GB2097376A - Bactericidal method and apparatus - Google Patents

Abstract

To kill bacteria in an aqueous liquid, especially an oil-water emulsion which is used as a coolant and lubricant for machine tools, an apparatus is set up comprising means for inflicting damage to the cell walls of the bacteria in association with a source providing heavy metal ions arranged to expose the bacteria to such ions substantially immediately after the damage is inflicted. The preferred form of the invention is a gear pump in which at least the gear wheels (3, 4) are silver-plated. <IMAGE>

Description

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GB 2 097 376 A 1

SPECIFICATION

Bactericidal method and apparatus

This invention relates to a method and apparatus for killing bacteria present in aqueous 5 liquids. It is of particular importance in relation to reducing the population of live bacteria in oil-water mixtures, especially the so-called "soluble oil" — water emulsions used as a coolant and lubricant.

10 "Soluble oil" is so called because the neat oil readily forms an emulsion when it is mixed with water, the oikwater ratio being typically about 1:24 to 1:32 by volume, i.e. about 3% to 4% of oil in the emulsion. (All oil:water ratios mentioned in 15 this specification are by volume). Such emulsions are used widely in the metal cutting and forming industries to cool and lubricate the workpiece. It has been estimated that some 20 million British gallons (90 million litres) per year of soluble oil 20 are used for this purpose in the U.K.

Aqueous emulsions of soluble oil become contaminated very easily by bacteria and the bacteria grow very rapidly. Many bacteria obtain sufficient nutrients for this purpose from the 25 hydrocarbons present in the oil, others from additives in the oil or contaminants, e.g. pieces of food, cigarettes or urine, which are introduced when the oil is circulating. Within a few weeks, a bacterial population of the order of millions per 30 ml. of emulsion is often obtained.

The bacteria chiefly found in oil are of the genus Pseudomonas, especially the species Pseudomonas oleovorans. Other Gram-negative bacteria commonly found are those of the 35 Escherichia, Aerobacter, Proteus and Klebsiella genera, including E. coli. The Gram-positive genus Streptococcus is also found. (See Wort, Lloyd and Schofield in Tribology International, February 1976, pages 35—37.)

40 The effects of contamination of the oil are serious. The include:—

1. Degradation of hydrocarbons and decomposition of some additives.

2. Acidic intermediate products in the

45 degradation or decomposition of constituents of the oil cause corrosion problems.

3. The emulsion is often de-stabilised so that an oily phase separates out.

4. The size of the oil droplets increases, thus 50 interfering with lubricating action.

5. Sludge and slime form in sumps or containers and rancid smells are produced, particularly after a shut-down of the machinery. This causes the oil to the replaced, at great

55 expense.

6. Infectious diseases are easily transmitted from oil containing these high counts of bacteria. Dermatitis, enteritis and bronchial complaints are believed to arise in this way. This is perhaps not

60 surprising, considering that a bacterial count of 107 per ml. is about the equivalent to that found in untreated sewage.

Various attempts have been made to overcome the problem of bacterial contamination of soluble

65 oil. Bactericides have generally not been successful, because strains resistant to them are developed quickly. It has been proposed periodically to clean out the whole system in which the oil circulates and add a bactericide, see 70 "Metalworking Production", April 1980, pages 78—80. However, to clean the whole system is a laborious operation.

It has now been found that bacteria in an aqueous liquid can be killed by inflicting physical 75 damage to the cell walls of bacteria and substantially immediately exposing the damaged bacteria to a source providing bactericidal heavy metal ions. Accordingly, the present invention provides such a method of treating an aqueous 80 liquid, especially an oil-water mixture and most especially an emulsion of soluble oil in water. The invention also includes apparatus comprising means for inflicting physical damage to the cell walls of bacteria in association with a source 85 providing heavy metal ions arranged to expose the bacteria to such ions substantially immediately after the damage is inflicted.

A preferred way of carrying out the invention is to circulate the bacteria-contaminated liquid 90 through a gear pump, the gear wheels of which have been silver-plated. By this means it has been found possible to reduce the number of bacteria per ml. from 107 to 102 or 103 within 12 hours.

