RU2701670C1 - Device for dehydration and packing of drilling oil sludge - Google Patents

Abstract

FIELD: waste processing and disposal.

SUBSTANCE: invention relates to disposal of drill cuttings, as well as to processing of wastes into construction materials. Device includes a filtering column for sludge pulp dehydration installed on a frame-base for subsequent loading into sealed bags-containers or loading into a dump transport facility. Column is equipped with a pneumatic hose which, after filling the column with sludge pulp, is filled with compressed air. Sleeve presses pulp to filtration walls of column, which provides rapid dehydration of slurry pulp for subsequent shipment by dump transport or packing in sealed bags-containers for further use as building blocks or disposal (burial) on underwater dredging areas in offshore drilling. After dehydration, the sludge is fed through a loading unit of the filter column into a sealed bag-container pouch arranged under the column on a sliding wheel carriage. Bags-container have external power shell of strong synthetic fabrics reinforced with slings and equipped with rigging slings for unloading from carriage, as well as loops for fixation of empty bags on carriage. Inner sealed shell is made of co-extrusion polyethylene film with barrier polyester layer or without it by thermal welding method and is a cubic bag with a conical upper part ending with an open hose for connection to the loading branch pipe of the filter column and subsequent sealing of the sludge inside the container shell.

EFFECT: increased rate and depth of filtration.

6 cl, 3 dwg

Description

The invention relates to the field of treatment of drill cuttings, their disposal and disposal during drilling of oil and gas wells, as well as to the field of processing waste into building materials.

The prior art devices and methods for processing oil sludge without the use of accumulative sludge pits, namely various types of filters, presses and separators for dewatering slurry pulp, as well as methods for thermal and chemical neutralization of oil sludge.

The prototypes include the following inventions:

The general disadvantages of the solutions presented in the analogues and prototypes are as follows:

- Low flow rate, sensitivity to the composition of the slurry pulp, climatic sensitivity and mechanical complexity of the units during dewatering of sludge using press filters and belt filters.

- Low flow rate, high demand for external energy sources and the mechanical complexity of the units and complexes of the pyrolysis (thermal destruction) method of disposal of oil sludge.

- The need for volumetric accumulators, a long period of consolidation of sludge, the inability to use at low temperatures, and the inability to move the dehydrated sludge to the disposal site without bulk excavation using filter methods using pillow-shaped geotextile containers.

The closest prototype for the claimed invention is patent RU 2481143 "Method for dewatering slurry pulp."

This decision provides for the injection of slurry through a slurry pipeline into a bag of a pillow shape, which is located in the drainage pan for gravity filtration.

The filtrate is forcibly pumped out of the sump for subsequent cleaning (processing) and the dehydrated sludge accumulates in the bag as it is periodically filled with pulp.

After the bag is completely filled with dehydrated sludge and then held in the sump for consolidating the sludge for several months, the bag shell is opened and the sludge is unloaded by an excavator onto a transport vehicle for transportation to the place of disposal (burial).

The main disadvantages of this solution are as follows:

- low productivity of the filter cartridge-shaped pillow by the flow of sludge due to the absence of excess pressure of the pulp column, and also due to the exclusion from the filtering process of the lower canvas of a flat shell lying on the bottom of the pan;

- the need for additional space to accommodate a large number of pallets with filter filters during a long process of consolidation of sludge;

- the impossibility of applying the method at low temperatures;

- the impossibility of moving dehydrated sludge directly in bags for subsequent disposal or use as a building material.

The technical result of the proposed group of inventions is to increase the speed and depth of filtration on a vertical filter column and the possibility of block, safe disposal of dehydrated sludge, and the liquid filtrate is discharged for purification and use on the rig, and the dry residue of the sludge is poured into a strong and sealed soft container equipped with rigging loops and reinforcement slings, which is placed on the platform of the sliding carriage for output from under the filter column and subsequent movement to the place of accumulation or use as a building block, or for safe disposal at an underwater range during offshore drilling.

The claimed technical result is ensured by the design of a device for dehydration and packaging of drilling oil sludge, which includes a filtering column for dehydration of pulp of drill sludge, which is a hollow cylindrical structure placed on top of a steel frame whose design allows you to freely place dump trucks underneath for removal of dehydrated sludge to the place of disposal or a carriage with an airtight bag-container for packaging sludge and subsequent use Nia containers with the sludge as building blocks.

The filter column is made in the form of a cylindrical shape open in the upper part of the hollow structure made of a collapsible strong steel frame whose walls are made of woven steel mesh with a removable insert made of synthetic filter fabric.

