NO144150B - Bleach, Sterilization, Disinfectant and Detergent Mixtures - Google Patents

Description

The invention relates to bleaching, sterilizing, disinfecting and detergent compositions containing a dry bleaching compound which provides active chlorine in water, prepared by a method which reduces the precautions associated with preparing such compositions in commercial quantities.

Bleaching, sterilizing and disinfectant mixtures

which uses active chlorine, has been produced in liquid form using aqueous solutions of sodium hypochlorite as a bleaching chemical which gives active chlorine in water. Dry bleaching compounds were used instead of aqueous solutions containing sodium hypochlorite in order to achieve increased stability (longer shelf life) and for convenience in handling, packing and shipping. Compounds which provide active chlorine in water include calcium hypochlorite, lithium hypochlorite and such organic compounds as 1,3-dichloro-5,5-dimethylhydantoin, trichloroisocyanuric acid, chlorinated trisodium phosphate, dihaloisocyanuric acids and their salts.

Use of haloisocyanuric acids and their salts is mentioned in US patent 2 913 460. Use of sodium dichloroisocyanurate is also described in US patent 3 035 056 and its related

the British patent 923 147.

Although chlorinated dry bleach compounds are used commercially, the problems associated with the manufacture of bleaching, sterilizing, disinfecting, and detergent compositions containing such compounds which evolve active chlorine are significant, and special precautions must be taken commercially to reduce the problems to a minimum.

A major commercial problem encountered during handling is due to the fact that such oxidizing chemicals can burn and evolve toxic and harmful gases during burning. In particular, sodium, potassium and calcium dichloroisocyanurate salts and other chlorinated dry bleach compounds, when exposed to a flame, spark or other high temperature source, begin to burn and continue to burn after the heat source is removed, until all material is incinerated. This phenomenon is referred to as self-sustaining and self-propagating decomposition.

Furthermore, certain organic auxiliaries for bleaching, sterilizing, disinfecting and detergent mixtures are not readily compatible with chlorinated, dry bleaching compounds. An example of such auxiliaries are cationic surfactants, especially quaternary ammonium compounds, which can react with and thereby initiate burning of certain chlorinated, dry bleach compounds.

Another problem associated with the manufacture of mixed- . ings that ..contain chlorinated dry bleach compounds are known as the dust problem. Fine particles (dust) form part of chlorinated, dry bleach compounds, and these particles tend to become electrostatically charged. The charged dust particles tend to accumulate in corners and crevices of the process equipment used to handle the chlorinated dry bleach. Accumulations of fine particles in and around the warehouse or other places where frictional heat is generated are particularly undesirable, as frictional heat can initiate decomposition. Precautions are taken to reduce such accumulations of dust in commercial operations to a minimum.

Therefore, commercial use of such bleaching compounds requires special precautions, especially if the compounds are stored in bulk and dispensed from a bulk container for mixing with auxiliaries for bleaching, sterilizing, disinfecting or detergent compositions. Such precautions for handling commercial quantities include: (1) shipping chlorinated dry bleaches in individual containers rather than as bulk cargoes;

(2) isolation of large quantities in a separate building which

has special fire protection equipment and fire extinguishing equipment;

(3) careful handling; and

(4) safety labeling on shipping containers. These precautions are intended to avoid accidental ignition of chlorinated dry bleach compounds with the resulting evolution of chlorine and other harmful gases.

The disclosure in US Patent 3,544,267 teaches the use of hydrated calcium hypochlorite as a solution to the substantial commercial need for a non-flammable chlorinated, inorganic, dry bleaching compound. However, the use of hydrated calcium hypochlorite (approximately the monohydrate) is not a satisfactory solution to the problem, as it burns when mixed with certain organic substances, as shown by its poor utilization in the proposed United States Bureau of Mines Method RI-7594

which will be discussed in the following. Furthermore, hydrated calcium hypochlorite introduces calcium ion into the solution, which is undesirable

as it increases the water hardness level.

The invention provides improved bleaching, sterilizing, disinfecting and detergent compositions comprising a mixture of sodium dichloroisocyanurate and detergent ingredients selected from the group consisting of detergent builders, anionic, nonionic or cationic surfactants and detergent fillers. The mixture according to the invention is characterized in that sodium dichloroisocyanurate is present in hydrated form, with an average combined water content of 11-14.1% by weight, where the detergent mixture may possibly contain a further 2% by weight of uncombined water. The fire risk is thereby reduced to a minimum.

Mixtures according to the invention are made by distributing the bleaching compound from bulk storage in the form of a non-flammable dihydrate of sodium dichloroisocyanurate into a mixing zone where the components are mixed.

The mixing of the components in bleaching, sterilizing, disinfecting and detergent mixtures can be carried out according to one of many known methods and is typically carried out in a commercial mixing equipment which mechanically mixes components that are fed into the equipment. The mixing and feeding of the components can take place continuously or periodically. Precautions to prevent dust accumulation are not necessary, as dihydrate particles generally have significantly reduced electrostatic charge compared to other chlorinated dry bleaches.

