piping system diagram of the tank trailer 101 in the third embodiment.

  As shown in FIG. 4, in the tank trailer 101, a first liquid port 102, a gas port 103, second liquid ports 105 and 106, and a return port 107 are formed at the bottom of the large diameter portion 13 (see FIG. 1) of the tank 2. Ru. The first liquid port 102 is an opening for allowing the liquefied gas to flow into the tank 2 when the tank 2 is filled with the liquefied gas, and one end of the first liquid pipe 111 is connected. In the first liquid pipe 111, the coupling 112 is connected to the other end, the first valve 113 is disposed on the first liquid port 102 side, and the first main valve 114 for opening and closing the first liquid pipe 111 is disposed on the coupling 112 side. It will be set up. The first liquid port 102 is provided with an emergency shutoff valve 115 for opening and closing the first liquid port 102.

  The gas port 103 is an opening for pushing out the vaporized gas in the tank 2 along with the supply of the liquefied gas from the first liquid port 102, and the vent pipe 104 is connected. The vent pipe 104 is a pipe having one end connected to the gas port 103 and the other end extending toward the top of the tank 2, and the gas port 103 communicates with the gas phase portion of the tank 2 by the vent pipe 104. One end of a gas pipe 116 is connected to the gas port 103. The coupling 117 is connected to the other end of the gas pipe 116, the gas valve 118 is disposed on the gas port 103 side, and the gas main valve 119 for opening and closing the gas pipe 116 is disposed on the coupling 117 side. The gas port 103 is provided with an emergency shutoff valve 120 for opening and closing the gas port 103.

  The second liquid ports 105 and 106 are openings for delivering the liquefied gas filled in the tank 2, and one ends of the second liquid pipes 121 and 129 are connected to each other. The coupling 122 is connected to the other end of the second liquid pipe 121, and the upstream valve 123 is disposed on the second liquid port 105 side. The pump 124 is disposed in the second liquid pipe 121 on the downstream side of the upstream valve 123. The pump 124 is a device driven by the motor 125. The downstream valve 126 is disposed on the second liquid pipe 121 on the downstream side of the pump 124, and the second liquid pipe 121 on the downstream side of the downstream valve 126 A second liquid source valve 127 for opening and closing the second liquid pipe 121 is disposed. The second liquid port 105 is provided with an emergency shutoff valve 128 that opens and closes the second liquid port 105.

  The second liquid pipe 129 is a pipe whose one end is connected to the second liquid port 106, and the other end is connected to the second liquid pipe 121 on the downstream side of the downstream valve 126 and on the upstream side of the second liquid source valve 127. The upstream valve 130 is disposed on the second liquid port 106 side. The pump 131 is disposed on the second liquid pipe 129 downstream of the upstream valve 130. The pump 131 is a device driven by the motor 132, and the downstream valve 133 is disposed on the second liquid pipe 129 downstream of the pump 131. The second liquid port 106 is provided with an emergency shutoff valve 134 that opens and closes the second liquid port 106.

  The return port 107 is connected to the downstream side of the pumps 124 and 131 and is an opening for returning at least a part of the liquefied gas discharged from the pumps 124 and 131 to the tank 2. The pipe 108 is connected to the return port 107. The pipe 108 is a pipe having one end connected to the return port 107 and the other end extending toward the top of the tank 2, and the return port 107 communicates with the gas phase portion of the tank 2 by the pipe 108. One end of a return pipe 135 is connected to the return port 107. The other end of the return pipe 135 is connected to the second liquid pipe 121 downstream of the communicating portion of the second liquid pipe 129 and upstream of the second liquid source valve 127, and the return pipe 135 is connected to the return port 107 side. A return valve 136 is provided to open and close. The return port 107 is provided with an emergency shutoff valve 137 for opening and closing the return port 107. Further, the return pipe 135 is provided with a relief valve 135a.

