JPWO2018199838A5 - - Google Patents

Description

The present invention relates to methods and systems for oil purification.

Purification of contaminated oils such as mineral oils, industrial oils, processed oils or hydraulic oils is important for the potential for oil reuse and therefore for the environmental future and limited natural oil resources. It is a factor. The contaminated oil is purified or restored by a liquid two-layer separation process, and a liquid separation aid is added to and mixed with the oil. Impurities will be trapped by separation aids and deposited in the bottom layer.

In addition, the process of purifying contaminated oil needs to be improved.

It is an object of the present invention to provide improved methods and systems for the purification of contaminated oil.

This is achieved with independent claims methods, systems and computer programs.

This provides a system for purifying different volumes of oil. The number of basic settling tanks will vary depending on the desired capacity and often one advanced settling tank is required. This saves costs and improves capacity flexibility. In addition, oil waste can be kept to a minimum.

In one embodiment of the system of the present invention, a system for oil purification is provided. The system is
-At least one supply tank with purified oil and
-Separation aid administration device and
-At least one basal settling tank comprising at least one inlet connected to a supply tank for receiving purified oil and a separation auxiliary and a separation auxiliary dosing device, said at least one basal settling tank. In addition, a basal settling tank comprising at least one sludge phase outlet and at least one oil phase outlet provided at the bottom of the basal settling tank.
-At least one advanced settling tank comprising at least one sludge phase inlet connected to at least one sludge phase outlet of at least one basic settling tank, wherein the advanced settling tank is further connected to a sludge tank. The advanced precipitation tank comprises at least one sludge phase outlet and at least one oil phase outlet, and the advanced precipitation tank further comprises at least one sensor for detecting the presence of the oil phase or sludge phase. Equipped with a tank.

In another aspect of the invention, the method is provided for purifying oil in a system comprising at least one basic settling tank and at least one advanced settling tank.
-A step of supplying a separation aid and purified oil to at least one basic settling tank,
-A step of waiting for the sludge phase to settle on the bottom of the basic settling tank, wherein the sludge phase contains a separation aid and impurities from the oil, and a waiting step.
-Steps to remove the oil phase from the basic settling tank and
-The step of transferring the sludge phase from the basic settling tank to at least one advanced settling tank,
-A step of waiting for the sludge phase to settle on the bottom of the advanced settling tank, wherein the sludge phase contains a separation aid and impurities from the oil.
-A step to detect the presence of an oil phase or sludge phase by at least one sensor provided to the advanced settling tank at at least one position in the advanced settling tank.
-Provides a step of removing the oil phase from the advanced settling tank depending on the detection.

In yet another aspect of the invention, a computer program product is provided. The computer program includes instructions to cause the control system to perform the method according to the invention when executed on the processor of the control system of the system for oil purification.

In one embodiment of the invention, the advanced settling tank comprises an oil outlet of the advanced settling tank and a sensor provided at substantially the same level of the advanced settling tank, wherein the sensor is this of the advanced settling tank. It is configured to detect if there is an oil phase or sludge phase at the level.

In one embodiment of the invention, the detecting step comprises detecting whether there is an oil phase or sludge phase at a substantial level of the advanced settling tank provided with the oil phase outlet.

This can ensure that only the oil phase is transferred using the oil phase outlet of the advanced settling tank.

In one embodiment of the invention, the advanced settling tank comprises at least three sensors, one sensor is provided at a position within the advanced settling tank so that it is always provided in the sludge phase, and one sensor. Provided at substantially the same level as the oil phase outlet in the advanced settling tank, one sensor is provided at a position in the advanced settling tank so that it is always provided in the oil phase. This ensures that reference values for sensor outputs for sludge and oil phases are always available.

In one embodiment of the invention, the at least one oil phase outlet of the at least one basal settling tank has a proportion of the contents of the basal settling tank from the basal settling tank using the oil phase outlet. The remnants of the contents at the bottom of the basic settling tank that have been removed are provided at positions within the basic settling tank that can be unaffected, and the position of the oil phase outlet is substantially sludge phase basic settling. Selected not to be removed from the tank using the oil outlet.

In one embodiment of the invention, the step of removing the oil phase from the basic settling tank removes a percentage of the contents of the basic settling tank from the basic settling tank and the rest of the contents at the bottom of the basic settling tank has an effect. It is provided with a step that does not receive, so that the sludge phase is not removed from the base settling tank along with the oil phase from which it is removed.

This ensures that only the oil phase is removed from the basal settling tank using the oil phase outlet.

In one embodiment of the invention, the system further
-A control system that is connected to the system's sensors, pumps and valves and is configured to control the flow of the system depending on the sensor signals, predefined settings and, in some cases, user input. The control system is configured to control the removal of the oil phase from at least one basal settling tank after the sludge phase has settled at the bottom of the basal settling tank, the sludge phase being a separation aid along with impurities from the oil. The control system is configured to control the transfer of the rest of the contents of the basic settling tank, including the sludge phase, to at least one advanced settling tank.
To prepare for.

In one embodiment of the invention, the control system removes the oil phase from the advanced settling tank after the sludge phase has settled to the bottom of the advanced settling tank, depending on the output from at least one sensor in the advanced settling tank. Configured to control, the sludge phase contains a separation aid as well as impurities from the oil.

