The present invention relates to the production of components useful in the manufacture of emulsion explosives, and to emulsion explosives manufactured from such components. The invention also relates to mixing apparatus suitable for use in practice of the invention.
Emulsion explosives used in commercial blasting operations are typically formed by mixing an emulsion comprising an aqueous solution of an oxidizer, a fuel and an emulsifier (hereafter referred to as an “intermediate emulsion”) with a suitable sensitising additive that renders the emulsion detonable. The result is a sensitised emulsion explosive. The intermediate emulsion is generally a high internal phase water-in-oil emulsion containing droplets of an oxidizer solution emulsified in a fuel.
Intermediate explosives and sensitised emulsion explosives are well known and described in the art. For example, U.S. Pat. No. 3,447,978 is master patent reference describing emulsions in term of individual components of emulsion blasting agents (non detonator sensitive), U.S. Pat. No. 4,149,917 is master patent reference for detonator sensitive emulsion blasting agents and U.S. Pat. No. 4,138,281 is the first patent describing emulsion manufacturing process of packaged detonator sensitive emulsions.
In order to achieve economies of scale and efficiencies the intermediate emulsion is usually manufactured in bulk at a centralised, dedicated facility and transported to the site of intended use or to a specialist plant for blending up as an emulsion explosive. That location may well be remote and quite possibly in a different country from where the intermediate explosive is manufactured.
Furthermore, with transportation in mind, the intermediate explosive is made to meet the UN non-explosive hazard classification. This requires the intermediate explosive to include a relatively large amount of water in the formulations. The water-diluted intermediate emulsions, besides being classified as non-explosive (Oxidizer class 5.1) also exhibits reduced sensitivity & explosives energies.
This manufacture and supply chain model has been commercially successful but, in recent times, there has been cause to reconsider it due to regulations relating to the security associated with manufacture and transport of explosives and explosives components.
It is also evident the process of supply and delivery of intermediate emulsions creates limitations and constraints in the applications on the customer sites. This is because due to varying customer needs, it is not easy to achieve specific performance characteristics, such as detonator sensitivity or high energy of the explosive products.
Against this background it would be desirable to be able to manufacture the intermediate emulsion and a corresponding emulsion explosive with suitably high performance on-site at the location of intended end use. However, this alternative approach is by no means straight forward as it brings with it various other practical issues. For example, the location of intended use can be remote and not easily accessible. Accordingly, it may not be feasible to transport and install large and/or complex manufacturing componentry. Any proposed local (on-site) manufacture will also need to have a suitably high production rate to cope with usage demand, and product quality must also be consistently high and predictable.
The present invention seeks to meet these needs by manufacture of an intermediate emulsion using micromixer (sometimes also referred to as a microstructured mixer) technology. Using currently available micromixers it is not believed to be possible to form such an emulsion from its constituent components in a single mixing step. However, in accordance with the present invention it has been found that successive stages of mixing can be employed to achieve an intermediate emulsion having suitable characteristics.
Accordingly, in one embodiment the invention provides a process for producing an intermediate emulsion comprising an aqueous oxidizer solution, fuel and emulsifier, which process comprises the steps of:
(a) mixing in a micromixer an aqueous oxidizer solution with a fuel blend comprising a fuel and an emulsifier so as to solubilise a portion of the oxidizer salt solution in the fuel blend to produce a precursor product;
(b) mixing the precursor product obtained in step (a) using a micromixer in one or more successive stages in order to form the intermediate emulsion.
In the context of the present invention the intermediate emulsion that is produced is of conventional kind and it has conventional characteristics in terms of volumetric ratios of internal dispersed phase to external continuous phase, viscosity, stability etc. The components used to produce the intermediate emulsion are also conventional and one skilled in the art would be familiar with components that may be used and their typically used proportions.
The present invention also relates to the manufacture of an emulsion explosive by suitable sensitisation of an intermediate emulsion produced in accordance with the invention.
The present invention also relates to the use of such an emulsion explosive in a blasting operation. The emulsion explosive is used in conventional manner and detonated using conventional means.
