JPS59187078A - Muddy water composition for boring - Google Patents

Abstract

PURPOSE:A muddy water composition for boring having improved reducing ability of water loss, obtained by adding a specific alkali metal salt of sulfoethyl cellulose as an essential component to specified muddy water for boring. CONSTITUTION:Muddy water for boring containing a monovalent salt and/or a polyvalent salt is blended with preferably 0.1-1.5wt% alkali metal salt of sulfoethyl cellulose having 0.5-2.5 substitution degree and 5-5,000cps viscosity at 1wt% aqueous solution, to give the desired muddy water for boring. EFFECT:Preventing collapse of wall of oil well and gas spouting.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a muddy water composition for polling which has an excellent ability to reduce water loss.

In oil well drilling technology, it is necessary to use mud compositions. Mud water acts as a lubricant for the drill stem, as a carrier for transporting cuttings from the bottom of the well to the ground surface, as a coolant in the drill pit, and as a filter on the walls of the well to prevent it from collapsing.
It is used to form er cakes (mud walls). In order to properly perform these important functions, muddy water must always have water loss reducing ability, stable viscosity, and thixotropic properties.

Na-CMC has been widely used as a conventional water loss reducing agent. In this case, the water used for muddy water may be either fresh water or seawater, and in the case of seawater muddy water, Na-CM
Salt tolerance can be imparted simply by increasing the degree of substitution (DS) of C.

However, in recent years, oil wells have become deeper, and it is required to drill underground layers that contain large amounts of polyvalent salts such as CaCl2.

Furthermore, the muddy water effective for 5hale transport excavation is ca (
Since it consists of a saturated aqueous system (p)I>10) of (Oft) 2, conventional Na-CMC cannot be expected to act as a water loss reducing agent at all. The same holds true even if the amount of Na-CMC added is simply increased.

Therefore, one object of the present invention is to provide a muddy water composition that has an excellent ability to reduce water loss even in a muddy water system containing a large amount of such polyvalent salts.

Still another object of the present invention is to provide a muddy water composition that also has the above-mentioned properties and has appropriate properties in a wide range of pl+. The amount of water loss reducer added is 2p for high-temperature concentration muddy water system.
Pb (0,571% by weight) is common, and preferably the water loss is 20 m 12 or more with this addition amount. The smaller the water loss, the better.

In view of the above-mentioned current situation, the present inventors have made efforts to obtain a stable water-soluble i-tar loss reducing agent for polling muddy water containing polyvalent salts or both polyvalent salts and monovalent salts. As a result of research, we have arrived at the present invention.

That is, the polling slurry containing at least one of a -valent group or a polyvalent salt has a degree of substitution in the range of 0.5 to 2.5, and a 1% (by weight) aqueous solution viscosity of 5 to 5,000.
The present invention provides a mud water silk composition for poling, which is characterized by containing a sulfoethyl cellulose alkali metal salt (cp) as an essential component.

Next, the structural formula of the repeating unit of the sulfoethyl cellulose alkali metal salt (provided that the degree of substitution is 1.0) is shown.

(in the formula, or glucose residue (II 611°02),
11 is an integer, and M is an alkali metal. ) The degree of substitution is the average number of substitutions per unit of glucose, which must be enough to make the molecule water-soluble.

In the present invention, the degree of substitution of the alkali metal salt of sulfoethylcellulose is particularly preferably in the range of 05 to 2.5.

When the degree of substitution is less than 0.5, the solubility is poor and the effects of the present invention cannot be exhibited to a certain degree.

A degree of substitution of 2.5 or higher is selected because if the degree of substitution is higher than that, industrial production becomes technically and economically difficult.

The viscosity of the sulfoethylcellulose alkali metal salt is not particularly limited, but as long as it has a viscosity of 1% aqueous solution or 5 to 5,000 cp, the object of the present invention can be achieved within minutes.

In such a high-temperature muddy water system, the degree of substitution rather than the viscosity greatly influences the ability to reduce water loss.

Monovalent salts contained in polling mud include N,
1+, t<+, l, i+, Nll 4+ etc. as N, :lC1, KC'', LjcJ, Nll 4
C1, etc., and the polyvalent salt is not limited by its solubility, but may be contained in the mud as a polyvalent salt source or solid substance having a solubility or higher.

For example, as a Ca2+ source, calcium chloride (
Cacl 2 ), calcium sulfate 1-(CaS
04 ), calcilla 11 acetate (Ca(c 2 I
f 302 )), calcium form 1-(Ca(C
1102) 2), Calcium nylon (Ca8N
03) 2), calcium gluconeh (Ca(
C1l 2011 (CIIOH) 4 (:00)2)
,and so on.