In one embodiment of the invention, the control system uses at least one sludge phase outlet from the advanced settling tank to control the removal of the sludge phase while effectively with the oil phase outlet of the advanced settling tank. Monitor the output from the sensor provided at the same level and remove the sludge phase when the output from the sensor indicates that the oil phase was supplied at the level of the oil phase outlet instead of the previous sludge phase. Is configured to stop.

In one embodiment of the invention, the method further uses at least one sludge phase outlet from the advanced settling tank to control the removal of the sludge phase while effectively with the oil phase outlet of the advanced settling tank. When the output from the sensor indicates that the oil phase was supplied at the level of the oil phase outlet instead of the previous sludge phase, with the step of monitoring the output from the sensor provided at the same level. Provide a step to stop the removal of.

This controls the position between the oil phase and the sludge phase to ensure that only the oil phase is removed from the advanced settling tank using the oil phase outlet.

In one embodiment of the invention, the control system is further described.
Supplying at least one basic settling tank with a separation aid and purified oil,
After precipitating the separation aid with impurities from the oil of the sludge phase to the bottom of the basal settling tank, the oil phase is removed from the basal settling tank and the sludge phase is transferred from at least one basic settling tank to at least one advanced settling tank. To move,
Waiting for the sludge phase containing the separation aid to settle to the bottom of the advanced settling tank with impurities from the oil,
Detecting the oil or sludge phase of the advanced settling tank by at least one sensor provided to the advanced settling tank,
Depleting the oil phase from the advanced settling tank, depending on the output of the sensor,
It is configured to control the system for.

In one embodiment of the invention, the control system is further integrated into at least two basal settling tanks so that one basal settling tank accepts new purified oil while the oil phase is removed from another basal settling tank. It is configured to control the supply of oil to be purified and the removal of the oil phase from at least two basic settling tanks. Thereby, the purified oil is continuously supplied to the system, and the purified oil phase can be continuously removed from the system. This allows the system to be used as an online system for continuous oil purification.

In one embodiment of the invention, the system further comprises at least one product tank connected to at least one oil phase outlet from at least one basal settling tank.

In one embodiment of the invention, the system further comprises a filter module connected to at least one oil phase outlet of at least one basic settling tank.

In one embodiment of the invention, the method of the invention further filters the oil phase removed from at least one basal settling tank to remove any separation aids and impurities that may remain. To prepare for.

This allows impurities that may remain to be filtered.

In one embodiment of the invention, the system further comprises a filter module and a heating tank provided between at least one oil phase outlet of at least one basic settling tank.

In one embodiment of the invention, the method comprises heating the oil phase removed from at least one basal settling tank prior to further filtration.

The step of heating the oil can improve the filtration efficiency.

In one embodiment of the invention, at least one advanced settling tank comprises two sludge phase outlets provided at different levels at the bottom of the advanced settling tank, both connected to at least one sludge tank. ..

In one embodiment of the invention, the oil to be purified is provided in one basal settling tank while the oil phase is removed from another basal settling tank.

A system for oil purification according to one embodiment of the present invention is schematically shown. A system for oil purification according to another embodiment of the present invention is schematically shown. It is a flowchart of the method by one Embodiment of this invention.

FIG. 1 schematically shows a system 1 for oil purification according to one embodiment of the present invention. The system 1 includes a supply tank 3 containing oil to be purified. The system 1 can similarly include two or more supply tanks 3. The supply tank 3 may include a heating device 5, but this is not essential. The supply tank 3 is a different sensor, as shown herein, for example, a level switch 7 that closes the inlet to the supply tank and / or initiates a warning when the contents of the supply tank 3 reach a certain level. Can be arbitrarily prepared. Other sensors that can be optionally provided to the supply tank 3 are one or more temperature sensors 9 that measure the temperature of the contents of the supply tank at a level of one or more, and a supply tank to which oil has been supplied. It is a level sensor 11 capable of detecting a level. The system 1 further includes a separation aid administration device 13 including a separation aid tank 15 and a separation aid pump 17. The use of separation aids, also known as chemical boosters, to capture impurities in contaminated oils has been previously described, as discussed above. The liquid separation aid will be added to the oil and mixed there, and impurities in the oil will be captured by the separation aid and deposited in the bottom phase.

Separation aids will absorb contaminated solids or dissolved impurities of the contamination target oil by chemical interaction. Separation aids should be liquid at the temperature at which the process runs. The separation aid composition is substantially insoluble in the contamination target oil and should form a two-phase mixture when mixing the contaminated oil. The liquid separation aid should also have a density different from the density of the contaminated oil to be purified.

Separation aids are insoluble in the contamination target oil due to their polar properties, so colloids consisting of small droplets of the liquid separation aid composition are formed by agitation and have chemical interactions (hydrophilic, hydrophobic and charge mutual). By action), it absorbs unwanted solids or dissolved impurities in the target oil. When the separation aid has a higher density than the oil, the separation aid forms a lower phase with solid and / or dissolved impurities in gravity separation. If the separation aid has a lower density than the contamination target oil, gravity separation will form the upper phase.

Liquid separation aids for use in the present invention are generally built on the following elements a) polar polymers; b) hydrotropes / solubilizers; and c) co-surfactants.

Suitable separation aids with the above described properties that can be used in the process of the invention are nonionic, anionic, cationic and, for example, capable of increasing the solubility of solid or dissolved impurities in the separation aid. It comprises a composition comprising a mixture of polar polymers such as organic surfactants having androgynous properties, polyethylene glycol, polypropylene glycol or similar polyalkylene glycols.

