JP6185785B2 - Fuel oil analyzer - Google Patents

Description

  The present invention relates to a fuel oil analyzer suitable for simple analysis of fuel oil.

  Conventionally, fuel oil is classified according to standards. For example, heavy oil is classified into A heavy oil, B heavy oil, and C heavy oil according to kinematic viscosity. Further, A heavy oil is further subdivided into Nos. 1 and 2 by the sulfur content, and C heavy oil is subdivided into Nos. 1, 2, and 3 by the kinematic viscosity. However, even with the subdivided fuel oil, fuel oils with different flammability are circulated because the mixture and the like differ depending on the way of the essential oil and the manufacturer.

  Therefore, for example, when a ship is taken as an example, the ship loads fuel oil at the port of call during voyage. However, there is a fuel oil with poor flammability that is not suitable for the ship, and troubles caused by the fuel oil are occurring. Examples of this trouble include combustion troubles such as poor ignitability and difficulty in continuous combustion, and troubles such as a mixture in fuel oil adversely affecting the engine.

  On the other hand, for example, in the case of a ship, the kinematic viscosity of the fuel oil that can be used is set according to the specifications of the main engine, but the suitability of the fuel oil varies depending on the type and size of the main engine. Moreover, even if it is the main machine of the same specification, the suitability of fuel oil may change with individual differences. Therefore, even if a ship uses fuel with the same kinematic viscosity, a fuel oil suitable for a certain ship is not necessarily a fuel oil suitable for another ship. That is, even if the fuel oil of the same classification has the same specifications, it is not necessarily a fuel oil suitable for all ships.

  The combustibility of fuel oil is generally represented by an estimated cetane number (hereinafter also referred to as “ECN”) based on the British Standard (IP541 / 06). In general, the lower the ECN, the greater the degree of flame retardancy of the fuel oil. And when ECN is 20 or less, it is said that combustion trouble may occur.

  For this reason, the crew members of the ship are required to submit fuel oil specifications from the fuel oil supplier when loading the fuel oil, collect samples for confirmation, and request analysis from specialists.

  However, since it takes about 3 to 5 days at the earliest to obtain the analysis result by a specialist, the crew does not use the fuel oil loaded in the tank until the analysis result comes out. It is in a situation to try to prevent trouble.

  Therefore, a fuel oil analyzer that can easily and quickly estimate the combustibility of various fuel oils is desired.

  For example, as a prior art of this type, there is a quality analyzer that attempts to determine the ignitability of fuel oil by calculating the CCAI value using the density of fuel oil at 15 ° C. and the kinematic viscosity at 50 ° C. ( For example, see Patent Document 1). In addition, this quality analyzer analyzes whether the fuel oil quality is suitable by analyzing the proportion of polymer components contained in the fuel oil, analyzing the proportion of insoluble fine particles, and analyzing the proportion of sulfur. Is determined.

  In addition, as another prior art, a device for measuring the content of volatile substances in which the inside of the apparatus is maintained at a temperature at which the sample does not burn and the volatile substance content is measured from a change in the weight of the sample (for example, a patent There is an asphalt content measuring device in which an asphalt component in a sample is burned and the asphalt content is calculated based on the weight loss (see, for example, Patent Document 3).

JP 2011-112362 A JP 2011-7809 A JP 2002-71541 A

  However, in the invention described in Patent Document 1, a density measuring unit for measuring the density of the fuel oil is necessary, and a viscosity measuring unit for measuring the kinematic viscosity in a state heated to 50 ° C. is necessary. The structure becomes larger as it becomes more complex.

  Even if it is attempted to determine whether the quality of the fuel oil is suitable by analyzing the proportion of the polymer component contained in the fuel oil, analyzing the proportion of insoluble fine particles, and analyzing the proportion of sulfur. The apparatus for performing the analysis is complicated in configuration. Moreover, in order to analyze the proportion of the polymer component contained in the fuel oil, temperature control for burning the low molecular component is required. Furthermore, in order to analyze the ratio of insoluble fine particles, it is necessary to obtain a non-soluble fine particle by filtering a mixed liquid to which a solvent such as toluene is added. Moreover, in order to analyze the ratio of sulfur, it is necessary to measure the X-ray dose corresponding to the weight ratio of sulfur by irradiating the sample container with X-rays. Therefore, in order to realize these, the configuration of the apparatus is complicated, and the user needs to be familiar with the handling method, which is difficult to use.

