JP6914014B2 - Vapor recovery device - Google Patents

Description

According to the present invention, when a volatile liquid is replenished in the liquid storage tank, the vapor of the volatile liquid (vapor) is among the gases released from the liquid storage tank when the volatile liquid is replenished. Regarding a vapor recovery device that separates and recovers gas.

In fuel supply facilities such as gas stations that replenish fuel such as gasoline consisting of volatile liquids to replenishment targets such as vehicles, the fuel is stored in an oil storage tank as a liquid storage tank installed on the premises. At the fuel supply facility, when the amount of fuel liquid in the oil storage tank decreases due to repeated fuel supply operations, fuel is appropriately delivered from the oil tank station by a tank lorry vehicle, and fuel is unloaded and replenished from the tank lorry vehicle.

However, when unloading and replenishing fuel from a tank lorry vehicle, it is installed in the oil storage tank to adjust the pressure inside the tank by communicating the atmosphere of the gas phase part (the space part in the upper part of the tank) with the outside. The air valve of the vent pipe is opened, and a part of the gas in the gas phase part (gas phase part gas) in the tank containing the fuel vapor is released into the atmosphere as it is from the vent hole of the vent pipe. There was something.

Therefore, a vapor recovery unit (VRU: Vapor Recovery Unit) is installed in the oil storage tank, and the vapor phase gas containing the fuel vapor, which was conventionally released as it is from the ventilation pipe when unloading and replenishing the fuel from the tank lorry vehicle, is removed from the vapor. It is designed to be released via a recovery device. The vapor recovery device uses an adsorbent to perform an adsorption process that adsorbs the fuel vapor component from the gas phase gas released from the oil storage tank to separate the fuel vapor component into a gas from which the fuel vapor component has been removed. It is configured to be released to the outside from. In addition, the vapor recovery device also has a configuration in which the fuel vapor component adsorbed on the adsorbent is desorbed by desorbing the fuel component from the adsorbent, and the desorbed fuel vapor component is returned to the oil storage tank to be recovered. It has become.

According to such a vapor recovery device, it is possible to prevent the gas containing fuel vapor from being released into the atmosphere as it is, and it is possible to suppress unnecessary loss of fuel.

Japanese Unexamined Patent Publication No. 2014-151274

By the way, in a normal vapor recovery device, when the fuel unloading and replenishing work in the oil storage tank where the pressure in the tank rises is executed, the unloading work detector provided in the vapor recovery device performs the unloading and replenishing work. Execution is detected, and the adsorption process is automatically performed based on the detection input. As a result, the clerk of the fuel supply facility and the driver of the tank lorry vehicle can perform the unloading and replenishment work of the fuel from the tank lorry vehicle without worrying about the operating status of the vapor recovery device.

However, due to some cause such as a failure of the detector itself or an abnormal state of the detection target, the unloading and replenishing work detector cannot detect the execution of the fuel unloading and replenishing work from the tank truck. If this happens, the vapor recovery device will not perform the adsorption process even though the fuel has been unloaded and replenished to the liquid storage tank.

Then, in such a situation, the gas phase gas including the fuel vapor in the tank whose pressure has risen with respect to the atmospheric pressure due to the fuel unloading and replenishment work is released to the outside as it is without going through the vapor recovery device. It is very likely that it has been done. Further, even for the vapor recovery device, since the suction process is performed as long as there is a detection input from the unloading / replenishment work detector, there is a high possibility that the device will be overlooked and continued to be used. As a result, there is a problem that the effect of collecting vapor by the vapor collecting device is lowered.

The present invention monitors and guarantees that the adsorption process is surely executed by the vapor recovery device during the unloading and replenishment work of fuel to the oil storage tank, and prevents the vapor recovery effect from being deteriorated. The purpose is to provide.

In order to solve the above-mentioned problems, the vapor recovery device of the present invention has the inside of the liquid storage tank based on the detection output of the unloading and replenishing work detector that detects the unloading and replenishment work of the volatile liquid to the liquid storage tank. Gas phase part gas is introduced, and the adsorption process of adsorbing the vapor of the volatile liquid contained in the introduced gas phase part gas to the adsorbent is executed, and the vapor of the volatile liquid after the adsorption process is removed. A vapor recovery device that discharges the gas to the outside, and is stored in an execution storage unit that stores the execution history of the adsorption process based on the detection output of the unloading / replenishment work detector, and an execution storage unit. Even if the execution time estimation unit that estimates the execution time of the next unloading and replenishment work based on the execution history of the adsorption process and the execution time of the next unloading and replenishment work estimated by the execution time estimation unit have passed. When the adsorption process is not executed, it is provided with an abnormality determination unit that determines and notifies the abnormality state.

According to the vapor recovery device of the present invention, the vapor of the volatile liquid contained in the gas phase gas in the liquid storage tank is not adsorbed during the unloading and replenishment work of the volatile liquid to the liquid storage tank. It is possible to prevent the vapor recovery device from being continuously used while being overlooked and the vapor recovery effect from being lowered.

Unloading and replenishing volatile liquid to the liquid storage tank Detecting replenishment work Not only the failure of the unloading and replenishing work detector itself, but also the gas phase containing fuel vapor in the tank, which is the detection target of the unloading and replenishing work detector. It is also possible to monitor the abnormal state of the partial gas and its cause.

In addition, problems, configurations, and effects other than those described above of the present invention will be clarified by the following description of the embodiments.

It is explanatory drawing of the system configuration of the vapor recovery apparatus which concerns on one Embodiment of this invention, and one Example of the gas station to which the vapor recovery apparatus which concerns on this Embodiment is applied. It is a functional block diagram of the execution monitoring device for execution monitoring / guarantee of unloading and replenishment work provided in the vapor recovery device of this embodiment. It is a flowchart of the monitoring control of the unloading and replenishing work executed by the execution monitoring device in the vapor recovery device of this embodiment.

FIG. 1 is an explanatory diagram of a system configuration of a vapor recovery device according to an embodiment of the present invention and a gas station to which the vapor recovery device according to the present embodiment is applied.

First, the configuration of the gas station 10 to which the vapor recovery device 1 according to the present embodiment is applied will be described with reference to FIG.

The gas station 10 has a configuration in which one or a plurality of oil storage tanks (liquid storage tanks) 11 are buried underground on the site surface 10G. Further, a refueling machine 12 for refueling a refueling target such as a vehicle is installed corresponding to the refueling area formed on the site surface 10G. The oil storage tank 11 and the refueling machine 12 are communicated with each other via a liquid supply pipe 13 extending underground on the site surface 10G.