One example of a separation aid that can be used in the present invention is a) insoluble in oil, such as polyethylene glycol having an average molecular weight of 190-210 g / mole, such as Carbowax PEG 200 (Dow Chemical). , At least one polar polymer that is denser than oil, b) for example, anionic surfactant, phosphate ester-based materials such as Simulsol SL 4, Simulsol SL 7G and Simulsol AS 48 (Seppic, Air Liquid group). Or at least one surfactant / solubilizer, such as a nonionic surfactant from the polyglycoside family, c) for example, Ampholak YJH-40 (Akzo Nobel), which is sodium capriliminodipropionate. , For example, such as propionic acid type, comprising at least one amphoteric cosurfactant.

The system 1 of the present invention further comprises at least one basic settling tank 21. In this embodiment of the invention, two basic settling tanks 21a, 21b are provided. One of the basic settling tanks 21b of FIG. 1 is shown by a dotted line depicting in another embodiment of the invention that only one basic settling tank is provided or three or more basic settling tanks are provided. .. The number of basic settling tanks 21 will define the capacity of the system. Each of the basic settling tanks 21a, 21b is connected to the supply tank 3 and the separation aid administration device 13 by at least one fluid connection 25 to receive the purified oil and the separation aid 23a. , 23b. Alternatively, a separation inlet and fluid connection for the purified oil and separation aids of the foundation settling tanks 21a, 21b can be provided. The pump 27 is provided to the fluid connection 25 to properly pump the oil and separation aids of the foundation settling tanks 21a, 21b. The valves 29a, 29b also have injection ports 23a, 21b of the basic settling tanks 21a, 21b so that one of the basic settling tanks 21a, 21b to which the fluid flow from the supply tank and the separation aid administration device 13 is supplied can be controlled. Provided at 23b. The control system 31 is also provided in this embodiment of the system 1. The control system 31 is connected to the pumps, valves and sensors of the system so that the system can be controlled. Connections between the control system 31 and all pumps, valves and sensors in the system are not shown. They are just drawn by the two dotted lines from the control system 31. The connection can be both a wired connection or a wireless connection. Further details of the control system can be obtained below.

Each of the basal settling tanks 21a, 21b further comprises at least one sludge phase discharge port 41a, 41b and at least one oil phase discharge port 39a, 39b provided at the bottoms 37a, 37b of the basal settling tanks 21a, 21b. In this embodiment, in the at least one oil phase discharge port 39a, 39b of the at least one basic settling tank 21a, 21b, a certain proportion of the contents of the tank is from the basic settling tank 21a, 21b to the oil phase discharge port. 39a, 39b are used to remove and the rest of the contents of the bottoms 37a, 37b of the foundation settling tank are provided at positions within the tank so that they cannot be affected. The positions of the oil phase outlets 39a, 39b are selected so that the sludge phase is not removed from the basic settling tanks 21a, 21b using the oil phase outlets 39a, 39b. As a result, only the contents of the tank provided above the level on which the oil phase outlets 39a, 39b are located are removed from the foundation settling tank using the oil phase outlets 39a, 39b and of the oil phase outlet. The position can be selected so that the sludge phase created at the bottoms 37a, 37b of the tank is not removed using the oil phase outlet. The oil phase outlet can be provided as a suction pipe pointing down through the tank wall as shown in FIGS. 1 and 2 or from the top of the tank to a certain level in the tank.

The sludge phase is instead removed from the foundation settling tanks 21a, 21b using the sludge phase outlets 41a, 41b. The sludge phase is properly removed from the settling tank after the oil phase has been properly removed using the oil phase outlets 39a, 39b. However, the method of the present invention is further described below.

According to the present invention, the system 1 also comprises at least one advanced settling tank 121. In the embodiments described in connection with FIG. 1, system 1 comprises one advanced settling tank 121. The advanced settling tank 121 comprises at least one sludge phase inlet 122 connected by at least one fluid connection 124 to at least one sludge phase discharge port 41a, 41b of at least one basic settling tank 21a, 21b. In this embodiment, the sludge phase discharge ports 41a and 41b from the two basic settling tanks 21a and 21b are connected to the sludge phase inlet 122 of the advanced settling tank 121 by the fluid connection 124. However, as pointed out above, the number of foundation settling tanks can vary. In this embodiment of the invention, the valves 42a, 42b are provided in sludge phase outlets 41a, 41b. These valves 42a, 42b are connected to a control system 31 which can control one of the basic settling tanks 21a, 21b to which the sludge phase is transferred to the advanced settling tank 121. The fluid connection 124 comprises a pump 125 and optionally an additional valve. In one embodiment of the invention, the advanced settling tank 121 comprises an inlet connected to a supply tank 3 and a separation aid administration device 13 to receive the oil to be purified and the separation aid. However, this is not mandatory and is not shown in the embodiments of FIGS. 1 and 2. The advanced settling tank is first used to treat the sludge phase received from the foundation settling tank. The advanced settling tank 121 further comprises at least one sludge removal outlet at the bottom 137 of the advanced settling tank 121. In the embodiment shown in FIG. 1, the advanced settling tank 121 comprises two sludge removal outlets 141a, 141b provided at different levels of the bottom 137 of the advanced settling tank 121. The two sludge removal outlets 141a and 141b are both connected to the sludge tank 143. The use of two sludge removal outlets 141a, 141b provided at different levels of the tank removes the entire sludge phase or removes part of the sludge phase of the advanced settling tank 121 for reuse in the next purification cycle. A convenient way is possible to choose to remove and store a certain amount of sludge phase. Sludge phase separation aids are often reused for further purification, which is suitable for economic reasons. By providing one sludge removal outlet 141b at a level slightly above the lowest point of the tank, the user can select the portion of sludge that he or she wants to retain in the tank for reuse. For example, the heaviest part of the sludge can be retained in the tank while the lighter part of the sludge can be removed. The heaviest part of the sludge may in some cases be the most suitable part for reuse. However, in another embodiment, only one sludge removal outlet is provided as seen in FIG. In both the embodiment shown in FIG. 1 and the embodiment shown in FIG. 2, the advanced settling tank 121 has only one sludge removal discharge port 141a, two sludge removal discharge ports 141a, 141b or three or more sludge removal ports. A discharge port can be provided.