Similarly, as Mg2+ sources, Mgcl2, MH5O
4, Mg(f211302), Mg(CIIo2
) 2, Mg(No 3) 2, 8g (C11
2011 (CIIOIri 4COO) 2, tJa
“As ten sources, 8acJ 2, Ha(OH) 2,)
3aSO4, Zn”↓ source, Znc, 1.2,
There are Zn(Oll) 2, Zn5o4, etc., and A
L” source dojite AlCl3 ・61120.AI(OR
) s, AJ(SO4)2, AL(CH3CO
2) I'ecl 3 as a source of 3, l'e
61120, Fe(011)3, Fe2(504
)3, l'c(NO:+)3, etc., and Cr3″-source, Cr(NO3)3, Cr(Cll3
co2)3, CrBr3, Crcl'3
, Cr(Oll) (NO3) 2 , Cr((l
tl) 2 (NO3) and the like, but are not particularly limited thereto.

The effects achieved by the present invention are as follows.

1. It has excellent ability to reduce water loss even in muddy water with high concentration of polyvalent salts (more than 10,0001-1 pm).

Contains both 2- and polyvalent salts and has a high concentration (1
It exhibits excellent water loss reduction ability even in muddy water with a concentration of 0,000 ppm or less.

3. The mud wall of the mud water composition of the present invention is thin and strong. Therefore, collapse of the oil valve wall can be prevented.

4. The muddy water composition of the present invention has initial gel strength (Inj),
aJ gelstrength) is low and gas bu
Since the bbJ-es (air bubbles) are quickly removed from the muddy water, it does not become (Hascl). That is, b J,
o v o u (gas blowout) can be prevented.

The amount of sulfoethylcellulose alkali metal salt added to the muddy water composition of the present invention is preferably 0.1 to 1.5% by weight.

EXAMPLES The present invention will be specifically explained below using examples.

(However, parts and % are based on weight.) Example 1 Aquagel (trade name manufactured by U.S. Ben 1 Henai 1-1 manufactured by U.S. I1Aroid, hereafter 1z times) was added to 100 parts of fresh water.
The sulfoethylcellulose Na salt (hereinafter referred to as Na-5IEC) in the present invention was added to 350 mQ of muddy water having a composition of 8° ( ) parts and (, a (011) 2 71.00 parts).
PPb (0,286tyL%) or 2PPb (0,5tyL%)
7tyt%).

The properties of the muddy water were tested. The results are shown in Table 1.

The muddy water test was carried out in accordance with the method of API (American Petroleum Institute), and a F a n v f viscometer was used.

Water loss reducing agent Na-5EC (1
) substitution degree (1) S) is 0.83.1% aqueous solution viscosity is 9
3 cp.

In addition, the degree of substitution (IJs) of Na-5 + EC (2) is ■,
The viscosity of the 10.1% aqueous solution is 357 cp.

The degree of substitution of the control Na-2)EC(3) is O,:'18.
The viscosity of a 1% aqueous solution is 223CP0.In addition, as a comparison of conventional salt resistance, - 1]S (carboxymethyl group) of C, MC, which has a high degree of substitution and is generally used in seawater mud, etc. = 1.07.1 % aqueous solution viscosity is 305
0cp.

As is clear from Table 3, conventional water loss reducing agents,
Na-CMC1 and also Na-S which is outside the scope of the present invention.
EC is muddy water with high polyvalent salt and high-valent group concentration (composite salt muddy water)
Inside, no ability to reduce water loss can be expected.

On the other hand, Na-5IEC in the present invention exhibits a very effective ability to reduce water loss. For example, Na-5
The water loss of the muddy water to which 2,00 ppb (0,571%) of EC was added was about 1/10 of the muddy water to which the same amount of mud and Na-CHc was added.

Therefore, the muddy water composition of the present invention shows excellent effects in high-concentration composite board muddy water.

Na-S[EC in the present invention is an excellent water loss reducing agent, and at the same time, the gel 1-length at that time can be used in muddy water, muddy water with Na-side added, and even low water loss outside the scope of the present invention. The degree of substitution is lower than that of muddy water to which Na-St:C is added, and the muddy water composition is excellent in that it does not become gas cut.

Furthermore, the usage amount is also the same as the general usage amount (2p
Pb=0.571%), l/1 of water loss due to mud addition
0, specifically, as shown in Table 3, 10+n&l or less means that the muddy water composition of the present invention is very excellent in practical terms.

Example 3 A mud water test was conducted using 100 parts of clear water using vented Aquagel (produced in the United States). As a control, Na-CMC added mud water was tested. The results are shown in Table 4.

Test J method is the same as Example 1.6 The water loss reducing agent Na-SEC according to the present invention is
Degree of substitution: 1.06, j% aqueous solution viscosity: 121 cp.

The control Na-CMC has a substitution degree of 1.07.1% and an aqueous solution viscosity of 3060p.

The loss reducing agent Na-CMC has no ability to reduce water loss at all in high A13-containing mud water.

On the other hand, Na-SEC in the present invention exhibits a very effective ability to reduce water loss even when added in a small amount. For example, when the amount added is 1 ppb (=0°286 L%), the water loss is 1/8.2 ppb (=0.
571%), it is 1/19.

Also, regarding the thickness of the mud wall, the Na-5EC-added mud of the present invention is thin and strong, which is another major feature, as in Example 1.2.