In the illustrated gas station 10, one oil storage tank 11 and one oil supply machine 12 are installed, but one oil storage tank 11 can be shared by a plurality of oil storage machines 12 and one oil storage machine 12. It is also possible to provide a plurality of combinations of the tank 11 and one or a plurality of refueling machines 12, and the configuration of the gas station 10 itself is not limited to the configuration shown in the figure.

Returning to FIG. 1, the tank side end of the liquid supply pipe 13 communicates with the liquid phase portion L in the oil storage tank 11, and the refueling machine side end is connected to the pump inflow side of the refueling machine 12 to communicate with the oil storage tank 11. The fuel oil liquid (volatile liquid) stored in 11 can be pumped up by a pump (not shown) of the refueling machine 12.

The refueling machine 12 pumps the fuel oil liquid stored in the refueling tank 11 via the refueling pipe 13 by a pump, and operates a refueling nozzle (not shown) provided at the tip of the refueling hose to operate a vehicle or the like. Can perform refueling work (fuel supply work) for replenishment targets. During this refueling operation, the refueling machine 12 measures and outputs the amount of refueling (fuel supply amount) for the replenishment target with a flow meter (not shown).

Therefore, the amount of the fuel oil liquid stored in the oil storage tank 11 is reduced by the amount of the refueling amount each time the refueling operation using the refueling machine 12 for the replenishment target is repeated.

Therefore, a lubrication port 14 for replenishing the oil solution to the oil storage tank 11 is arranged at an appropriate position on the site surface 10G that does not interfere with the refueling work at the gas station 10 so as to correspond to the oil storage tank 11. The lubrication port 14 communicates with the inside of the corresponding oil storage tank 11 via an lubrication pipe 15 extending underground on the site surface 10G. The lubrication port 14 is a lubrication port of the unloading hose provided in the tank lorry vehicle in order to receive the unloading and replenishment of the fuel oil liquid from the tank lorry vehicle that has loaded and transferred the replenishing oil liquid from the oil tank station to the hatch (compartment chamber). The side connection end is removable, and it can be closed with a removable lid (not shown) except during unloading and replenishment work.

When unloading and replenishing the fuel oil liquid from the hatch of the tank lorry vehicle, the lubrication port 14 is connected to the unloading port of the tank lorry vehicle communicating with the corresponding hatch loaded with the replenishment oil liquid by a unloading hose. NS. Then, by opening the hatch bottom valve provided at the liquid discharge port on the bottom surface of the hatch and the unload valve provided at the unloading port of the tank truck, the fuel oil liquid loaded on the hatch is opened. Is unloaded and replenished to the oil storage tank 11.

Therefore, the amount of fuel oil liquid stored in the oil storage tank 11 increases by the amount of unloading (replenishment oil amount) each time the fuel oil liquid is unloaded and replenished from the hatch of the tank lorry vehicle. It will be.

In this way, the amount of liquid in the oil storage tank 11 increases or decreases depending on the unloading and replenishment work of the fuel oil liquid and the refueling work to the replenishment target, and the boundary between the liquid phase portion L and the gas phase portion G in the oil storage tank 11 The position of the liquid level of the fuel oil liquid stored in the tank according to the above is also displaced according to the amount of the stored liquid.

Therefore, the oil storage tank 11 is provided with a liquid level sensor (liquid amount sensor) 16 in order to measure the liquid level or the liquid amount of the oil liquid stored in the tank. The measurement output of the liquid level sensor 16 is transmitted to a liquid amount management device 17 arranged in a gas station office or the like, and the liquid amount management device 17 records and displays the momentary stored liquid amount of the oil storage tank 11 and manages it. NS.

In addition, in the oil storage tank 11, the ventilation pipe 18 is provided so that the pressure of the atmosphere of the gas phase portion G in the tank does not become abnormally high or low due to a temperature change in the tank, supply of oil liquid, unloading and replenishment, or the like. Is provided. One side of the ventilation pipe 18 communicates with the gas phase portion G in the oil storage tank 11, while the other side extends to a high place on the site (for example, 4 meters above the ground) and has a ventilation hole in the atmosphere through the atmosphere valve 19. It is open and open as.

As a breather valve, the atmosphere valve 19 opens when the internal pressure of each ventilation pipe 18, that is, the pressure of the atmosphere of the gas phase portion G in the tank of the oil storage tank 11 causes a pressure difference of a predetermined value or more with respect to the atmospheric pressure. , The pressure of the atmosphere of the gas phase portion G in the tank is adjusted. Specifically, when the pressure in the atmosphere of the gas phase portion G becomes higher than a predetermined value with respect to the atmospheric pressure due to an increase in the amount of stored liquid due to a temperature rise in the tank or unloading and replenishment of fuel oil liquid, the atmosphere valve 19 is released. The valve is opened, and a part of the gas phase portion G in the tank is released to the outside so as not to become abnormally high pressure. Further, the atmospheric valve 19 is also opened when the pressure of the atmosphere of the gas phase portion G in the tank becomes lower than a predetermined value with respect to the atmospheric pressure due to a decrease in the amount of stored liquid due to a decrease in the temperature in the tank or repeated refueling work. The valve is valved, and air is supplied from the outside so that the pressure in the atmosphere of the gas phase portion G in the tank does not become abnormally low.

It should be noted that the magnitude of the predetermined value of the differential pressure with respect to the atmospheric pressure when the atmospheric valve 19 is opened (the positive pressure and the negative pressure with respect to the atmospheric pressure are not taken into consideration) in relation to the release and air supply of the atmospheric valve 19 due to the valve opening. The predetermined value as an absolute value) may be a different value depending on whether the pressure in the atmosphere of the gas phase portion G in the tank is high pressure or low pressure.

Next, the system configuration of the vapor recovery device 1 according to the present embodiment applied to the gas station 10 having the above-described configuration will be described with reference to FIG.

As shown in FIG. 1, the vapor recovery device 1 according to the present embodiment includes a vapor recovery unit 20, an adsorption unit 30, a gas supply / discharge unit 40, a desorption / reflux unit 50, and a control unit 60.

The vapor recovery unit 20 introduces the atmosphere of the gas phase portion G containing the fuel vapor (fuel vapor) of the oil storage tank 11 into the adsorption unit 30. The vapor recovery unit 20 has a vapor recovery pipe 21 in which one side communicates with the gas phase portion G in the oil storage tank 11 and the other side communicates with the suction tower 31 of the suction unit 30. In the illustrated example, one side of the vapor recovery pipe 21 is connected to the ventilation pipe 18 of the oil storage tank 11 and communicates with the gas phase portion G in the oil storage tank 11 via the ventilation pipe 18. Further, the other side of the vapor recovery pipe 21 communicates with the suction tower 31 of the suction unit 30.