The present invention also provides mixing apparatus suitable for producing an intermediate emulsion in accordance with the present invention, the apparatus comprising a micromixer capable of producing a precursor emulsion as described herein, and one or more further micromixers for converting the precursor emulsion into an intermediate emulsion as described herein. The design of suitable micromixers for use in the apparatus is described in more detail later. The individual micromixers may be provided in the same housing, but this is not essential. The function and working inter-relationship of the micromixers is central to the present invention.
The present invention also provides an array of such mixing apparatus arranged in parallel in order to achieve scale-up in production of the intermediate emulsion using the principles of the present invention.
As will be explained, one advantage of the methodology of the present invention is that it may be applied to produce intermediate emulsions having a range of intrinsic sensitivities. It may be possible in accordance with the present invention to produce emulsions that require very little, if any, sensitisation in order to render them useful in blasting operations.
The key to the present invention is the stage-wise and successive mixing of components using micromixers to produce an intermediate emulsion having desirable characteristics.
The first stage of mixing is intended to achieve solubilisation (dissolution) of a portion of the oxidizer solution in the fuel blend (of fuel and emulsifier). In this regard it is understood that emulsifier molecules form micellar solution (fuel blend) that comprises a dispersion of micelles of emulsifier in the fuel solvent. Micelles consist of aggregated amphiphiles, and in a micellar solution these are in equilibrium with free, un-aggregated amphiphiles. Micellar solutions form when the concentration of amphiphiles exceed the critical micellar concentration (in the present invention this is always the case). It is believed that during mixing only un-aggregated, free micelles are available to stabilize the oxidizer droplets formed during the first stage of mixing. The free micelles arrange themselves on the surface of oxidizer solution droplets according to energetically favourable hydrophobic and hydrophilic interactions with respective aqueous and organic phases.
The first stage of mixing solubilises only a portion of the oxidizer solution that is available based on the intended ratio of oxidizer to fuel components. This is because this stage of mixing is of relatively low energy and does not impart sufficient shear and turbulence to provide additional solubilisation of the oxidizer solution in the fuel blend and thus emulsion formation. This is due to failure of the mixer to break the aggregated micelles and make them free (available) for the oxidizer droplet stabilization. Indeed, no single micromixer apparatus is believed to be available that would achieve this. The first stage of mixing preferably involves contacting of thin lamellae of oxidiser solution and fuel blend which are subsequently mixed through diffusion mixing and the micromixer is designed accordingly.
The process of the invention is intended to be run continuously as between respective mixing stages. However, the principles underlying the invention may be understood by analysing the output from the first stage of mixing. The precursor material produced in the first stage has no emulsion stability to speak of and settles quickly into relatively discrete phases. The material does include droplets of oxidizer solution in an oil phase but it is evident that a significant portion of the oxidizer solution remains largely unmixed with the fuel blend.
The precursor material is delivered directly (and without delay) to another downstream micromixer that imparts increased shear into the stream. Depending on design and mixing efficacy, it is possible to use one or more such micromixers. If multiple downstream micromixers are employed, these are arranged in series to achieve successive mixing stages.
Irrespective of the number of micromixers involved after the first stage of mixing, the intention is to form a stable emulsion having desired characteristics by applying shear stress to the precursor material produced in the first stage. Without wishing to be bound by theory it is believed that the free oxidizer solution in the precursor material is caused to fragment due to hydrodynamic instabilities created by shear stress and then decays into regular droplets. It is also believed that in the same shear field the aggregated micelles are broken down into free micelles of emulsifier that are instantaneously available to stabilize the newly formed surface of the oxidizer droplets. At suitable flow rates relatively small and emulsifier stabilized droplets of oxidizer solution are produced, thereby resulting in formation of a stable emulsion. In other words, the micromixing after step (a) ensures conversion of what is effectively fluid flow energy in the first step of mixing into shear energy. The first step of mixing does not provide enough energy to achieve the necessary dispersion of oxidizer solution in the fuel phase and also the necessary de-aggregation of micelles to achieve emulsion formation, although important structural changes are achieved that facilitate emulsion formation by subsequent micromixing. The invention relies on the inter-relationship between the various steps of mixing in order to achieve the desired result.