Definitions

When we talk about distribution here, we mean the regulated removal of material from a first zone to another zone, and this can take place continuously or periodically in any suitable amount (units of material).

A bulk storage area is a room where a significant amount of material is found in an essentially clean state. About. 4.54 kg or more is a significant amount for interpreter storage of a chlorinated, dry bleach because burning of ea. 4.54 kg or more results in the release of unacceptably high quantities of noxious gas requiring the evacuation of even a large building.

Mixing zone is a room where material is mixed.

Hazardous materials are intended herein to refer to such materials as, when tested in accordance with the United States

The Bureau of Mines proposed method RI-7594 has a flame propagation rate that is greater than the pure sawdust standard used in the method. Therefore, such a material improves rather than impairs the combustion of sawdust.

Non-flammability refers to a property of a material, namely the material's unsuitability to support flames separately. Specifically, when an external flame is brought into contact with a non-burning material and then removed, the material will not continue to burn, as evidenced by the flame extinguishing itself while unburned material remains.

Detergent builder is a material that has the ability to improve the cleaning ability and washing activity levels in detergent mixtures.

A chlorinated, dry bleach is a bleaching compound that develops active chlorine in water. Active chlorine is chlorine of that type. which is obtained by hydrolysis of the chlorine-containing compound to produce hypochloric acid (H0C1) and/or 0C1 ion depending on the system's pH value. Such end products from hydrolysis consist of , oxygen which has two negative charges, in combination, with a chlorine which must be positively charged. Such a positive chlorine ion is considered active chlorine. Active chlorine is obtained not only by hydrolysis of inorganic hypochlorite but also from N-chlorine compounds, e.g. chlorinated cyanuric acid, and other chlorine compounds containing an N-Cl bond in which position hydrolysis takes place.and cleaves the N-Cl bond and gives H0C1 and/or OCl~ ion.

If a chlorinated, dry bleach is stored as an essentially pure material in bulk quantities in excess of approx. 4.54 kg,

the burning of such material is dangerous and can seriously interrupt a commercial operation. The danger is not only due to the heat or flames that occur during the burning of the material, but a serious risk is caused by chlorine gas and other harmful gases that are developed during the rapid heat-induced decomposition of such material.-

There are many types of suitable bulk storage areas as material

can be distributed from. The choice of a specific type depends on what suits the user, such factors as the type of distribution means used, the quantities to be distributed and the type of shipping container in which the chlorinated, dry bleach is received. Often an integrated system is used with a single container which is designed to suit the production, shipping and user of the chlorinated dry bleach compound. Examples of such containers as that

chlorinated, dry bleach is shipped and stored in, and from which the chlorinated, dry bleach can be distributed, includes various transport containers, drums and the like. The distribution of chlorinated dry bleach directly from such a container transforms the container into a bulk storage zone during the distribution period. The distribution of material from such containers can be carried out with any suitable aids, e.g. conveyor belts, screw conveyors and manual or automatic bucket or scoop systems.

The best method for distributing the material from a bulk storage zone and then mixing the components is believed to consist of (1) storing the components in individual silos (bulk storage zone) that can be easily filled; (2) distribution of each component from its silo by means of standard aids such as a conveyor belt, a screw conveyor, gravity distribution aids or other similar apparatus which also transfers the material from the storage zone to a mixing zone, usually a commercial mixer, where the materials are added in the desired quantities and mixed to a homogeneous mixture. The mixture is then taken from the mixing zone and packed in a suitable unit, depending on the final use.

Typical adjuvants for bleaching, sterilizing, disinfecting and detergent compositions used in combination with a chlorinated dry bleach compound include a detergent builder, an anionic, nonionic or cationic surfactant and a detergent filler. Selection of specific excipients and their concentrations in a particular mixture depends on the specific application the mixture is to have. Examples of mixtures in which a chlorinated, dry bleach is used are detergent mixtures for automatic household dishwashers, mixtures for commercial dishwashers, scouring powders, household bleaches, commercial laundry bleaches, sanitizers, broad-spectrum biocides and products for general washing and hygiene. Typical recipes for detergent mixes containing a chlorinated dry bleach and typical auxiliaries are as follows:

Typical detergent builders include alkali salts of nitrile-triacetic acid, ethylenediaminetetraacetic acid, gluconic acid and citric acid. Other suitable excipients include polycarboxylates, organic phosphonates, alkali metal carbonates, bicarbonates, borates, silicates and cyanuric acid. ^-Suitable fillers used in such mixtures are well known and can be passive or of active use in the washing function or storage by means of e.g. pH adjustment. Examples of suitable detergent fillers are sodium sulphate, sodium chloride, borax, sodium carbonate or other carbonates.

Suitable surfactants for use in connection with the invention are:

1. Anionic surfactants suitable for use

in connection with the invention, includes both soap- and non-soap-containing washing compounds.

