JP2010194391A - Strainer for sludge recovery - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a strainer for sludge recovery, for reducing the amount of oil-containing sludge transferred to a recovery tank. <P>SOLUTION: The strainer for sludge recovery includes: a screw 4 which comprises a screw shaft 2 and a screw blade 3 spirally provided on at least a part of the outer periphery of the screw shaft; an inner cylinder 5 which is provided with an oil passing hole and surrounds the screw; an outer cylinder 6 which is installed on the outer side of the inner cylinder and forms an oil discharge gap with the inner cylinder; an oil supply port 10 for supplying oil into the inner cylinder; a stopper 7 which is installed near the cylinder end on the oil-containing sludge discharge side of the inner cylinder, and for adjusting the discharge of the oil-containing sludge; an oil discharge port 13 for discharging the oil discharged to the oil discharge gap to the outside of an apparatus; an oil-containing sludge discharge port 12 for discharging the oil-containing sludge discharged from the inner cylinder to the outside of the apparatus; and a driving means for rotationally driving the screw. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an oil tank common oil washing method for washing an oil tank such as a crude oil tank or a heavy oil tank with a common oil, and removes the oil containing sludge from the common oil containing the oil containing sludge discharged from the oil tank. It relates to a strainer.

  Since crude oil usually contains several percent of sludge, when such crude oil is stored in a tank, it settles at the bottom of the tank as sludge containing oil (hereinafter also referred to as oil-containing sludge). To do. Similarly, in the heavy oil tank, oil-containing sludge settles at the bottom of the tank.

  If the amount of oil-containing sludge that settles at the bottom of these oil tanks increases, the oil tank is cleaned to remove the oil-containing sludge, and after removing the residual sludge, Must be disposed of as waste.

  A conventional oil tank cleaning operation will be described with reference to FIG. FIG. 13 is a schematic flow diagram showing a common oil tank common oil cleaning work. In the conventional oil tank common oil cleaning work, first, the oil 204 in the oil tank 201 to be cleaned is transferred to the recovery tank 209 using the recovery system pump 210, and then the cleaning system pump 203. The oil 204 in the recovery tank 209 is supplied to the oil discharger 205 by using the oil jet to inject the oil 204 into the oil-containing sludge 206 in the oil tank 201, thereby Fluidize. At this time, the oil 204 is heated through the warmer 202 as necessary depending on the oil type. Next, using the recovery system pump 210, the oil 204 in the oil tank 201 is discharged from the oil drain pipe 214 to the outside of the oil tank 201, temporarily recovered in the recovery vessel 211, and then transferred to the oil The oil is transferred from the oil tank 201 to the recovery tank 209 via a pipe 208. At this time, the fluidized oil-containing sludge 206 is discharged out of the oil tank 201 together with the oil 204. Then, the oil 204 is circulated between the recovery tank 209 and the oil tank 201, and the oil-containing sludge 206 of the oil tank 201 is discharged out of the oil tank 201, thereby cleaning the oil tank 201. Do. At this time, since the fluidized oil-containing sludge 206 is discharged out of the oil tank 201 together with the oil 204, the oil 204 discharged from the oil tank 201 contains the oil-containing sludge 206. Therefore, the oil-containing sludge 206 is transferred to the recovery tank 209. It should be noted that a strainer is usually installed in the front stage of the recovery system pump 210, but this strainer is used to remove large contaminants in the oil 204 in order to protect the recovery system pump 210. Therefore, the oil-containing sludge 206 cannot be removed with this strainer.

  In FIG. 13, the cleaning system pump 203, the warmer 202, and the oil discharge device 205 are a cleaning system 212 (portion indicated by a one-dot chain line in FIG. 13), and the oil drain pipe 214, The recovery vessel 211 and the recovery system pump 210 are a recovery system 213 (portion indicated by a two-dot chain line in FIG. 13).

  The conventional oil tank co-oil cleaning method as described above has a problem in that fluidized sludge is transferred to a recovery tank.

  Therefore, the subject of this invention is providing the strainer for sludge collection | recovery which can reduce the quantity of the oil-containing sludge transferred to a collection | recovery tank.

That is, the present invention (1) includes a screw comprising a screw shaft and a screw blade provided spirally on the outer periphery of at least a part of the screw shaft;
An inner cylinder having an oil passage hole and surrounding the screw;
An outer cylinder that is installed outside the inner cylinder and forms an oil discharge gap with the inner cylinder;
An oil supply port for supplying the oil into the inner cylinder;
Installed in the vicinity of the cylinder end of the inner cylinder on the oil-impregnated sludge discharge side, and a stopper for adjusting the discharge of the oil-containing sludge;
An oil discharge port for discharging the oil discharged into the oil discharge gap to the outside of the device;
An oil-containing sludge discharge port for discharging the oil-containing sludge discharged from the inner cylinder to the outside of the apparatus;
Drive means for rotationally driving the screw;
The present invention provides a strainer for collecting sludge.

  ADVANTAGE OF THE INVENTION According to this invention, the strainer for sludge collection | recovery which can reduce the quantity of the oil-containing sludge transferred to a collection | recovery tank can be provided.

It is typical sectional drawing which shows the 1st form example of the strainer for sludge collection | recovery of this invention. It is typical sectional drawing which shows the 1st form example of the strainer for sludge collection | recovery of this invention. It is a side view of the screw in FIG.1 and FIG.2. It is a figure which shows the positional relationship of the cylinder end and stopper of the oil-containing sludge discharge | emission side of the inner cylinder in FIG. It is typical sectional drawing of this strainer for sludge collection | recovery which shows a mode that oil is filtered using the strainer for sludge collection | recovery of FIG.1 and FIG.2. It is a schematic diagram which shows the form example of the washing | cleaning system of the oil tank for implementing the sludge removal method at the time of the co-oil washing | cleaning of an oil tank using the 1st form example of the strainer for sludge collection | recovery of this invention. It is typical sectional drawing of the processing apparatus of a screw type oil-containing sludge. It is typical sectional drawing of the processing apparatus of a screw type oil-containing sludge. It is a side view of the screw (B) in FIG.7 and FIG.8. It is sectional drawing which described the inner cylinder (B) and outer cylinder (B) of FIG. It is typical sectional drawing of the processing apparatus 131 of this screw type oil-containing sludge which shows a mode that the processing operation of oil-containing sludge is performed using the processing apparatus 131 of a screw type oil-containing sludge. It is sectional drawing of the oil-water separator 61. It is a typical flowchart which shows the co-oil cleaning method of the conventional oil tank.

The strainer for sludge recovery of the present invention is a screw (A) comprising a screw shaft (A) and screw blades (A) provided spirally on the outer periphery of at least a part of the screw shaft (A),
An inner cylinder (A) having an oil passage hole and surrounding the screw (A);
An outer cylinder (A) installed outside the inner cylinder (A) and forming an oil discharge gap with the inner cylinder (A);
An oil supply port for supplying oil into the inner cylinder (A);
A stopper (A) installed near the end of the inner cylinder (A) on the oil-impregnated sludge discharge side for adjusting the discharge of the oil-containing sludge;
An oil discharge port for discharging the oil discharged into the oil discharge gap to the outside of the device;
An oil-containing sludge discharge port for discharging the oil-containing sludge discharged from the inner cylinder (A) to the outside of the apparatus;
Drive means for rotationally driving the screw (A);
A strainer for collecting sludge.

The strainer for sludge recovery of the present invention transfers oil in the oil tank to be cleaned to the recovery tank, and then injects the oil in the recovery tank onto the oil-containing sludge in the oil tank, Fluid oil sludge is fluidized, and then the oil in the oil tank is transferred from the oil tank to the recovery tank, whereby the oil is circulated to wash the oil tank. In the method
Installed in the middle of an oil transfer pipe for transferring the oil discharged from the oil tank to the recovery tank, and for removing oil-containing sludge in the oil after being injected into the oil-containing sludge in the oil tank Strainer.

  The sludge recovery strainer of the present invention will be described with reference to FIGS. 1 and 2 are schematic cross-sectional views showing a sludge recovery strainer of the present invention. FIG. 1 is a cross-sectional view taken along a plane parallel to the moving direction of the oil-containing sludge, and FIG. It is sectional drawing when it cuts in the surface perpendicular | vertical with respect to the moving direction of oil-containing sludge. FIG. 3 is a side view of the screw in FIGS. 1 and 2. 1 and 2, the sludge recovery strainer 1 includes a screw (A) 4, an inner cylinder (A) 5 surrounding the screw (A) 4, and an outer side of the inner cylinder (A) 5. An outer cylinder (A) 6 installed so as to form an oil discharge gap 22 for discharging oil after filtration between the cylinder (A) 5 and the oil content of the inner cylinder (A) 5 A stopper 7 (A) installed in the vicinity of the cylinder end 18 on the sludge discharge side, an oil supply side flange 8 installed on the oil supply side of the inner cylinder (A) 5 and the outer cylinder (A) 6, An oil-impregnated sludge discharge side flange 9 installed so as to form an oil-impregnated sludge discharge chamber 14 on the oil-impregnated sludge discharge side of the inner cylinder (A) 5 and the outer cylinder (A) 6, and the inner cylinder (A) 5 An oil supply port 10 for supplying oil into the inside, and steam on the outer cylinder side for supplying water vapor or washing water into the outer cylinder (A) 6 The purified water supply port 11, the oil-containing sludge discharge port 12 for discharging the oil-containing sludge from the oil-containing sludge discharge chamber 14 to the outside of the device, and the filtered oil discharged to the oil discharge gap 22 to the outside of the device And an oil discharge port 13 for discharging.

