DE3808341A1 - Adhesive cement composition - Google Patents

Abstract

An adhesive cement composition M) obtained by reacting A) a polymeric compound containing at least one -SH terminal group with B) a mixture containing alpha ) sodium perborate, advantageously sodium perborate monohydrate and/or sodium perborate tetrahydrate, having a mean particle size of up to 0.5 mm and preferably of about 0.06 mm, beta ) zinc oxide having a mean particle size of up to 0.5 mm and preferably of about 0.06 mm, and gamma ) a long-chain polymeric epoxy compound, preferably a long-chain polymeric aliphatic epoxy compound, where the polymeric epoxy compound has a viscosity in the range from 2000 to 4000 mPa.s and an epoxy equivalent weight of 400-500, and C) a catalyst K) containing an amino group, preferably a tertiary amino group. The adhesive cement composition M) can be used for the construction industry.

Description

The invention relates to a cement compound M), obtained by reacting

• A) a polymeric compound having at least one -SH end group with a mixture
• B) containing
  • α ) Sodium perborate, preferably sodium perborate monohydrate and / or sodium perborate tetrahydrate having an average particle size of up to 0.5 mm and preferably of about 0.06 mm, the borates having the property of 20% to 90% of the -SH end groups mentioned under A) to condense polymeric compounds,
  • β ) zinc oxide having an average particle size of up to 0.5 mm and preferably of about 0.06 mm, the zinc oxide having the property of condensing 5% to 60% of the -SH end groups of the polymeric compound mentioned under A) and
  • γ ) a long-chain polymeric epoxy compound, preferably a long-chain polymeric aliphatic epoxy compound, wherein the polymeric epoxy compound has a viscosity range of 2000 to 4000 mPa · s and an epoxy equivalent weight of 400-500, and the polymeric epoxy compound has the property of 1 to 50% of -SH End group of the polymer compounds mentioned under A) and optionally
• C) a catalyst K) having an amino group, preferably one tertiary amino group.

As polymeric compound A), which are mostly known, with at least -SH end groups are advantageously those with one or more bi- and / or trifunctional -SH-terminated polymeric compounds, in particular polyether compounds A₁), hydrocarbon polymer compounds A₂), Polysulfidpolythiolpolymerverbindungen A₃), Polyalkylensul fidpolymerverbindungen A₄) or polyurethane compounds A₅) or mixtures such compounds, wherein these polymeric compounds have a molecular weight have greater than 1000 (Ullmanns Encyklopadie der Technischen Chemie, 4. Edition, Volume 14 (1977)).

The cement mass M) is advantageously free of solvents, for example free of water and / or organic solvents; she can fillers, like  Calcium Carboant, Titanium Dioxide, Sulfur Blossom, Stabilizers, Plasticizers, such as (1-4C) alkyl benzyl phthalates, e.g. Butylbenzyl phthalate, plasticizer, such as Chloro-paraffin plasticizers, retarders, dyes or known UV protectants contain. The putty compositions M) obtained according to the invention have a Tensile stress value less than that at -20 ° C at 100% elongation double tension value at + 20 ° C. The resilience of the putties M) after a temperature change storage in air between + 20 ° C and + 80 ° C and in the water at + 20 ° C and then 24 hours of 100% elongation from 10% to 80%, preferably by 50%.

Another object of the invention is a method for producing the cement composition M), characterized in that reacting A) with B), optionally in the presence of a catalyst K) at temperatures of 5 ° C to about + 60 ° C, or crosslinked , In this case, it is possible to obtain the cement compound M) if, if appropriate in the presence of K), either A) is condensed in the presence of α ) and then β ) is added and condensed and then γ ) is used to carry out a condensation or addition reaction, or condensed in the presence of ( α + β ) and then performing an addition reaction with γ ), wherein the addition reaction of γ ) with the polymeric condensed compound A) in the presence of ( α + β ) with a polymeric epoxy resin compound having a viscosity range of 2000- 4000 mPa.s and an epoxy equivalent weight of 400-500. Long-chain polymeric-aliphatic epoxy compounds may have 6-24 C atoms, advantageously 8-10 C atoms in the aliphatic chain.