  In the inventions described in Patent Documents 2 and 3, the volatile substance content is measured from the change in the weight of the sample, or the asphalt content is calculated by reducing the weight by burning the asphalt component in the sample. It is not possible to analyze fuel oil combustibility.

  Accordingly, an object of the present invention is to provide a fuel oil analyzer that can easily and quickly estimate the combustibility of fuel oil with a simple device configuration.

  In order to achieve the above object, the present invention provides a sample container for containing a fuel oil sample, a heating container having an internal space for accommodating the sample container, a lid disposed on the heating container, and the heating A heating section for heating the sample container in the container, a temperature measuring section for measuring a temperature change in the heating container, a weight measuring section for measuring a weight change of the fuel oil in the sample container, and a heating container A placement unit of the weight measurement unit disposed in an internal space, and an analysis unit for estimating the combustibility of the fuel oil from the temperature change measured by the temperature measurement unit and the weight change measured by the weight measurement unit. And the sample container is configured to be placed on the placement portion by closing the lid. In this specification and claims, the “sample of fuel oil” is referred to as “sample oil”.

  With this configuration, the sample container can be disposed in the internal space of the heating container by closing the lid. Then, by heating the sample container in the heating container, the temperature change in the heating container and the weight change of the sample oil are measured, and the combustibility of the sample oil can be estimated from the relationship between the temperature change and the weight change. it can. Therefore, in the case of a ship, the crew can easily estimate the combustibility of the fuel oil in a short time when the fuel oil is loaded, and can quickly determine the suitability of the fuel oil. . For this reason, it is possible to quickly start using the fuel oil that has been loaded, or in some cases to refuse loading, without waiting for an analysis result by a specialist.

  The lid includes a locking claw that locks the sample container, and the locking claw closes the lid to place the sample container on the mounting portion, You may be comprised so that it may leave | separate from a sample container.

  If comprised in this way, the sample container locked with the latching claw by the closing operation of the lid body enters the inside of the heating container, and this sample container can be mounted on the mounting portion in the heating container. In addition, since the latching claw is separated and waits after the sample container is placed, the weight measurement of the sample container is not affected.

  The locking claw may be formed so as to insert the sample container from the side to lock the outer peripheral portion, and a fall prevention portion may be extended in the insertion direction of the sample container.

  If comprised in this way, the sample container mounted in the mounting part in a heating container by the closure operation | movement of a cover body can be appropriately latched with a latching claw, and can be prevented from dropping into the inside of a heating container.

  The fall prevention part may have a vent hole penetrating in the vertical direction.

  If comprised in this way, although the fall prevention part will remain in a heating container after arrange | positioning a sample container in the inside of a heating container, it can avoid greatly disturbing the airflow which raises the inside of a heating container by a vent hole.

  In addition, the lid body has a cylindrical body that is movable in the vertical direction with respect to the lid body, and the cylindrical body is guided by the lid body and the lower end portion protrudes downward from the lid body. The lid is lowered toward the heating container, and the lower surface of the cylindrical body comes into contact with the upper surface of the heating container, and then is lowered by a predetermined amount to be in a closed state. It may be configured.

  If comprised in this way, a cylindrical body can be made to contact | abut a heating container by closing a cover body, and the exhaust_gas | exhaustion from a heating container can be discharged | emitted appropriately from a cylindrical body.

  Further, the upper surface of the heating container and the lower surface of the cylindrical body may be configured so that the lower surface of the cylindrical body is in close contact with the upper surface of the heating container.

  With this configuration, the bottom surface of the cylindrical body is brought into close contact with the top surface of the heating container in the process of closing the lid body, and the lid body is further lowered in this state, so that the cylindrical body is in close contact with the heating container under its own weight (metal Touch), and the exhaust from the heating container can be discharged from the cylindrical body more stably.

  Further, an upper case in which the heating container is disposed and a lower case in which the weight measuring unit is disposed may be provided, and a gap forming a space may be provided between the upper case and the lower case.

  If comprised in this way, even if a heating container is heated in an upper case, the heat will not be transmitted to the lower case which has arrange | positioned the weight measurement part, but stable weight measurement can be performed in a weight measurement part.

  The heating container may be formed in a cylindrical shape, and the heating unit may be configured so as to form a cylindrical space having an equal horizontal cross section around the heating container.

  If comprised in this way, since a heating container can be heated uniformly from the circumference | surroundings, the sample oil in a sample container can be heated equally from the circumference | surroundings.