  As shown in FIG. 3, the screw (A) 4 includes a screw shaft (A) 2 and a screw blade (A) 3. The screw blade (A) 3 is provided in a spiral shape on the outer periphery of at least a part of the screw shaft (A) 2. The screw shaft (A) 2 is rotatably fixed to the oil supply side flange 8 and the oil-containing sludge discharge side flange 9.

  When the screw (A) 4 rotates, the oil-impregnated sludge remaining in the inner cylinder (A) 5 after being filtered by the inner cylinder (A) 5 is removed from the oil-impregnated oil in the inner cylinder (A) 5. It is a member for moving to the sludge discharge side.

  The screw blade (A) 3 is formed in a spiral shape on the outer periphery of the screw shaft (A) 2 and is filtered by the inner cylinder (A) 5 when the screw (A) 4 rotates. The oil-containing sludge in the inner cylinder (A) 5 separated from the oil is not particularly limited as long as the oil-containing sludge can be moved from the oil supply side to the oil-containing sludge discharge side.

  The diameter 25 of the screw blade (A) 3 may be the same length as the inner diameter of the inner cylinder (A) 5, or may be slightly smaller than the inner diameter of the inner cylinder (A) 5. When the diameter 25 of the screw blade (A) 3 is smaller than the inner diameter of the inner cylinder (A) 5, the clearance between the screw blade (A) 3 and the inner cylinder (A) 5 is usually 1 mm or less, The thickness is preferably 0.5 mm or less, particularly preferably 0.1 mm or less.

  The ratio (reference numeral 26 / reference numeral 25) of the pitch 26 of the screw blade (A) 3 to the diameter 25 of the screw blade (A) 3 is 0.25 to 1.25, preferably 0.75 to 1.0, Especially preferably, it is 0.9-1.0. In the present invention, the pitch 26 of the screw blade (A) 3 is the distance between the apexes 261a and 261b of the screw blade (A) in FIG. 3, that is, the screw blade (A) 3 is viewed from the side. The distance between the vertices of adjacent blades.

  The pitch 26 of the screw blade (A) 3 may be the same or different over the entire range of the screw blade (A) 3.

  In the present invention, the shape of the screw (A) 4 is not limited to the shape shown in FIGS. 1 and 3. For example, the diameter of the screw shaft increases toward the oil-containing sludge discharge side. And those having a pitch that decreases toward the discharge side of the oil-containing sludge.

  The inner cylinder (A) 5 is for filtering oil and filtering oil-containing sludge in the oil.

  The inner cylinder (A) 5 has a cylindrical shape. The cylinder end 19 on the oil supply side of the inner cylinder (A) 5 is fixed to the oil supply side flange 8, and the cylinder end 19 is closed by the oil supply side flange 8. On the other hand, the cylinder end 18 on the oil-containing sludge discharge side of the inner cylinder (A) 5 is fixed to the oil-containing sludge discharge-side flange 9, and the opening of the cylinder end 18 is connected to the oil-containing sludge discharge chamber 14. Yes. That is, the cylinder end 18 is opened so that the oil-containing sludge is discharged out of the inner cylinder (A) 5.

  The inner cylinder (A) 5 has a cylindrical wall on which the oil is filtered, the oil-containing sludge in the oil is filtered, and the filtered oil is discharged into the oil discharge gap 22. A passage hole (not shown) is formed.

  The cylinder wall of the inner cylinder (A) 5 is not particularly limited as long as the oil passage hole is formed. Examples of the cylinder wall of the inner cylinder (A) 5 include a wire mesh and punching. Examples thereof include a plate material in which holes such as metal are punched out, a screen wire mesh, and the like.

  The diameter of the oil passage hole formed in the cylinder wall of the inner cylinder (A) 5 varies depending on the size of the sludge in the oil to be treated, and is larger than the diameter of the sludge accumulated at the bottom of the oil tank. Although it is appropriately selected within a small range, it is usually 0.1 to 0.5 mm, preferably 0.2 to 0.4 mm, and particularly preferably 0.2 to 0.3 mm. When the cylinder wall of the inner cylinder (A) 5 is a wire mesh, the diameter of the oil passage hole indicates the mesh opening length of the wire mesh, and the cylinder wall of the inner cylinder (A) 5 is In the case of screen wire mesh, it refers to the length of the screen mesh.

  The sludge filtered from the oil remains in the inner cylinder (A) 5 as oil-containing sludge containing oil.

  The outer cylinder (A) 6 has a cylindrical shape. A cylinder end 20 on the oil supply side of the outer cylinder (A) 6 is fixed to the oil supply side flange 8, and the cylinder end 20 is closed by the oil supply side flange 8. On the other hand, the cylinder end 21 on the oil-containing sludge discharge side of the outer cylinder (A) 6 is fixed to the oil-containing sludge discharge-side flange 9, and the oil discharge gap 22 and the oil-containing sludge discharge chamber 14 are It is isolated by the oil-containing sludge discharge side flange 9. That is, the oil discharge gap 22 is closed by the oil-containing sludge discharge side flange 9 so that the oil after filtration discharged into the oil discharge gap 22 does not flow into the oil-containing sludge discharge chamber 14. Yes.

  The width of the oil discharge gap 22 formed by the inner cylinder (A) 5 and the outer cylinder (A) 6, in other words, the outer side of the inner cylinder (A) 5 and the outer cylinder (A) 6 The distance from the inside is not particularly limited as long as the filtered oil is discharged and can flow to the oil discharge port 13.

  In addition, in FIG.1 and FIG.2, although the shape of this outer cylinder (A) 6 has shown that the cross-sectional shape when cut by a surface perpendicular | vertical with respect to the moving direction of oil-containing sludge is circular, The shape of the outer cylinder (A) 6 is not limited to this, and the inner cylinder (A) 5 can be installed on the inner side, and the oil is discharged to flow to the oil discharge port 13. What is necessary is just to be able to form the discharge gap. In addition, as the shape of the outer cylinder (A), for example, the outer cylinder (A) has a flat top and a rounded bottom. Further, the bottom cylindrical wall of the outer cylinder (A) 6 may be inclined toward the oil discharge port 13.

  The stopper (A) 7 is attached to the screw shaft (A) 2 and is installed in the vicinity of the cylinder end 18 on the oil-containing sludge discharge side of the inner cylinder (A) 5. When the oil is being filtered, the stopper (A) 7 moves the oil from the cylinder end 18 on the oil-containing sludge discharge side of the inner cylinder (A) 5 to the oil-containing sludge discharge chamber 14. When the oil-impregnated sludge is discharged from the inner cylinder (A) 5 to the oil-containing sludge discharge chamber 14, the inner cylinder ( A) The oil-containing sludge is discharged between the inner cylinder (A) 5 and the cylinder end 18 on the oil-containing sludge discharge side so that the oil-containing sludge is discharged from the inside 5 to the oil-containing sludge discharge chamber 14. It plays the role of forming the gap 15. When the oil-containing sludge is discharged from the inner cylinder (A) 5, the stopper (A) 7 and the screw (A) 4 are selected by selecting the size of the oil-containing sludge discharge gap 15. And while pressing the oil-containing sludge with the inner cylinder (A) 5, the oil content squeezed by the pressing is discharged from the oil passage hole of the inner cylinder (A) 5 to the oil discharge gap 22. On the other hand, since the oil-containing sludge after being squeezed can be discharged from the oil-containing sludge discharge gap 15, the amount of oil contained in the oil-containing sludge discharged from the sludge recovery strainer 1 is reduced. be able to.