The process is characterized in that the catalyst is a Amino, advantageously one, having at least one tertiary amino group Compound used such as hexamethylenetetramine, and Although advantageous in an amount of 0.1 to 2.0 parts by weight K) to 100 Parts by weight of the polymeric compound A). M) is advantageously obtained uniform mixing of B) as hardener combination to A).

Another object of the invention is the mixture B), optionally containing a catalyst K); the mixture B) is used as a crosslinking agent or curing agent to form the cement composition M) by reacting B) with A), if appropriate in the presence of a catalyst. The mixture B) containing the compounds α ) and β ) can be advantageously obtained by comminuting a sodium perborate and zinc oxide in the same process at a temperature below + 40 ° C and advantageously homogenized with, for example, calcium carbonate as the filler of ultrafine grain size, preferably of about 75 nm, in an amount of 2 to 15 wt .-% based on the sum of the products ( α + β ). Component B) may contain auxiliaries or fillers as listed under A) or the cement compound M).

A good putty M) z. B. as a joint sealant of 100 parts contains next known fillers, plasticizers, retarders and other additives advantageous as A)

3 to 36 parts of a polymeric compound having at least one SH end group and as B)
5 to 20, or 5 to 15 and preferably 13 parts B).

Component B) contains advantageous

190 to 360 parts α )
20 to 190 parts β )
and 10 to 100 parts γ ).

In general, that per 100 parts of thiol groups in the polymer A) about

20 to 90 parts α )
5 to 6 parts β ) and
1 to 50 parts γ ) are to be reacted.

The putties M) can be used as sealant or adhesive, neutron shielding compound, as a reversible deformable mass, coating material, potting compound or jointing compound or for the construction industry in civil engineering and / or civil engineering. The putty can be registered for example by means of pressure, spraying or brushing into cavities and, for example, be glued to concrete. Polysulfide sealants A) are in Ullmann's Encyclopedia of Industrial Chemistry, 4th Edition, Volume 14 (1977), in particular pages 261-265 known. In this literature, information on plasticizers, dyes, retarders, adhesion promoters, active and inactive fillers are listed. As state of the art, lead oxide or manganese dioxide has hitherto been used for component B) (hardener combination), see the above Ullmann literature. Lead compounds are known to be toxic and the manganese compounds act after a short period of application as facade polluters. The hardener combination according to the invention α ), β ), γ ) is neither toxic nor does it pollute the concrete or façade elements, even after a relatively long time.

Example 1

For the preparation of a curing mixture B) are used in a laboratory mixing plant, equipped with anchor and dissolver stirrer

5 g of aliphatic epoxy resin γ ) with a viscosity of 2800 mPas and an epoxy equivalent weight of 420 submitted
and with
20 g of hexamethylenetetramine mixed.

To the resulting mixture are added in portions

190 g sodium perborate monohydrate α ) and
190 g of zinc oxide β )

mixed and stirred.

When the components are evenly distributed, the whole mass will be on rubbed on a cooled 3-roll mill and homogenized, whereupon make sure that the melt temperature does not rise above 40 ° C.

To form the putty M), the procedure is as follows:

100 g of the total commercial mass "Thiokol R", LP 32, Thiokol Chem. Corp., in addition to known fillers, such as plasticizers, retarders and other additives
Contains 36 g of a polysulfide polymer compound,

be with 13 g of the previously prepared curing composition B) with a Spiral stirrer intimately homogenized. You get a white-colored, soft but Stable jointing compound, which is suitable for overhead application is.

The material properties of the obtained ready-to-use putty M) were tested on the basis of DIN 18 540:

Processing at room temperature: more than 3 hours,
Stability: very good
Curing at room temperature: 3-4 days
Glass transition temperature range: from -43 ° C to -53 ° C

Fracture: cohesive failure
Recovery: 70% after 24 hours of relaxation.

The determination of the recovery capacity was carried out according to the following parameters.

Joint dimensions: 50 × 15 × 15 mm
Joint flank: aluminum.

Alternate storage after the two-week shift in normal climate

3 days 70 ° C air 1 day 23 ° C water 3 days 70 ° C air 1 day 23 ° C water

The removable storage was carried out 3 times. The bias of 100% was run for 24 hours.

