JP2014025821A - Detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a detector capable of correctly detecting mixing of water or air into fuel oil which will be supplied by a measuring apparatus for supporting a case in which water or air is mixed into fuel oil from a side nearer to the measuring apparatus than an underground tank.SOLUTION: An ultrasonic transmission device (1) emitting ultrasonic waves (Ws) and an ultrasonic receiver (2) receiving the ultrasonic waves (Ws) are provided in an oil supply circuit (3).

Description

  The present invention relates to a detection device used in an oil supply device that supplies fuel oil, kerosene, and other various oils, and relates to a detection device for an oil supply device that determines the type of oil or the like supplied by the oil supply device.

At gas stations (gas stations), a large amount of water may flow into underground storage tanks due to heavy rain. Further, cracks and holes may be formed in the piping due to piping work and corrosion, and water may enter from there.
If water is mixed in due to various reasons like this, when gasoline containing water is supplied to the vehicle and the gasoline (containing water) flows into the combustion chamber of the engine, knocking or engine stop due to poor combustion In some cases, it may lead to the worst situation of engine damage.
And if you sell the gasoline (gas mixed with water) without detecting that water is mixed in the gasoline, you need to check the sales customer data and contact each customer. A great deal of effort must be expended in handling and handling such as reporting to.

On the other hand, there are cases where air is mixed into fuel oil to be sold at a gas station due to various factors. When air is mixed into the fuel oil, the amount actually supplied to the vehicle or the like (actual oil supply amount) is less than the fuel supply amount (measured value: display value) measured by the flow meter. As a result, a measurement accuracy problem occurs.
Troubles in underground oil storage tanks and underground piping systems, especially when water or air enters fuel oil, may cause serious problems. It is desired. However, when water or air is mixed into the fuel oil, a detection device that can quickly detect that is not proposed in the prior art.

As another conventional technique, an oil level gauge attached to an underground storage tank of a gas station has been proposed which has a function of detecting water accumulated at the bottom from the amount of float movement (see Patent Document 1).
However, in the related art, even if the water accumulated in the underground tank can be detected, the water that has entered the piping system from the underground tank to the fueling device is mixed into the fuel oil flowing through the piping system. Can not cope with the situation.
In addition to this, in the related art (Patent Document 1), it is possible to cope with the mixing of water into the fuel oil, but cannot cope with the case where air is mixed into the fuel oil.

JP-A-9-323799

  The present invention has been proposed in view of the above-described problems of the prior art, and accurately detects that water or air has been mixed into the fuel oil supplied by the fuel supply device, and more accurately measures than the underground tank. An object of the present invention is to provide a detection device that can cope with a case where water or air is mixed into fuel oil from the region on the vessel side.

  The detection device (101) of the present invention includes an ultrasonic transmission device (for example, the piezoelectric element 1) that transmits ultrasonic waves (for example, an ultrasonic pulse Ws) and an ultrasonic reception device (for example, the piezoelectric element 1) that receives the ultrasonic waves (Ws). For example, the piezoelectric element 2) is provided in an oil supply system (3: for example, an oil supply pipe, a pump, an oil supply pipe, etc.).

  In the present invention, including the control device (first control device 10), the control device (10) is introduced into the oil flowing through the oil supply system from the attenuation rate of the ultrasonic wave received by the ultrasonic receiving device (2). It is preferable to have a function of determining the mixing rate of mixed foreign matters (water, air).

In carrying out the present invention, the oil supply system (3) is preferably an oil supply pipe.
Moreover, it is preferable that the said oil supply system (3) is piping in a pump (5).

Further, in the present invention, a control device (second control device 20) is included, and the control device (20) is a velocity (oil supply) of an ultrasonic wave (for example, an ultrasonic pulse Ws) received by the ultrasonic receiving device (2). It is preferable to have a function of determining the oil type based on the speed at which the ultrasonic pulse Ws travels through the oil in the system.
In this case, it is preferable that the oil supply system (3) is an oil supply pipe (7) communicating with an oil storage tank (6) of a gas station.