The overall philosophy of the invention is to apply micromixing to each stage/step of production of an intermediate emulsion. In the context of the present invention this is advantageous for a number of reasons as follows.
The present invention can advantageously be applied to produce intermediate emulsions that have a range of inherent sensitivity. Thus, the invention may be applied to produce emulsions that are intrinsically insensitive through to emulsions that are intrinsically sensitive to a shock or mechanical stimuli. This will be a function of the nature of the dispersed oxidizer phase. The oxidizer phase may vary from water diluted oxidizer salt solutions up to very concentrated solutions with negligible amount of water or to oxidizers that are based on molten salts and eutectic explosive fluids. In relation to producing intrinsically shock or mechanically sensitive emulsions the following advantages of using micromixers are also particularly relevant:
In terms of process parameters, typically the output of each stage of mixing, and of the process as a whole, is typically 50 to 125 ml/min. The residence time for the entire process is short and is generally from 20 to 100 milliseconds. Over each stage of mixing it is desirable for the micromixer design to achieve efficient conversion of fluid flow energy into shear stress while maintaining a relatively low overall pressure drop. Desirably, the pressure drop for the process as a whole is less than 20 bar.
The first step of the process of the invention involves mixing an aqueous oxidizer solution with a fuel blend comprising a fuel and suitable emulsifier. The aqueous oxidizer solution and fuel blend will be metered into a suitable micromixer at flow rates based on the required ratio of these components in the final emulsion to be produced. The latter is generally a high internal phase water-in-oil emulsion so that the rate of supply of the aqueous oxidizer solution will be somewhat higher than the rate of supply of the fuel blend. The desired output rate for this first stage of mixing will also influence the rate of supply of the individual components for mixing. By way of example the volume supply rates for the aqueous oxidizer solution and fuel blend respectively may be 10 to 250 ml/min and 0.5 to 25 ml/min, preferably 30 to 150 ml/min and 3 to 15 ml/min, more preferably 50 to 125 ml/min and 5 to 12.5 ml/min.
In the first stage of mixing the flow rates of the components to be mixed may need to be adjusted so that a precursor material as required is produced. The aqueous oxidizer solution and fuel blend are not easily mixed by a laminar diffusion mixing because the miscibility of the aqueous and the fuel phase strongly depends on the micellar arrangement of the surfactant in the fuel phase.
In the present invention the amount of emulsifier must be always higher than the critical micelle concentration in order to ultimately ensure formation of a stable emulsion. In the case of emulsifier concentration being less that critical micelle concentration it is not possible to form a stable emulsion system, regardless of the shear energy and shear application time.
The fuel phase of the present invention consists of micellar solution that comprises a dispersion of aggregated micelles that are always in equilibrium with free, un-aggregated micelles. In order to form satisfactory stable emulsions the mixing must be energetic enough to disperse the aggregated micelles to make them free and available for stabilization of newly formed oxidizer droplets. At high flow rates there is likely to be segregation of immiscible fluid sheaths with the result being little or no emulsion diffusion mixing and also because of limited concentration of free micelles available. At low flow rates there may be increased diffusion mixing performance (for a given micromixer design) but it is not possible to form in a single step a high internal phase emulsion having the requisite characteristics. The reason being that there is only limited energy in diffusion mixing to simultaneously form droplets and also disperse the all aggregated micelles and in the process form a stable emulsion. The precursor is formed on the basis of the system utilizing only free, un-aggregated emulsifier micelles. Hence, there is no effective droplet stabilization due to aggregated micelles being unavailable to coat the newly formed oxidizer droplet surfaces.
After formation of the precursor, the material is subjected to further mixing in one or more successive stages. This leads to formation of an intermediate emulsion having desirable characteristics.