  The emergency shutoff valves 115, 120, 128, 134, and 137 are hydraulically opened and closed valves. The hydraulic piping 138 is connected to the emergency shutoff valves 115 and 120, and the hydraulic piping 143 is connected to the emergency shutoff valves 128, 134, and 137. Connected The hydraulic pipes 138 and 143 are pipes for transmitting the hydraulic pressure to the emergency shutoff valves 115 and 120 and the emergency shutoff valves 128, 134 and 137, respectively, and the hydraulic stop valves 139 and 144 and the pneumatic hydraulic pressure converters 140 and 145 are respectively Connected The air-oil pressure transducers 140 and 145 are devices for converting air pressure into oil pressure, and are connected to the air pipes 141 and 146 via three-way valves.

  The air pipe 141 is connected to a joint 142 fixed to the connection operation box 110. The joint 142 is a member to which the joint 148 of the air pipe 147 connected to an air pressure source (not shown) installed at the filling station is connected. When the joints 142 and 148 are connected, air pressure can be introduced from the filling station to the air-hydraulic transducers 140 and 145 by switching the three-way valve. Thus, the emergency shutoff valve 115, 120, 128, 134, 137 can be remotely operated from the filling station.

  The air pipe 146 is connected to the air tank 58. Therefore, air pressure can be introduced from the air tank 58 to the air-hydraulic transducers 140 and 145 by switching the three-way valve. Thus, even if air pressure is not introduced from the air pipe 141, the air pressure of the air tank 58 can open and close the emergency shutoff valves 115, 120, 128, 134, and 137.

  Electric wires 149 and 151 are connected to the motors 125 and 132 for driving the pumps 124 and 131, respectively. The electric wires 149 and 151 are wires for supplying power to the motors 125 and 132 from the filling station side and transmitting an operation signal. The electrical wires 149 and 151 are connected to connectors 150 and 152 fixed to the connection operation box 110. The connectors 150 and 152 are members to which the control devices 153 of the motors 125 and 132 installed at the filling station and the connectors 155 and 157 electrically connected by the electric wires 154 and 156 are respectively connected.

  Next, a method of filling liquefied gas using the tank trailer 101 will be described. At a base such as an import base or a refinery, the air tank 58 or a compressor (not shown) of the tractor T is connected to the air-hydraulic converter 140, and the emergency shutoff valves 115 and 120 are opened. A liquid hose and a gas hose (both not shown) extending from the base are connected to the couplings 112 and 117, respectively, and the first liquid main valve 114 and the gas main valve 119 are opened. Thus, the tank 2 is filled with the liquefied gas.

  The tank trailer 101 is towed by the tractor T and transferred to the filling station. At the filling station, the connectors 64, 150, 152 and the joint 142, and the connectors 66, 155, 157 and the joint 148 are connected, respectively. As a result, the emergency shutoff valves 128, 134 and 137 are opened via the air-hydraulic pressure converter 145.

  Next, after the container (not shown) filled with liquefied gas is connected to the coupling 122 via the filling machine (not shown), the first liquid main valve 114 and the gas main valve 119 are closed. Then, the motors 125 and 132 are operated to operate the pumps 124 and 131. When the second liquid source valve 127 is opened, the liquefied gas in the tank 2 is sucked by the pumps 124 and 131 and discharged from the coupling 122 to the container side (filler side). Since the relief valve 135a is disposed in the return pipe 135, liquefied gas is pushed into the container by the filling machine until the pressure of the return pipe 135 becomes the set pressure of the relief valve 135a. When the pressure of the return pipe 135 exceeds the set pressure of the relief valve 135 a, the liquefied gas is returned from the return pipe 135 through the return port 107 into the tank 2.

  As described above, according to the tank trailer 101, since the pumps 124 and 131 are installed with respect to the tank 2, the control device 153 controls the motors 125 and 132 from the filling station even at the filling station where the pump is not provided. The pump 124 and 131 can be used to deliver liquefied gas out of the tank 2 by remotely controlling the When the control device 153 for the motors 125 and 132 is mounted on the tank trailer 101, the pumps 124 and 131 can be operated only by supplying a commercial power source (external power source). In that case, if it is a place where it is possible to supply a commercial power supply (external power supply) to the tank trailer 101, the commercial power can be supplied to the motors 125, 132 as well as the filling station to deliver liquefied gas to the outside of the tank 2. . Therefore, the filling of the liquefied gas from the tank trailer 101 to the cylinder (small container) can be performed at places other than the filling station.