On top of that, the suction tower introduction valve 26 is arranged in the vapor recovery pipe 21. The suction tower introduction valve 26 communicates / shuts off between the gas phase portion G in the oil storage tank 11 with which the vapor recovery pipe 21 communicates and the introduction / return port 33 of the suction tower 31 in the suction portion 30. The suction tower introduction valve 26 is composed of, for example, an electromagnetically operated or pneumatically operated on-off valve, and opens and closes according to the supply / stop of an operation signal. The adsorption tower introduction valve 26 controls the introduction / shutoff of the atmosphere of the gas phase portion G containing the fuel vapor as the released gas to the adsorption tower 31 of the adsorption unit 30 according to the opening and closing of the valve 26.

Further, in the portion of the vapor recovery pipe 21 closer to the oil storage tank 11 than the suction tower introduction valve 26, the internal pressure of the ventilation pipe 18 communicating with the vapor recovery pipe 21, that is, the atmosphere of the gas phase portion G in the oil storage tank 11. A pressure sensor 25 for measuring the pressure of the above is provided.

The pressure sensor 25 is composed of, for example, a differential piezoelectric feeder (differential pressure type pressure gauge), and sets the internal pressure of the ventilation pipe 18, that is, the pressure (pressure change) of the atmosphere of the gas phase portion G in the oil storage tank 11 to the atmospheric pressure. Measure with the differential pressure of. Therefore, according to the measurement output of the pressure sensor 25, for example, the liquid level height of the oil liquid stored in the tank is displaced by the unloading and replenishment of the oil liquid, and the pressure of the atmosphere of the gas phase portion G in the tank. When the pressure rises with respect to the atmospheric pressure, it appears as a change in the differential pressure output.

The adsorption unit 30 adsorbs and separates / recovers the fuel vapor component from the atmosphere of the gas phase portion G containing the fuel vapor introduced via the vapor recovery unit 20. The adsorption unit 30 has an adsorption tower 31 in which the adsorbent 32 for adsorbing the fuel vapor component is filled in the tank. As the adsorbent 32, various adsorbents such as silica gel, zeolite, and activated carbon capable of desorbing adsorbed gas (for example, mesophase activated carbon) can be used.

In the adsorption tower 31, the atmosphere of the gas phase portion G containing the fuel vapor supplied via the vapor recovery unit 20 was introduced into the tank, or the atmosphere was separated and recovered by being adsorbed by the adsorbent 32 in the tank. An introduction / recirculation port 33 for desorbing the fuel vapor component and recirculating it to the oil storage tank 11 is formed. Further, in the adsorption tower 31, the gas from which the fuel vapor component has been removed is exhausted to the outside of the adsorption tower 31, and the adsorption tower 31 is in a negative pressure state due to the desorption of the fuel vapor component adsorbed on the adsorbent 32. An exhaust / air supply port 34 for introducing a depressurizing gas when depressurizing the pressure in the tank and returning it to the original pressure is also formed.

In addition, in the illustrated example, the adsorption tower 31 is provided with an adsorption status detection sensor 35 for monitoring the adsorption status of the fuel vapor component by the adsorbent 32 filled in the tank. The adsorption status detection sensor 35 is, for example, a plurality of temperatures provided for each region formed by dividing the inside of the tank from the introduction / return port 33 side in the lower part of the tank to the exhaust / air supply port 34 side in the upper part of the tank. Equipped with a sensor.

The adsorption status detection sensor 35 detects the adsorption status of the adsorbent 32 in each region with the detection output of each temperature sensor that changes according to the adsorption status, so that the inside of the tank filled with the adsorbent 32 of the adsorption tower 31 is filled. It is possible to detect the adsorption status of the fuel vapor component as a whole. In this case, as the temperature sensor, a thermocouple, a resistance temperature detector, a thermistor, or the like is used.

The introduction / recirculation port 33 is communicated with the other side of the vapor recovery pipe 21 constituting the vapor recovery unit 20, and is also connected with one side of the fuel vapor recirculation pipe 51 constituting the desorption / recirculation unit 50. A pressure sensor 36 for measuring the pressure in the atmosphere inside the suction tower 31 is provided in the introduction / return port 33 or the pipeline in the vicinity thereof. The pressure sensor 36 is composed of, for example, a pressure transmitter (absolute pressure pressure gauge).

On the other hand, one side of the air supply / exhaust pipe 41 constituting the gas supply / exhaust unit 40 is communicated with the exhaust / air supply port 34. The gas supply / discharge unit 40 releases the gas from which the fuel vapor component is adsorbed by the adsorbent 32 at the adsorption unit 30 to the atmosphere from the adsorption tower 31. Further, the pressure in the tank atmosphere of the adsorption tower 31 which is in a negative pressure state (extremely low pressure state) when the fuel vapor component is desorbed from the adsorbent 32 filled in the tank of the adsorption tower 31 is changed to an atmospheric pressure state. Alternatively, in order to depressurize to a reference state consisting of a state in the vicinity thereof, for example, an outside air pressure is introduced into the tank of the adsorption tower 31.

The gas supply / exhaust unit 40 has an air supply / exhaust pipe 41 having one side connected to an exhaust / air supply port 34 formed in the adsorption tower 31 of the adsorption unit 30. The other side of the air supply / exhaust pipe 41 extends to a high place on the site (for example, 4 meters above the ground) and is opened to the atmosphere as an air supply / exhaust hole through an air valve 42. The air valve 42 is for preventing rain and dust from entering the air supply / exhaust pipe 41 from the outside, and a cover for preventing rain and dust from entering is provided in place of the air valve 42. It may be.

A supply / exhaust valve 43 is provided in the middle of the supply / exhaust pipe 41 so as to be located closer to one side (closer to the suction portion 30 side) than the atmospheric valve 42. The supply / exhaust valve 43 is composed of, for example, an electromagnetically operated type, a pneumatically operated type, or an on-off valve having a flow rate adjusting function by driving a motor or the like, and opens and closes according to the supply / stop of an operation signal to form an air supply / exhaust pipe 41. In addition to communicating / shutting off, the valve opening amount can be adjusted according to the operation signal to adjust the passing flow rate per unit time.