A sealed pneumatic sleeve is placed centrally inside the filter column, into which compressed air is supplied to the column after filling the column with a slurry pulp. Inflating, the pneumatic sleeve presses the sludge against the filter walls of the column, significantly reducing dewatering time.

Outside, the column is equipped with a sealed shell of waterproof material to drain the filtrate into the nozzles and maintain a positive temperature inside the structure in the winter.

The lower end of the filter column is equipped with a conical funnel with a slide gate valve and a nozzle for attaching the neck of the container bag.

The container bag includes an external power shell and an internal airtight shell.

The external power casing is made of durable synthetic fabric, equipped with reinforcing slings, rigging slings for unloading the bag from the carriage and then loading the bag onto the transport, holding container bag slings on the brackets of the carriage racks, and also with web-valves for durable container packing after filling with slurry.

The inner sealed shell is made by heat welding from a co-extrusion polyethylene film with or without a barrier polyester layer and is a cubic bag with a conical upper part ending with an open sleeve for connecting to the loading nozzle of the filter column and subsequent sealing of the sludge inside the container’s power shell.

Oil sludge pulp is fed into the column from the storage hopper using a slurry pump via a slurry pipeline or a screw conveyor.

A mixer can be located in the storage hopper for even distribution of coagulants in the slurry pulp.

Slurry is fed through the slurry pipeline to the top of the filter column. Sludge dewatering begins immediately from the moment the pulp is fed into the column. The liquid filtrate passes through the layer of the filter sleeve and flows down the wall of the column to the drain pipe for pumping and subsequent post-treatment, injection into the formation or for preparing drilling mud.

After filling the column with sludge, the pneumatic sleeve located inside the column is filled with compressed air and uniformly presses the sludge to the inner surface of the filter column, significantly reducing the time for dehydration of the sludge, compared with gravity sludge.

Under the filter column is the body of a dump truck or carriage with a container bag attached to it.

After dewatering the sludge, the pressure in the pneumatic sleeve is relieved, after which the sludge is fed through the gate valve and the pipe of the conical end of the column into the sealed liner of the container bag.

The filled bag-container is rolled out on the carriage from under the filter column. Further, the sleeve of the sealed liner is twisted and tied. Valve-webs of the external power shell cover the upper face of the cubic container and are fastened with slings by puffs or tied with ropes.

A bag-container filled with dehydrated sludge by means of a crane, or other lifting equipment (excavator, loader, etc.) for lifting slings is removed from the carriage for storage or loading and subsequent transportation to the place of disposal or use.

An empty bag-container is installed on an empty carriage for the next cycle of filling with dehydrated sludge.

Further, the solution is illustrated by reference to the figures in which

FIG. 1 is a General view of a device for dehydration and packaging of oil drill cuttings.

FIG. 2 - a bag-container for the packaging of oil drill cuttings.

FIG. 3 - an option for unloading dehydrated sludge into the body of a dump truck.

Explanation of the figures:

1. Cap to protect the filter column from precipitation.

2. Steel collapsible frame of the filter column.

3. External waterproof casing of the filter column wall.

4. Pulp line for the supply of sludge.

5. Pneumatic filter sleeve.

6. Steel frame-base installation.

7. Hopper drive-mixer oil drill cuttings.

8. Slurry pump.

9. A pipe for draining the filtrate from the conical base of the filter column.

10. A pipe for draining the filtrate from the cylindrical part of the filter column.

11. Carriage for placement, loading and unloading of a slurry bag-container.

12. The bag is a container.

13. Gate valve.

14. The carriage stand.

15. Water-permeable filter wall of the filter column.

16. A cable with a hook of a lifting device for removing the container bag from the carriage.

17. The rails.

18. Packed bag-container ready for unloading from the carriage.

19. Racks for fixing the container bag.

20. The outer shell of the container bag.

21. Bracket for fixing the slings of the container bag.

22. Lifting slings of a container bag.

23. Loops of the container bag for fixing on the brackets of the carriage racks.

24. The base of the carriage.

25. Filter column.

26. Cloth-valve external power shell bag-container.

27. The internal tight shell of the container bag.

28. Dehydrated sludge.

29. Tipper transport.

The device comprises a steel frame-base of the installation 6, on which is placed a steel collapsible frame 2 of the filter column 25, equipped with a permeable filter wall 15, consisting of a steel woven mesh and filter synthetic fabric, as well as a cap for protection against precipitation 1 of the filter column 25, external waterproof shell of the wall of the filter column 3, a pneumatic sleeve 5 of the filter column, as well as a slide gate valve 13 with a pipe for unloading dehydrated sludge from the filter column 25.