  In addition, emergency shutoff valves 115 and 120 are respectively provided to the first liquid port 102 and the gas port 103 used in the supply operation for supplying the liquefied gas to the tank 2, and are used for the delivery operation for transmitting the liquefied gas from the tank 2 Emergency shutoff valves 128, 134 and 137 are disposed at the second liquid ports 105 and 106 and the return port 107, respectively. The hydraulic piping 138 connected to the emergency shutoff valves 115 and 120 is separate from the hydraulic piping 143 connected to the emergency shutoff valves 128, 134 and 137. Therefore, when an emergency occurs during the supply operation, the emergency shutoff valves 115 and 120 are closed by the hydraulic pressure of the hydraulic piping 138, and when an emergency occurs during the delivery operation, the emergency hydraulic shutoff by the hydraulic pressure of the hydraulic piping 143 The valves 128, 134, 137 can be closed. Since the plurality of emergency shutoff valves related to the supply work or the delivery work can be opened and closed by one operation, it is possible to improve the certainty of the emergency shutoff work when an abnormality occurs.

  Also, the air piping 147 on the filling station side and the air tank 58 on the tank trailer 101 side are connected to the hydraulic piping 138 and 143, and the flow path is switched by the three-way valve, thereby the air piping 147 on the filling station side or the tank trailer 101 side It is possible to select which of the air tanks 58 is to be the pneumatic pressure source. Therefore, even when air pressure is not introduced from the filling station side, the emergency shutoff valves 115, 120, 128, 134, and 137 can be opened and closed using the air tank 58 as an air pressure source. When compressed air in the air tank 58 runs short and the pressure in the air tank 58 decreases, compressed air is supplied to the air tank 58 from the compressor of the tractor T (see FIG. 1).

  Further, a plurality of second liquid ports 105 and 106 (two in the present embodiment) are provided, and the pumps 124 and 131 are connected to the second liquid ports 105 and 106, respectively. Even if the capacity is small, it is possible to secure the discharge capacity and total head of the pumps 124 and 131 as a whole.

  Next, a fourth embodiment will be described with reference to FIG. In the third embodiment, the case where the first liquid port 102, the gas port 103, the second liquid ports 105 and 106, and the return port 107 are formed at the bottom of the tank 2 has been described. On the other hand, in the fourth embodiment, a case where the first liquid port and the second liquid port are shared by the liquid port 202 and the gas port 203 is shared with the return port will be described. The same parts as those described in the first embodiment and the third embodiment are given the same reference numerals, and the description thereof will be omitted. FIG. 5 is a piping system diagram of the tank trailer 201 in the fourth embodiment.

  As shown in FIG. 5, in the tank trailer 201, a liquid port 202, a gas port 203 and a second liquid port 106 are formed at the bottom of the large diameter portion 13 (see FIG. 1) of the tank 2. The liquid port 202 is an opening from which the liquefied gas flows into the tank 2 when the tank 2 is filled with the liquefied gas, and the liquefied gas filled in the tank 2 is discharged. The gas port 203 is an opening through which at least a part of the liquefied gas discharged from the pumps 124 and 131 is returned to the tank 2 while the vaporized gas in the tank 2 is discharged along with the supply of the liquefied gas from the liquid port 202 It is a department.

  The first pipe 204 is a pipe through which the liquefied gas flows when the tank 2 is filled with the liquefied gas, the coupling 112 is connected to one end, and the second liquid pipe 121 between the upstream valve 123 and the pump 124 The other end is connected to The second pipe 205 is a pipe through which the vaporized gas flows when the tank 2 is filled with the liquefied gas, the coupling 117 is connected to one end, and the other pipe is connected to the return pipe 135 between the return valve 136 and the relief valve 135a. The ends are connected. The hydraulic stop valve 206 is a valve that prevents the hydraulic pressure from being transmitted to the emergency shutoff valve 134 that opens and closes the second liquid port 106 when the tank 2 is filled with liquefied gas, and hydraulic piping near the emergency shutoff valve 134 It is disposed at 143.