Furthermore, Example 1 is a strongly alkaline muddy water (pH>12), but this example is a strongly acidic muddy water (pH<2.5),
It is clear that the Na-SEC in the present invention can be used in a wide pl+ range.

Example 4 Table 5 The properties of the added dissolved mud of C were tested. Na as a control
- CMC added mud was tested. The results are shown in Table 6.

The test method was the same as in Example 1.

The water loss reducing agent Na-SEC according to the present invention is
The degree of substitution is 1.30.1% aqueous solution bottom is 1000 cp.

The control Na-CMC has a degree of substitution of 2 and a 10.1% aqueous solution viscosity of 500 cp.

As mentioned above, in muddy water systems with high concentrations of monovalent, divalent, and trivalent salts, the conventional water loss reducing agent Na-C is
It has almost no ability to reduce water loss. On the other hand, in the present invention, even a small amount added exhibits a very effective ability to reduce water loss. As shown in the examples,
The water loss when the amount added is 1 ppb (=0.286wt%) is 1/6.2ppb (=0.571w) of the added mud.
t%), the thickness of the mud wall was reduced to 1/14, and the mud wall thickness of the present invention is also characterized by being thin and strong, similar to Examples 1 and 2. Furthermore, in Example 1, the water was strongly alkaline muddy water (pH > 12), but in this example, it was strong acidic muddy water (pH < 1.0). Another characteristic is that it has high viscosity.

Applicant No. 1 - Industrial Pharmaceutical Co., Ltd. Procedural Amendment May 10, 1980 To the Commissioner of the Patent Office■, Minor Case Notification 1981 Patent Application No. 60392 2, Name of the Invention Polylip Man Sludge Water Composition 3 , Relationship with the person making the amendment Patent applicant 4 Date of amendment order Voluntary amendment 5 Number of inventions increased by the amendment 6 Column 7 for detailed explanation of the invention in the specification subject to amendment 7 Contents of the amendment The present application is amended as follows based on the original specification.

■) Correct rcacJ2J on page 2, line lυ of the specification to rcacl 2 J.

2) Same, page 2, line 12 [..., for transporting and excavating 5 bales...] was replaced with "..., for excavating swellable 5 hales..."
``...'' Correct.

3) Same, page 3, line 4 It says "high temperature concentration muddy water system" Corrected to "high salt concentration muddy water system."

4) Same, page 5, line 2-3 It says "The viscosity is better than that..." [Rather than viscosity…]” and “J pressure.

5) Same, page 5, line 7 - line 8, rNacl, KcJ, LicL, NlI4C1, etc.
-...” is replaced by rNacI, KCI, LiC1, N
Corrected as i14CI etc.--J.

6) Same, page 5, line 13 r (Cacl 2 ) J and r (CaC12) J
I am corrected.

7) Same, page 5, line 15 section a (c211:+02)), calcium form 1
-” means r(Ca(C2H302)), calcium form-1
・” iT corrected.

8) Same, page 5, line 16 r (Ca8N03) 2),” is replaced by r (C
a(NO3) 2 ),” is corrected.

9) Same, p. 5, line 19, replace rMgcL 2 J with rMgcl 2 J.

10) Same, page 6, lines 1-5 r, = ..., as a Ba2 source, Bacl2,
As a source of Ba(Oll)2, BaSO4, Zn2,
There are Zncl 2, Zn(011) 2, Zn5o 4, etc., and Alcl:i'61120 as an Al' source.
, A1 (Off) 3. AL(504)2, AL
(C1ls CO2)3, Fcc as a Fe3 source
L 3 ・61120 ・--J is written as ``..., BaC12, Ba(
OR) 2, BaSO4, Zn” + as a source, Zn
There are C12, Zn(OH)2, Zn504, etc., and AlCl3' is used as an A13+ source.

11) Page 6 of the specification, line 8 rcrcl, 3, J is rCrCJ 3,
J and power ■ Yu.

12) Same, page 7, line 3 [...-, so please replace gasJ with [...]
・・・・・・AsJ and Hf come out of the muddy water.
jE.

3 4 15) Same, in Table 2 on page 10, r (13 onije) J is written as r (13 en
J and d] Correct.

16) Same, page 13, line 8, correct rAlcl 3 J to rAlcJ, 3 J.

17) Same, on the last line of page 13, ``is 3060p, J'' is changed to ``is 3060cρ.'' by Hf.

18) Same, page 14, line 9 from do. Correct the text "High A1" to "High ^] 3 +".

19) Same, in Table 5 on page 15. Correct rNacJi to rNaclJ.

rFe(NO3) J
It's more than just crying out

Claims (1)

[Claims] The muddy water for polling contains at least one type of monovalent salt or polyvalent salt, and the degree of substitution is in the range of 0.5 to 2.5,
and 1% (by weight) aqueous solution viscosity 5 to 5,000 (
A mud water composition for polling, characterized in that it contains a sulfoethylcellulose alkali metal salt, which is cp), as an essential component.