  The stopper (A) 7 will be described in detail with reference to FIG. FIG. 4 is a schematic sectional view showing the stopper (A) of the first embodiment of the sludge recovery strainer of the present invention. The stopper (A) 7, as shown in FIG. 4 (4-1), is in contact with the cylinder end 18 on the oil-impregnated sludge discharge side of the inner cylinder (A) 5 and closes the cylinder end 18. , (4-2), the oil-containing sludge discharge gap 15 for discharging the oil-containing sludge to the oil-containing sludge discharge chamber 14 away from the cylinder end 18 on the oil-containing sludge discharge side of the inner cylinder (A) 5. The screw shaft (A) 2 is attached to the screw shaft (A) 2 so as to be movable between positions where the screw is formed. In FIG. 1, the stopper (A) 7 is shown at the position (4-2) in FIG. If the first embodiment of the sludge recovery strainer of the present invention is used, for example, first, as shown in (4-1) of FIG. 4, the stopper (A) 7 is oil-impregnated in the inner cylinder (A) 5. Oil is supplied from the oil supply port 10 at a position in contact with the cylinder end 18 on the sludge discharge side, the oil is filtered, then the oil supply is stopped, and then (4-2) in FIG. As shown, the stopper (A) 7 is moved away from the cylinder end 18 on the oil-impregnated sludge discharge side of the inner cylinder (A) 5, and the screw (A) 4 is rotated so that the inner cylinder (A ) The oil-containing sludge remaining in 5 is moved to the oil-containing sludge discharge side of the inner cylinder (A) 5 and the oil-containing sludge is discharged from the oil-containing sludge discharge gap 15. That is, the first embodiment of the sludge recovery strainer of the present invention is an embodiment in which the position of the stopper (A) itself is selected.

  Moreover, as another form example (second form example) of the sludge recovery strainer of the present invention, the stopper (A) is slidably attached to the screw shaft (A) via a bearing or the like, In addition, one having a pressure adjusting member for applying pressure by an elastic body, hydraulic pressure, air pressure, or the like on the back surface can be used. If the second embodiment of the sludge recovery strainer of the present invention is used, when the oil is filtered, the oil-containing sludge is discharged from the cylinder end of the inner cylinder (A) 5 on the oil-containing sludge discharge side. In order to prevent the oil from being discharged into the chamber, the pressure applied to the back surface of the stopper (A) with the pressure adjusting member is adjusted so that the cylinder end on the discharge side of the oil-containing sludge is closed, When the oil-containing sludge is discharged from the inner cylinder (A) 5 to the oil-containing sludge discharge chamber, the stopper (A) 7, the screw (A) 4 and the inner cylinder (A) After squeezing the oil-containing sludge, the oil component squeezed by the oil is discharged from the oil passage hole of the inner cylinder (A) 5 into the oil discharge gap and compressed. The pressure regulating member so that the oil-containing sludge is discharged from the oil-containing sludge discharge gap. It is operated as of regulating the pressure applied to the rear surface of the stopper (A). That is, when discharging the oil-containing sludge from the inner cylinder (A) 5 to the oil-containing sludge discharge chamber, by adjusting the pressure applied to the back surface of the stopper (A) with the pressure adjusting member, Since the compressibility of the oil-containing sludge can be adjusted, if the pressure applied by the pressure adjusting member is adjusted, the size of the oil-containing sludge discharge gap is set to the size at which the oil-containing sludge is compressed. Adjusted automatically. The back surface of the stopper (A) is the side opposite to the side that forms the oil-containing sludge discharge gap with the inner cylinder (A) 5. That is, in the second embodiment of the sludge recovery strainer of the present invention, the position of the stopper (A) is automatically adjusted by adjusting the pressure applied to the back surface of the stopper (A) by the pressure adjusting member. It is an example.

  The oil supply port 10 is a supply port for supplying oil into the inner cylinder (A) 5. The installation position of the oil-containing sludge supply port 10 in the moving direction of the oil-containing sludge is not particularly limited. Further, the installation position of the oil sludge supply port 10 in the circumferential direction of the inner cylinder (A) 5 and the outer cylinder (A) 6 is usually the uppermost position as shown in FIG. It is not limited and is appropriately selected depending on the position of an oil supply pipe (not shown).

  The steam or cleaning water supply port 11 on the outer cylinder side is supplied with steam or water for supplying high-pressure steam or cleaning water to the inner cylinder (A) 5 from the outside of the inner cylinder (A) 5. This is the cleaning water supply port. The oil passage hole formed in the cylinder wall of the inner cylinder (A) 5 is gradually blocked by sludge in the oil, for example, iron rust, sand, mud, etc., as oil filtration continues. . Then, when the amount of blockage of the passage hole increases, the supply of oil is stopped, and the passage is performed by supplying steam or washing water at a high pressure from the steam or washing water supply port 11 on the outer cylinder side. Sludge clogged in the holes can be removed. The washing water is not particularly limited, and industrial water is usually used. In addition, the supply pressure of the water vapor or the washing water is appropriately selected within a range of pressure at which sludge clogged in the passage hole is removed. The installation position of the steam or cleaning water supply port 11 on the outer cylinder side in the moving direction of the oil-containing sludge, and the steam or cleaning water supply port on the outer cylinder side in the circumferential direction of the outer cylinder (A) 6 The installation position of 11 is not particularly limited. Also, the number of steam or cleaning water supply ports 11 on the outer cylinder side in the moving direction of the oil-containing sludge and the supply of steam or cleaning water on the outer cylinder side in the circumferential direction of the outer cylinder (A) 6 The number of the mouths 11 is not particularly limited, and is appropriately selected so that the steam or the washing water is supplied to the entire inner cylinder (A) 5.

  The oil-containing sludge discharge port 12 is a discharge port for discharging oil-containing sludge from the oil-containing sludge discharge chamber 14 to the outside of the apparatus. The installation position of the oil-containing sludge discharge port 12 in the circumferential direction of the outer cylinder (A) 6 is usually at the lowest position.

  The oil discharge port 13 is a discharge port for discharging the filtered oil discharged to the oil discharge gap 22 to the outside of the apparatus. The installation position of the oil discharge port 13 and the number of the oil discharge ports 13 in the moving direction of the oil-containing sludge are not particularly limited and are appropriately selected. Moreover, the installation position of the oil discharge port 13 in the circumferential direction of the outer cylinder (A) 6 is normally the lowest. And as an installation position of this oil discharge port 13, the center in the movement direction of this oil-containing sludge or its vicinity and the lowest part in the circumferential direction of this outer cylinder (A) 6 or its vicinity are preferable.

  In the sludge recovery strainer 1, the screw shaft (A) 2 and the inner cylinder (A) 5 may be horizontal, may be inclined to the oil supply side, and may be inclined to the oil-containing sludge discharge side. You may do it.

  Next, a method for operating the sludge recovery strainer of the present invention will be described with reference to FIG. FIG. 5 is a schematic cross-sectional view of the sludge recovery strainer 1 showing how oil is filtered using the sludge recovery strainer 1.

  In the sludge collection strainer 1, that is, the first embodiment of the sludge collection strainer of the present invention, first, as shown in FIG. 4 (4-1), the stopper (A) 7 is attached to the inner cylinder ( A) The oil 41 is supplied from the oil supply port 10 at a position in contact with the cylinder end 18 on the oil-containing sludge discharge side of 5, and the oil 41 is filtered by the inner cylinder (A) 5. The oil-containing sludge in 41 is filtered off. At this time, the filtered oil 42 is discharged from the oil discharge port 13 to the outside of the apparatus through the oil discharge gap 22. In addition, the oil-containing sludge 43 filtered from the oil 41 remains in the inner cylinder (A) 5.

  Next, when the amount of the oil-containing sludge accumulated in the inner cylinder (A) 5 increases, the supply of the oil 41 is stopped. Next, the position of the stopper (A) 7 is changed, and as shown in FIG. 4 (4-2), the stopper (A) 7 is moved to the cylinder end 18 on the oil-containing sludge discharge side of the inner cylinder (A) 5. The oil-containing sludge in the inner cylinder (A) 5 is moved to the oil-containing sludge discharge side of the inner cylinder (A) 5 by rotating the screw (A) 4 to a position away from the oil-containing sludge. The sludge is squeezed, and the squeezed oil is discharged from the oil discharge gap 22, and the oil-containing sludge 43 is discharged from the oil-containing sludge discharge gap 15. Further, from the oil-containing sludge discharge port 12, Discharge out of the device.

  In the second embodiment of the sludge recovery strainer of the present invention, first, the pressure applied to the back surface of the stopper (A) is adjusted by the pressure adjusting member, and the stopper (A) is the inner cylinder (A) 5. The oil is filtered through the inner cylinder (A) 5 by supplying oil from the oil supply port so as to be in contact with the cylinder end on the oil-containing sludge discharge side of the oil-containing sludge, and the oil-containing sludge in the oil is separated by filtration. To do. At this time, the filtered oil is discharged out of the apparatus through the oil discharge port through the oil discharge gap. The oil-containing sludge filtered from the oil remains in the inner cylinder (A) 5.

  Next, when the amount of the oil-containing sludge accumulated in the inner cylinder (A) 5 increases, the supply of the oil is stopped. Next, by adjusting the pressure applied to the back surface of the stopper (A) with the pressure adjusting member so that the oil-containing sludge discharge gap of an appropriate size is formed, the screw (A) 4 is rotated. The oil-containing sludge in the inner cylinder (A) 5 is moved to the oil-containing sludge discharge side of the inner cylinder (A) 5, the oil-containing sludge is compressed, and the oil-containing sludge is compressed from the oil discharge gap. While oil is discharged, the oil-containing sludge is discharged from the oil-containing sludge discharge gap, and is further discharged out of the apparatus from the oil-containing sludge discharge port.