  Next, a method of filling liquefied gas using the tank trailer 201 will be described. At a base such as an import base or a refinery, with the hydraulic stop valve 206 closed, the air tank 58 or the compressor (not shown) of the tractor T is connected to the air-hydraulic converter 145, and the emergency shut-off valve 128, 137 is It is opened. A liquid hose and a gas hose (both not shown) extending from the base are connected to the couplings 112 and 117, respectively, and the first liquid main valve 114 and the gas main valve 119 are opened. Thus, the tank 2 is filled with the liquefied gas.

  The tank trailer 201 is towed by the tractor T and transferred to the filling station. At the filling station, the connectors 64, 150, 152 and the joint 142, and the connectors 66, 155, 157 and the joint 148 are connected, respectively, with the hydraulic stop valve 206 opened. As a result, the emergency shutoff valves 128, 134 and 137 are opened via the air-hydraulic pressure converter 145.

  Next, after the container (not shown) filled with liquefied gas is connected to the coupling 122 via the filling machine (not shown), the first liquid main valve 114 and the gas main valve 119 are closed. Then, the motors 125 and 132 are operated to operate the pumps 124 and 131. When the second liquid source valve 127 is opened, the liquefied gas in the tank 2 is sucked by the pumps 124 and 131 and discharged from the coupling 122 to the container side (filler side).

  According to the tank trailer 201, compared with the third embodiment, the first liquid port 102 and the gas port 103 can be omitted. Therefore, parts, such as an emergency shutoff valve which comprises the 1st liquid port 102 and the gas port 103, piping connected to each liquid port, and the space where the piping is arrange | positioned can be made unnecessary. Therefore, the number of parts can be reduced and the space saving can be improved.

  Although the present invention has been described above based on the embodiment, the present invention is not limited to the above embodiment, and various improvements and modifications can be made without departing from the scope of the present invention. It can be easily guessed. For example, the shape of the tank 2 described in the above embodiment and the dimensions such as the diameter and the axial length of each part are merely an example, and can be set arbitrarily.

  Although the above-mentioned embodiment explained the case where tank trailer 1 was tank semi-trailer, it is not necessarily limited to this, and it is naturally possible to set it as a tank full trailer.

  In each of the above embodiments, the case where the tank 2 is arranged so that the axis O inclines backward is not limited to this, and the tank 2 is arranged so that the axis O is horizontal. It is naturally possible to do. Moreover, although the tank 2 (D2> D1) provided with the 1st small diameter part 11, the 2nd small diameter part 12 (inner diameter D1), and the large diameter part 13 (inner diameter D2) was explained, it is not necessarily restricted to this. Naturally, it is possible to use a tank (D2 = D1) which is set to the same inner diameter throughout the axial center O except for the part.

  Although the above embodiments have described the case where the emergency shutoff valves 25, 34, 38, 50, 115, 120, 128, 134, and 137 are opened and closed by hydraulic pressure, the present invention is not necessarily limited thereto. It is of course possible to adopt an emergency shutoff valve that is opened and closed. In the above embodiment, although the case where the emergency shutoff valves 34, 38, 50 are formed by the globe valve and the emergency shutoff valve 42 is formed by the ball valve has been described, the invention is not necessarily limited thereto. Various valves can be adopted appropriately in consideration of resistance and the like.

  In each of the above embodiments, the tank trailer 1 stretches the support leg 7 to adjust the distance between the ground surface and the tank 2 and adjusts the inclination of the axial center O of the tank 2 with respect to the horizontal surface. It is not necessarily limited to this. A mechanism capable of adjusting the distance between the frame supporting the tank 2 and the tank 2 is provided between the tank 2 and the frame, and the inclination of the axis O of the tank 2 with respect to the horizontal plane is adjusted by raising and lowering the mechanism. Of course it is possible.