  In addition, a cooling device that gas-cools the heating container is provided, and the cooling device supplies the cooling gas downward toward the heating container in a range of 15 ° to 40 ° with respect to the upper surface of the heating container. It may be configured.

  If comprised in this way, after a combustion test of fuel oil, a cooling gas can be flowed toward a heating container, and a heating container can be cooled rapidly, and a several times combustion test can be performed rapidly.

  According to the present invention, since the combustibility of the fuel oil can be estimated easily and in a short time with a simple device, troubles due to the fuel oil can be avoided and whether or not the fuel oil can be loaded quickly. It becomes possible to judge.

FIG. 1 is an overall configuration diagram showing a fuel oil analyzer according to an embodiment of the present invention. FIG. 2 is a block diagram showing a main configuration of the fuel oil analyzer shown in FIG. FIG. 3 is a cross-sectional view showing a heating device of the fuel oil analyzer shown in FIG. FIG. 4 is a perspective view showing the sample container shown in FIG. 3 and locking claws that support it. FIG. 5A is a cross-sectional view showing a state in which the lid of the heating apparatus shown in FIG. 3 is opened. FIG. 5B is a cross-sectional view showing a state where the lid in the heating apparatus shown in FIG. 3 is closed. FIG. 6 is an example of a combustion characteristic graph created from temperature change and weight change of C heavy oil (500 cSt) by the fuel oil analyzer shown in FIG. FIG. 7 is an explanatory view showing a gas flow when the inside of the heating container shown in FIG. 3 is cooled by a cooler.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, a fuel oil analyzer that analyzes heavy oil that is fuel oil for ships will be described as an example.

  As shown in FIG. 1, the fuel oil analyzer 1 of this embodiment includes a heating device 10 that measures temperature change and weight change by heating, evaporating, or burning sample oil 80 put in a sample container 60, and this heating. A control device 50 that controls the device 10 and analyzes and displays the measurement result and the like is provided.

  The heating device 10 has an upper case 20 and a lower case 23. The upper case 20 includes a heating container 12 having an internal space 11 in which a sample container 60 containing sample oil 80 is accommodated. The heating container 12 is formed in a cylindrical shape with the upper part opened, and the lower part is closed. The lower part of the heating container 12 is supported by the upper case 20 by a leg member 19.

  In addition, the heating device 10 includes a lid 13 disposed above the heating container 12, a heater 14 serving as a heating unit that heats the sample container 60 in the heating container 12, and a temperature measurement that measures a temperature change in the heating container 12. Temperature sensors 15 to 18 serving as the parts, and a balance 70 serving as a weight measuring part for measuring a change in the weight of the sample oil 80 in the sample container 60. The scale 70 includes a support member 71 extending upward and a placement portion 72 provided at the upper end thereof.

  The sample container 60 is placed on a placement portion 72 disposed in the internal space 11 of the heating container 12. The placement portion 72 is set at a substantially central portion in the internal space 11 of the heating container 12. The mounting portion 72 is provided at a substantially central portion in the axial direction in the central portion of the heating container 12 formed in a cylindrical shape, and the sample oil 80 put in the sample container 60 disposed on the mounting portion 72. Can be tested by appropriately heating, evaporating or burning. Further, the heating container 12 is provided with an outer peripheral space 21 around it, and the heater 14 is arranged around the outer peripheral space 21. As the outer peripheral space 21 provided around the heating container 12, a cylindrical gas layer having the same horizontal cross section is preferable. A heat insulating material 22 is provided around and below the heater 14. The heat insulating material 22 is provided inside the upper case 20.

  The scale 70 can accurately measure the weight of the sample container 60 placed on the placement unit 72 without the support member 71 being in contact with the heating container 12. The scale 70 is provided inside the upper case 20 provided with the heating container 12 and the lower case 23 provided with a predetermined gap 24 therebetween. The gap 24 provided between the lower case 23 and the upper case 20 is set to a gap that can form a space where the temperature of the heating container 12 is not transmitted to the lower case 23. As the scale 70, for example, a scale capable of measuring a change in weight within a range of measurement accuracy of about 1 mg to several hundred mg is used. Further, a temperature control unit 25 of the heater 14 and the like are also provided in the lower case 23.

  Further, a cooler 26 for cooling the inside of the heating container 12 is provided on the side of the upper case 20. The cooler 26 is provided with a fan 27 at the lower portion, and a nozzle portion 28 and an auxiliary nozzle 29 for efficiently supplying cooling air to the inside of the heating container 12 with the lid 13 opened at the upper portion. Yes. By providing this cooler 26, the heating container 12 can be rapidly cooled after the test.