  Although not shown in FIGS. 1 and 4, the water vapor or the cleaning water used for cleaning the inner cylinder (A) 5 is discharged into the oil discharge gap as water after cleaning. Therefore, in order to discharge this moisture out of the apparatus, the sludge recovery strainer of the present invention may have a moisture discharge pipe after cleaning.

  The sludge recovery strainer of the present invention is used to remove oil-containing sludge in the oil discharged together with the oil from the oil tank. The installation position of the sludge recovery strainer of the present invention is in the middle of the oil transfer pipe between the oil tank and the recovery tank.

  An example (first embodiment) of how to use the sludge recovery strainer of the present invention will be described with reference to FIG. FIG. 6 is a schematic view showing a common oil cleaning system for an oil tank having a first embodiment of the sludge recovery strainer of the present invention.

  In FIG. 6, the oil tank co-oil cleaning system 50 includes a cleaning system 80 (portion surrounded by a one-dot chain line in FIG. 6) and a recovery system 81 (portion surrounded by a two-dot chain line in FIG. 6). Have. The cleaning system 80 includes a cleaning system pump 74 that transfers oil 71 in the recovery tank 57 to an oil discharger 73, a warmer 72 that heats the oil 71, and an oil that is subject to cleaning. And an oil discharger 73 for injecting the oil-containing sludge accumulated on the bottom of the tank 51. The cleaning system pump 74 and the recovery tank 57 are connected by an oil transport pipe 75.

  On the other hand, the recovery system 81 includes an oil extraction pipe 77 that is an extraction pipe for the oil 41 in the oil tank 51, a recovery vessel 76 that recovers the oil 41 extracted from the oil tank 51, and the oil A recovery system pump 53 for extracting the oil 41 from the tank 51 and supplying the oil 41 to the sludge recovery strainers 1a and 1b through the recovery vessel 76; An oil transfer pipe 52 a is connected to the recovery system pump 53.

  In the middle of the oil transfer pipe 52 (52a and 52b) for transferring the oil 41 discharged from the oil tank 51 to the recovery tank 57, two sludge recovery strainers 1a and 1b are installed. Yes. The oil supply pipes 54a and 54b are connected to the oil supply ports of the sludge recovery strainers 1a and 1b. The other ends of the oil supply pipes 54a and 54b are connected to the oil transfer pipe 52a. In addition, one ends of oil discharge pipes 56a and 56b are connected to the oil discharge ports of the sludge recovery strainers 1a and 1b. The other ends of the oil discharge pipes 56a and 56b are connected to the oil transfer pipe 52b. Further, one end of a screw conveyor 58 (58a, 58b) for conveying the oil-containing sludge is connected to the oil-containing sludge discharge ports of the sludge collecting strainers 1a and 1b. The other end of the screw conveyor 58 for conveying the oil-containing sludge is connected to the oil-containing sludge processing device 60 of the oil recovery unit X. Further, valves 55a and 55b are attached to the oil supply pipes 54a and 54b, and valves 55c and 55d are attached to the oil discharge pipes 56a and 56b. The sludge recovery strainers 1a and 1b are a first embodiment of the sludge recovery strainer of the present invention. In addition, the part enclosed with the dotted line in FIG. In FIG. 6, the oil tank cleaning system 50 is other than the oil tank 51 and the oil recovery tank 57.

  The oil content recovery unit X treats the oil-containing sludge with the oil-containing sludge processing device 60 that separates the residual sludge from the oil-containing sludge by bringing water vapor into contact with the oil-containing sludge, and the oil-containing sludge processing device 60. The oil-water separator 61 which separates the oil-water produced by this into oil and moisture is provided. The oil-containing sludge treatment device 60 and the oil / water separator 61 are connected by an oil / water transfer pipe 68. The oil-containing sludge treatment device 60 is connected to a residue sludge discharge pipe 62 for discharging the residue sludge 65 separated from the oil-containing sludge to the outside of the device. The oil / water separator 61 is connected to an oil discharge pipe 63 for discharging the oil 66 to the outside of the apparatus and a water discharge pipe 64 for discharging the moisture 67 to the outside of the apparatus. The oil / water transfer pipe 68 is usually provided with a pump (not shown) for transporting the oil / water 70 to the oil / water separator 61. Further, a filtration member (not shown) for removing fine sludge usually present in the oil water 70 is attached to the front stage of the pump for transporting the oil water 70 to the oil water separator 61. Yes.

  The oil tank 51 to be cleaned is a crude oil tank or a heavy oil tank.

  In the first embodiment of the method of using the sludge recovery strainer of the present invention, first, before installing the cleaning system 80, the recovery system 81, and the sludge recovery strainers 1a and 1b, Oil is transferred to the collection tank 57.

  Next, in the first embodiment of the method for using the sludge recovery strainer of the present invention, the cleaning system pump 74 transfers the oil 71 from the oil recovery tank 57 to the oil discharger 73. Then, the oil 71 is jetted onto the oil-containing sludge accumulated on the bottom of the oil tank 51 by the oil discharger 73 to fluidize the oil-containing sludge. In addition, before supplying this oil 71 to this oil discharge device 73, it heats with this warmer 72 as needed with oil seed | species. In FIG. 6, the oil discharger 73 is sprayed onto the oil-containing sludge to fluidize the oil-containing sludge, and the fluidized oil-containing sludge is discharged from the oil tank 51, thereby In the present invention, the method for cleaning the oil tank is not limited to the above description.

  Next, the oil 41 after being injected into the oil-containing sludge in the oil tank 51 is discharged from the oil tank 51 and once collected in the recovery vessel 76, then the oil transfer pipe 52a and the oil supply pipe 54a. Or, it is supplied to the sludge recovery strainer 1a or the sludge recovery strainer 1b via 54b. At this time, the oil-containing sludge fluidized along with the oil 41 is also discharged from the oil tank 51. Therefore, the oil 41 contains the oil-containing sludge.

  Next, the oil 41 is filtered by the sludge recovery strainer 1a or 1b, and the oil filtered by the sludge recovery strainer 1a or 1b, that is, the oil 42 after filtration is supplied to the oil discharge pipe 56a or 56b. Then, the oil is transferred to the recovery tank 57 through the oil transfer pipe 52b.

  Next, the filtered oil 42 transferred to the recovery tank 57 is recycled and used as the oil 71 again. The oil tank 51 is washed by circulating the oil through the oil tank 51 and the recovery tank 57 and discharging the oil-containing sludge in the oil tank 51 to the outside of the tank.

  Further, the oil-containing sludge 43 filtered by the sludge recovery strainer 1a or 1b is supplied to the oil content recovery unit X through the screw conveyor 58. Then, the oil content recovery unit X recovers the oil content 66 and the residual sludge 65 from the oil-containing sludge.

  The oil filtration step according to the first embodiment of the method of using the sludge recovery strainer of the present invention will be described. First, the valves 55a and 55c are opened and the valves 55b and 55d are closed, and then the recovery is performed. The oil 41 after being injected into the oil-containing sludge in the oil tank 51 is recovered in the recovery vessel 76 using a system pump 53, and then passed through the oil transfer pipe 52a and the oil supply pipe 54a. The sludge recovery strainer 1a is supplied. At this time, the stopper (A) 7 is brought into contact with the cylinder end of the inner cylinder (A) 5 on the oil-impregnated sludge discharge side to block the cylinder end of the inner cylinder (A) 5 on the oil-containing sludge discharge side. . Then, the oil 41 is filtered by the sludge recovery strainer 1a, and the oil 42 after the filtration is discharged out of the apparatus, passed through the oil discharge pipe 56a and the oil transfer pipe 52b, and then to the recovery tank 57. Transfer to

  Next, until the pressure difference between the pressure gauge (not shown) attached to the oil supply pipe 54a and the pressure gauge (not shown) attached to the oil discharge pipe 56a exceeds a certain value, After the oil 41 is filtered by the sludge recovery strainer 1a, the valves 55b and 55d are opened and the valves 55a and 55c are closed. Then, using the recovery system pump 53, the oil 41 is supplied to the sludge recovery strainer 1b through the oil transfer pipe 52a and the oil supply pipe 54b. At this time, the stopper (A) 7 is brought into contact with the cylinder end of the inner cylinder (A) 5 on the oil-impregnated sludge discharge side to block the cylinder end of the inner cylinder (A) 5 on the oil-containing sludge discharge side. . Then, the oil 41 is filtered by the sludge recovery strainer 1b, the filtered oil 42 is discharged to the outside of the apparatus, and passes through the oil discharge pipe 56b and the oil transfer pipe 52b, and then the recovery tank 57. Transfer to In the above description, it has been described that the switching time from the sludge recovery strainer 1a to the sludge recovery strainer 1b is determined based on the differential pressure, but the present invention is not limited to this. A method that can appropriately determine the switching timing can be used as appropriate, such as grasping the amount of the oil-containing sludge accumulated in the sludge recovery strainer 1a.