According to the present invention having the above-described configuration, an ultrasonic transmission device (1) that transmits ultrasonic waves (for example, an ultrasonic pulse Ws) and an ultrasonic reception device (2) that receives the ultrasonic waves are refueled. Since it was provided in the system (3: for example, oil supply pipe, pump, oil supply pipe, etc.), it is possible to transmit ultrasonic waves into the oil flowing through the flow path (3F) and receive ultrasonic waves propagated in the oil. . At that time, when foreign matter (C: water, air, etc.) mixed as fine particles is mixed in the oil, when the foreign matter (C) is irradiated with ultrasonic waves, The sound wave pulse (Ws) is reflected, and the ultrasonic pulse (Ws) reaching the ultrasonic wave receiver (2) is attenuated.
Therefore, if the attenuation rate of the ultrasonic pulse (Ws) reaching the ultrasonic receiver (2) is obtained, the ratio of foreign matter in the oil, that is, the mixing rate of water, air, etc. (so-called “foreign matter” C) is obtained. Can be determined.
Therefore, according to the present invention, the mixing rate of the foreign matter (C) in the oil can be instantaneously measured.

As a result, the risk of refueling gasoline containing water can be prevented, and there is no risk of knocking, engine stop, or engine damage due to poor combustion.
Similarly, when air is mixed in the fuel oil, it can be immediately detected, so that the fuel is actually supplied to the vehicle etc. rather than the fuel supply amount (measured value: displayed value) measured by the flow meter. In addition, there is no problem that the amount (actual oil supply amount) is reduced (measurement accuracy problem).

Here, since the fuel station sells multiple types of fuel oil, for example, if you make a mistake in supplying a kerosene to a gasoline car, or if you make a mistake in selling it with kerosene (so-called “misplaced oil”) There is a risk of causing a serious accident.
In addition, the introduction of different types of fuel oil to the underground storage tank at the gas station (so-called “wrong unloading”) can also lead to a serious accident. . And by “unloading”, the fuel oil (kerosene) stored in the underground tank is mixed with different types of fuel oil (gasoline), and the fuel oil mixed with different types of fuel oil is sold to customers. If this happens, there may be serious inconveniences such as failure, damage, accidents due to engine damage, fires, and the like.

On the other hand, in the present invention, oil is detected from the speed of ultrasonic waves (for example, ultrasonic pulses Ws) received by the ultrasonic receiver (2) (speed at which the ultrasonic pulses Ws travel in the oil in the oil supply system). If it is configured to have a control device (second control device 20) having a function of determining the seed, it is possible to immediately identify the oil type in the flow path (3F).
The speed at which the ultrasonic wave propagates through the oil when the ultrasonic wave is transmitted from the ultrasonic transmission device (1), propagates through the oil in the flow path (3F), and is received by the ultrasonic reception device (2). Since it differs depending on the type of oil in the pipeline, the type of oil in the pipeline can be determined by calculating the speed at which the ultrasonic wave propagates in the oil (the speed of the ultrasonic pulse Ws). Because.
As a result, it is possible to constantly monitor the oil flowing through the oil supply system, discriminate the oil type, and prevent erroneous oil supply and unloading.

It is a block diagram of a 1st embodiment of the present invention. It is a block diagram which shows the state which has arrange | positioned the ultrasonic transmitter and the ultrasonic receiver in the aspect different from FIG. It is an AA arrow end view of Drawing 1, and is a block diagram showing an example of arrangement in the pipe circumference direction of an ultrasonic transmitter and an ultrasonic receiver. It is a block diagram which shows the modification of 1st Embodiment. In 1st Embodiment, it is a block diagram which shows the structure of the control unit which calculates | requires the mixing rate of water or air. In 1st Embodiment, it is a flowchart which shows the control which calculates | requires the mixing rate of water or air. It is a top view of an oil supply pump incorporating a 1st embodiment. It is a block diagram of a 2nd embodiment of the present invention. In 2nd Embodiment, it is a block diagram which shows the structure of the control unit which discriminate | determines an oil kind. In 2nd Embodiment, it is a flowchart which shows the control which discriminate | determines an oil kind. It is explanatory drawing which shows the outline | summary of the gas station which implemented 2nd Embodiment.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
First, a first embodiment of the present invention will be described with reference to FIGS.
In FIG. 1, the detection apparatus according to the first embodiment denoted as a whole by reference numeral 101 includes an ultrasonic transmission device 1, an ultrasonic reception device 2, a first control device 10, and a control device 30 for a fueling device. I have.