2. Non-ionic surfactants which are suitable for use in connection with the invention can be roughly defined as compounds which are aliphatic or alkylaromatic in nature, which do not ionise in aqueous solution, e.g. such as are available on the market under the trade name "Pluronic", further polyethylene oxide condensates of e.g. alkylphenols. 3. Cationic surfactants suitable for use in connection with the invention are compounds with one of the following formulas:

where R and R<1> are hydrophobic alkyl or alkylaryl groups containing 10 or more carbon atoms, a, b and c are methyl, ethyl or benzyl groups, Ar is a nitrogenous aromatic group and X is halide, sulfate, methosulfate or ethosulfate .

Of the sources of active chlorine, only sodium dichloroisocyanurate dihydrate has been found to have fire-resistant properties that would place it in Class 1 as proposed by the Bureau of Mines, which is the least hazardous class, while most of the other chlorinated dry bleach compounds would in the proposed class 3, which is more hazardous.

The combination of dihydrate and sodium dichloroisocyanurate

which has less water than the dihydrate, e.g. monohydrate and/or anhydrous forms, results in a mixture with the good properties described here, if there is sufficient dihydrate in the mixture so that the average combined vaiin content in

the mixture is higher than 11%. Such mixtures having more than 11% water are referred to herein as hydrated sodium dichloroisocyanurate. Since the dihydrate contains 14.1% by weight of combined water, sodium dichloroisocyanurate is hydrated with 11-14.1% by weight

average combined H^O suitable for use in connection with the invention. Additional uncombined water, up to 2% by weight, may be present (in addition to the 14.1% combined water) without changing the properties of the dihydrate.

In addition to its non-flammable property, the sodium dichloroisocyanurate dihydrate particles possess substantially less electrostatic charge than anhydrous particles which reduces the tendency of fine particles to accumulate, thereby eliminating one of the risks of handling chlorinated dry bleach compounds.

The following experiments justify the surprising difference in fire resistance properties between sodium dichloroisocyanurate dihydrate and other chlorinated dry bleach chemicals. All quantities used are based on weight unless otherwise stated.

Attempt 1

An 18 gauge nichrome wire was surrounded by a 25 g sample of chlorinated dry bleach. The wire was heated by passing a current through it for several seconds until the material in contact with the wire began to decompose. The current was then turned off and the sample observed to determine the tendency for self-propagating decomposition after the initial cause of the decomposition was removed. This process was followed for samples of anhydrous and hydrated forms of both sodium dichloroisocyanurate and potassium dichloroisocyanurate. The results are reproduced in Table I.

Attempt 2

The procedure from Experiment 1 was repeated for samples of chlorinated dry bleach mixed with 2% by weight of the cationic surfactant [dimethylbenzyl-3-(isobutylphenoxyethoxy)-ethylammonium chloride] to demonstrate the risk of mixing a cationic surfactant with conventional chlorinated, dry bleaches. The dihydrate was tested with both 2% and 4% surfactant mixtures. The results are reproduced in table II.

Attempt 3

An amount of each of the chlorinated dry bleaches listed in Table III was placed in a bed of dimensions 2.54 cm x 5.08 cm x 17.8 cm and ignited at one end with a flame according to the proposed Bureau of Mines method RI-7593. The horizontal speed of the spread of the flame in the material was measured, and the results are given in Table III.

Attempt 4

Samples were prepared containing an 80:20 mixture of a chlorinated dry bleach as indicated in Table IV, and red oak sawdust, according to proposed Bireau of Mines method RI-7594. In addition, a control sample was also prepared with pure sawdust. Each sample was placed in a bed of dimensions 2.54 cm x 5.0 cm x 17.8 cm and ignited with a flame as indicated in Example 3, and the rate of spread of the flame was measured.

The results are shown in Table IV.

As can be readily deduced from Experiments 1-4, sodium dichloroisocyanurate dihydrate is not only non-combustible, but actually inhibits the rate of flame propagation of combustible material (dihydrate-sawdust combination burns noticeably slower than sawdust alone).

Example 1

A detergent composition for automatic household dishwashers was made and contained sodium dichloroisocyanurate dihydrate with the safety properties previously described and exemplified. The components in the amounts indicated below were distributed with a ladle or bucket from a suitable storage container and transported to a mixer where they were mixed mechanically until the mixture appeared uniform. The components were

added to the mixer in the order indicated below.

Claims (1)

Bleaching, sterilizing, disinfecting and detergent mixtures consisting of a mixture of sodium dichloroisocyanurate and detergent ingredients selected from the group consisting of detergent builders, anionic, non-ionic or cationic surfactants and detergent fillers, characterized in that sodium dichloroisocyanurate is present in hydrated form, with an average , combined water content of 11-14.1% by weight, where the detergent mixture may possibly contain a further 2% by weight of uncombined water, whereby the risk of fire is reduced to a minimum.