  In parallel with the filtration of the oil 41 by the sludge recovery strainer 1b, the oil-containing sludge in the inner cylinder (A) 5 of the sludge recovery strainer 1a is discharged outside the apparatus, and the inner cylinder (A) Washing 5 is performed. First, the stopper (A) 7 is separated from the cylinder end of the inner cylinder (A) 5 on the oil-impregnated sludge discharge side, and the oil-impregnated oil is placed between the inner cylinder (A) 5 and the stopper (A) 7. A sludge discharge gap 15 is formed. Then, the screw (A) 4 of the sludge recovery strainer 1a is rotated to move the oil-containing sludge in the inner cylinder (A) 5 to the oil-containing sludge discharge side, and the oil-containing sludge discharge gap 15 The oil-containing sludge discharge chamber 14 is used to discharge the oil-containing sludge discharge port 12 to the outside of the apparatus. Next, the water vapor 40 is supplied from the water vapor or washing water supply port (A) 11 on the outer cylinder side, and the inner cylinder (A) 5 is cleaned, and the inner cylinder (A) 5 is passed through the passage hole. Remove clogged sludge. In the above description, it is described that steam is supplied from the steam or cleaning water supply port (A) 11 on the outer cylinder side, but high-pressure cleaning water, for example, industrial water can also be supplied.

  Next, until the pressure difference between the pressure gauge (not shown) attached to the oil supply pipe 54b and the pressure gauge (not shown) attached to the oil discharge pipe 56b exceeds a certain value, After the oil 41 is filtered by the sludge collection strainer 1b, the valves 55a and 55c are opened and the valves 55b and 55d are closed, and again, the sludge collection strainer 1a is used to remove the oil 41. Filter. In parallel with this, discharge of the oil-containing sludge in the inner cylinder (A) 5 of the sludge recovery strainer 1b to the outside of the apparatus and cleaning of the inner cylinder (A) 5 are performed.

  Thereafter, the oil 41 is filtered alternately by the sludge recovery strainer 1a and the sludge recovery strainer 1b. In parallel with the filtration of the oil 41 by the sludge recovery strainer 1a, the oil-containing sludge in the inner cylinder (A) 5 of the sludge recovery strainer 1b is discharged to the outside of the apparatus, and the inner cylinder (A) 5 is cleaned, and in parallel with the filtration of the oil 41 by the sludge recovery strainer 1b, the oil-containing sludge device in the inner cylinder (A) 5 of the sludge recovery strainer 1a The discharge to the outside and the cleaning of the inner cylinder (A) 5 are performed.

  In this way, the oil filtration step according to the first embodiment of the method for using the sludge recovery strainer of the present invention is performed.

  Next, the oil-containing sludge 43 discharged to the outside of the apparatus is supplied to the oil-containing sludge processing apparatus 60 via the screw conveyor 58. The oil-containing sludge processing unit 60 processes the oil-containing sludge 43, separates the residue sludge 65 from the oil-containing sludge 43, and discharges the residue sludge 65 from the residue sludge discharge pipe 62 to the outside of the device. At the same time, the oil water 70 generated by processing the oil-containing sludge in the oil-containing sludge processing device 60 is supplied to the oil-water separation device 61 through the oil-water transfer pipe 68. Next, the oil / water separator 61 separates the oil 66 and the water 67.

  In this way, the oil content recovery unit X recovers the oil content 66 from the oil-containing sludge 43 and performs the oil content recovery process according to the first embodiment of the method of using the sludge recovery strainer of the present invention. .

  After the oil content recovery step, the oil content 66 recovered from the oil-containing sludge 43 is normally returned to the subsequent stage of the sludge recovery strainers 1a and 1b, but may be returned to the previous stage. Alternatively, the oil 66 may be transferred to another tank.

  The method of using the strainer for recovering sludge of the present invention is not limited to this. Examples of the method of using the strainer for recovering sludge of the present invention (second embodiment) include, for example, sludge recovery of the present invention. An example of using the second example of the strainer for the machine is given.

  When installing the second embodiment of the method for using the sludge recovery strainer of the present invention, that is, when installing the second embodiment of the sludge recovery strainer of the present invention, the oil filtration step is performed in the inner cylinder (A). The oil-impregnated sludge is compressed by adjusting the pressure applied to the back surface of the stopper (A) by the pressure-regulating member when the oil-impregnated sludge is compressed out of the apparatus. Except for automatically adjusting the size of the oil-containing sludge discharge gap by adjusting the rate, this is the same as the first embodiment of the method of using the sludge recovery strainer of the present invention.

  Further, the oil recovery step according to the second embodiment of the method of using the sludge recovery strainer of the present invention is the same as the first embodiment of the method of using the sludge recovery strainer of the present invention.

  FIG. 6 shows that there are two sludge recovery strainers of the present invention installed in the middle of the oil transfer pipe. However, the present invention is not limited to this. It may be the above. FIG. 6 also shows that the means for conveying the oil-containing sludge 43 from the oil-containing sludge discharge port of the sludge collection strainers 1a and 1b to the oil content recovery unit X is a screw conveyor 58. However, the present invention is not limited to this, and a means capable of transporting the oil-containing sludge 43 from the oil-containing sludge discharge port of the sludge collection strainers 1a and 1b to the oil content recovery unit X is appropriately selected.

  FIG. 6 shows that the unit for recovering oil from the oil-containing sludge is the oil recovery unit X. However, the present invention is not limited to this, and any unit that can recover oil from the oil-containing sludge can be used. That's fine.

  The oil component recovery step according to the first embodiment of the method for using the sludge recovery strainer of the present invention will be described in more detail. The oil recovery step is a step of performing an oil-containing sludge treatment operation for separating residual sludge from the oil-containing sludge, and an oil-water separation operation for separating oil water generated by the oil-containing sludge treatment operation into oil and moisture.

  The oil-containing sludge processing operation related to the oil content recovery step is a processing operation of oil-containing sludge in which the oil-containing sludge is brought into contact with water vapor at 100 to 200 ° C., and then the oil-containing sludge is compressed and separated into oil water and residual sludge. is there. In the treatment operation of the oil-containing sludge, the oil and water in the oil-containing sludge and the supplied water vapor are separated into the condensed water and the residual sludge, but the oil and water in the oil-containing sludge and the supplied water are supplied. Including all the moisture condensed by water vapor, it is also referred to as “oil water”.

  The oil-containing sludge treatment operation is a continuous oil-containing sludge treatment operation.

The oil-containing sludge processing operation is, for example, the following screw-type oil-containing sludge processing apparatus, that is,
A screw (B) comprising a screw shaft (B) having a water supply hole, and screw blades (B) spirally provided on the outer periphery of at least a part of the screw shaft (B);
An inner cylinder (B) having an oil-water passage hole and surrounding the screw;
An outer cylinder (B) that is installed outside the inner cylinder (B) and forms an oil-water discharge gap with the inner cylinder (B);
An oil-containing sludge supply port for supplying oil-containing sludge into the inner cylinder (B);
An outer cylinder side water vapor supply port (B) for supplying water vapor into the outer cylinder (B);
A stopper (B) installed in the vicinity of the cylinder end on the residue sludge discharge side of the inner cylinder (B), and forming a residue sludge discharge gap with the cylinder end on the residue sludge discharge side of the inner cylinder (B); ,
An oil water discharge port for discharging the oil water discharged into the oil water discharge gap to the outside of the device;
Drive means (B) for rotationally driving the screw;
A screw-type oil-containing sludge treatment apparatus having
Can be used.

  The oil-containing sludge treatment apparatus has a ratio of a length from a cylinder end on the oil-containing sludge supply side of the inner cylinder (B) to the outer cylinder-side steam supply port (B) with respect to the length of the inner cylinder (B). , 0.5 or less is preferable.

  The screw-type oil-containing sludge treatment apparatus will be described with reference to FIGS. 7 and 8 are schematic cross-sectional views of the screw-type oil-containing sludge treatment apparatus, and FIG. 7 is a cross-sectional view taken along a plane parallel to the moving direction of the oil-containing sludge. These are sectional drawings when it cuts in the surface perpendicular | vertical with respect to the moving direction of oil-containing sludge. FIG. 9 is a side view of the screw (B) in FIGS. 7 and 8. FIG. 10 is a cross-sectional view illustrating the inner cylinder and the outer cylinder of FIG. 7 and 8, the screw-type oil-containing sludge treatment device 131 includes a screw (B) 134, an inner cylinder (B) 135 surrounding the screw (B) 134, and an outer side of the inner cylinder (B) 135. In addition, an outer cylinder (B) 136 installed so that an oil water discharge gap 152 is formed between the inner cylinder (B) 135 and a cylinder on the residue sludge discharge side of the inner cylinder (B) 135. Stopper (B) 137 installed in the vicinity of end 148, oil-impregnated sludge supply side flange 138 installed on the oil-impregnated sludge supply side of inner cylinder (B) 135 and outer cylinder (B) 136, and inner cylinder (B) 135 and residue sludge discharge side flange 139 installed so as to form a residue sludge discharge chamber 144 on the residue sludge discharge side of the outer cylinder (B) 136, and the inner cylinder (B) 135 containing oil To supply sludge Residual sludge is supplied to the outside from the oil-impregnated sludge supply port 140, the outer cylinder side water vapor supply port (B) 141 for supplying water vapor into the outer cylinder (B) 136, and the residue sludge discharge chamber (B) 144. Residual sludge discharge port 142 for discharging, oil water discharge port 143 for discharging oil water discharged to the oil water discharge gap 152 to the outside of the apparatus, and gas in the outer cylinder (B) 136 And an exhaust port (B) 146 for discharging to the outside.