After formation it is important that the precursor material is subjected to further mixing before any significant change in the characteristics of the precursor material. In practice once formed the precursor material is delivered directly into an associated micromixer where further mixing is conducted. It is believed that in the new shear field the aggregated micelles are broken down into free micelles of emulsifier that are instantaneously available to stabilize the newly formed surface of the oxidizer droplets. If two or more stages of mixing are employed, the output of each respective step is usually delivered directly to the next step to avoid any possible changes in the characteristics of the product between successive stages of mixing.
The intermediate emulsion that is produced will typically have viscosity of at least 6,000 cP (Brookfield viscosity taken with spindle #7 at 50 rpm) at ambient temperature (20-25° C.). Generally the viscosity may be as high as 50,000 cP, for example, 20,000 cP at ambient temperature (Brookfield viscosity taken with spindle #7 at 50 rpm). The droplet size of the emulsion is typically less than 40 μm and the droplet size shows low polydispersity. The intermediate emulsion is also stable and compares well in this regard to corresponding emulsions prepared using conventional techniques.
In the following the principles of the present invention are described with reference to particular designs for achieving mixing as required in accordance with the invention. The particular designs that are described have been found to be particularly suitable for forming an intermediate emulsion in accordance with the invention. However, the invention should not be understood as being limited to these particular designs, and other designs are possible.
In accordance with an embodiment of the invention the first stage of mixing (to produce a precursor material) can be carried out using a “star laminator” micromixer available from Institüu für Microtechnik Mainz GmbH (IMM). The basis for these mixers is the alternating injection of two (or more) fluid streams into one flow-through mixing chamber whose geometric design can induce secondary effects. Using interdigital structures, multilamination of streams can be obtained in the laminar flow region. The two liquids to be mixed enter one cylindrical channel via star-shaped feeding structures which are incorporated in circular, thin foils. To obtain lamination in the feeding structures without premixing at least one sealing foil is required. By adjusting the size of the cylindrical inner mixing channel and the planned throughput turbulent flow of fine, alternating injected fluid flows, the corresponding mixing mechanism can be predicted.
In accordance with this embodiment formation of a precursor material can be achieved using a star laminator micromixer. Specifically, a Star Laminator 30 model mixer available from IMM may be used. This comprises a stack of stainless steel microstructured foils each having a thickness of about 25 μm. The foils have channels cut through them (using a laser) to provide a microstructured design. A total of 100-260 foils are stacked on top of each other in a steel housing. The resultant stack arrangement feeds oxidizer salt solution and fuel blend into a main mixing channel in the centre of the stack arrangement. The result of mixing is a precursor material as described.
In accordance with this embodiment of the invention this precursor material can then be subjected to further mixing by feeding it through another micromixer. In one particular design, the latter achieves further mixing by switching flow velocity periodically while decreasing the diffusion path of each phase. In this micromixer the precursor material is subjected to mixing by periodical, alternating switches of flow from a high flow velocity to a low flow velocity In this way, it is believed that pulsation of flow of the whole stream (of precursor material) promotes mixing. A variety of micromixer designs may be employed to achieve this. In accordance with the invention it has been found that the following arrangement may be suitable in this regard.
The micromixer that receives the precursor material may comprise a stack of stainless steel foils of constant dimension. Typically the foils are circular but this is not mandatory. One orifice is usually provided in each foil. In use the precursor material is caused to flow through a channel or channels defined by these orifices in a stack of foils. The flow velocity can be varied periodically by suitable arrangement of foils and orifices noting that the flow velocity through a small orifice channel will be higher than through a channel of equal length but having a larger orifice. By varying the diameter and length of the orifice, the number of orifices and the channel length for a given orifice diameter, the characteristics of the product of mixing can be manipulated. Herein this kind of mixer is referred to as a micro-orifice mixer.