The ultrasonic transmission device 1 is connected to a commercial AC power source (not shown). The ultrasonic transmission device 1 is exposed in the flow path 3 and is configured to be able to transmit ultrasonic waves (for example, ultrasonic pulses) Ws in oil flowing through the flow path 3F.
The ultrasonic receiver 2 is also exposed in the flow path 3 and is configured to be able to receive ultrasonic waves (for example, ultrasonic pulses) Ws propagating through the oil flowing through the flow path 3F.

The ultrasonic receiver 2 is connected to the first controller 10 via a line L1. When the ultrasonic receiver 2 receives the ultrasonic pulse, the detection signal is transmitted to the first controller 10 via the line L1.
The first control device 10 is connected to the control device 30 of the refueling device through a line L2, and is processed by the first control means 10 (for example, to stop refueling or to send a foreign matter alarm). Is transmitted to the control device 30 of the fueling device.

The ultrasonic transmission device 1 is composed of, for example, a piezoelectric element, and is configured to transmit an ultrasonic wave or an ultrasonic pulse when an AC voltage or a pulse voltage is applied.
The ultrasonic receiving device 2 is also composed of a piezoelectric element, for example, and converts it into an alternating voltage or a pulse voltage when receiving an ultrasonic wave or an ultrasonic pulse. Then, the AC voltage or pulse voltage can be transmitted to the first control device 10 as a detection signal.
When a piezoelectric element is used, there is no risk of generating sparks, so there is little danger in installing it at a gas station.

When the ultrasonic pulse Ws is transmitted into the oil flowing through the flow path 3F and water or air (so-called “foreign matter”) C is mixed in the oil, as shown in FIG. The foreign matter C is mixed in the oil flowing through the flow path 3F as fine particles.
When the foreign object C exists in the transmission path of the ultrasonic pulse Ws transmitted into the oil, the ultrasonic pulse Ws is attenuated by the amount reflected by the foreign object C, and the ultrasonic pulse Ws reaching the ultrasonic receiver 2 is attenuated. .
Therefore, if the attenuation rate of the ultrasonic pulse Ws reaching the ultrasonic receiver 2 is obtained, the ratio of the foreign matter C present in the oil, that is, the mixing rate of water or air (so-called “foreign matter”) C is determined. I can do it.

In FIG. 1, the transmission path of the ultrasonic pulse Ws is a path connecting the ultrasonic transmission device 1 and the ultrasonic reception device 2 (path from the upper left to the lower right in FIG. 1). And shown as an inclined path.
However, as shown in FIG. 2, it is possible to arrange the ultrasonic transmission device 1 and the ultrasonic reception device 2 so as to form a path extending in the horizontal direction.
However, the path shown in FIG. 1 (path inclined with respect to the horizontal direction and the vertical direction) has a longer propagation distance of the ultrasonic pulse Ws than the path shown in FIG. 2 (horizontal path). Accordingly, there is a high possibility that foreign matter (water, air) particles C are mixed.
If there is a high possibility that foreign matter (water, air) particles C are mixed, the accuracy of the foreign matter mixing rate is improved.

Although only one pair of the ultrasonic transmission device 1 and the ultrasonic reception device 2 may be provided, it is preferable to provide a plurality of pairs (three pairs in FIG. 3) as shown in FIG. By arranging a plurality of pairs, there are a plurality of paths through which the ultrasonic pulse Ws propagates, and there is a high possibility that foreign particles (water, air) are mixed, and the accuracy of calculating the foreign matter mixing rate is improved.
In the case where a plurality of pairs of the ultrasonic transmission device 1 and the ultrasonic reception device 2 are provided, for example, as shown in FIG. 3, the ultrasonic transmission device 1 and the ultrasonic reception device 2 are arranged in a circle of a duct (flow path) 3F. It is preferable to arrange | position at equal intervals about the circumferential direction.

FIG. 4 shows a modification of the first embodiment (reference numeral 101A is attached to the entire detection apparatus).
1 to 3, the ultrasonic pulse Ws transmitted from the ultrasonic transmission device 2 is directly received by the ultrasonic reception device 2 via the oil in the flow path 3F.
However, in FIG. 4, the ultrasonic pulse Ws transmitted from the ultrasonic transmission device 1 is reflected by the inner wall surface 3i of the flow path (pipe) 3F, and then attached to the opposite inner wall surface 3ri. 2 is received.