Drilled cuttings from the drilling machine through the tray enters the storage hopper-mixer of oil drill cuttings 7, in which, if necessary, coagulants are added to the cuttings and the cuttings are mixed with the coagulant. From the hopper of the accumulator-mixer 7, the drill cuttings are supplied by a slurry pump 8 through a slurry line 4 to the upper part of the filter column 25.

Immediately from the moment the filter column 25 is filled with sludge, water filtration begins through the permeable filter wall 15 of the filter column. After filling the filter column 25 to the nominal capacity, compressed air is supplied to the pneumatic sleeve 5 of the filter column 25, providing uniform pulp pressure against the permeable filter walls of the filter column 15. Under the influence of compressed air and gravity, the liquid filtrate is separated from the sediment.

After dewatering the sludge to a predetermined value, air from the pneumatic sleeve 5 is lowered and the dehydrated sludge is showered in the lower part of the filter column 25.

Through the branch pipes of the filtrate discharge 9, 10, the liquid fraction of the sludge is discharged to the drilling fluid preparation unit, or for additional cleaning, or for injection into the formation.

In the case of using a dump truck (Fig. 3), the transport body is placed under the feed pipe of the slide gate valve 13. The slide gate 13 opens to fill the body with dehydrated sludge and then transport it for disposal or use.

In the case of the use of sealed bag containers (hereinafter, Fig. 1 and Fig. 2) for the packaging of sludge, a bag-container 12 is fixed on the nozzle with a slide gate valve 13 for supplying dry sludge, which is previously placed on the carriage 11.

After installing the container bag 12 in its normal position, the slide gate valve 13 opens and the dehydrated sludge is fed into the inner sealed shell 27 of the container bag until it is full, after which the slide gate valve 13 closes. The neck of the sealed liner of the container bag is disconnected from the supply pipe of the slide gate valve 13 of the filter column.

The filled bag-container 12 on the carriage 11 is rolled out from under the installation. The sealed film liner of the bag-container 12 is twisted and tied. Cloths-valves of the outer power shell of the bag-container 26 are closed on the upper edge of the container and are fixed with tie straps or ropes.

For rigging slings 22, using a cable with a hook 16 of a lifting device (crane) or forklift, a filled and packaged bag-container 18 is removed from the carriage 11 for storage at the site or transportation to the place of disposal or use.

After unloading the filled and packed bag-container 18 from the carriage 11, the next empty shell of the bag-container 12 is placed on the brackets 21 of the racks of the carriage 14. The carriage 11 equipped with the bag-container 12, the carriage 11 is rolled (placed) under the slide gate valve 13 with the dehydrated sludge supply pipe. The neck of the bag-container 12 is fixed on the nozzle for supplying dehydrated sludge to perform the next loading cycle.

Claims (6)

1. Device for dehydration and packaging of oil drill cuttings, comprising a filter column for dewatering slurry pulp mounted on a base frame for subsequent loading into sealed bag containers or loading into a dump truck, characterized in that the filter column is equipped with a pneumatic sleeve, which after filling the column with slurry pulp is filled with compressed air, the sleeve presses the pulp against the filtering walls of the column, which ensures rapid dewatering of the slurry pulp for subsequent shipment by dump truck or packing in airtight container bags for the purpose of subsequent use as building blocks or disposal (burial) at underwater landfills during offshore drilling. 2. The device according to p. 1, characterized in that the permeable wall of the filter column is equipped with an external waterproof shell to collect the filtrate and protect the device from freezing in the winter. 3. The device according to p. 1, characterized in that a wheeled carriage is used for feeding sealed bag containers for loading, moving along the rails under the loading device of the filter column for filling with dehydrated sludge and from under the filter column for subsequent removal from the carriage of filled and packaged container lifting equipment. 4. The device according to p. 1, characterized in that the sealed bag containers contain an external power shell and an internal airtight shell. 5. The device according to p. 4, characterized in that the external power shell is made of strong synthetic fabric and is equipped with reinforcing slings, lifting slings for unloading and transportation, loops for fixing the container on the carriage, as well as upper flaps with tie straps or ropes for strong packaging of a container filled with dehydrated sludge. 6. The device according to p. 4, characterized in that the inner sealed shell is made of co-extrusion polyethylene film with or without a barrier polyester layer and is a cubic bag with a conical upper part ending in an open sleeve for connection to the boot the nozzle of the filter column and subsequent sealing of the sludge inside the power shell of the container.

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