  Thus, by providing the cooler 26 and allowing the heated container 12 after the test to be quickly cooled, the fuel oil analyzer 1 can perform a plurality of combustion tests efficiently. That is, the accuracy of the result of the combustion test can be increased in the simple fuel oil analyzer 1 by efficiently performing a plurality of combustion tests. The internal cooling of the heating container 12 by the cooler 26 will be described in detail with reference to FIG.

  On the other hand, the control device 50 is connected to the heating device 10 by a plurality of wires 58. The heating device 10 is controlled by the control device 50 via these wires 58. The control device 50 includes an analysis unit 53 that estimates the combustibility of the sample oil 80 from the temperature change measured by the temperature sensors 15 to 18 and the weight change measured by the scale 70.

  In addition, the control device 50 is provided with a display unit 55 for displaying the results analyzed by the analysis unit 53. The display unit 55 is a liquid crystal monitor or the like. The data displayed on the display unit 55 includes a combustion characteristic graph showing the relationship between the temperature change and the weight change of the sample oil shown in the figure, and the estimated flammability (estimated cetane number) of the sample oil calculated from the temperature change and the weight change. : Hereinafter also referred to as “ECN”).

  Further, the control device 50 stores the above-mentioned combustion characteristic graph, estimated combustibility, and the like as a database together with information such as “oiling place”, “name”, “contractor”, etc. of the sample oil 80 that has been tested. A portion 56 is also provided. By storing the combustion characteristic graph, estimated combustibility, and the like in the storage unit 56 as a database, it can be used later as data for estimating the quality of the sample oil 80 in comparison with the test results of other sample oils.

  As this utilization method, the combustion characteristic graph of the sample oil 80 that has been tested and displayed on the display unit 55 and the combustion characteristic graph of the sample oil of the same classification from the past database are displayed and compared. Thereby, the combustibility suitability of the sample oil 80 just tested can be estimated from past data. For example, the display unit 55 displays a combustion characteristic graph of sample oil that had a problem in the past and a combustion characteristic graph of sample oil that had no problem in the past. Then, it is confirmed which combustion characteristic graph of the sample oil 80 just tested is close to which combustion characteristic graph. Thus, there is a problem if the combustion characteristic graph of the sample oil 80 just tested approximates the combustion characteristic graph of the sample oil that had a problem in the past, and it approximates to the combustion characteristic graph of the sample oil that had no problem If so, the combustibility of the sample oil 80 can be estimated that there will be no problem. Further, the control device 50 may calculate ECN and display it at the same time to determine whether the sample oil 80 is combustible.

  Further, the control device 50 is provided with an operation unit 57 for performing various operations. As the operation unit 57, a touch panel type, a button type, or the like is used.

  FIG. 2 is a block diagram showing a main configuration relating to control in the fuel oil analyzer 1. As shown in the figure, the recording unit 52 of the control device 50 includes a temperature change measured by the temperature sensors (temperature measurement units) 15 to 18 and a weight change measured by the scale (weight measurement unit) 70. It is input via the input unit 51. The analysis unit 53 generates a combustion characteristic graph of the sample oil (fuel oil) 80 and ECN from the temperature change and the weight change recorded in the recording unit 52. The analysis unit 53 is, for example, a CPU that can perform numerical calculation.

  The storage unit 56 stores a past combustion characteristic graph and the like, which is displayed on the display unit 55 as described above, and the newly tested combustion characteristic graph is compared with the past combustion characteristic graph. Can do. In addition, the newly obtained combustion characteristic graph can be compared with the past combustion characteristic graph in the comparison unit 54 of the analysis unit 53.

  In this embodiment, the recording unit 52 is shown as a single configuration, but separate configurations such as a temperature recording unit and a weight recording unit may be used. Further, the recording unit 52 and the analysis unit 53 may be a personal computer, for example. In this case, the temperature and weight measurement results may be sent to the personal computer and analyzed by the personal computer to display the results.

  Next, the configuration around the heating container 12 in the heating apparatus 10 will be described in detail with reference to FIG. The heating container 12 is a cylindrical container in which a collar part 31 is provided in the upper part and the lower end is closed. The heating container 12 has a vertical shape and the inner space 11 has a cylindrical shape so that the temperature rises uniformly around the sample container 60.