By reflecting the ultrasonic pulse Ws on the inner wall surface 3i of the pipe line, the Ws transmission path of the ultrasonic pulse becomes longer, and there is a high possibility that an object (water, air) is present in the path, and the foreign matter contamination rate is calculated. The accuracy is improved. However, there is a possibility that the ultrasonic pulse Ws is greatly attenuated when reflected by the inner wall surface 3i.
Other configurations and operational effects of the modification 101A of FIG. 4 are the same as those of the embodiment of FIGS.

Next, referring to FIG. 5, in the detection apparatus 101 according to the first embodiment, the first control apparatus 10 having a function of obtaining a mixing rate of foreign matter (water or air) C in the oil flowing in the flow path 3F. Will be described.
In FIG. 5, the first control device 10 includes an ultrasonic attenuation rate calculation block 10a, a mixing rate calculation block 10b, a determination block 10c, a storage block 10d, a notification processing block 10e, and a refueling stop processing block 10f. I have.

The ultrasonic attenuation rate calculation block 12a is connected to the ultrasonic receiving device 2 (see FIG. 1) through a line L1, and crosses the flow path 3F from the output (ultrasonic pulse Ws) received from the ultrasonic receiving device 2. The attenuation rate of the ultrasonic pulse Ws is calculated.
The mixing rate calculation block 10b is connected to the ultrasonic attenuation rate calculation block 12a via a line Lab, and is connected to the storage block 10d via a line Ldb.
Then, the mixing rate calculation block 10b calculates the flow rate from the attenuation rate calculated by the ultrasonic attenuation rate calculation block 12a and the “relationship (characteristic) between attenuation rate and mixing rate” information stored in the storage block 10d. It has a function of calculating the foreign matter mixing rate of the fuel oil flowing through the path 3F.

The determination block 10c is connected to the mixing rate calculation block 10b via a line Lbc, and is connected to the storage block 10d via a line Ldc.
The determination block 10c compares the foreign substance mixing rate calculated by the mixing rate calculation block 10b with the “threshold for oiling stop, threshold for alarm transmission” stored in the storage block 10d to determine the foreign substance mixing rate. Has a function of determining whether or not the threshold value exceeds the threshold value.

The determination block 10c is connected to the notification processing block 10e via a line Lce, and is connected to the refueling stop processing block 10f via a line Lcf.
The determination block 10c has a function of outputting a control signal for causing the notification processing block 10e to perform processing such as alarm transmission when the foreign matter mixing rate exceeds the alarm transmission threshold. Further, the determination block 10c has a function of outputting a control signal for causing the oil supply stop processing block 10f to perform the oil supply stop process when the foreign matter mixing rate exceeds the threshold value of the oil supply stop.
Further, the determination block 10c is connected to the storage block 10d via a line Lcd, and is connected to a display unit (monitor) M outside the control device via a line Lcm. The determination block 10c has a function of feeding back the determination result (determination result as to whether or not the foreign matter mixing rate exceeds the threshold value) to the storage block 10d, and displays the determination result on the display unit ( The monitor) has a function of transmitting a determination result to the display unit M so as to be displayed on the display M.

The notification processing block 10e is connected to the control device 30 of the fueling device via the line Le3, and when the control signal for performing processing such as alarm transmission is received from the determination block 10c, the control device of the fueling device. 30 has a function of transmitting a control signal for issuing an alarm to an alarm device which is not clearly shown through 30.
The fuel supply stop processing block 10f is connected to the control device 30 of the fuel supply device via the line Lf3, and when the control signal for performing the fuel supply stop processing is received from the determination block 10c, the control device 30 of the fuel supply device. There is a function of transmitting a control signal for performing an oil supply stop (for example, an oil supply pump stop) to an oil supply stop mechanism (for example, an oil supply pump) that is not clearly indicated via the.