In the illustrated example, one on-off valve is used to release the gas from which the fuel vapor component has been removed from the adsorption tower 31 of the adsorption unit 30 into the atmosphere and to introduce the external atmosphere into the tank of the adsorption tower 31. Although the configuration is such that the supply / exhaust valve 43 is composed of the above, the supply / exhaust pipe 41 may be configured in parallel with the air supply pipe portion provided with the air supply valve and the exhaust pipe portion provided with the exhaust valve.

The air valve 42 is opened as a breather valve when the internal pressure of the air supply / exhaust pipe 41 is equal to or more than a predetermined value with respect to the atmospheric pressure in the communication state of the air supply / exhaust pipe 41 in which the air supply / exhaust valve 43 is open. The valve is designed to adjust the internal pressure of the air supply / exhaust pipe 41, that is, the pressure inside the tank filled with the adsorbent 32 of the adsorption tower 31. The magnitude of the predetermined value of the differential pressure with respect to the atmospheric pressure when the atmospheric valve 42 is opened (the predetermined value as an absolute value without considering the positive pressure and the negative pressure with respect to the atmospheric pressure) is the internal pressure of the air supply / exhaust pipe 41. The value may be different between the time of exhaust when the pressure is high with respect to the atmospheric pressure and the time of supply when the pressure is low.

Further, in relation to the atmospheric valve 19 provided in the ventilation pipe 18 described above, a predetermined value of the differential pressure when the internal pressure of the air supply / exhaust pipe 41 becomes higher than the atmospheric pressure and the atmospheric valve 42 opens. The size is set smaller than the magnitude of the predetermined value of the differential pressure when the atmospheric valve 19 provided in the ventilation pipe 18 described above opens the valve when the internal pressure of the ventilation pipe 18 becomes higher than the atmospheric pressure. ing.

Therefore, in the illustrated example, when the internal pressure of the ventilation pipe 18, that is, the pressure of the atmosphere of the gas phase portion G in the oil storage tank 11 with which the ventilation pipe 18 communicates rises, the suction tower introduction valve 26 of the vapor recovery unit 20 increases. If is in the valve open state, the atmospheric valve 42 opens prior to the atmospheric valve 19. As a result, the atmosphere in which the pressure of the gas phase portion G of the ventilation pipe 18 and the oil storage tank 11 is increased is not normally caused by the ventilation pipe 18, but first, the vapor recovery pipe 21 of the vapor recovery unit 20 and the suction tower of the suction unit 30 are used. The pressure is released from the vapor recovery device 1 via the air supply / exhaust pipe 41 of the gas supply / exhaust unit 40 and the gas supply / exhaust unit 40.

Therefore, when the fuel oil liquid is unloaded and replenished from the tank lorry vehicle to the oil storage tank 11 via the lubrication port 14 and the lubrication pipe 15, the atmosphere of the gas phase portion G in the tank rises in the liquid level, that is, in the tank. The pressure will increase as the amount of liquid increases. At this time, if the atmosphere of the gas phase portion G is also introduced into the adsorption tower 31 of the adsorption unit 30 via the vapor recovery unit 20, the atmosphere of the gas phase portion G including the fuel vapor whose pressure has risen is the adsorption tower. The fuel vapor component is adsorbed by the adsorbent 32 filled in the tank of 31, and the gas from which the fuel vapor component has been removed is introduced into the atmosphere through the supply / exhaust pipe 41 of the gas supply / exhaust section 40. It is released and the pressure inside the oil storage tank 11 is released.

As a result, even when the fuel oil liquid is unloaded and replenished from the tank lorry vehicle to the oil storage tank 11, there is no significant delay such that the inside of the tank becomes abnormally high pressure, and the fuel vapor in which the pressure of the oil storage tank 11 has increased is included. If the atmosphere of the gas phase portion G can be introduced into the suction portion 30, the atmosphere valve 19 of the ventilation pipe 18 is not opened, but the gas from which the fuel vapor component is removed is converted into a gas and discharged from the gas supply / discharge portion 40. It is possible to prevent the gas containing the fuel vapor from being released into the atmosphere as it is from the ventilation holes of the ventilation pipe 18.

The desorption / reflux unit 50 desorbs the fuel vapor component adsorbed by the adsorbent 32 filled in the tank of the adsorption tower 31 of the adsorption unit 30 and refluxes it to the oil storage tank 11.

The desorption / reflux unit 50 has a fuel vapor recirculation pipe 51 having one side communicating with the introduction / recirculation port 33 of the adsorption tower 31 in the adsorption unit 30 and the other side communicating with the gas phase portion G in the tank of the oil storage tank 11. In the illustrated example, the fuel vapor recirculation pipe 51 has a configuration in which the other side is directly connected to the oil storage tank 11, but the connection point on the other side is always communicated with the oil storage tank 11 without a valve or the like. As long as it is a place where it is, for example, the ventilation pipe 18 may be used. Further, if the oil storage tank 11 with which the other side communicates is another oil storage tank 11 in which the same or the same type of oil liquid is stored, the atmosphere of the gas phase portion G is introduced in order to recirculate the desorbed fuel vapor. It may be different from the oil storage tank 11. Further, the present invention is not limited to one oil storage tank 11, and may be configured to always communicate with a plurality of oil storage tanks 11 in which the same or the same type of oil liquid is stored.

In the illustrated example, the desorption / recirculation unit 50 has a recirculation valve 52, a vacuum pump (suction pump) 53, and a cooling unit 54 interposed in this fuel vapor recirculation pipe 51 in order from one side to the other. It is configured.

The recirculation valve 52 communicates / shuts off the fuel vapor recirculation pipe 51 between the introduction / recirculation port 33 of the suction tower 31 in the suction unit 30 and the vacuum pump 53 and the cooling unit 54 in the subsequent stage according to the opening and closing of the recirculation valve 52. The recirculation valve 52 is composed of, for example, an electromagnetically operated or pneumatically operated on-off valve, and opens and closes according to the supply / stop of an operation signal to communicate / shut off the fuel vapor recirculation pipe 51 on the suction side of the vacuum pump 53. .. The recirculation valve 52 is an oil storage tank 11 in which the introduction / recirculation port 33 of the suction tower 31 in the suction unit 30 is connected to the other side of the desorption / recirculation unit 50 via the vacuum pump 53 and the cooling unit 54 in communication with each other according to the opening / closing of the recirculation valve 52. Communicate / shut off to the side.