The advanced settling tank 121 also comprises at least one oil phase outlet 139a, 139b for removing the oil phase from the advanced settling tank 121 after the sludge phase has settled on the bottom 137 of the settling tank 121. In the embodiment shown in FIG. 1, the two oil phase outlets 139a and 139b are provided at different levels of the settling tank 121. Valves are not numbered, but are also adequately provided at the respective oil phase outlets 139a, 139b. However, three or more oil phase outlets may be provided or only one may be provided. In the embodiment shown in FIG. 2, only one oil phase outlet 139 is shown, but in this embodiment, another number of oil phase outlets can be provided. In that case, the oil phase can also be removed from the settling tank at two or more different levels. In another embodiment, the oil phase outlet is instead provided as one or more suction pipes pointing down from the top of the tank. Multiple pipes of different lengths can be provided due to the possibility of extracting oil from different levels in the tank. Another possibility is to provide operable pipes that can move to different levels within the tank. However, in the embodiment shown in FIG. 1, the oil outlets 139a and 139b are provided through the wall of the advanced settling tank. The oil phase discharge ports 139a and 139b are here connected to the injection ports 23a and 23b of the basic settling tanks 21a and 21b. Thereby, the oil phase removed from the advanced settling tank will be treated again in the basic settling tanks 21a, 21b before being transferred to the product tank. In this embodiment, the fluid connection 26 connects the oil phase discharge ports 139a and 139b to the fluid connection 25 that provides the oil to be purified and the separation aid to the basic settling tanks 21a and 21b. In another embodiment, however, the oil phase removed from the advanced settling tank 121 is delivered directly to the product tank.

Optionally, the foundation and / or advanced settling tanks 21a, 21b, 121 include a heating device 35. This heats the contents of the tank. The heating device 35 is, for example, in the form of a hot water pipe provided inside or outside the tank. The separation aid captures impurities in the oil and forms a phase with impurities called the sludge phase that sink into the bottoms 37a, 37b, 137 of the foundation and advanced precipitation tanks 21a, 21b, 121. Thereby, due to gravity, the two phases form one oil phase and one sludge phase in the tanks 21a, 21b, 121 after a while. The step of warming the contents of the tank by the heating device 35 improves the separation efficiency. The heating device, however, is not essential for the present invention.

Further, the altitude and foundation settling tanks 121, 21a, 21b are appropriately equipped with mixing devices 133, 33a, 33b. The mixing devices 133, 33a, 33b include motors and are appropriately connected to the control system 31. The step of mixing the contents in a settling tank is often appropriate to improve separation efficiency.

The advanced settling tank 121 also comprises at least one sensor 55; 55a, 55b, 55c for detecting the presence of an oil phase or sludge phase in the advanced settling tank 121. The oil phase is then removed from the advanced settling tank depending on the detection. One or two at least one sensors 55; 55b, 55c shall be provided at substantially the same level as one of at least one oil phase outlet 139; 139a, 139b of the advanced settling tank 121. It can be configured to detect if there is an oil phase or sludge phase at this level in the advanced settling tank.

In the embodiment shown in FIG. 1, the advanced settling tank 121 comprises at least three sensors 55a, 55b, 55c and one sensor 55a is located in the advanced settling tank such that it is always provided to the sludge phase. Provided, one sensor 55b is provided at substantially the same level in the oil phase outlet 139a and the advanced settling tank, and one sensor 55c is provided in the advanced settling tank 121 such that it is always provided to the oil phase. Provided in the position of. Thereby, the sensor output from the sensor 55b provided at substantially the same level as one of the oil phase outlets 139a is the other two to know if there is an oil phase or sludge phase at the position of the sensor 55b. It is compared with the output from one of the sensors 55a, 55c. If two or more oil phase outlets 139a and 139b are provided in the advanced settling tank 121 as shown in FIG. 1, the sensor 55c is provided at substantially the same level as one of the oil phase outlets 139b. .. However, the number of sensors, the number of oil outlets and their relative positions can be varied within the scope of the present invention. When only one sensor 55 is provided at substantially the same level as the oil outlet 139 and is provided to the oil and sludge phases, comparing the sensor output with the pre-known values for such sensor output. Is another possibility shown in FIG. Sensors 55; 55a, 55b, 55c can be based, for example, on measuring the dielectric or density properties of the contents.

The sensor 55 can instead be, in another embodiment, a guided wave radar, which is a long wire attached to the top of the tank that hangs, eg, inside the tank almost to the bottom of the tank. Such guided wave radars can provide information on where the interfaces of the two phases are located by comparing different reflected microwave pulses when the wires are provided in different environments. If the oil phase outlet is provided as an operable tube provided from the top of the tank, the operable tube is controlled depending on that level to remove the oil phase from the detected interphase level. Can be.