Next, with reference to FIG. 6, the control in the first control device 10 for obtaining the mixing rate of foreign matter C such as water and air will be described.
In step S1 of FIG. 6, the output of the ultrasonic receiver 2 is read, and the process proceeds to step S2. In step S <b> 2, the ultrasonic attenuation rate calculation block 10 a in the first control device 10 obtains the attenuation rate of the ultrasonic pulse in the flow path 3 </ b> F based on the information on the ultrasonic pulse from the ultrasonic reception device 2. Here, since the data of the ultrasonic pulse transmitted from the ultrasonic transmission device 1 is stored in the ultrasonic attenuation rate calculation block 10a, the information of the ultrasonic pulse from the ultrasonic reception device 2 is the ultrasonic wave. If input to the attenuation factor calculation block 10a, the attenuation factor of the ultrasonic pulse can be obtained.
When the attenuation rate of the ultrasonic pulse is obtained in the ultrasonic attenuation rate calculation block 10a, the “relationship between attenuation rate and mixing rate (characteristic) transmitted from the storage block 10d via the line Ldb in the mixing rate calculation block 10b. ”To calculate the mixing ratio of the foreign matter C contained in the fuel oil flowing through the flow path 3F.

In step S3, the judgment block 10c in the first control device 10 compares the alarm threshold value stored in the storage block 10d with the contamination rate of the foreign material C calculated in the contamination rate calculation block 10b. It is determined whether or not the mixing rate is equal to or higher than the alarm transmission threshold.
If the contamination rate of foreign matter C is equal to or greater than the alarm transmission threshold (YES in step S3), the process proceeds to step S4. On the other hand, if the contamination rate of foreign matter C is less than the alarm transmission threshold value (NO in step S3), there is no problem in continuing the operation of the fueling device and continuing to supply the fuel oil flowing through the flow path 3F. It judges, it judges that it is not necessary to issue a warning or to stop refueling, and it progresses to Step S5.

In step S5 (when the contamination rate of foreign matter C is less than the alarm transmission threshold), the first control device 10 determines whether or not to end a series of controls.
If the series of control is to be ended (YES in step S5), the control is ended as it is, and if not to be ended (NO in step S5), the process returns to step S1, and step S1 and subsequent steps are repeated.

In step S4 (when the contamination rate of foreign matter C is equal to or higher than the alarm transmission threshold value), the determination block 10c in the first control device 10 determines the contamination rate and the threshold value for stopping refueling stored in the storage block 10d. Are compared to determine whether or not the contamination rate of the foreign matter C is equal to or greater than the threshold for stopping fueling.
If the contamination rate of the foreign matter C is equal to or greater than the fuel supply stop threshold (YES in step S4), the determination block 10c may cause a serious accident if the fuel oil flowing through the flow path 3F is continuously supplied. Determination is made and a control signal for causing the refueling stop processing block 10f to perform the refueling stop processing is transmitted (step S7). The oil supply stop processing block 10f that has received the control signal for causing the oil supply stop process transmits a control signal to the oil supply stop mechanism (for example, an oil supply pump) via the control device 30 of the oil supply device (for example, an oil supply pump). Stop refueling).
Although not explicitly shown, the determination block 10c transmits a control signal for issuing a refueling stop alarm to a not-illustrated alarm device when transmitting a control signal for causing the refueling stop processing block 10f to perform the refueling stop process.

  In step S4, if the contamination rate of foreign matter C is less than the threshold value for stopping refueling (NO in step S4), the contamination rate is not so high as to stop refueling, but at a level where an alarm needs to be issued. Then, the determination block 10c transmits a control signal for issuing an alarm to the alarm processing block 10e (step S6). The alarm processing block 10e that has received the control signal for issuing an alarm issues an alarm that foreign matter is mixed in the fuel oil that is being supplied to the alarm device that is not explicitly specified via the control device 30 of the fuel supply device. A control signal is transmitted accordingly.

FIG. 7 shows a state in which the detection device 101 according to the first embodiment is incorporated in the oil supply pump 5, and the detection device 101 is incorporated in a region at positions indicated by reference signs P <b> 1 and P <b> 2.
Here, the position P1 is a position in the vicinity of the inlet portion of the gas-liquid separation cyclone, and the position P1 is in a direction perpendicular to the paper surface of FIG. 7 and on the side (rear) away from the viewer of FIG. Exists.
Further, the position P2 is a position in the vicinity of the pump discharge port 51, and the position P2 is present in a direction perpendicular to the paper surface of FIG.