  As shown in FIG. 9, the screw (B) 134 includes a screw shaft (B) 132 and a screw blade (B) 133. The screw blade (B) 133 is spirally provided on the outer periphery of at least a part of the screw shaft (B) 132. The screw shaft (B) 132 is rotatably fixed to the oil-impregnated sludge supply side flange 138 and the residue sludge discharge side flange 139.

  The screw shaft (B) 132 is a hollow tube, and one end 158 of the screw shaft (B) 132 is an opening for supplying water vapor into the tube of the screw shaft (B) 132. The other end 159 of the screw shaft (B) 132 is sealed. The shaft wall of the screw shaft (B) 132 is formed with a water vapor supply hole 157 for discharging water vapor from the space inside the shaft to the outside of the shaft. The water vapor supply hole 157 supplies water vapor to the oil-impregnated sludge in the inner cylinder (B) 135 from the screw shaft (B) 132 side, that is, from the center of the inner cylinder (B) 135 to the outside. This is a water vapor supply hole.

  The diameter of the water vapor supply hole 157 is appropriately selected depending on the size of the sludge in the oil-containing sludge to be treated, but is usually 5 to 12 mm, preferably 8 to 12 mm, and particularly preferably 8 to 10 mm. In FIG. 9, a range 154 in which the water vapor supply hole 157 is formed is selected as appropriate. Usually, the oil-containing sludge supply side is close to the oil-containing sludge supply-side flange 138, and usually the residue sludge is discharged. The ratio of the length of the range 154 in which the water vapor supply hole 157 is formed to the length of the portion 153 surrounded by the inner cylinder (B) 135 (reference numeral 154 / reference numeral 153) is 0.5 to The position is 0.866, preferably 0.66 to 0.866, particularly preferably 0.76 to 0.866. When the ratio of the length of the range 154 in which the water vapor supply hole 157 is formed to the length of the portion 153 surrounded by the inner cylinder (B) 135 (symbol 154 / symbol 153) exceeds the above range, the residue The amount of water in the sludge tends to increase. The number of the water vapor supply holes 157 is appropriately selected depending on the type of oil-containing sludge, the scale of the apparatus, and the like.

  The screw blade (B) 133 is formed in a spiral shape on the outer periphery of the screw shaft (B) 132, and the oil-containing sludge in the inner cylinder (B) 135 is rotated by the rotation of the screw (B) 134. If it is the shape which can be moved from oil-containing sludge supply side to residue sludge discharge side, it will not be restrict | limited in particular.

  The diameter 155 of the screw blade (B) 133 may be the same length as the inner diameter of the inner cylinder (B) 135, or may be slightly smaller than the inner diameter of the inner cylinder (B) 135. When the diameter 155 of the screw blade (B) 133 is smaller than the inner diameter of the inner cylinder (B) 135, the clearance between the screw blade (B) 133 and the inner cylinder (B) 135 is usually 1 mm or less, The thickness is preferably 0.5 mm or less, particularly preferably 0.1 mm or less.

  The ratio (reference numeral 156 / reference numeral 155) of the pitch 156 of the screw blade (B) 133 to the diameter 155 of the screw blade (B) 133 is 0.25 to 1.25. And since it becomes easy to slow down the moving speed of oil-impregnated sludge, in other words, it becomes easy to lengthen the compression time of the oil-impregnated sludge, and therefore the screw blade (B ) The ratio of the pitch 156 of the screw blade (B) 133 to the diameter 155 of 133 (reference numeral 156 / reference numeral 155) is preferably 0.5 to 1.25, particularly preferably 0.75 to 1, and more preferably 0. .9-1. In the processing operation of the oil-impregnated sludge, the pitch 156 of the screw blade (B) 133 is the distance between the apexes 561a and 561b of the screw blade in FIG. 9, that is, the screw blade (B) 133 is viewed from the side. The distance between the vertices of adjacent blades.

  The pitch 156 of the screw blade (B) 133 may be the same or different over the entire range of the screw blade (B) 133.

  In addition, in the processing operation of the oil-impregnated sludge, the shape of the screw (B) 134 is not limited to the shape shown in FIGS. 7 and 9, and for example, the screw shaft is moved toward the residue sludge discharge side. Examples include those having a larger diameter and those having a smaller pitch toward the residue sludge discharge side.

  The inner cylinder (B) 135 has a cylindrical shape. A cylinder end 149 on the oil-impregnated sludge supply side of the inner cylinder (B) 135 is fixed to the oil-impregnated sludge supply-side flange 138, and the cylinder end 149 is closed by the oil-containing sludge supply-side flange 138. On the other hand, the cylinder end 148 on the residue sludge discharge side of the inner cylinder (B) 135 is fixed to the residue sludge discharge side flange 139, and the opening of the cylinder end 148 is connected to the residue sludge discharge chamber 144. Yes. That is, the tube end 148 is opened so that the residual sludge is discharged out of the inner tube (B) 135.

  Oil water separated from the object to be squeezed in the inner cylinder (B) 135 by squeezing oil-containing sludge on the cylinder wall of the inner cylinder (B) 135 is discharged from the inner cylinder (B) 135 to the oil water. An oil water passage hole (not shown) is formed so as to be discharged into the gap 152.

  The cylindrical wall of the inner cylinder (B) 135 is not particularly limited as long as the oil water passage hole is formed. Examples of the cylindrical wall of the inner cylinder (B) 135 include a wire mesh, punching, and the like. Examples thereof include a plate material in which holes such as metal are punched out, a screen wire mesh, and the like.

  The diameter of the oil water passage hole formed in the cylindrical wall of the inner cylinder (B) 135 is appropriately selected depending on the size of the sludge in the oil-containing sludge to be treated. It is 96 mm, preferably 0.2 to 1.74 mm, particularly preferably 0.3 to 0.5 mm. When the cylinder wall of the inner cylinder (B) 135 is a wire mesh, the diameter of the oil water passage hole indicates the length of the opening of the wire mesh, and the cylinder wall of the inner cylinder (B) 135 is In the case of punching metal, the diameter of the oil water passage hole refers to the diameter of the punched hole.

  By installing the inner cylinder (B) 135 so as to surround the screw (B) 134, oil-containing sludge is compressed between the inner wall of the inner cylinder (B) 135 and the screw blade (B) 134. A compressed space 147 is formed.

  The outer cylinder (B) 136 has a cylindrical shape. The cylinder end 150 on the oil-impregnated sludge supply side of the outer cylinder (B) 136 is fixed to the oil-impregnated sludge supply-side flange 138, and the cylinder end 150 is closed by the oil-containing sludge supply-side flange 138. On the other hand, a cylinder end 151 on the residue sludge discharge side of the outer cylinder (B) 136 is fixed to the residue sludge discharge side flange 139, and the oil water discharge gap 152 and the residue sludge discharge chamber 144 are It is isolated by a residue sludge discharge side flange 139. That is, the oil water discharge gap 152 is blocked by the residue sludge discharge side flange 139 so that the oil water discharged into the oil water discharge gap 152 does not flow into the residue sludge discharge chamber 144.

  The width of the oil-water discharge gap 152 formed by the inner cylinder (B) 135 and the outer cylinder (B) 136, in other words, the outside of the inner cylinder (B) 135 and the outer cylinder (B) 136 The distance from the inside is the oil and water separated from the object to be compressed in the inner cylinder (B) 135 by compressing the oil-containing sludge, and the water in which the supplied water vapor is condensed, that is, the oil water is discharged. There is no particular limitation as long as it can flow to the oil / water discharge port 143.

  7 and 8, the outer cylinder (B) 136 has a circular cross section when cut along a plane perpendicular to the moving direction of the oil-containing sludge. The shape of the outer cylinder (B) 136 is not limited to this, and the inner cylinder (B) 135 can be installed on the inner side, and the oil water is discharged to flow to the oil water discharge port 143. What is necessary is just to be able to form the discharge gap. In addition, as the shape of the outer cylinder (B), for example, a cylindrical shape having a flat upper side and a rounded lower side can be cited. Further, the cylindrical wall at the bottom of the outer cylinder (B) 136 may be inclined toward the oil / water discharge port 143.