  In the internal space 11 of the heating container 12, the above-described placement portion 72 is located in the central portion, and the sample container 60 is placed on this placement portion 72. The mounting portion 72 is provided at the upper end of the support member 71, and the weight change of the sample container 60 is measured by the scale 70 (FIG. 1) through the support member 71. The support member 71 passes through the lower end of the heating container 12 and is connected to the scale 70.

  The sample container 60 is a circular dish-like container having a recess 61 formed in the center, and the outer peripheral portion is a flange portion 62. The recess 61 has a capacity to put a predetermined amount of sample oil 80. The sample container 60 is placed on a mounting portion 72 provided at the upper end of the support member 71, and the subsequent change in the weight of the sample oil 80 is measured with a scale 70.

  Furthermore, in the internal space 11 of the heating container 12, a plurality of temperature sensors 15 to 18 for measuring the internal temperature of the heating container 12 are provided in the vertical position. In this embodiment, the temperature change in the internal space 11 of the heating container 12 is measured by the temperature sensors 15 and 17 provided above the sample container 60 and the temperature sensors 16 and 18 provided below the sample container 60. ing. Temperature sensors 15 and 16 are provided relatively close to the upper and lower positions of the sample container 60, and temperature sensors 17 and 18 are provided at remote positions. The temperature sensors 15 to 18 may be at least the temperature sensors 15 and 16 provided above and below the sample container 60, but the temperature sensors 17 and 18 are provided to accurately measure the temperature in the heating container 12. Yes. These temperature sensors 15 to 18 can use thermocouples.

  The heater 14 is provided at the periphery so as to heat the sample container 60 from the entire circumference in the internal space 11 of the heating container 12. The heater 14 is embedded in the heat insulating material 22 so that the heater wires do not contact each other. The outer periphery of the heater 14 is also covered with a heat insulating material 22. Thereby, even if the heating container 12 is heated by the heater 14, the outer surface of the upper case 20 is kept at an appropriate temperature by the heat insulating material 22.

  A temperature control unit 25 that controls the temperature of the heater 14 is provided in the lower case 23. The temperature control unit 25 controls the temperature of the heater 14, and the temperature of the internal space 11 of the heating container 12 is controlled to be heated within a predetermined temperature range.

  Furthermore, in this embodiment, an air pump 75 that supplies air from the outside to the internal space 11 is provided. The air pump 75 is driven by a motor 76. Air is sent to the internal space 11 via the pipe 77 by the air pump 75. The air pump 75 is provided as necessary.

  On the other hand, a lid 13 that can be opened and closed is provided above the heating container 12. The lid 13 closes the upper surface of the heating container 12. A cylindrical body 33 having an exhaust port 34 that is in close contact with the upper surface of the heating container 12 and allows air to escape from the internal space 11 of the heating container 12 is provided at the center of the lid body 13.

  The cylindrical body 33 is provided with a flange 35 at the lower end, and is in close contact (metal touch) with the flange 31 of the heating container 12. The cylindrical body 33 is provided so as to be movable up and down inside the lid body 13. The lid 13 can be moved up and down along a guide shaft 32 provided in the upper case 20. The lid 13 is raised and lowered by an actuator or manually.

  In this embodiment, as described above, the heating container 12 is a vertical type and the internal space 11 is cylindrical, so that the air supplied to the internal space 11 by the air pump 75 is uniform inside the heating container 12. It flows to the exhaust port 34 of the lid 13 while generating convection.

  The cylindrical body 33 is provided with a locking claw 37 for mounting the sample container 60 on the mounting portion 72. The locking claw 37 is provided on a bracket 36 that extends downward on the central axis of the cylindrical body 33. The locking claw 37 is formed in a size that can lock the flange 62 of the sample container 60 from below. The illustrated state shows a state in which the sample container 60 is locked to the locking claw 37, the lid 13 is closed, and the sample container 60 is mounted on the mounting portion 72.

  As shown in FIG. 4, the locking claw 37 is provided with claw members 38 on three sides so that the sample container 60 can be inserted from one side (near side) and the collar 62 can be locked. Claw members 38 are provided in the illustrated back and left and right positions, and these claw members 38 project inward so as to lock the collar portion (outer peripheral portion) 62 of the sample container 60. Further, the nail member 38 provided at the left and right positions shown in the figure is extended with a fall prevention portion 39 in a forward direction from a portion protruding inward. The fall prevention unit 39 extends in the insertion direction (frontward direction) so that the sample container 60 is not dropped into the internal space 11 of the heating container 12 when the sample container 60 is locked to the locking claw 37. Yes.