The detection device 101 according to the first embodiment is interposed in the oil supply piping system of the oil supply device (see FIG. 1) or incorporated in the pump 5 of the oil supply device (see FIG. 7).
In addition, it is possible to incorporate the detection device 101 according to the first embodiment into an oil supply device or a pipe-type flow meter.

According to the first embodiment shown in FIG. 1 to FIG. 7, the ultrasonic transmission device 1 that transmits the ultrasonic pulse Ws and the ultrasonic reception device 2 that receives the ultrasonic wave are provided in the flow path 3F. Ultrasonic waves are transmitted into the oil flowing through the path 3F, and the ultrasonic waves propagated in the oil are received. When foreign matter C such as water or air is mixed in the oil, if the foreign matter C is present in the propagation path of the ultrasonic wave, the ultrasonic receiver 2 is reflected by the amount of the ultrasonic pulse Ws reflected by the foreign matter C. The ultrasonic pulse Ws that reaches is attenuated.
In the first embodiment, by determining the attenuation rate of the ultrasonic pulse Ws that reaches the ultrasonic receiver 2, the ratio of the presence of foreign matter in the oil, that is, the mixing rate of water, air, etc. (so-called “foreign matter”) C Is determined. Therefore, it is possible to instantaneously measure the mixing rate of the foreign matter C in the oil.

As a result, for example, it is possible to prevent the risk of supplying gasoline containing water to the vehicle, and to prevent knocking, engine stop, and engine damage due to poor combustion.
Similarly, when air is mixed in the fuel oil, it is immediately detected to prevent the problem of measurement accuracy from occurring.

8 to 11 show a second embodiment of the present invention.
1 to 7, the mixing rate of water, air, etc. (so-called “foreign matter”) is determined. However, according to the second embodiment of FIGS. In addition, oil type discrimination is possible.
The detection apparatus 102 of the second embodiment in FIGS. 8 to 11 may be combined with the detection apparatus 101 of the first embodiment described with reference to FIGS. I can do it. Such calculation (control) is the same as that described with reference to FIGS.

In FIG. 8, the entire detection apparatus according to the second embodiment is denoted by reference numeral 102. The detection apparatus 102 shown in FIG. 8 has added the 2nd control apparatus 20 compared with the detection apparatus 101 of FIG.
The second control device 20 is connected to the ultrasonic transmission device 1 by a line L3 and is connected to the ultrasonic reception device 2 by a line L4. And the 2nd control apparatus 20 is connected with the control apparatus 30 of the oil supply apparatus via the line L5.

Oil (various oils: fuel oil, kerosene, etc.) flows in the flow path (for example, piping) 3F. In FIG. 8 showing an outline for identifying the type of oil, an ultrasonic pulse Ws is transmitted from the ultrasonic transmission device 1, propagates through the oil in the flow path 3 </ b> F, and is received by the ultrasonic reception device 2.
Since the second control device 20 is connected to the ultrasonic transmission device 1 and the ultrasonic reception device 2 via the line L3 and the line L4, the timing at which the ultrasonic transmission device 1 transmits the ultrasonic wave Ws, The time difference of the timing at which the sound wave receiving device 2 receives the ultrasonic pulse Ws can be calculated.
With this time difference, the second control device 20 can calculate the speed at which the ultrasonic pulse Ws propagates through the oil (the speed of the ultrasonic pulse).

Here, the speed at which the ultrasonic pulse Ws propagates in the oil differs depending on the type of oil in the flow path 3F.
Therefore, if the speed at which the ultrasonic pulse Ws propagates in the oil is obtained, the type of oil in the flow path 3F can be determined (specified).

Next, the second control device 20 having an oil type discrimination function will be described with reference to FIG.
Note that in the detection device 102 according to the second embodiment, the configuration and work effects of the control unit 10 for calculating the contamination rate are described with reference to the control device 10 described with reference to FIG. 5 (the first embodiment in the first embodiment). 1).
In FIG. 9, the second control device 20 includes an ultrasonic velocity determination block 20a, an oil type determination block 20b, a storage block 20c, and an alarm determination block 20d.