In the illustrated example, the recirculation valve 52 has a separate configuration from the suction tower introduction valve 26 of the vapor recovery unit 20, but is integrated with the suction tower introduction valve 26 of the vapor recovery unit 20 for suction / desorption. It can also be a switching valve. In this case, the suction / desorption switching valve is composed of, for example, an electromagnetically operated or pneumatically operated three-way valve, and the introduction / reflux port 33 of the suction tower 31 in the suction section 30 is replaced with the vapor recovery section 20 according to the operation signal. The common pipe portion 23 of the vapor recovery pipe 21 or the fuel vapor recirculation pipe 51 of the recirculation portion 50 can be selectively communicated with each other.

As a suction pump, the vacuum pump 53 is driven by the adsorbent of the suction tower 31 in a state where the recirculation valve 52 is opened and the suction side of the vacuum pump 53 is communicated with the introduction / recirculation port 33 of the suction tower 31. The atmosphere in the tank filled with 32 is sucked. Therefore, in a state where the fuel vapor component is adsorbed on the adsorbent 32, the fuel vapor component is desorbed from the adsorbent 32 by driving the vacuum pump 53, and the atmosphere in the tank is sucked together with the desorbed fuel vapor component. Will be done.

The suction in the tank of the adsorption tower 31 by the vacuum pump 53 for desorbing the fuel vapor component from the adsorbent 32 is a state in which the supply / exhaust valve 43 of the gas supply / exhaust unit 40 is closed. It is done in. Along with this, the atmosphere in the tank is decompressed and becomes a negative pressure state (extremely low pressure state).

The cooling unit 54 cools and liquefies the atmosphere containing the desorbed fuel vapor component desorbed from the adsorbent 32 sucked by the vacuum pump 53. As the cooling configuration of the cooling unit 54, for example, a configuration in which the refrigerant is compressed by a compressor to be cooled, a configuration in which cooling by cooling water is used, or the like can be used. The atmosphere containing the desorbed fuel vapor component liquefied by the cooling unit 54 and the desorbed fuel vapor component that could not be completely liquefied is returned to the oil storage tank 11 from the other side of the fuel vapor return pipe 51.

As a control device for the vapor recovery device 1, the control unit 60 introduces a suction tower based on the outputs of various sensors such as the pressure sensors 25 and 36 and the suction status detection sensor 35 described above and the outputs from the liquid amount management device 17. It controls the operation of each part such as the valve 26, the supply / exhaust valve 43, the recirculation valve 52, the vacuum pump 53, the cooling unit 54, etc., and controls the execution of the suction process, the desorption process, and the depressurization process of the vapor recovery device 1. The control unit 60 is composed of, for example, a microcomputer including a storage unit such as a memory.

In the execution control of the suction process, the control unit 60 determines the detection output of the pressure sensor 25, the liquid amount increase output of the liquid amount management device 17 based on the detection output of the liquid level sensor 16, or the unloading hose to the lubrication port 14. When it is detected that the unloading and replenishment work of the fuel oil liquid from the tank lorry vehicle is started for the oil storage tank 11 based on the connection detection of the above, it is adsorbed by the adsorbent 32 filled in the tank of the adsorption tower 31. If the desorption of the fuel vapor component and the subsequent decompression of the tank have not been performed, the adsorption process is immediately started. In the case of this embodiment, the control unit 60 unloads and replenishes the fuel oil liquid from the tank lorry vehicle to the oil storage tank 11 based on the pressure of the atmosphere of the gas phase portion G in the oil storage tank 11 measured by the pressure sensor 25. By detecting a predetermined pressure rise of the atmospheric pressure of the gas phase portion G based on the work, it is detected that the unloading and replenishment work of the fuel oil liquid from the tank lorry vehicle is started for the oil storage tank 11.

In the suction process, the control unit 60 introduces a suction tower related to the oil storage tank 11 in which the unloading and replenishment work is performed while the recirculation valve 52 is in the closed state and the supply / discharge valve 43 is in the open state. By opening the valve 26 and introducing the atmosphere of the gas phase portion G containing the fuel vapor whose pressure in the oil storage tank 11 has increased into the adsorption portion 30, the fuel vapor component thereof is generated by the adsorbent 32 filled in the tank. Is adsorbed to form a gas from which the fuel vapor component has been removed, and then discharged from the supply / exhaust holes of the supply / exhaust pipe 41.

As a result, even when the pressure inside the oil storage tank 11 rises due to the unloading and replenishment of the fuel oil liquid from the tank lorry vehicle to the oil storage tank 11, the adsorbent 32 filled in the tank of the adsorption tower 31 If the desorption and subsequent decompression in the tank have already been completed, the control unit 60 immediately opens the adsorption tower introduction valve 26 corresponding to the oil storage tank 11 and releases the gas (steam) from the oil storage tank 11. Since the adsorption process of the fuel vapor component contained in the atmosphere of the phase portion G) can be started, it is possible to prevent the gas containing the fuel vapor from being released into the atmosphere as it is from the ventilation hole of the ventilation pipe 18.

Further, in the execution control of the desorption process and the depressurization process, the control unit 60 removes the unloading hose connected to the lubrication port 14, outputs the liquid amount management device 17, or operates the unloading completion button (not shown). When it is detected that the unloading and replenishment of the fuel oil liquid to the oil storage tank 11 is completed from the tank lorry vehicle, the suction tower introduction valve 26 of the vapor recovery unit 20 and the supply / discharge valve 43 of the gas supply / exhaust unit 40 are closed. While the valve is opened, the recirculation valve 52 of the desorption / recirculation section 50 is opened, while the vacuum pump 53 and the cooling unit 54 of the desorption / recirculation section 50 are started to start the desorption process in the tank of the adsorption tower 31.

As a result, the atmosphere in the tank filled with the adsorbent 32 of the adsorption tower 31 is sucked into a negative pressure state (ultra-low pressure state) by the vacuum pump 53, and the fuel vapor component adsorbed on the adsorbent 32 is desorbed. Will be done. At that time, the atmosphere in the tank of the adsorption tower 31 containing the sucked desorbed fuel vapor component is supplied to the cooling unit 54, and the desorbed fuel vapor component is liquefied. Then, the atmosphere containing the desorbed fuel vapor component liquefied by the cooling unit 54 and the desorbed fuel vapor component that could not be completely liquefied is returned to the oil storage tank 11 from the other side of the fuel vapor recirculation pipe 51.