By way of example, the stack arrangement in the micro-orifice mixer may be made up of three different types of foil. Each foil may be circular with the same diameter and each having a single, central orifice/opening. Typically, the foil is about 2 cm in diameter. One foil has a thickness of 50 μm and an orifice/opening diameter of 500 μm, the others have a thickness of 3.5 or 7 mm and an orifice/opening diameter of 2.2 mm. Providing a stack of foils with the same characteristics will define a flow channel having a particular diameter (corresponding to the orifice diameter) and length (corresponding to the thickness of each foil multiplied by the number of foils in the stack). By appropriate arrangement of stacks of respective foils it is possible to produce an overall stack arrangement in which the flow channel dimensions varies periodically. The result is that precursor material flowing through the stack will be subjected to a cycle of different flow velocities, thereby causing mixing by shear. By manipulating the various parameters of the stack, the characteristics of the product of mixing (output of the stack) can be manipulated. This may yield an intermediate emulsion of desired characteristics, or the product of mixing may be subjected to further mixing (refinement) in one or more subsequent steps in order to achieve those desired characteristics.
In accordance with the invention there is also provided an apparatus for producing an intermediate emulsion by the principles described herein. In simple and general terms the apparatus comprises a micromixer capable of producing a precursor material as described from mixing an oxidizer salt solution and fuel blend (fuel plus emulsifier), and one or more further micromixers that are adapted to subject the precursor material to further mixing so as to produce an emulsion blasting agent. The components of the apparatus may be provided in a single housing or arranged in series as individual units. As will be appreciated from the discussion of
Embodiments of the invention are illustrated with reference to the accompanying non-limiting drawings in which:
In the embodiment shown a precursor material is formed by mixing the components using a star laminator pre-mixer (10). The outlet of that mixer feeds precursor material directly into a micro-orifice mixer (11) where the precursor material is further mixed and an intermediate emulsion having desired characteristics is tapped off from an outlet (12). It will be appreciated that the star laminator mixer and/or micro-orifice mixer may be replaced by functionally equivalent mixer(s) of difference design.
No additional pumping is usually required from the outlet of the Star Laminator mixer to ensure suitable flow through the micro-orifice mixer.
Embodiments of the present invention are illustrated with reference to the accompanying non-limiting examples.
Once formed in accordance with the invention the intermediate emulsion can be used in conventional manner. Prior to use the intermediate emulsion must be sensitised and usual techniques may be employed here. In these respects the intermediate emulsion is intended to have the same characteristics and behave in the same way as an intermediate emulsion produced in conventional manner.
Experimental samples were produced in a specially designed emulsion experimental rig (continuous emulsion micromixing unit). This figure shows a Star Laminator mixer feeding into a Micro-orifice mixer. In control examples reported below, the experimental rig did not include the Micro-orifice mixer, but otherwise the rig design was the same.
The experimental rig comprises fuel blend and oxidiser solution holding tanks with stirrers, filters, gear metering pumps and Corialis mass flow meters in order to allow control of the experimental processes. The rig also has hot water heaters for heating of the holding tanks, and temperature and pressure indicators and pipe heat insulation. Gear pumps drive the fluid streams through the experimental micro mixers. The emulsion experiments and their processes were controlled through a Lab view-based program that is installed on a PC.
The oxidizer solution used in the experiment are prepared by dissolving the oxygen releasing materials in water at a temperature above the crystallizing point of the solution, preferably at a temperature in the range from 25 deg C. to 130 deg C. to give aqueous oxidizer solutions.
The water-immiscible organic fuel used in the experiment forms the continuous oil phase of the water in oil emulsion and also acts as a fuel in the explosive emulsion. For the purpose of demonstrating the invention we have selected for our examples suitable fuel materials like diesel oil, paraffin oil, mineral oil, canola vegetable oil and their respective blends. Those fuels are in the liquid state at the formulation operating temperature. However, if necessary the fuels are heated to temperature which may be in the range from 25 deg C. to 90 deg C.
The emulsifier materials utilized in the examples are basically selected from the group of polymeric and conventional type emulsifiers. The polymeric emulsifiers E25/66, E25L and E21/70 T are typical condensation products of Poly-alkenyl succinic acid or anhydride with primary amines. The typical conventional emulsifier used in our examples was selected from the group of the sorbitan esters. The sorbitan mono-oleate (SMO) was used in our formulations.