A similarly good putty M) is obtained when in Example 1 at

• γ ) 543 g of butyl benzyl phthalate and at
• β ) 50 g precipitated calcium carbonate coated with calcium stearate and having a maximum particle size of 75 nm

admits.

example 2

A putty M) is prepared as described in Example 1.

Curing compound B₁) contains

100 g of epoxy resin (as in Example 1)
10 g of hexamethylenetetramine
360 g sodium perborate monohydrate
20 g of zinc oxide.

A similarly good curing compound B₂) is obtained if B₁) in addition 367 gr. Chloroparaffin plasticizer with a chlorine content of 55% and 140 g Calcium carbonate adds.

To form the putty M), the procedure is as follows:

100 g of the total commercially available polysulfide "Thiokol R" LP 2, in addition to 8 g of titanium dioxide, 1 g of sulfur bloom, 1.5 g of UV protectant, 30 g of calcium carbonate, 29 g of chloro-para-plasticizer
Contains 20 g of a Polysulfidpolymerverbindung LP₂,

are mixed with 10 g of the curing composition B₁) as in Example 1.

This gives a ready-to-use putty which is flowable, which as self-leveling potting compound or coating material can be used can.

After 3 days of crosslinking at room temperature to obtain a rubber-elastic Product with a glass transition temperature range of -40 ° C to -50 ° C. Is replaced in place of 20 g LP₂ compound, 10 g of a polysulfide compound LP₃ used or a mixture of LP₂ plus LP₃ gives a similarly good Putty.

example 3

A putty M) is prepared as described in Example 1. Hardening compound B₃) contains:

10 g of epoxy resin as Example 1
240 g of sodium perborate tetrahydrate
140 g of zinc oxide
10 g of hexamethylenetetramine.

A similarly good hardening compound B₄) is obtained if you at B₃) in addition

300 g butyl benzyl phthalate,
270 g of chlorinated paraffin softener
20 g calcium carbonate

admits.

To form the putty M) 20 g of tetramethylthiurandisulfide with 1000 g the curing compound B₃) or B₄) mixed.

Claims (10)

1. Kittmasse M), obtained by reacting

• A) a polymeric compound having at least one -SH end group with a mixture
• B) containing
  • α ) sodium perborate having an average particle size up to 0.5 mm, and preferably about 0.06 mm,
  • β ) zinc oxide having an average particle size up to 0.5 mm, and preferably about 0.06 mm, and
  • γ ) a long-chain polymeric epoxy compound, preferably a long-chain polymeric aliphatic epoxy compound, wherein the polymeric epoxy compound has a viscosity range of 2000 to 4000 mPa · s and an epoxy equivalent weight of 400-500, and optionally
• C) a catalyst K) having an amino group, preferably a tertiary amino group.

2. Mixture B) according to claim 1, optionally containing a catalyst K). 3. Use of the mixture B) (as crosslinker or curing agent) for Formation of the putty composition M) by reacting B) with A), optionally in Presence of a catalyst K). 4. A process for the preparation of the cement compound M) according to claim 1, characterized characterized in that A) with B), optionally with a catalyst K) at temperatures of + 5 ° C to 60 ° C. 5. A process for the preparation of the cement composition M) according to claim 1, characterized in that optionally in the presence of K) either A) in the presence of

• α ) condenses and then
• β ) admitting and condensing and then carrying out an addition reaction with γ ) or optionally condensing in the presence of ( α + β ) in the presence of K) A) and subsequently carrying out an addition reaction with γ ).

6. Mixture B) of compounds α ) and β ) according to claim 2, characterized in that comminuting a sodium perborate and zinc oxide in the same process at a temperature below + 40 ° C with concomitant use of calcium carbonate of ultrafine grain size, preferably of about 75 nm in an amount of 2 to 15 percent by weight based on the sum of the products ( α + β ). 7. The method according to claim 4, characterized in that as a catalyst K) hexamethylenetetramine used. 8. Process according to Claims 4 and 7, characterized in that 0.1 to 2.0 parts by weight of a catalyst K) per 100 parts by weight of polymeric compound A) is used. 9. Use of the cement compound M) as a sealant or adhesive, neutron radiation shielding mass, as a reversible deformable mass, Coating compound, potting compound or jointing compound. 10. Use of putty M) for the construction industry in civil engineering and / or civil engineering.