  The fall prevention part 39 is provided with a vent hole 40 penetrating in the vertical direction. By providing this vent hole 40, after the sample container 60 is placed on the placement part 72 (FIG. 3), the fall prevention part 39 that remains in the internal space 11 of the heating container 12 does not greatly disturb the airflow in the internal space 11. I am doing so.

  Furthermore, in this embodiment, a plurality of through holes 63 are also provided in the flange portion 62 of the sample container 60. This through hole 63 also prevents the airflow in the internal space 11 of the heating container 12 from being disturbed.

  Next, the flow of placing the sample container 60 on the placement unit 72 will be described with reference to FIGS. 5A and 5B. As shown in FIG. 5A, in the state where the lid 13 is opened (raised), the cylindrical body 33 is lowered by its own weight with the guide portion 44 guided by the guide portion 42 provided on the lid body 41, and at the lower end. It will be in the state supported by the provided locking piece 43. FIG. In this state, the flange 35 at the lower end of the cylindrical body 33 protrudes from the lower surface of the lid body 41, and the locking claw 37 is positioned above the heating container 12. In this state, the sample container 60 containing a predetermined amount of sample oil 80 is locked to the locking claw 37.

  Then, as shown in FIG. 5B, when the lid 13 is lowered, the sample container 60 locked to the locking claw 37 is first mounted on the mounting portion 72. Thereafter, the lower surface of the flange portion 35 of the cylindrical body 33 is in close contact with the upper surface of the flange portion 31 of the heating container 12 by metal touch. Thereafter, when the lid 13 is further lowered, only the lid main body 41 is lowered and comes into contact with the upper surface of the heat insulating material 22 while the cylindrical body 33 is placed on the upper portion of the heating container 12. When the lid 13 is closed as described above, the heating container 12 and the cylindrical body 33 are in close contact with each other, so that the air heated inside the heating container 12 is smoothly supplied from the exhaust port 34 of the cylindrical body 33. It can be discharged to the outside.

  As described above, the sample container 60 containing the sample oil 80 is placed on the placement portion 72 and the lid 13 is closed, and the combustion test of the sample oil (fuel oil) 80 is performed by the fuel oil analyzer 1. Is called. In this test, the control device 50 energizes the heater 14 to heat the internal space 11 of the heating container 12. By this heating, the internal temperature of the heating container 12 rises. This temperature change is measured by temperature sensors 15 to 18 which are temperature measuring units. The measured temperature is recorded in the recording unit 52 via the input unit 51.

  Further, the weight changes as the sample oil 80 put in the sample container 60 evaporates or ignites as the internal temperature of the heating container 12 rises. This change in weight is measured by a scale 70 which is a weight measuring unit. The measured weight change is also recorded in the recording unit 52 via the input unit 51.

  Thereafter, from the temperature change obtained by raising the internal temperature of the heating container 12 to a predetermined temperature and the weight change of the sample oil 80 obtained in the course of the temperature rise, the analysis unit 53 performs the following. The combustibility of the sample oil (fuel oil) 80 is estimated.

  First, in the analysis unit 53, the temperature at which the weight of the sample oil 80 is greatly reduced and the internal temperature of the heating container 12 is greatly increased is estimated as the ignition temperature of the sample oil 80. The combustibility of the sample oil 80 can be estimated by estimating the ECN of the sample oil 80 from the ignition temperature. As this estimation, for example, whether ECN exceeds 20 may be displayed at the same time.

  Further, in the analysis unit 53, for example, an ECN estimation formula is created in advance based on the ECN actual measurement value of the fuel oil to be tested. Then, the ECN is estimated from the weight reduction amount of the sample oil 80 in the set temperature range (for example, the low temperature range and the high temperature range) by the ECN estimation formula, so that the combustibility of the sample oil 80 is estimated. Good. Also as this estimation, whether ECN exceeds 20, for example, may be displayed simultaneously.

  Further, the analysis unit 53 creates a weight change with respect to the heating temperature as a combustion characteristic graph of the sample oil from the temperature change and the weight change recorded in the recording unit 52, and displays the combustion characteristic graph on the display unit 55. The combustibility of the sample oil (fuel oil) 80 may be estimated.