For the purpose of the continuous process a fuel blend comprising of the water immiscible fuel and the emulsifier was prepared to allow a single stream in-process metering of a continuous oil phase. The fuel blend is a micellar solution of emulsifier in an oil phase.
In the continuous emulsion micromixing unit the process rapidly combines aqueous oxidizer solution with a blend of water immiscible organic fuel and the emulsifier. The materials are rapidly mixed and the uniform and stable emulsion is formed.
The preparation procedure for the oxidizer solution and the fuel blend were the same as procedures that are normally used in the manufacturing emulsions. The oxidizer solution and the fuel blend were transferred into respective holding tanks and heated to process temperatures 80 to 90° C. and 40 to 50° C., respectively. The oxidizer solution and the fuel blend were continuously metered into the experimental mixing rig in the mass ratios between 92 to 98% oxidiser and 8 to 2% fuel blends.
Experimental data were collected during and at the end of each experiment, including process flow rate, oxidizer solution and fuel blend pump pressure, oxidizer and fuel blend mixer pressure, oxidizer and fuel blend mass flow meter temperature and micro-mixer outlet pressure. The final emulsion viscosity and the emulsion droplets size distribution were also measured.
The emulsion viscosity produced by the emulsion testing rig was measured using a RVT model Brookfield Viscometer utilizing spindle number 3, 4 or 7 depending on the viscosity of the sample. The sample temperature was usually between 20° C. to 70° C. at the time of measurement.
The emulsion droplet size and its distribution were measured by taking pictures of droplets using a light microscope and analysing them using in-house Emulsion Droplet Size Analysis (EDSA) software. When the large droplets (>50 mm) were observed, a Howard Cell was used to contain the sample when pictures were captured, thereby avoiding squashing of the droplets. The pictures were then analysed using a “manual ruler” available within the EDSA software. If small droplets were observed, standard micrograph sample glass was used when taking droplet pictures and they were analysed automatically by the algorithm of the EDSA software. The average, median and standard deviation of the droplets diameter were calculated.
The mixing process in Example 1 utilized commercial device the Star Laminator—V2.3-30/300 micromixer. The mixer operates on the principle of multilamination using mixing channels with the foil thickness of 25 μm. A total of 125 foils were used in this example. The oxidizer to fuel blend feeding ratio into the micromixer unit was set at 1:1.
In the formulation of Example 1, the amount of ammonium nitrate in the oxidizer solution was slightly reduced in order to lower the crystallization point of the solution. The oxidizer solution was maintained at 80° C., while the fuel blend was heated to only 50° C. with the view to assist emulsion formation.
The experiment above has shown that a highly unstable dispersion of oxidizer phase in the fuel blend has been formed. Because of the incomplete emulsion formation and its subsequent break down within a relatively short time the viscosity of the sample was taken within 1 minute of mixing to allow reading of the instrument values.
This example clearly shows that Star Laminator-V2.3-30/300 micromixer can not form a stable emulsion. The failure to form stable emulsion is due to the fact that there is only a limited mixing energy available as shown by a relatively low pressure drop across the Star Laminator mixer. The pressure drop across the unit for both lines is also a function of volumetric flow rates, phase ratio of components, liquid density and viscosity.
As in the previous example, the mixing process in Example 2 utilized the same commercial device the Star Laminator-V2.3-30/300. The mixer operates on the principle of multilamination using mixing channels with the foil thickness of 25 μm. A total of 125 of foils were also used in this example. However, the oxidiser to fuel blend feeding ratio into the micromixer unit was set at 2:1.
In this example, a slightly different configuration of foils in the Star Laminator micromixer was used in an attempt to improve mixing via enhancement of the local velocity of the fuel blend by halving the number of injection channels for the blend. This action caused an increase of the pressure drop across the fuel blend line as indicated in table 2 above.
The material produced in this example was a highly unstable dispersion of oxidizer in the fuel blend, which started to phase separate almost immediately after collection. The viscosity of the sample was not taken due to the fact that the sample, upon collection have phase separated.