The ultrasonic velocity determination block 20a is connected to the ultrasonic transmission device 1 through a line L3, and is connected to the ultrasonic reception device 2 (refer to FIG. 1 above) through a line L4.
Since the propagation path of the ultrasonic pulse Ws in the oil in the flow path 3F is constant and the distance between the ultrasonic transmission device 1 and the ultrasonic reception device 2 is also constant, the ultrasonic wave transmitted by the ultrasonic transmission device 1 If the time difference (temporal deviation) between the transmission timing and the ultrasonic reception timing received by the ultrasonic receiver 2 is obtained, the speed of the ultrasonic pulse Ws propagating through the oil in the flow path 3F can be calculated. I can do it. The ultrasonic velocity determination block 20a has a function of executing such calculation.

The oil type determination block 20b is connected to the ultrasonic velocity determination block 20a via a line Lab, and is connected to the storage block 20c via a line Lcb.
Then, the oil type determination block 20b includes the speed of the ultrasonic pulse Ws determined by the ultrasonic speed determination block 20a (the speed of propagation through the oil in the flow path 3F) and the “ultrasonic wave” stored in the storage block 20c. From the “relationship (characteristic) between speed and oil type”, the oil type that flows through the flow path 3F is determined.

The alarm determination block 20d is connected to the oil type determination block 20b via a line Lbd, and is connected to the control device 30 of the oil supply device via lines L5, L51, and L52.
In the warning determination block 20d, the oil type (oil type in the flow path 3F) determined in the oil type determination block 20b is (data is sent from the control device 30 of the oil supply device to the warning determination block 20d via the line L5). It has a function of determining whether or not it matches the oil type to be supplied by the oil supply device.

Further, when the oil type flowing through the flow path 3F is different from the oil type that should be refueled, the alarm determination block 20d indicates that the oil type that flows through the flow path 3F is different from the oil type that should be refueled. It has a function of transmitting a control signal for issuing a warning to the effect of “through the line L51”.
Further, the alarm determination block 20d is connected to an oil supply stop device (for example, an oil supply pump) via a line L52 via the control device 30 of the oil supply device, and the oil type that the oil flowing through the flow path 3F should originally supply oil is. If the difference is different from the above, the oil supply stop device (for example, oil supply pump) has a function of transmitting a control signal for stopping the oil supply (stopping the oil supply pump) via the line L52.

Next, the control in 2nd Embodiment is demonstrated with reference to FIG.
In the second embodiment, the control for determining the presence or absence of foreign matter is the same as that described above with reference to FIG.
In step S11 of FIG. 10, the second control device 20 determines whether or not the ultrasonic receiver 2 has received an ultrasonic wave.
If the ultrasonic receiver 2 is not receiving ultrasonic waves (NO in step S11), step S11 is repeated (a loop in which step S11 is NO). If the ultrasonic receiver 2 is receiving ultrasonic waves (YES in step S11), the process proceeds to step S12, and the ultrasonic velocity is calculated by the ultrasonic velocity determination block 20a in the second controller 20.

As described above, in the ultrasonic velocity determination block 20a, the propagation path distance of the ultrasonic pulse Ws in the oil in the flow path 3F, the transmission timing of the ultrasonic wave transmitted by the ultrasonic transmission device 1, and the ultrasonic reception The speed of the ultrasonic pulse Ws propagating through the oil in the flow path 3F is calculated from the time difference (temporal shift) of the ultrasonic reception timing received by the device 2. Since the propagation speed of the ultrasonic pulse Ws varies depending on the type of fuel oil flowing through the flow path 3F, the type of fuel oil flowing through the flow path 3F can be identified from the propagation speed of the ultrasonic pulse Ws.
If the propagation speed of the ultrasonic pulse Ws is obtained in step S12, the process proceeds to step S13, and the propagation speed of the ultrasonic pulse Ws calculated in step S12 and the “super” stored in the storage block 20c are determined by the oil type determination block 20b. From the “relationship (characteristic) between the speed of sound waves and the oil type”, the oil type of the fuel oil flowing through the flow path 3F is specified. Then, the process proceeds to step S14.