Then, in this way, for example, when the desorption process for the set time is completed, the control unit 60 stops the vacuum pump 53 and the cooling unit 54 of the desorption / recirculation unit 50, and opens the supply / discharge valve 43 of the gas supply / discharge unit 40. Then, an atmosphere containing no fuel vapor is introduced from the outside as a depressurizing gas into the tank of the adsorption tower 31 via the supply / exhaust pipe 41 of the gas supply / exhaust unit 40, and the inside of the tank of the adsorption tower 31 is introduced. The depressurization process is started. At that time, the atmospheric valve 42 of the gas supply / discharge unit 40 is set so that the negative pressure state (ultra-low pressure state) at the end of the desorption process in the tank of the adsorption tower 31 acts by opening the supply / discharge valve 43. The valve is opened by the pressure difference between the atmospheric pressure and the internal pressure of the air supply / exhaust pipe 41, that is, the pressure in the desorbed suction tower 31 tank.

After that, when the depressurization process for the set time is completed in this way, the control unit 60 closes the recirculation valve 52 of the desorption / recirculation unit 50 which was opened by the desorption process, and the valve is closed by the desorption process. The suction tower introduction valve 26 of the vapor recovery unit 20 is opened to return the vapor recovery device 1 to a state capable of supporting the suction process.

In the vapor recovery device 1 according to the present embodiment, the control unit 60 functions as an execution control unit for each of the adsorption process, the desorption process, and the depressurization process in this way, and in particular, the execution monitoring device 70 for the adsorption process. The monitoring and control unit 72 of the above is configured to monitor and control that the adsorption process at the time of unloading and replenishing the oil liquid from the tank lorry vehicle is surely executed.

FIG. 2 is a functional configuration diagram of an execution monitoring device for execution monitoring / guarantee of unloading / replenishment work provided in the vapor recovery device of this embodiment.

The execution monitoring device 70 has a unloading / replenishment work detector 71, a monitoring control unit 72, an execution storage unit 73, a calendar unit 74, a clock unit 75, and an abnormality notification device 76.

The unloading / replenishment work detector 71 unloads the fuel oil liquid from the tank lorry vehicle to the oil storage tank 11 so that the control unit 60, which functions as the execution control unit of the adsorption process in the vapor recovery device 1, starts the execution of the adsorption process. Detects the execution or start of replenishment work. In the case of this embodiment, the control unit 60, which functions as the execution control unit of the adsorption process, detects the increase in the predetermined pressure of the gas phase portion G in the oil storage tank 11, so that the fuel from the tank lorry vehicle is charged to the oil storage tank 11. Since it is detected that the unloading and replenishing work of the oil liquid has started, the unloading and replenishing work detector 71 is a pressure sensor that measures the pressure of the atmosphere of the gas phase portion G in the oil storage tank 11 at that time. 25 is used.

The control unit 60, which functions as an execution control unit for the adsorption process, presses the execution or execution start of the unloading and replenishment work of the fuel oil liquid from the tank lorry vehicle to the oil storage tank 11 for starting the execution of the adsorption process. If it is detected by the liquid amount increase output of the liquid amount management device 17 or the connection detection of the unloading hose to the lubrication port 14 instead of the sensor 25, the liquid amount management device 17 or the lubrication port 14 The unloading hose connection detection sensor or the like provided in the above can be used as the unloading / replenishment work detector 71.

As described above, in this embodiment, as the unloading / replenishment work detector 71, the unloading / replenishment work detector 71 itself detects the execution or execution start of the unloading / replenishment work in order to start the execution of the adsorption process. Not only the failure of the detector itself to start the execution of the suction process, but also the abnormal state of the detection target of the detector used to detect the start of the execution of the suction process (the detector itself has no failure). In addition, it is possible to detect an abnormal state in which the adsorption process is not executed during the unloading and replenishment work of the oil liquid from the tank lorry vehicle, including the abnormal state in which the detector does not detect the execution or start of execution of the unloading and replenishment work. I have to.

The monitoring and control unit 72 executes unloading and replenishing work of fuel oil liquid from the tank lorry vehicle based on a predetermined pressure change in the atmosphere of the gas phase portion G measured by the pressure sensor 25 as the unloading and replenishing work detector 71. Detects that execution has started.

Then, when the monitoring control unit 72 detects that the unloading / replenishment work of the fuel oil liquid has been executed or started from the tank lorry vehicle to the oil storage tank 11, first, as a history generation means 77 of the execution history of the unloading / replenishment work. , The current date and time are acquired from the calendar unit 74 and the clock unit 75, and the history information Rn of the nth unloading and replenishment work this time is created based on these dates and times and stored in the execution storage unit 73. As a result, the execution storage unit 73 accumulates history information R1, R2, ..., Rn of the unloading and replenishing work each time the unloading and replenishing work is executed.

Subsequently, the monitoring control unit 72 creates the history information Rn of the nth unloading and replenishment work this time as the history generation means 77 and saves it in the execution storage unit 73. The permissible time interval T from the next unloading and replenishing work to the next n + 1th unloading and replenishing work, or the execution deadline and time D of the next n + 1th unloading and replenishing work is estimated as the execution time TD of the next unloading and replenishing work. ..

The execution time T or D of the next unloading and replenishment work is estimated by the execution time estimation means 78 as described below.

For example, the execution time estimating means 78 first executes the date and time of the history information Rn of the nth unloading and replenishing work this time each time the history generating means 77 generates the history information Rn of the nth unloading and replenishing work. The difference dR (n to n-1) between the two is calculated from the date and time of the history information Rn-1 of the previous n-1th unloading and replenishment work stored in the storage unit 73, and this difference dR (n to n-1) is calculated. n-1) is associated with the history information Rn of the nth unloading and replenishment work this time, and is stored in the execution storage unit 73.

Then, in this embodiment, the execution time estimation means 78 is stored in the execution storage unit 73 for a predetermined number of times x minutes (x is a preset integer of 1 or more) up to the nth time of this time. The average value dRav of the difference dR (n-x to n-x + 1), ..., DR (n to n-1) corresponding to each is calculated, and the calculated average value dRav is multiplied by the safety factor s, and this time n The permissible time interval T from the first unloading replenishment work to the next n + 1th unloading replenishment work is calculated, and if necessary, this calculated permissible time interval is set to the date and time of the history information Rn of the nth unloading replenishment work this time. The execution deadline date and time D of the next n + 1th unloading and replenishment work to which T is added is further calculated.

In this way, the execution time estimation means 78 is the permissible time interval T from the nth unloading and replenishing work this time to the next n + 1th unloading and replenishing work, or the execution deadline date and time D of the next n + 1th unloading and replenishing work. Is estimated as the execution time TD of the next unloading and replenishment work.