The invention is most surprising, bearing in 95 mind that merely inflicting physical damage on the cells and merely exposing the cells to a silver surface are individually ineffective to reduce the number of bacteria significantly. Indeed, even the combination is ineffective unless the bacteria are 100 exposed to the silver in such a way that silver ions penetrate into the bacteria cell before the damage done to the cell wall can be repaired by the bacterium. The biochemical reasons for the success of the invention are not yet fully 105 understood. Seen at a simple, level, it appears that the energy of the cell is consumed in attempting to produce materials for the repair of the damaged wall and that during this period it is more vulnerable than usual to attack by silver 110 ions. It seems that this effect is peculiar to use of metal ions as the bactericidal agent. Use of a conventional gear pump (unplated) in combination with a conventional biocide is ineffective.

115 In principle, the silver ions could be provided in other ways than by bringing the liquid into contact with a silver surface. For example introduction of a silver salt into the liquid could be contemplated. However, it is a specific advantage 120 of the invention that the silver or other bactericidal heavy metal is provided in an economical and convenient manner by plating. In this way, there is no need to rely on an operative carrying out an instruction to add chemicals to the 125 system, and no risk of waste or pilferage of supplies of such chemicals. Further, the use of silver-plating provides a slow release of silver and therefore a relatively long-lasting bactericidal action.

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GB 2 097 376 A 2

The exact mechanism by which silver exerts a bactericidal action is not known. It appears, however, that it acts to provide silver ions within the bacterial cell.

5 Other bactericidal heavy metals, e.g. copper or a copper alloy, could be used in place of silver. However copper metal itself in unsuitable on account of its softness. Copper-containing metals are also liable to attack by sulphur present in oils. 10 Brass, cast iron and steel are ineffective.

Desirably, physical or mechanical damage to the bacteria is inflicted by a device which is plated by silver or other bactericidal heavy metal, or plated on part of its surface with silver and on 15 other parts with the other metal. Plating the device is one way of ensuring that the heavy metal will strike at the bacteria when they are at their weakest, in accordance with the principles explained above. A preferred means of inflicting 20 the damage is by way of a device which chews the bacteria, as in the gear pump. However, other means can be used. Thus the liquid could be subjected to violent pressure changes, turbulence, intensive multi-directional agitation or any 25 combination of two or more such effects sufficient to cause the damage, and preferably to burst a significant proportion of the cells. Ultrasonic energy has been found to be particularly effective, but the high cost of the probe and 30 associated equipment makes this an unrealistic choice.

The primary function of the gear pump, preferred as the damage-inflicting means, is to cause the damage by chewing and cavitation. The 35 main pumping action could be provided by another pump in the circulatory system, if desired.

The invention is applicable to any aqueous liquid which is circulated. The principal application of current interest is to circulating oil-40 water mixtures, especially such mixtures used in association with tools for metal-cutting, forming and rolling. However, the invention could also be used to reduce bacteria in ordinary domestic or commerical water systems. In many of these 45 systems some of the bacteria are killed by the action of heat, but this does not entirely dispose of the problem and there is a build-up of bacteria in cold water tanks or header tanks.

In the application of the invention to the 50 circulating soluble oil-water mixtures the oil to water ratio is preferably maintained at about 1:30, especially 1:24 to 1:36. If the ratio is allowed to fall too far, e.g. to below 1:10, the bactericidal effect does not persist for as long as 55 normal. 1:36 is about as dilute an emulsion as is normally likely to be useful in industrial metal-cutting, forming and rolling.

The bactericidal effect can be enhanced by adding a biocide, even in substantially smaller 60 proportions than normal.

It might be necessary to clean the gear pump pariodically to remove slime and sludge, but this can be done with various solvents or back-washing with detergent and is an easier operation 65 than cleaning tanks and other part of the system.

Preferred features of the invention will now be described with reference to the accompanying drawing. The drawing is a plan view of a gear pump, partly cut away to show its interior. Within 70 the housing 1 is a gear chamber 2 of approximately figure-of-eight configuration, containing a driving gear wheel 3 meshing with a driven gearwheel 4 of the same diameter (1 inch; 2.5 cm.) and having the same number of teeth, 75 namely sixteen. Gear wheel 3 has a shaft 5 for connection to an electric motor (not shown). A pipe 6 leads into an inlet 7 in the gear chamber. An outlet 8 from the gear chamber leads back into an outlet pipe 9. Oil from inlet 7 is impelled 80 around the gear chamber 2 by the gear wheels and leaves via outlet 8. Bacteria in the oil are "chewed" between the meshing gear teeth.