  As an example, FIG. 6 is a combustion characteristic graph created from a temperature change and a weight change of a C heavy oil (500 cSt) burned by the fuel oil analyzer 1. Such combustion characteristic graphs can be similarly created for different fuel oils (for example, C heavy oil (180 cSt), C heavy oil (380 cSt), etc.). As a method of estimating the combustibility from this combustion characteristic graph, for example, the weight of a good fuel oil decreases from a low temperature, but the weight of a bad fuel oil decreases gradually, and the weight decreases rapidly at a high temperature. It can be estimated based on such past experiences. According to the combustion characteristic graph shown in FIG. 6, the weights of the fuel oils indicated as “500-1” and “500-3” are reduced from a low temperature. However, since the weight of the fuel oil indicated as “500-6” is rapidly reduced at a high temperature, it can be estimated that the fuel oil of “500-6” has poor combustibility.

  Moreover, as an estimation of the combustibility by this combustion characteristic graph, the comparison unit 54 displays on the display unit 55 the combustion characteristic graph of the fuel oil that has been tested and the combustion characteristic graph of the past fuel oil of the same classification. The combustion characteristics may be estimated by comparing the combustion characteristics graphs. When the combustibility is estimated in this way, for example, the combustion characteristic graph of the fuel oil that has been tested, the fuel oil that has not been problematic in the past, and the combustion characteristic graph that has been problematic are simultaneously displayed on the display unit 55. Display. Then, by comparing which combustion characteristic graph of the fuel oil just tested is similar to the past combustion characteristic graph, it is estimated whether there is a problem in the combustibility of the fuel oil just tested be able to.

  On the other hand, as shown in FIG. 1, the fuel oil analyzer 1 of this embodiment includes a cooler 26 that forcibly cools the heating container 12 on the side of the heating container 12. Since the combustion test in the fuel oil analyzer 1 is performed by burning a small amount of sample oil 80, it is possible to make a highly reliable determination of combustibility by performing a plurality of tests. Therefore, by quickly cooling the heating container 12 heated to a high temperature (for example, 800 ° C.) by the combustion test, the test interval can be shortened and the combustion test can be efficiently performed.

  As shown in FIG. 7, in this embodiment, an auxiliary nozzle 29 is provided at the tip of the nozzle portion 28, and after opening the lid body 13, the auxiliary nozzle 29 is tilted toward the heating container 12. When the fan 27 (FIG. 1) provided at the lower part of the cooler 26 is driven, the cooling air 30 is jetted from the upper nozzle part 28 toward the heating container 12. Thereby, the cooling gas 30 injected from the tip of the auxiliary nozzle 29 is injected at an angle at which the injection angle θ is easily supplied to the internal space 11 of the heating container 12. The injection angle θ is preferably about 15 ° to 40 ° with respect to the horizontal line.

  Moreover, in this embodiment, the cooling gas 30 injected from the auxiliary nozzle 29 is passed through the outer space 21 between the internal space 11 of the heating container 12, the heating container 12, and the heater 14 (heat insulating material 22), The heating container 12 can be efficiently cooled from the inside and the outside.

  Therefore, the heating container 12 heated to a high temperature can be quickly cooled to the measurement start temperature, and a plurality of combustion tests can be efficiently performed.

  As described above, according to the fuel oil analyzer 1, a predetermined amount of sample oil 80 is put into the sample container 60, and the sample container 60 is locked to the locking claw 37 of the lid 13 to fix the lid 13. By closing, the sample container 60 can be appropriately placed on the placement portion 72 provided in the internal space 11 of the heating container 12. Thereafter, by operating the control device 50, the heating container 12 is heated by the heater 14, and the combustion test of the sample oil 80 is performed in the internal space 11. Then, the temperature change in the internal space 11 and the weight change of the sample container 60 are measured and recorded in the recording unit 52 of the control device 50. At the time of this combustion test, the heat of the upper case 20 provided with the heating container 12 is not transmitted to the lower case 23 through the gap 24, so that the weight measurement by the scale 70 can be performed stably.

  Further, from the relationship between the weight change and the temperature change, a combustion characteristic graph of the sample oil 80 put in the sample container 60 is created by the analysis unit 53, and an estimated cetane number (ECN) is calculated. By displaying the combustion characteristic graph and ECN on the display unit 55, the tester can determine the combustibility of the sample oil 80 from these information.

  Moreover, according to the fuel oil analyzer 1, after the test, the sample container 60 can be taken out above the heating container 12 by the locking claw 37 by opening the lid 13. And the auxiliary | assistant nozzle 29 of the cooler 26 is inclined toward the heating container 12, and the heating container 12 can be rapidly cooled by supplying the cooling gas 30. FIG. Therefore, even when a plurality of combustion tests are performed, the heating container 12 heated to a high temperature can be quickly cooled to the measurement start temperature, and a plurality of combustion tests can be performed efficiently.