The control system 31 of the system 1 is configured to control the step of removing the oil phase from the advanced settling tank 121 depending on the detection by the sensors 55; 55a, 55b, 55c. If the sensors 55; 55b provided at substantially the same level as the oil phase outlets 139a; 139 initially indicate the presence of a sludge phase, then the control system 31 in one embodiment of the invention is initially highly settling. The control system controls the system to remove sludge from the tank 121 using at least one of the sludge phase outlets 141a, 141b, while at the same time the control system is at substantially the same level as the oil phase outlets 139a; 139. Monitor the output from the provided sensors 55, 55b. Sludge should then be removed until the sensor output changes, indicating that the oil phase is provided at substantially the same level as the oil phase outlet 139a; 139. At this point, sludge removal is interrupted and the oil phase is removed using the oil phase outlet 139a; 139 instead.

The advanced settling tank 121 further comprises at least one temperature sensor 57a, 57b in this embodiment. In the embodiment of FIG. 1, it is shown that the two temperature sensors 57a, 57b are located at different levels in the advanced settling tank 121. However, another number of temperature sensors can be provided as well. The control system 31 is connected to both the temperature sensors 57a, 57b and the heating device 35 of the advanced settling tank 121, thereby controlling the heating device 35 and depending on the temperature measured by at least one temperature sensor 57a, 57b. The contents of the settling tank can be heated. By providing temperature sensors at different levels inside the settling tank 21, the heating of the tank contents is optimized and a uniform temperature is provided for all the contents of the tank. In addition, the sensor output can be adjusted depending on the measured temperature.

In the embodiment shown in FIG. 1, a product tank 53 is also provided. The product tank 53 is connected from at least one basic settling tank 21a, 21b to at least one oil phase discharge port 39a, 39b by a fluid connection 45 having a branch pipe at each oil phase discharge port 39a, 39b. .. At least one pump 49 is provided in the fluid connection 45 and the valves 46a, 46b of the oil phase outlets 39a, 39b allow control of the fluid between the basic settling tanks 21a, 21b and the product tank 53. Provided to each of the fluid branch pipes. The control system 31 is thereby appropriately connected to valves 461, 46b of the fluid connection 45 between the pump 49 and the oil phase outlets 39a, 39b and the product tank 53. The control system 31 can control the basic settling tanks 21a and 21b from which the oil phase is taken out. In a system comprising at least two basic settling tanks 21a, 21b, the control system 31 takes the oil phase out of another basic settling tank 21a, 21b while accepting new oil to be purified by one basic settling tank 21a, 21b. As such, it is configured to supply purified oil to at least two basal settling tanks 21a, 21b and control the removal of the oil phase from at least two basal settling tanks 21a, 21b. Thereby, the purified oil is continuously supplied to the system, and the purified oil phase is continuously removed from the system 1. Thereby, the system 1 is used as an online system for continuous purification of oil, that is, the purified oil is continuously supplied to the supply tank 3 and the purified oil is continuously supplied to the product tank. Recovered from 53, the system 1 can be connected to a process where the oil needs to be continuously used and continuously purified. Thereby, the oil level of the system connected to the system for oil purification according to the present invention can be maintained at a constant level during the oil purification process.

The product tank 53 may include sensors similar to the supply tank 3, such as a level switch 7, a temperature sensor 9, and a level sensor 11. However, these sensors are not essential to the present invention. The altitude and foundation settling tanks 21a, 21b, 121 may include a level switch 7 and a level sensor 11. The temperature sensors 57a, 57b have already been described in the advanced settling tank 121, but one or more temperature sensors 9 are optionally also provided in the basic settling tanks 21a, 21b.

The control system 31 is connected to the sensors, pumps and valves of the system 1 and is configured to control the flow of the system 1 depending on the sensor signals, predefined settings and possibly user input. To. The control system 31 is configured to control the supply of oil purified from the supply tank 3 to at least one basic settling tank 21a, 21b in the order of circulation if two or more basic settling tanks are provided. Will be done. The separation aid is also provided with the oil purified from the separation aid administration device 13. The control system 31 is further configured to control the removal of the oil phase from at least one basic settling tank 21a, 21b after the sludge phase has settled on the bottoms 37a, 37b of the basic settling tanks 21a, 21b. The sludge phase contains a separation aid along with impurities from the oil, and the control system 31 further to at least one advanced settling tank 121, the rest of the contents of the basic settling tanks 21a, 21b containing the sludge phase and optionally the oil. It is configured to control the transfer of some of the phases.

Further, the control system 31 depends on the sensor output from at least one sensor 55; 55a, 55b, 55c provided to the advanced settling tank 121 after the sludge phase has settled on the bottom 137 of the advanced settling tank 121. It is configured to control the removal of the oil phase from the settling tank 121. The sludge phase contains a separation aid as well as impurities from the oil. The at least one sensor 55; 55a, 55b, 55c detects the presence of an oil phase or sludge phase at at least one position in the advanced settling tank 121.