  Although the case where the plurality of pumps 124 and 131 are disposed in the tank trailer 101 has been described in the third embodiment, the invention is not necessarily limited thereto. Of course, it is possible to make one pump by using a pump that can satisfy the required specifications of discharge capacity and full head with one.

  In the first embodiment and the second embodiment, the case where the function of the recovery port for recovering the circulating fluid into the tank 2 is given to the gas port 22 and the gas port 22 and the recovery port are shared has been described. However, the present invention is not necessarily limited thereto, and it is of course possible to share the gas port 22 and the return port 25 by making the function of the return port 25 be the gas port 22.

  Note that part or all of any of the above-described embodiments can be combined with part or all of the other embodiments. Moreover, it is also possible to abbreviate | omit the structure of one part of said each embodiment.

1, 71, 101, 201 Tank trailer 2 Tank 7 Support leg (tilt adjustment mechanism)
11 first small diameter portion 12 second small diameter portion 13 large diameter portion 21, 102 first liquid port 22 gas port (recovery port)
24, 105, 106 second liquid port 25, 107 return port 27 liquid level detection device
39 second fluid piping 42, 128, 134 emergency shutoff valve
45 bypass pipe
46 relief valve 58 air tank 65 alarm device 72 liquid port (first liquid port, second liquid port)
73 liquid piping
76 bypass pipe
77 relief valve 103 gas port 124, 131 pump 202 liquid port (first liquid port, second liquid port)
203 gas port (return port)
O shaft center P pump T tractor

Claims (11)

In a tank trailer which is provided with a tank filled with liquefied gas and is towed by a tractor,
The tank has a first liquid port to which the liquefied gas is supplied;
A gas port through which vaporized gas is discharged with supply of liquefied gas from the first liquid port;
Includes a second liquid inlet for liquefied gas charged therein by connecting the pump is sent to the outside, the,
A liquid pipe connected to the second liquid port;
An emergency shutoff valve disposed in the fluid pipe;
A bypass pipe that bypasses the emergency shutoff valve and communicates with the liquid pipe;
And a relief valve disposed in the bypass pipe,
The emergency trailer valve is a tank trailer composed of a ball valve .   The tank trailer according to claim 1, wherein the tank includes a recovery port through which a portion of the liquefied gas delivered to the pump from the second liquid port is circulated and recovered from the pump.   The tank trailer according to claim 1 or 2, wherein the tank is provided with a return port connected to the downstream side of the pump and at least a part of the liquefied gas discharged from the pump is returned. .   The tank trailer according to claim 2, wherein the gas port is shared with the recovery port or the return port.   The tank trailer according to any one of claims 1 to 4, wherein the second liquid port is shared with the first liquid port. A liquid level detection device for detecting the position of the liquid level of the liquefied gas filled in the tank;
The tank has cylindrical first and second small diameter portions located on both sides in the axial direction,
And a large diameter portion formed between the first small diameter portion and the second small diameter portion and formed in a cylindrical shape having an inner diameter larger than that of the first small diameter portion and the second small diameter portion.
It is set horizontally so that the axis is inclined downward toward the rear of the vehicle,
The tank trailer according to any one of claims 1 to 5, wherein the second liquid port is formed in the large diameter portion, and the liquid level detection device detects the position of the liquid surface of the large diameter portion. .   The tank trailer according to claim 6, wherein the liquid level detection device transmits a detection signal regarding the position of the liquid level to an alarm device installed at an installation place of the tank. The tank is set in a horizontal position,
The tank trailer according to any one of claims 1 to 7, further comprising a tilt adjustment mechanism that adjusts the tilt of the axial center of the tank with respect to a horizontal surface.   The tank trailer according to any one of claims 1 to 8, wherein the pump is installed with respect to the tank. The tank trailer according to any one of claims 1 to 9, wherein the emergency shutoff valve is opened and closed based on compressed air supplied from an installation place of the tank. The tank trailer according to any one of claims 1 to 9, wherein the emergency shutoff valve is opened and closed based on compressed air supplied from an air tank installed in the tank.

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