In the next step S14, the oil type (oil type to be supplied by the fuel oil flowing through the flow path 3F) determined in step S13 and the oil type to be supplied by the oil supply device are determined by the warning determination block 20d. It is determined whether or not they match.
If the fuel oil flowing through the flow path 3F does not match the type of oil to be supplied (NO in step S14), it is determined that the type of oil different from the oil that should be supplied is being supplied. In step S16, the control device 30 of the fueling device sends a control signal to stop the fueling and issues an alarm about the fueling stop to the alarm device, and also supplies a fueling stop device (for example, a fuel pump drive of the fueling device). A control signal for stopping oil supply (for example, a stop signal for the oil supply pump drive motor of the oil supply device) is transmitted to a mechanism for stopping the motor.

On the other hand, if the fuel oil flowing through the flow path 3F matches the type of oil to be supplied (YES in step S14), it is determined that the oil to be supplied is definitely supplied, and the process proceeds to step S15.
In step S15, the second control device 20 determines whether or not to end a series of controls.
If control is to be continued (NO in step S15), the process returns to step S11, and step S11 and subsequent steps are repeated. If a series of controls are to be terminated (YES in step S15), the control is terminated as it is.

The detection device 102 according to the second embodiment can be provided not only in the piping but also at the positions P1 and P2 of the oil supply pump 5 shown in FIG.
Moreover, the detection apparatus 102 which concerns on 2nd Embodiment can be applied to prevention of unloading of a gas station.
FIG. 11 shows a mode in which the second embodiment is applied to prevent unloading at a gas station.

In FIG. 11, the detection device 101 according to the first embodiment is interposed in each of the oil supply pipes 7... Communicating with the oil storage tanks 6.
In the example of FIG. 11, the fuel filler ports 71 of the plurality of fuel filler tubes 7 are collectively provided in the fuel filler box 250. The tank 90 of the tank lorry 8 is also divided into a plurality of hatches 9... Each hatch 9... Is connected to the discharge pipe 12 via each bottom valve 11. A coupling 13 also serving as a discharge port is provided.
The coupling 13 is connected to any one of the oil supply ports 71 of the oil supply pipes 7.

In FIG. 11, the detection device 102 according to the second embodiment is interposed in each oil supply pipe 7, and an oil type different from the oil type to be stored in each oil storage tank 6 is provided in the oil supply pipe 7. At that stage, it can detect that fact and stop the refueling.
Thereby, an accident (so-called “contamination”) that unloads oil of different oil types to the underground oil storage tank 6 in the gas station 200 can be prevented.
8 to 11, the first control device 10 may be omitted, and only the control for determining the oil type may be performed.

According to 2nd Embodiment shown in FIGS. 8-11, the function which pinpoints the oil seed | species from which the ultrasonic pulse Ws was transmitted from the propagation speed in the oil of the ultrasonic pulse Ws which the ultrasonic receiver 2 received. The 2nd control apparatus 20 which has is provided, and the oil kind in the flow path 3F can be identified instantly.
As a result, it is possible to constantly monitor the oil flowing through the oil supply system, discriminate (specify) the oil type, and prevent erroneous oil supply and erroneous unloading.

Other configurations, operations, effects, and controls in the second embodiment of FIGS. 8 to 11 are the same as those of the first embodiment of FIGS.
And in 2nd Embodiment of FIGS. 8-11, it is also possible to arrange | position an ultrasonic transmitter and an ultrasonic receiver as shown in FIGS.

  It should be noted that the illustrated embodiment is merely an example, and is not a description to limit the technical scope of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Ultrasonic transmitter 2 ... Ultrasonic receiver 3 ... Flow path 4 ... Optical fiber 5 ... Oil pump 6 ... Oil storage tank 7 ... Oil supply pipe 8 ... Tank truck DESCRIPTION OF SYMBOLS 9 ... Hatch 10 ... 1st control apparatus 11 ... Bottom valve 12 ... Discharge pipe 20 ... 2nd control apparatus 30 ... Control apparatus of oil supply apparatus

Claims (3)

  A detection apparatus comprising: an ultrasonic transmission device that transmits ultrasonic waves; and an ultrasonic reception device that receives the ultrasonic waves, provided in an oil supply system.   The control device includes a control device, and the control device has a function of determining a different mixing rate mixed in the oil flowing through the oil supply system from the attenuation rate of the ultrasonic wave received by the ultrasonic receiving device. Detection device.   The detection device according to claim 1, further comprising a control device, wherein the control device has a function of determining an oil type from an ultrasonic velocity received by the ultrasonic reception device.

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