Thereby, in this embodiment, the control system 31 supplies at least one basic settling tank 21a, 21b with a separation aid and purified oil.
After precipitating the separation aid with impurities from the oil in the sludge phase onto the bottoms 37a, 37b of the basal settling tanks 21a, 21b, the oil phase is removed from the basal settling tank and at least 1 from at least one basal settling tank 21a, 21b. Transferring the sludge phase to one advanced settling tank 121,
Waiting for the sludge phase containing the separation aid to settle to the bottom 137 of the advanced settling tank 121 with impurities from the oil and possibly mixing.
Detecting the oil or sludge phase at at least one position in the advanced settling tank by at least one sensor 55; 55a, 55b, 55c provided in the advanced settling tank 121.
Depleting the oil phase from the advanced settling tank 121, depending on the output of the sensor,
It is configured to control for.

FIG. 2 schematically shows a system 101 for oil purification according to another embodiment of the present invention. There are only a few differences from the embodiments described in connection with FIG. One of them is that the filter module 51 and the heating tank 47 are provided in the fluid connection 45 between the oil phase outlets 39a, 39b and the product tank 53. Such a filter module 51 and a heating tank 47 are provided in the embodiments described with respect to FIG. Another difference is that only one sludge phase outlet 141 is provided to the bottom 137 of the advanced settling tank 121. However, also in these embodiments, two or more sludge phase outlets 141 can be provided. Further, only one oil phase discharge port 139 is provided in the advanced settling tank 121 and there is only one sensor 55 for detecting the presence of the oil phase or sludge phase. However, also in this embodiment, two or more oil phase outlets are provided in the advanced settling tank as described above with respect to FIG. 1, and two or more sensors 55a, 55b, 55c are provided at different levels in the tank. Can be In this embodiment, the sensor 55 is provided at substantially the same level as the oil phase outlet 139, and the control system 31 determines the value of the sensor output when this type of sensor is provided to the oil and sludge phases. The ability to compare is provided. All other details are exactly the same as in the previously described embodiment, with the same reference numerals and not described again. By including the filter module 51, impurities and separation aids that may remain in the oil phase taken out of the basal settling tanks 21a, 21b can be filtered by the filter module 51. The product tank 53 receives the oil phase from the basic settling tanks 21a and 21b after being filtered by the filter module 51. All impurities and separation aids that may remain in the oil phase are retained in the filter module 51. In this embodiment of the invention, the heating tank 47 is also provided in the fluid connection 45 between the oil phase outlets 39a, 39b and the filter module 51. Although the heating tank 47 is not essential to the present invention, heating the oil phase prior to filtration improves filtration efficiency. The filter module 51 can include, for example, a capillary filter, eg, a standard filter and / or a water absorption filter based on paper and having different filtration grades. Oil passes through the filter, but separation aids and impurities are captured by the filter.

FIG. 3 is a flow chart of a method for purifying oil in System 1; 101, comprising at least one basic settling tank 21a, 21b and at least one advanced settling tank 121, according to one embodiment of the present invention. The method steps are described in order below.
S1: A step of supplying the separation aid and the purified oil to the at least one basic settling tanks 21a and 21b. In the embodiments described with respect to FIGS. 1 and 2, the two basic settling tanks 21a, 21b are provided for system 1; 101, but a number of other basic settling tanks can be provided. If more than one basal settling tank is provided to the system, the separation aid and the oil to be purified are in the order of circulation, i.e. first to one of the basal settling tanks, then to another basal settling tank, etc. , Supplied to the basal settling tank and finally back to the step of supplying the first basal settling tank with new separation aids and purified oil. However, it is when the first basal settling tank is emptied after the sludge and oil phases have been created in the tank-see further steps S3-S7 below.
S3: A step of waiting for the sludge phase to settle on the bottoms 37a and 37b of the basic settling tanks 21a and 21b. The sludge phase contains a separation aid from oil and impurities.
S5: A step of taking out the oil phase from the basic settling tanks 21a and 21b using the oil phase discharge ports 39a and 39b. In one embodiment of the invention, the oil phase is transferred from the basic settling tanks 21a, 21b to the product tank 53 using the fluid connection 45. Further, in the embodiment described with respect to FIG. 2, the oil phase is filtered by the filter module 51 on the way to the product tank 53 to remove any separation aids and impurities that may remain. The removed oil phase is optionally heated in the heating tank 47 also before filtration. In one embodiment of the invention, the step of removing the oil phase from the basic settling tanks 21a, 21b removes a proportion of the contents from the basic settling tank and the rest of the contents of the bottoms 37a, 37b of the basic settling tank. It comprises an unaffected step, whereby the sludge phase is not removed from the basal settling tank together with the removed oil phase using the oil phase outlets 39a, 39b.
S7: In step S5, when the oil phase is taken out, the step of transferring the remaining contents of the bottoms 37a and 37b of the basic settling tanks 21a and 21b from the basic settling tanks 21a and 21b to at least one advanced settling tank 121. The contents remaining at the bottom of the foundation settling tanks 21a, 21b are the contents provided below the positions of the oil phase outlets 39a, 39b and include a sludge phase and possibly some oil phase. The oil phase outlets 39a, 39b of the basic settling tanks 21a, 21b are such as to ensure that the smallest sludge phase is removed or not removed from the basic settling tanks 21a, 21b using the oil phase discharge ports 39a, 39b. Provided in position.
S9: In some cases, a step of mixing the contents of the advanced settling tank 121.
S11: A step of waiting for the sludge phase to settle on the bottom 137 of the advanced settling tank 121. The sludge phase contains separation aids and impurities from the oil.
S13: A step of detecting an oil phase or a sludge phase at at least one position of the advanced settling tank 121. At least one sensor 55 as described above; 55a, 55b, 55c can be used.
S15: A step of removing the oil phase from the advanced settling tank 121 depending on the detection / sensor output received in S13.