At that time, with respect to the safety factor s, a plurality of safety factors s1, s2, ..., Sm are prepared in advance, and the execution time estimating means 78 analyzes the tendency to receive the unloading and replenishment work of the gas station 10 and the oil storage tank 11. You can select what you have reflected.

For example, the gas station 10 and the oil storage tank 11 tend to receive unloading and replenishment work. Receive unloading and replenishment of liquid, but do not receive unloading and replenishment of fuel oil from tank trucks on holidays, * Receive unloading and replenishment of fuel oil from tank lorry vehicles once every 2-3 days, etc. There is a feature of.

Therefore, regarding the safety factor, the execution time estimation means 78 tends to have a difference dR (n-x to n-x + 1), ..., DR (n to n-1) before multiplying the average value dRav by the safety factor s. (For example, how many days are the intervals for receiving unloading and replenishment of fuel oil from a tank truck, whether the interval dR for receiving unloading and replenishment tends to be shortened or extended, etc.), this difference dR (n-x to n) -X + 1), ..., dR (n to n-1) history information of unloading and replenishment work used for each calculation Rn-x, ..., Rn tendencies (for example, whether unloading and replenishment is received even on holidays) Whether or not, the time to receive unloading replenishment is, for example, substantially constant or irregular as in the early morning each time, the nth replenishment number this time (that is, the history of replenishment work accumulated in the execution storage unit 73). Based on the number of information R), the safety factor s corresponding to the analysis result is selected from the table.

Specifically, for example, the safety factor s when receiving unloading and replenishment work every day is higher than the safety factor s when receiving unloading and replenishment work once every two to three days. For example, in the history information R of the replenishment work stored in the execution storage unit 73, the safety factor s when the unloading is not received is higher than the safety factor s when the replenishment is received. An appropriate safety factor s is selected so that the smaller the number, the higher the safety factor s.

The method for estimating the allowable time interval T from the nth unloading and replenishing work this time to the next n + 1th unloading and replenishing work is not limited to the above-mentioned estimation method, and is, for example, within the value range of the difference dR. It is also possible to calculate the occurrence frequency divided according to the situation and set the maximum value of the value range of the difference dR having the highest occurrence frequency as the allowable time interval T.

When the monitoring and control unit 72 estimates the execution time TD of the next unloading and replenishing work as the execution time estimating means 78, this time, as the abnormality determining means 79, the clock output of the calendar unit 74 and the clock unit 75 and the unloading and replenishing work detection. Based on the detection output of the next n + 1th unloading / replenishment work from the vessel 71, the control unit 60 as the execution control unit of the adsorption process detects that the unloading / replenishment work of the fuel oil liquid from the tank lorry vehicle has started. It is determined whether or not the failure state of the pressure sensor 25 itself used for this purpose and the abnormal state of the atmosphere of the gas phase portion G in the oil storage tank 11 which is the detection target of the pressure sensor 25 have occurred.

In this case, the abnormality determining means 79 serves as the execution time estimating means 78 to execute the next unloading and replenishing work at the execution time TD (allowable time interval T from the nth unloading and replenishing work this time to the next n + 1th unloading and replenishing work). Or, regarding the execution deadline date and time D) of the next n + 1th unloading replenishment work, even after the execution time TD of the next unloading replenishment work has passed, the next n + 1th unloading replenishment from the unloading replenishment work detector 71 If the work detection output is not supplied, it is determined that a failure state of the pressure sensor 25 itself or an abnormal state of the atmosphere of the gas phase portion G in the oil storage tank 11 has occurred.

Here, the abnormal state of the atmosphere of the gas phase portion G in the oil storage tank 11 is defined as the execution control unit of the adsorption process depending on the leaked portion generated in the ventilation pipe 18 or the air valve 19 even if the pressure sensor 25 itself does not have a failure. This refers to a situation in which the pressure in the atmosphere of the gas phase portion G in the oil storage tank 11 does not rise until the control unit 60 of the above can detect the start of the unloading and replenishing work.

When the abnormality determination means 79 determines any of these abnormal states, the abnormality alarm 76 is activated to notify the occurrence of the abnormal state.

FIG. 3 is a flowchart of monitoring and control of unloading and replenishing work executed by the execution monitoring device configured as described above in the vapor recovery device of the present embodiment.

Step S10: The execution monitoring device 70 of the adsorption process initially sets the execution time TD of the next unloading / replenishment operation in the monitoring control unit 72 when the vapor recovery device 1 is activated. In this case, since the history information R of the unloading and replenishment work has not yet been accumulated in the execution storage unit 73, the preset execution time TD is based on the execution deadline date and time D in which the safety factor s is sufficiently high. The execution time is TD.

Step S20: The monitoring control unit 72 of the execution monitoring device 70 starts timing the execution interval t of the unloading and replenishing work from the nth unloading and replenishing work this time to the next n + 1th unloading and replenishing work. When the vapor recovery device 1 is activated, n = 0.

Step S30: The monitoring control unit 72 of the execution monitoring device 70 monitors whether or not the execution detection of the fuel oil liquid unloading / replenishing work from the tank lorry vehicle is supplied from the unloading / replenishment work detector 71.

Step S40: The monitoring control unit 72 of the execution monitoring device 70 has the execution time TD of the next unloading / replenishment work in which the execution interval t of the unloading / replenishment work started in step S20 is set in step S10 or step S34 described later. Monitor whether or not has passed.

Here, the monitoring of steps S30 and S40 is performed until the execution detection of the fuel oil liquid unloading / replenishing work from the tank lorry vehicle is supplied from the unloading / replenishment work detector 71, or the execution time of the next unloading / replenishment work. It is repeated until TD has passed.

Step S32: The monitoring control unit 72 of the execution monitoring device 70 performs the unloading / replenishment work detector 71 in step S30 before the execution interval t of the unloading / replenishment work elapses from the execution time TD of the next unloading / replenishment work. When the execution detection of the unloading and replenishing work of the fuel oil liquid from the tank lorry vehicle is supplied, the history information Rn of the nth unloading and replenishing work is created and stored in the execution storage unit 73.

Step S34: The monitoring control unit 72 of the execution monitoring device 70 unloads the next n + 1 times based on the history information R1 to Rn of the unloading and replenishing work up to the nth time this time stored and stored in the execution storage unit 73. The execution time TD of the replenishment work is estimated, and the update is set as the execution time TD of the next unloading replenishment work.