At least the gear wheels and teeth should be silver-plated; as a matter of convenience it is 85 preferred to plate the whole surface of the chamber shown in the drawing.

Any kind of gear pump could be substituted for the particular pump shown, but preferably it should be one having a small tolerance. The pump 90 shown has a meshing clearance of a few thou (1 thou=0.001 inch=0.025 mm.). Generally, the smaller the meshing clearance, the greater the damage that can be inflicted on the cell walls. It is usually sufficient merely to abrade the wall, 95 without necessarily piercing it. It has been observed however that many of the bacteria emerge from the outlet of the pump in a burst condition, i.e. with severe rupture of the wall.

The silver-plate need have a thickness of only 1 100 thou (0.025 mm.). A greater thickness is preferable in order to prolong the useful life of the pump before it has to be re-plated and it is expected that about 3 thou (0.075 mm.) will be very suitable. Provided that there is sufficient 105 clearance between the gear teeth greater thicknesses than 3 thou, for example up to 5 thou (0.125 mm.) or even greater would be usable.

The following Example further illustrates the invention.

110 Example

A gear pump as specifically described above with reference to the drawing having silver-plating of thickness 1 thou (0.025 mm.) on its interior gear-carrying surface was installed in 11 5 place of a conventional gear pump in the cooling and lubricating system of a machine tool. The lubricant/coolant was an emulsion of the soluble oil "Dromus B" (made by Shell) in water in the ratio 1:30. The gear pump was run at a speed of 120 2,000 rev./min. and with a throughput of 2

gallons (9 litres) per minute. Within 4 to 12 hours the concentration of bacteria was reduced from 107/ml. to 102 or 103/ml.

When 1 g./litre of a biocide "Grotan" was 125 added to the oil, the concentration of bacteria was around the lower end of the range, i.e. of the order of 102/ml. "Grotan" is a formaldehyde-based biocide.

The effectiveness of this method diminished

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after about 6 or 7 weeks, owing to a build-up of sludge on the silver-plated surfaces of the gear pump. However, when the pump was backwashed with a caustic alkali or detergent, its 5 efficiency was restored.

It is expected that the efficiency of the method could be improved by providing a surface of activated silver instead of ordinary silver plate.

Claims (14)

1. Claims

   10 1. Apparatus suitable for use in killing bacteria present in an aqueous liquid, comprising means for inflicting physical damage to the cell walls of the bacteria in association with a source providing heavy metal ions arranged to expose the bacteria 15 to such ions substantially immediately after the damage is inflicted.
2. 2. Apparatus according to Claim 1 wherein the damage-inflicting means and the heavy metal ion source are provided by a device which is plated on

   20 damage-inflicting surfaces thereof with the heavy metal.
3. 3. Apparatus according to Claim 1 wherein the damage-inflicting means is a gear pump.
4. 4. Apparatus according to Claim 2 wherein the 25 damage-inflicting means is a gear pump of which at least the gear wheels are plated.
5. 5. A gear pump of which at least the gear wheels are silver-plated.
6. 6. A gear pump substantially as hereinbefore

   30 described with reference to the accompanying drawing.
7. 7. A method of treating a bacterially contaminated aqueous liquid which comprises inflicting physical damage to the cell walls of

   35 bacteria in said liquid and substantially immediately exposing the damaged bacteria to a source providing bactericidal heavy metal ions.
8. 8. A method according to Claim 7 wherein the damage is inflicted by circulating the liquid

   40 through a gear pump.
9. 9. A method according to Claim 7 or 8 wherein the heavy metal ions are silver ions.
10. 10. A method of treating a bacterially contaminated aqueous liquid which comprises

    45 circulating it through a gear pump of which at least the gear wheels are silver-plated.
11. 11. A method according to any one of Claims 7 to 10 wherein the aqueous liquid is a mixture of oil and water.

    50
12. 12. A method according to Claim 11 wherein the mixture in an emulsion having an oihwater volume ratio of from 1:10 to 1:36.
13. 13. A method according to Claim 11 or 12 wherein the liquid contains bacteria of the genus

    55 Pseudomonas.
14. 14. A method of killing bacteria in an aqueous liquid with the aid of a bactericidal heavy metal and bacteria-damaging means, substantially as hereinbefore described.

    Printed for Her Majesty's Stationery Office by the Courier Press, Leamington Spa, 1982. Published by the Patent Office, 25 Southampton Buildings, London, WC2A 1 AY, from which copies may be obtained.