The detection step comprises, in one embodiment of the invention, the step of detecting the presence or absence of an oil phase or sludge phase at a substantial level of the highly settling tank provided with the oil phase outlets 139a; 139b; 139. ..

Appropriately at least a portion of the sludge phase is transferred from the advanced settling tank 121 to the sludge tank 143. As mentioned above, a portion of the sludge phase can be stored in a highly settling tank for reuse of the sludge phase separation aid.

In one embodiment of the invention, the method of the invention further uses at least one sludge phase outlet 141; 141a, 141b from the advanced precipitation tank 121 to control the removal of the sludge phase while performing advanced precipitation. The step of monitoring the output from the sensor 55; 55b provided at substantially the same level as the oil phase outlet 139a; 139 of the tank 121 and the oil phase instead of the previous sludge phase oil phase outlet 139a; 139. When the output from the sensor 55; 55b indicates that it is provided at the level of, it comprises a step of stopping the removal of the sludge phase. While sludge removal is subsequently interrupted, the oil phase is instead removed from the advanced settling tank 121 using the oil phase outlet 139a; 139. After the oil phase is removed, another sludge phase can be removed. This ensures that by monitoring the sensor output while extracting the sludge phase, the level between the oil phase and the sludge phase is provided at the same level as the oil phase outlet before starting the oil phase extraction. Be controlled. This effectively removes the entire oil phase from the advanced settling tank in a convenient way and wastes very little oil. Properly, the oil phase outlets 139a and 139 are provided exactly on the sensor 55b; 55.

In one embodiment of the present invention, there is provided a method in which the oil to be purified is supplied to one basic settling tank 21a, 21b while the oil phase is taken out from another basic settling tank.

When the computer program product is further executed by the processor 32 of the control system 31 of the system 1; 101 for oil purification, the control system 31 is provided with a step comprising instructing the control system 31 to perform the above method.

Claims (20)