The mixing process in Example 3 utilized the same commercial device “the Star Laminator-V2.3-30/300 as Example 1. The mixer operates on the principle of multilamination using mixing channels with the foil thickness of 25 μm. However, a total of 250 foils were used in the Star Laminator mixer. The oxidizer to fuel blend feeding ratio into the micromixer unit was set at 1:1.
In Example 3 the number of foils in the Star Laminator micromixer was doubled when it is compared with the foil configuration used in Example 1. The foils configuration was changed to obtain reduction in local velocity of the fuel and oxidizer fluid streams as they are injected into the mixing channel in the Star Laminator mixer.
It is believed that lowering of the local velocities (i.e. lower local volumetric flow rates) of the streams leads to formation of thinner lamellae of the fuel blend and oxidizer solution as the lamellae are contacted in the Star Laminator's mixing channel. Hence, it was expected that the larger number of foils would cause formation of a finer dispersion of oxidizer solution in the continuous fuel blend.
However, the Example 3 clearly failed to produce material of improved stability and viscosity. This is because of the incomplete emulsion formation and its subsequent break down within a relatively short time, the viscosity of the sample was taken within 1 minute of mixing to allow reading of the instrument values.
Experimental set up of the mixing processes in Examples 1, 2 and 3 suggests that stability of the emulsion material is not achieved because of the insufficiency of the diffusion mixing within the Star Laminator micromixer. It seems that conversion of flow energy into shear energy and turbulent mixing is needed in order to achieve the required dispersion of oxidiser droplets and emulsifier molecules.
The Example 4 material was prepared following the general mixing procedures of Example 1, except that the precursor material was taken directly from the outlet of the Star Laminator micromixer and conducted to an inlet of the Micro-orifice mixer.
The Micro-orifice mixer is constructed of 4 repeat units consisting of: 1× unit of 500 μm diameter×50 μm thick orifice, 2× units of 2.2 mm diameter×3.5 mm thick orifices (channels) and 1× unit of 2.2 mm diameter×7 mm thick orifices (channels). The oxidizer to fuel blend feeding ratio into the Star Laminator mixer was maintained at 1:1.
In Example 4, the Micro-orifice mixer further mixed the precursor material by converting the flow energy into the shear energy that enabled it to reduce the size of oxidizer solution droplets in the fuel blend. In addition, the Micro-orifice mixer allowed more efficient dispersion and hence the use of the emulsifier in stabilizing the newly formed oxidizer droplet surfaces.
It is observed that more energy is used in the Micro-orifice process than in the Star Laminator. This fact is clearly reflected in the higher pressure drop across the unit for both oxidizer solution and fuel blend feeds when comparison is made to the pressure drop across the Star Laminator micromixer unit in Example 1.
Pressure drop across the unit for both lines is also a function of volumetric flow rates, phase ratio of components, liquid density and viscosity.
The material produced in Example 4 was a stable emulsion with a Brookfield viscosity of 10,560 cP (spindle #7, 50 rpm). The viscosity measurement was taken within 1 minute of its formation at sample temperature of 55° C. The size of the oxidizer solution droplet was measured using an optical microscope within 24 hours of its collection. Analysis of the droplet pictures showed that the size distribution of the droplets was a normal distribution function with an average size of 15 μm and standard deviation of 10 μm. Sample was a good quality water-in-oil emulsion that was not phase separating for at least 90 days.
Example 5 was performed following the mixing procedures of Example 2, with an exception that the precursor material was taken directly from the outlet of the Star Laminator mixer and conducted to an inlet of the Micro-orifice mixer as used previously in the Example 4. The oxidizer solution to fuel blend feeding ratio into the Star Laminator unit was maintained at 2:1.
As demonstrated in the Example 5 the Micro-orifice mixer further mixed the precursor material by converting the flow energy into the shear energy that enabled to reduce the size of oxidizer solution droplets in the fuel blend. Moreover, the Micro-orifice process allowed more efficient dispersion and hence the use of the emulsifier in stabilizing the newly formed oxidizer droplet surfaces.