  The stopper (B) 137 is fixed to the screw shaft (B) 132 and is installed in the vicinity of the cylinder end 148 on the residue sludge discharge side of the inner cylinder (B) 135. The stopper (B) 137 adjusts the compressibility of the oil-containing sludge by adjusting the discharge amount of the residual sludge when the residual sludge is discharged from the tube end 148 to the residual sludge discharge chamber 144. Fulfills the function. Specifically, the size of the residue sludge discharge gap 145 formed between the stopper (B) 137 and the cylinder end 148 is adjusted by adjusting the installation position of the stopper (B) 137. Thus, the discharge amount of the residual sludge can be adjusted. And the compression rate of this oil-containing sludge can be adjusted by adjusting the ratio of the discharge amount of this residual sludge with respect to the supply amount of this oil-containing sludge. The installation position of the stopper 137 or the residual sludge discharge gap 145 formed by the stopper 137 and the tube end 148 is appropriately selected depending on the type of oil-containing sludge, the oil content of the oil-containing sludge, the processing conditions, and the like. The

  The oil-containing sludge supply port 140 is a supply port for supplying oil-containing sludge into the inner cylinder (B) 135. As shown in FIG. 10, the installation position of the oil-containing sludge supply port 140 in the oil-containing sludge movement direction 164 is the oil-containing sludge supply side of the inner cylinder (B) 135 with respect to the length 161 of the inner cylinder (B) 135. The ratio of the length 163 from the cylinder end 149 to the oil-impregnated sludge supply port 140 (reference numeral 163 / reference numeral 161) is 0.15 or less, preferably 0.125 or less, particularly preferably 0.093 to 0.125. Is the position. The ratio of the length 163 from the cylinder end 149 on the oil-impregnated sludge supply side of the inner cylinder (B) 135 to the oil-impregnated sludge supply port 140 with respect to the length 161 of the inner cylinder (B) 135 is within the above range. In addition, the treatment effect of the oil content of the oil-containing sludge is increased. In the operation of processing the oil-containing sludge, the length 161 of the inner cylinder (B) 135 is the discharge of residual sludge from the inner cylinder (B) from the cylinder end 149 on the oil-containing sludge supply side of the inner cylinder (B). This refers to the distance to the tube end 148 on the side, and the position of the oil-containing sludge supply port 140 refers to the center position of the oil-containing sludge supply port 140. In addition, the installation position of the oil-impregnated sludge supply port 140 in the circumferential direction of the inner cylinder (B) 135 and the outer cylinder (B) 136 is usually the uppermost position as shown in FIGS. However, it is not limited to this, and is appropriately selected depending on the position of an oil-containing sludge supply pipe (not shown).

  The outer cylinder side steam supply port (B) 141 is centered from the inner cylinder (B) 135 side with respect to the oil-impregnated sludge in the inner cylinder (B) 135, that is, from the outside of the inner cylinder (B) 135. It is the supply port of the water vapor | steam for supplying water vapor | steam toward. As shown in FIG. 10, the installation position of the outer cylinder side water vapor supply port (B) 141 in the moving direction of the oil-containing sludge is the inner cylinder (B) 135 with respect to the length 161 of the inner cylinder (B) 135. The ratio of the length 162 from the cylinder end 149 on the oil-impregnated sludge supply side to the outer cylinder-side water vapor supply port (B) 141 (reference numeral 162 / reference numeral 161) is 0.5 or less, preferably 0.03 to 0.00. 5, particularly preferably 0.14 to 0.3, and more preferably 0.18 to 0.25. The ratio of the length 162 from the cylinder end 149 on the oil-impregnated sludge supply side of the inner cylinder (B) 135 to the length 161 of the inner cylinder (B) 135 to the outer cylinder-side water vapor supply port (B) 141 is as described above. By being in the range, a large amount of water vapor can be brought into contact with the oil-containing sludge at the initial stage when the oil-containing sludge is squeezed in the inner cylinder (B) 135. The processing effect is increased. In the operation of treating the oil-containing sludge, the position of the outer cylinder side water vapor supply port (B) 141 refers to the center position of the outer cylinder side water vapor supply port (B) 141.

  Moreover, although the installation position of this outer cylinder side water vapor supply port (B) 141 in the circumferential direction of this outer cylinder (B) 136 is the lowest in FIG.7 and FIG.10, it is not restricted to this. However, it is appropriately selected depending on the position of a water vapor supply pipe (not shown). The number of the outer cylinder side water vapor supply ports (B) 141 is not particularly limited, and may be 1 or 2 or more.

  The oil water discharge port 143 is a discharge port for discharging the oil water discharged into the oil water discharge gap 152 to the outside of the apparatus. The installation position of the oil / water discharge port 143 and the number of the oil / water discharge ports 143 in the moving direction of the oil-containing sludge are not particularly limited and are appropriately selected. Further, the installation position of the oil / water discharge port 143 in the circumferential direction of the outer cylinder (B) 136 is usually at the lowest position.

  The exhaust port (B) 146 is a gas exhaust port for exhausting a gas such as water vapor in the apparatus to the outside of the apparatus. The installation position of the exhaust port (B) 146 and the number of installation of the exhaust port (B) 146 in the moving direction of the oil-containing sludge are not particularly limited and are appropriately selected.

  When water vapor is brought into contact with the oil-containing sludge, steam such as hydrocarbons is generated. Therefore, in order to recover them, it is preferable to install a cooling means at the exhaust port (B).

  The screw-type oil-containing sludge treatment device 131 is provided with drive means (B) (not shown) for rotating the screw (B) 134.

  In the screw-type oil-containing sludge treatment apparatus 131, the screw shaft (B) 132 and the inner cylinder (B) 135 may be horizontal, may be inclined toward the oil-containing sludge supply side, and the residue It may be inclined toward the sludge discharge side or may be vertical.

  With reference to FIG. 11, an operation procedure for performing the processing operation of the oil-containing sludge using the screw-type oil-containing sludge processing device 131 will be described. FIG. 11 is a schematic cross-sectional view of the screw-type oil-impregnated sludge treatment apparatus 131, showing a state in which the screw-type oil-impregnated sludge treatment apparatus 131 is performing the treatment operation of the oil-containing sludge. .

  The oil-containing sludge 171 is supplied to the screw-type oil-containing sludge treatment device 131 from the oil-containing sludge supply port 140, and the screw (B) 134 is rotated to supply the oil-containing sludge 171 to the oil-containing sludge. The oil-containing sludge 171 is moved from the port 140 toward the cylinder end 148 on the residue sludge discharge side of the inner cylinder by moving the compression space 147 formed in a spiral around the screw shaft (B) 132. By pressing the oil-containing sludge 171, a high pressure is applied to the oil-containing sludge 171 and the oil-containing sludge 171 is squeezed. While supplying the oil-containing sludge, water vapor 170a at 100 to 200 ° C. is supplied from one end 158 of the screw shaft 132, and water vapor 170b at 100 to 200 ° C. is supplied from the outer cylinder side water vapor supply port (B) 141. Thus, water vapor is brought into contact with the oil-containing sludge 171 from both the center and the outside of the inner cylinder (B) 135.

  Therefore, the oil-impregnated sludge supplied from the oil-impregnated sludge supply port 140 immediately after being supplied to the inner cylinder (B) 135, the steam 170a from the steam supply hole 157 of the screw shaft (B) 132, and the It contacts the steam 170b from the outer cylinder side steam supply port (B) 141. Subsequently, the oil-containing sludge 171 moves to the residue sludge discharge side while being compressed by the rotation of the screw (B) 134. During this time, the water vapor 170a from the water vapor supply hole 157 and the water supply from the outer cylinder side are supplied. The water vapor 170b from the mouth (B) 141 is in contact. That is, the water vapor is in contact with the oil-containing sludge 141 even during the pressing.

  Then, while rotating the screw (B) 134, supplying the steam 170a and 170b, continuously supplying the oil-containing sludge 171 and discharging the residue sludge 173, continuously. The oil content of the oil-containing sludge 171 can be processed. At that time, the oil water 172 is appropriately discharged from the oil water discharge port 143, and the exhaust gas 175 is discharged from the exhaust port (B) 146.

  Thus, the treatment operation of the oil-containing sludge is a treatment operation of the oil-containing sludge that contacts the oil-containing sludge with water vapor of 100 to 200 ° C. and then squeezes the oil-containing sludge and separates it into the oil water and the residual sludge. is there. And the processing operation of this oil-containing sludge is the method of processing this oil-containing sludge continuously.

  During the pressing, the oil-containing sludge 171 is heated by steam supplied into the screw-type oil-containing sludge treatment device 131, and the temperature of the supplied steam is 100 to 200 ° C, preferably 100 to 180 ° C. ° C, particularly preferably 110 to 150 ° C, more preferably 130 to 150 ° C. When the temperature of the water vapor to be supplied is within the above range, the oil content in the oil-containing sludge 171 can be satisfactorily processed. Further, the temperature in the screw-type oil-containing sludge treatment apparatus 131 during the pressing is a steady-state temperature of 100 to 200 ° C, preferably 100 to 180 ° C, particularly preferably 110 to 150 ° C, and more preferably. Is 130-150 ° C. The oil content in the oil-containing sludge 171 can be satisfactorily processed when the temperature in the screw-type oil-containing sludge processing device 131 during the pressing is within the above range. The temperature in the screw-type oil-containing sludge treatment device 131 at the time of the compression is such that a thermocouple or the like is installed in the oil water discharge gap 152 at a position not in direct contact with the supplied steam. It is obtained by measuring the temperature of the discharge gap 152.