Step S36: The monitoring control unit 72 of the execution monitoring device 70 determines whether or not the unloading and replenishment work of the fuel oil liquid from the nth tank lorry vehicle has been completed this time. This determination is detected by the pressure sensor 25 by the control unit 60 which functions as the execution control unit for each of the suction process, the desorption process, and the depressurization process of the vapor recovery device 1 and also functions as the monitoring control unit 72 of the execution monitoring device 70. It can be detected based on the output, the liquid amount increase output of the liquid amount management device 17 based on the detection output of the liquid level sensor 16, the connection detection of the unloading hose to the lubrication port 14, and the like.

Then, when it is determined in step S36 that the unloading and replenishment work of the fuel oil liquid from the nth tank lorry vehicle has been completed, the process returns to step S20, and the above-mentioned processes of step S20 and the like are repeated.

In this embodiment, according to this step S36, the timing of the execution interval t of the unloading / replenishing work is strictly reset-started from the time when the unloading / replenishing work of the fuel oil liquid is completed. If the execution time TD of the next unloading / replenishing work updated and set in step S34 is set in consideration of the execution time of the unloading / replenishing work, the process of step S36 can be omitted.

Step S42: In response to the processes of steps S32 to S36, the monitoring control unit 72 of the execution monitoring device 70 supplies the execution detection of the unloading and replenishing work of the fuel oil liquid from the tank lorry vehicle from the unloading and replenishing work detector 71. If it is determined in step S40 that the execution time TD of the next unloading / replenishment work has passed without being performed, the failure state of the pressure sensor 25 itself included in the unloading / replenishment work detector 71 or the pressure sensor thereof. It is determined that an abnormal state has occurred in the atmosphere of the gas phase portion G in the oil storage tank 11 which is the detection target of the 25, and the abnormality alarm 76 is operated.

As described above, according to the vapor recovery device 1 of the present embodiment, not only the failure of the pressure sensor 25 itself for starting the execution of the suction process but also the pressure sensor 25 used for detecting the start of the execution of the suction process. Unloading of fuel oil liquid from the tank lorry vehicle, including the abnormal state of the detection target (the pressure of the atmosphere of the gas phase portion G in the oil storage tank 11 measured by the pressure sensor 25 even if the pressure sensor 25 itself is not defective). It is possible to detect an abnormal state in which the suction process is not executed during replenishment work. As a result, the staff at the gas station 10 stores oil up to a value at which the control unit 60 as the execution control unit of the adsorption process can detect the start of the unloading and replenishment work due to the leaked portion generated in the ventilation pipe 18 and the air valve 19. The situation in which the pressure in the atmosphere of the gas phase portion G in the tank 11 does not rise can also be recognized by the operation of the abnormality alarm 76. Then, it is overlooked that the vapor oil liquid vapor contained in the gas of the gas phase portion G in the oil storage tank 11 is not adsorbed during the unloading and replenishment work of the fuel oil liquid to the oil storage tank 11. , It is possible to prevent the vapor recovery device 1 from being continuously used and the vapor recovery effect from being lowered.

The vapor recovery device according to the present invention is not limited to the vapor recovery device 1 of the above-described embodiment. For example, the execution monitoring device 70 is shared by a plurality of vapor recovery devices 1. It is also possible to centrally monitor the abnormal state in which the adsorption process is not performed during the unloading and replenishment work of the fuel oil liquid from the tank lorry vehicle of each of the plurality of vapor recovery devices 1.

In the above embodiment, the execution or execution start of the unloading and replenishing work is detected by the detector that detects the execution or execution start of the unloading and replenishing work in order to start the execution of the adsorption process, and the estimated execution time of the unloading is based on the detection. However, the calculation is not limited to this, and it is of course possible to calculate the estimated execution time of unloading based on, for example, the desorption process.

1 Vapor recovery device, 10 gas station, 10G site surface,
11 Oil storage tank (liquid storage tank), L liquid phase part, G gas phase part,
12 Lubrication machine, 13 Lubrication pipe, 14 Lubrication port, 15 Lubrication pipe,
16 Liquid level sensor, 17 Liquid level control device, 18 Vent pipe, 19 Atmospheric valve,
20 Vapor recovery section, 21 Vapor recovery tube, 22 Branch tube section,
23 Common pipe, 25 Pressure sensor, 26 Suction tower introduction valve,
30 Adsorbent, 31 Adsorption tower, 32 Adsorbent, 33 Introductory / reflux port,
34 Exhaust / air supply port, 35 Adsorption status detection sensor, 36 Pressure sensor,
40 Gas supply / exhaust part, 41 Supply / exhaust pipe, 42 Atmospheric valve, 43 Supply / exhaust valve,
44 Exhaust valve, 45 Air supply valve, 46 Bypass pipeline,
50 Desorption / reflux part, 51 Fuel vapor reflux pipe, 52 Reflux valve,
53 vacuum pump, 54 cooling unit, 60 control unit,
70 Execution monitoring device, 71 Unloading and replenishment work detector, 72 Monitoring and control unit,
73 Execution storage unit, 74 Calendar unit, 75 Clock unit, 76 Abnormality alarm,
77 History generation means, 78 Execution time estimation means, 79 Abnormality determination means

Claims (2)

The gas phase gas in the liquid storage tank is introduced based on the detection output of the unloading replenishment work detector that detects the execution or start of the unloading and replenishment work of the volatile liquid to the liquid storage tank, and the gas is introduced. It is a vapor recovery device that executes an adsorption process that adsorbs the vapor of the volatile liquid contained in the gas in the gas phase part to the adsorbent, and releases the gas from which the vapor of the volatile liquid after the adsorption process has been removed to the outside. hand,
An execution storage unit that stores the execution history of the unloading and replenishing work based on the detection output of the unloading and replenishing work detector, and
An execution time estimation unit that estimates the execution time of the next unloading / replenishment work based on the execution history of the unloading / replenishment work stored in the execution storage unit.
If the execution or execution start of the unloading replenishment work is not detected by the unloading replenishment work detector even after the execution time of the next unloading replenishment work estimated by the execution time estimation unit has passed, the adsorption A vapor recovery device provided with an abnormality determination unit that determines and notifies an abnormal state in which processing is not executed. The unloading and replenishing work detector comprises a pressure sensor that detects the pressure in the liquid storage tank.
The adsorption treatment is performed when the pressure in the reservoir tank is detected that were raised by the pressure sensor,
The abnormality determination unit detects the execution or start of execution of the unloading / replenishment work by the unloading / replenishment work detector even after the execution time of the next detection unloading / replenishment work estimated by the execution time estimation unit has passed. The vapor recovery device according to claim 1, wherein if not, it is determined that the adsorption process is not executed and a notification is given.

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