A system for oil purification (1; 101),
The system is
-At least one supply tank (3) with purified oil and
-Separation aid administration device (13) and
-At least one basis comprising at least one inlet (23a, 23b) connected to the supply tank (3) for receiving the oil to be purified and the separation aid administration device (13). A settling tank (21a, 21b), wherein the at least one basal settling tank (21a, 21b) is further provided to the bottom (37a, 37b) of the basal settling tank with at least one sludge phase outlet (41a). , 41b) and a basal settling tank comprising at least one oil phase outlet (39a, 39b).
At least one advanced settling tank (121) comprising at least one sludge phase inlet (122) connected to said at least one sludge phase discharge port (41a, 41b) of the at least one basal settling tank (21a, 21b). ), In the highly settling tank (121), at least one sludge phase discharge port (141; 141a, 141b) further connected to the sludge tank (143) and at least one oil phase discharge port (139a, With an advanced settling tank, with 139b; 139),
The advanced settling tank (121) further comprises at least one sensor (55; 55a, 55b, 55c) for detecting the presence of an oil phase or sludge phase .
The system further comprises a control system (31), wherein the control system (31) is the at least one sensor of the advanced settling tank (121) after the sludge phase has settled on the bottom (137) of the advanced settling tank. It is configured to control the oil phase to be taken out from the advanced settling tank (121) depending on the output from (55; 55a, 55b, 55c).
The system , wherein the sludge phase contains a separation aid along with impurities from the oil . The advanced settling tank (121) comprises an oil outlet (139a; 139) of the advanced settling tank (121) and a sensor (55; 55b) provided at substantially the same level as the advanced settling tank.
The system of claim 1, wherein the sensor (55; 55b) is configured to detect the presence of an oil phase or sludge phase at this level in the advanced settling tank. The advanced settling tank (121) comprises at least three sensors (55a, 55b, 55c).
One sensor (55a) is provided at a position within the advanced settling tank such that it is always provided in the sludge phase.
One sensor (55b) is provided at substantially the same level as the oil phase outlet (139a) in the advanced settling tank.
The system of claim 1 or 2, wherein one sensor (55c) is provided at a location within said advanced settling tank (121) such that it is always provided in the oil phase. In the at least one oil phase discharge port (39a, 39b) of the at least one basic settling tank (21a, 21b), a certain proportion of the contents of the basic settling tank is oil from the basic settling tank (21a, 21b). Removed using the phase outlets (39a, 39b), the rest of the contents of the bottom (37a, 37b) of the basal settling tank is provided at a position within the basal settling tank that is unaffected.
The position of the oil phase outlets (39a, 39b) is selected so that substantially no sludge phase is removed from the basal settling tank using the oil phase outlet, according to any one of claims 1 to 3. The system according to item 1. The control system (31)
It is connected to the sensors, pumps and valves of the system and is configured to control the flow of the system depending on the sensor signals, predefined settings and possibly user input .
The control system (31) is configured to control the oil phase to be taken out from the at least one basic settling tank (21a, 21b) after the sludge phase has settled on the bottom (37a, 37b) of the basic settling tank. Being done
The sludge phase contains a separation aid along with impurities from the oil.
The control system (31) is further configured to control the transfer of the rest of the contents of the basic settling tanks (21a, 21b) containing the sludge phase to the at least one advanced settling tank (121). The system according to any one of claims 1 to 4. The control system (31) uses the at least one sludge phase outlet (141; 141a, 141b) to control the removal of the sludge phase from the advanced sedimentation tank (121) while controlling the advanced sedimentation tank. The output from the sensor (55; 55b) provided at substantially the same level as the oil phase outlet (139a; 139) of (121) is monitored and the oil phase replaces the previous sludge phase with said oil phase discharge. Any of claims 1-5 configured to stop the removal of the sludge phase when the output from the sensor (55; 55b) indicates that it was supplied at said level at the outlet (139a; 139). The system according to item 1. The control system (31) further
Supplying at least one basic settling tank (21a, 21b) with a separation aid and purified oil,
After precipitating the separation aid together with the impurities from the oil of the sludge phase to the bottom (37a, 37b) of the basal settling tank (21a, 21b), the oil phase is taken out from the basal settling tank and the at least one foundation. Transferring the sludge phase from the settling tanks (21a, 21b) to the at least one advanced settling tank (121).
Waiting for the sludge phase containing the separation aid to precipitate on the bottom (137) of the advanced precipitation tank (121) with impurities from the oil.
Detecting the oil phase or sludge phase of the advanced settling tank by at least one sensor (55; 55; 55a, 55b, 55c) provided to the advanced settling tank (121).
Depleting the oil phase from the advanced settling tank (121), depending on the output of the sensor (55; 55a, 55b, 55c).
The system according to any one of claims 1 to 6, which is configured to control the system (1; 101) for the purpose of. The control system (31) further comprises at least two basal settling tanks (21a, 21b) such that the oil phase is removed from another basal settling tank while one basal settling tank accepts new purified oil. The system according to any one of claims 1 to 7, wherein the system is configured to control the supply of oil to be purified and the removal of the oil phase from the at least two basic settling tanks. Further, claim 1 comprises at least one product tank (53) connected to the at least one oil phase outlet (39a, 39b) from the at least one basal settling tank (21a, 21b). The system according to any one of 8 to 8. Further, any one of claims 1 to 9, further comprising a filter module (51) connected to the at least one oil phase discharge port (39a, 39b) of the at least one basic sedimentation tank (21a, 21b). The system according to item 1. Further, the filter module (51) is provided with a heating tank (47) provided between the at least one oil phase discharge port (39a, 39b) of the at least one basic sedimentation tank (21a, 21b). , The system according to claim 10. The at least one advanced settling tank (121) comprises two sludge phase outlets (141a, 141b) provided at different levels of the bottom (137) of the advanced settling tank (121), both of which are at least one. The system according to any one of claims 1 to 11, which is connected to one sludge tank (143). A method of purifying oil in a system (1; 101) comprising at least one basic settling tank (21a, 21b) and at least one advanced settling tank (121).
The method is
-The step (S1) of supplying the separation aid and the purified oil to the at least one basic settling tank (21a, 21b).
-A step of waiting for the sludge phase to settle on the bottom (37a, 37b) of the basic settling tank (21a, 21b), wherein the sludge phase contains impurities from the separation aid and the oil. Step (S3) and
-The step (S5) of taking out the oil phase from the basic settling tanks (21a, 21b) and
-The step (S7) of transferring the sludge phase from the basic settling tanks (21a, 21b) to the at least one advanced settling tank (121).
-A step of waiting for the sludge phase to settle on the bottom (137) of the advanced precipitation tank (121), wherein the sludge phase contains the separation aid and impurities from the oil, and waits (S11). When,
-At least one position of the advanced settling tank (121), the presence of an oil phase or sludge phase by at least one sensor (55; 55a, 55b, 55c) provided to the advanced settling tank (121). The step to detect (S13) and
-A method comprising a step (S15) of taking out the oil phase from the advanced settling tank (121) depending on the detection (S13). 13. The method of claim 13, wherein the detecting step (S13) comprises a step of detecting whether or not there is an oil phase or a sludge phase in the highly settling tank provided with the oil phase discharge port (139a; 139). In the step (S5) of taking out the oil phase from the basic settling tanks (21a, 21b), a certain proportion of the contents of the basic settling tank is taken out from the basic settling tank, and the bottom of the basic settling tank (37a, 37b). The method of claim 13 or 14, wherein the rest of the contents of) is provided with an unaffected step, whereby the sludge phase is not removed from the basic settling tank (21a, 21b) together with the oil phase to be removed. .. The method further controls the removal of the sludge phase from the advanced settling tank (121) using the at least one sludge phase discharge port (141; 141a, 141b) while controlling the advanced settling tank (121). The step of monitoring the output from the sensor (55; 55b) provided at substantially the same level as the oil phase discharge port (139a; 139) and the oil phase instead of the previous sludge phase are the oil phase discharge port. 13. description
the method of. 13-16, further comprising filtering the oil phase removed from the at least one basal settling tank (21a, 21b) to remove any separation aids and impurities that may remain. The method according to any one. 17. The method of claim 17, further comprising heating the oil phase taken out of the at least one basal settling tank (21a, 21b) before being filtered. Any one of claims 13-18, wherein the oil to be purified is provided to one of the basal settling tanks (21a, 21b) while the oil phase is withdrawn from another of the basal settling tanks (21a, 21b). The method described in the section. The method according to any one of claims 13 to 19 when executed in the processor (32) of the control system (31) of the system (1; 101) for oil purification. A computer program product that contains instructions to execute.