  In the pressing, the pressing pressure for pressing the oil-containing sludge is appropriately selected depending on the type of oil-containing sludge.

  The pressing time of the oil-containing sludge 171 at the time of pressing, that is, the time from when the oil-containing sludge 171 is supplied from the oil-containing sludge supply port 140 until it is discharged from the residue sludge discharge gap 145 as the residue sludge 173. Is preferably 1 hour or more, particularly preferably 1 to 3 hours, further preferably 1.5 to 3 hours, and more preferably 2 to 2.5 hours. When the pressing time of the oil-containing sludge 171 during the pressing is within the above range, the effect of treating oil and harmful substances in the oil-containing sludge 171 is enhanced. That is, in the treatment operation of the oil-impregnated sludge, the effect of treating the oil in the oil-impregnated sludge is enhanced by slowly pressing the oil-containing sludge over time by setting the compression time of the oil-containing sludge within the above range. can do. On the other hand, even if the squeezing time is too long, the effect is obtained, but the improvement of the effect reaches a peak, and the processing efficiency deteriorates. In the screw-type oil-containing sludge treatment device 131, the rotational speed of the screw (B) 134, the supply amount of the oil-containing sludge 171 from the oil-containing sludge supply port 140, and the residual sludge from the discharge gap 145 By appropriately selecting the discharge amount of the sludge 173, the pressing time of the oil-containing sludge 171 during the pressing can be adjusted.

  In the treatment operation of the oil-containing sludge, the oil-containing sludge is heated to a high temperature and the moisture content of the oil-containing sludge is increased by bringing the oil-containing sludge 171 into contact with the steam 170 immediately after the oil-containing sludge is supplied and during pressing. The solid content and the liquid content in the oil-containing sludge 171 can be easily separated. Therefore, the oil-containing sludge treatment operation can satisfactorily treat the oil in the oil-containing sludge 171.

  Further, in the screw-type oil-containing sludge treatment device 131, the screw shaft (B) 132 is formed with the water vapor supply hole 157, and the oil-containing sludge supply side of the inner cylinder with respect to the length of the inner cylinder. Since the ratio of the length from the cylinder end to the outer cylinder side water vapor supply port (B) is 0.5 or less, the oil-containing sludge is immediately put into the inner cylinder (B) 135 when the oil-containing sludge is introduced into the inner cylinder (B) 135. Therefore, the screw-type oil-containing sludge treatment device 131 is preferably used for the operation of treating the oil-containing sludge.

  In this manner, the oil-containing sludge is treated, the oil-containing sludge is treated, and the residual sludge is separated from the oil-containing sludge.

  The oil / water separation operation is an operation for separating the oil / water generated by the treatment operation of the oil-containing sludge into the oil and the water, but may be any oil / water separation operation usually performed in petroleum refining or the like. Examples of the oil / water separation operation include an operation of separating an oil layer and an aqueous layer into two layers in a separation tank and extracting oil from the upper layer and moisture from the lower layer.

  FIG. 12 shows a cross-sectional view of the oil / water separator 61 for performing the oil / water separation operation. In the oil / water separator 61, the oil / water 70 is supplied from the oil / water transfer pipe 68 to the oil / water separator 61. In the oil / water separator 61, the oil component 66 layer is separated into two layers, the upper oil layer and the moisture 67 layer as the lower layer. Then, the oil-water separation operation is performed by discharging the moisture 67 from the lower water layer while discharging the oil 66 from the upper oil layer outside the apparatus.

  In the sludge recovery strainer of the present invention, the oil-containing sludge accumulated in the apparatus can be discharged out of the apparatus by rotating the screw (A) without exchanging the filter medium. Therefore, there is no problem that the fluidized sludge is transferred to the recovery tank, unlike the conventional oil tank co-oil cleaning method.

  Further, among the embodiments of the method for using the sludge recovery strainer of the present invention, the residue of the oil-containing sludge according to the oil-recovery step is treated using the screw-type oil-containing sludge treatment device. Since the oil content in the sludge can be extremely reduced, the residual sludge can be disposed of as general waste.

  ADVANTAGE OF THE INVENTION According to this invention, the removal of the sludge in oil can be performed easily in the co-oil washing | cleaning method of an oil tank.

1, 1a, 1b Sludge recovery strainer 2 Screw shaft (A)
3 Screw blade (A)
4 Screw (A)
5 Inner cylinder (A)
6 Outer cylinder (A)
7 Stopper (A)
8 Oil supply side flange 9 Oil containing sludge discharge side flange 10 Oil supply port 11 Steam or cleaning water supply port 12 on the outer cylinder side Oil containing sludge discharge port 13 Oil discharge port 14 Oil containing sludge discharge chamber 15 Oil containing sludge discharge gap 18 Inner cylinder (A) Tube end 19 on the oil-impregnated sludge discharge side Tube end 20 on the oil supply side of the inner tube (A) Tube end 21 on the oil supply side of the outer tube (A) Tube on the oil-containing sludge discharge side of the outer tube (A) End 22 Oil discharge gap 25 Diameter of screw blade (A) 3 Pitch 40 of screw blade (A) 3 Water vapor 41 Oil 42 injected into oil-containing sludge Oil 42 after filtration 43 Oil-containing sludge 50 Oil tank cleaning system 51 Oil tank 52, 52a, 52b Oil transfer pipe 53 Recovery system pump 54a, 54b Oil supply pipe 55a, 55b, 55c, 55d Valve 56a, 56b Oil discharge pipe 57 Recovery tank 58 Crew conveyor 60 Oil-impregnated sludge treatment device 61 Oil-water separator 62 Residual sludge discharge pipe 63 Oil content discharge pipe 64 Moisture discharge pipe 65 Residual sludge 66 Oil content 67 Moisture 68 Oil-water transfer pipe 70 Oil water 71 Oil 72 before being injected into the oil-containing sludge Warmer 73 Oil discharger 74 Cleaning system pump 75 Oil transport pipe 76 Recovery vessel 77 Oil drain pipe 80 Cleaning system 81 Recovery system 131 Screw-type oil-impregnated sludge reduction device 132 Screw shaft (B)
133 Screw blade (B)
134 Screw (B)
137 Stopper (B)
138 Oil-impregnated sludge supply side flange 139 Residual sludge discharge-side flange 140 Oil-containing sludge supply port 141 Outer cylinder side water vapor supply port 142 Residual sludge discharge port 144 Residual sludge discharge chamber 145 Residual sludge discharge gap 147 Compressed space 148 Inner cylinder (B) Residual sludge discharge side cylinder end 149 Inner cylinder (B) oil-impregnated sludge supply side cylinder end 150 Outer cylinder (B) oil-impregnated sludge supply side cylinder end 151 Outer cylinder (B) residue sludge discharge side cylinder end 153 A portion 154 surrounded by the inner cylinder (B) 135 is a range 155 in which the water vapor supply hole 157 is formed 155 The diameter 156 of the screw blade (B) 133 The pitch 157 of the screw blade (B) 133 The water vapor supply hole 158 The screw shaft (B) One end 159 of 132 132 Other end 161 of screw shaft (B) 132 Length 16 of inner cylinder (B) 135 Length 163 from the cylinder end 149 on the oil-impregnated sludge supply side of the inner cylinder (B) 135 to the outer cylinder-side steam supply port 141 to the oil-impregnated sludge supply port 140 from the cylinder end 149 on the oil-impregnated sludge supply side of the inner cylinder (B) 135 Length 164 of oil-impregnated sludge moving direction 170a, 170b Water vapor 171 Oil-impregnated sludge 172 Oil water 173 Residual sludge 175 Exhaust gas 261a, 261b Apex 561a, 561b of screw blade (A) Apex of screw blade (B)

Claims (2)

A screw comprising a screw shaft, and a screw blade spirally provided on the outer periphery of at least a part of the screw shaft;
An inner cylinder having an oil passage hole and surrounding the screw;
An outer cylinder that is installed outside the inner cylinder and forms an oil discharge gap with the inner cylinder;
An oil supply port for supplying the oil into the inner cylinder;
Installed in the vicinity of the cylinder end of the inner cylinder on the oil-impregnated sludge discharge side, and a stopper for adjusting the discharge of the oil-containing sludge;
An oil discharge port for discharging the oil discharged into the oil discharge gap to the outside of the device;
An oil-containing sludge discharge port for discharging the oil-containing sludge discharged from the inner cylinder to the outside of the apparatus;
Drive means for rotationally driving the screw;
A strainer for collecting sludge.   The sludge recovery strainer according to claim 1, further comprising a supply port on the outer cylinder side for supplying water vapor or cleaning water into the outer cylinder.

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