  In the above-described embodiment, the sample container 60 is placed on the placement portion 72 by the cylindrical body 33 of the lid body 13, and the lower surface of the cylindrical body 33 is brought into close contact with the upper surface of the heating container 12 to form the exhaust port 34. It tries to be connected. However, the configuration in which the sample container 60 is placed on the placement unit 72 and the configuration in which the upper surface of the heating container 12 is connected to the exhaust port 34 may be separated, and these are limited to the above embodiment. is not.

  Moreover, in the said embodiment, the temperature control part 25 of the heater 14 is provided in the lower case 23 of the heating apparatus 10. FIG. However, the temperature control unit 25 may be provided in the control device 50, and each configuration may be provided in the preferred one of the heating device 10 or the control device 50, and is not limited to the above embodiment.

  Furthermore, the said embodiment has shown an example, The various change in the range which does not impair the summary of this invention is possible, and this invention is not limited to the said embodiment.

  The fuel oil analyzer according to the present invention is used as a simple fuel oil analyzer that wants to analyze fuel oil such as heavy oil easily and in a short time to determine whether the fuel oil has suitable combustibility. it can.

DESCRIPTION OF SYMBOLS 1 Fuel oil analyzer 10 Heating device 11 Internal space 12 Heating container 13 Cover body 14 Heater (heating part)
15-18 Temperature sensor (temperature measurement unit)
DESCRIPTION OF SYMBOLS 20 Upper case 21 Peripheral space 22 Heat insulating material 23 Lower case 24 Crevice 25 Temperature control part 26 Cooling machine 28 Nozzle part 29 Auxiliary nozzle 30 Cooling gas 31 Gutter part 33 Cylindrical body 34 Exhaust port 35 Gutter part 37 Locking claw 39 Fall prevention Part 40 Ventilation hole 41 Lid main body 42 Guide part 43 Locking piece 50 Control device 53 Analysis part 55 Display part 56 Storage part 57 Operation part 60 Sample container 61 Recess 62 Hook part 63 Through hole 70 Scale (Weight measurement part)
72 Placement unit 80 Sample oil (fuel oil)

Claims (8)

A sample container for a fuel oil sample;
A heating container having an internal space for accommodating the sample container;
A lid disposed on top of the heating vessel;
A heating unit for heating the sample container in the heating container;
A temperature measuring unit for measuring a temperature change in the heating container;
A weight measuring unit for measuring a change in weight of the fuel oil in the sample container;
A placement unit for the weight measurement unit disposed in the internal space of the heating container;
An analysis unit that estimates the combustibility of fuel oil from the temperature change measured by the temperature measurement unit and the weight change measured by the weight measurement unit,
The lid includes a locking claw for locking the sample container,
The said locking claw is comprised so that it may leave | separate from the said sample container, after mounting the said sample container in the said mounting part by closing the said cover body. The locking claw is described the sample container while being formed so as to lock the outer peripheral portion is inserted from the side, to claim 1 drop preventing portion in the insertion direction of the sample container is extended Fuel oil analyzer. The fuel oil analyzer according to claim 2 , wherein the fall prevention unit has a vent hole penetrating in a vertical direction. The lid body has a cylindrical body provided to be movable in the vertical direction with respect to the lid body,
The cylindrical body is configured to move up and down from a state where the lower end portion is guided downward by the lid body and protrudes downward from the lid body,
The lid is then lowered toward the heating container, after the lower surface of the tubular body is in contact with the upper surface of the heating vessel, according to claim 1 to 3, which is configured to be closed by a predetermined amount downward The fuel oil analyzer according to any one of the above. 5. The fuel oil analyzer according to claim 4 , wherein the upper surface of the heating container and the lower surface of the cylindrical body are in close contact with each other when the lower surface of the cylindrical body is in contact with the upper surface of the heating container. An upper case in which the heating container is disposed and a lower case in which the weight measuring unit is disposed;
The fuel oil analyzer according to any one of claims 1 to 5 , wherein a gap that forms a space is provided between the upper case and the lower case. Said heating vessel has a cylindrical shape, around the heating vessel to said any one of claim 1 to 6, the heating unit is configured to form a horizontal cross-section is equal cylindrical space The fuel oil analyzer of description. A cooler for gas cooling the heating vessel;
The cooling machine, any one of claim 1 to 7, which is configured down to the cooling gas in the range of 15 ° to 40 ° with respect to the upper surface of the heating vessel to supply toward the heating container The fuel oil analyzer of description.

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