It is clear that more energy is used in the Micro-orifice process than in the Star Laminator. This fact is reflected in the higher pressure drop across the unit for both oxidizer solution and fuel blend feeds if comparison is made to the pressure drop across the Star Laminator micromixer in Example 2.
Pressure drop across the unit for both lines is also a function of volumetric flow rates, phase ratio of components, liquid density and viscosity.
The material produced in this example was a good quality stable emulsion with a Brookfield viscosity of 10,800 cP (spindle #7, 50 rpm) similar to Example 4. The viscosity measurement was taken within 1 minute of emulsion formation at sample temperature of 55° C. The size of the oxidizer solution droplets was measured using an optical microscope within 24 hours of the sample collection. Analysis of the droplet pictures showed that the size distribution of the droplets was a normal distribution function with average size of 21 μm and standard deviation of 11 μm. The sample material was a good quality water-in-oil emulsion that was not phase separating for at least 90 days.
The experiment in Example 6 was following the mixing procedures that were used in Example 4, however modified oxidizer and fuel blend formulation was employed (Table 6). The oxidizer to fuel blend feeding ratio into the Star Laminator pre-mixer unit was maintained at 1:1.
The same Star Laminator micromixer and Micro-orifice mixer combination was used as in Example 4.
The experimental work has shown that the Micro-orifice mixer can be employed to produce good quality emulsion when different formulations of oxidizer solution and fuel blend are used. The oxidizer solution used in this work has higher content of ammonium nitrate which made the solution slightly more viscous and of a higher density when compared to oxidizer solution used in Example 4. The fuel blend comprised of diesel oil, canola oil and emulsifier and as such the blend was more viscous due the addition of canola oil.
The conversion of flow energy into mixing in the Micro-orifice mixer was as efficient as in Example 4. This is reflected in the similar pressure drop across the unit for both oxidizer solution and fuel blend feeds. Pressure drop across the unit for both lines is a function of volumetric flow rates, phase ratio of components, liquid density and viscosity.
The material produced in Example 6 was a stable emulsion with a Brookfield viscosity of 15,600 cP (spindle #7, 50 rpm) that was more viscous than the emulsion made in example 4. The higher emulsion viscosity is mainly reflexion of a more viscous fuel blend used in this example. The viscosity measurement was taken within 1 minute of its formation at sample temperature of 57° C. The size of the oxidizer solution droplets was measured using an optical microscope within 24 hours of its collection. Analysis of the droplet pictures showed that the size distribution of the droplets was a normal distribution function with average size of 15 μm and standard deviation of 9 μm. The sample was an excellent water-in-oil emulsion that was not phase separating for at least 90 days.
The experiment in Example 7 followed mixing procedures that were used in Example 5; however, the oxidizer and fuel blend were modified as shown in table 7 below. The oxidizer to fuel blend feeding ratio into the pre-mixer unit was maintained at 2:1.
The experimental work has shown that the Micro-orifice mixer can be employed to produce good quality emulsion when different formulations of oxidizer solution and fuel blend are used.
The conversion of flow energy into mixing in the micro-orifice mixer was as efficient as in Example 5, as reflected in the similar pressure drop across the unit for both oxidiser solution and fuel blend feeds.
The material produced in Example 7 was a stable emulsion with a Brookfield viscosity of 16,800 cP (spindle #7, 50 rpm) that was more viscous than the Example 5. The higher emulsion viscosity is mainly an attribute of a more viscous fuel blend used in this example. The viscosity measurement was taken within 1 minute of its formation at sample temperature of 60° C. The size of the oxidizer solution droplet was then measured using an optical microscope within 24 hours of its collection. Analysis of the droplet pictures showed that the size distribution of the droplets was a normal distribution function with average size of 15 μm and standard deviation of 9 μm. The sample was a quality water-in-oil emulsion that was not phase separating for at least 90 days.
The experiment in Example 8 was following the mixing procedures that were used in Example 4, however modified fuel blend formulation was employed (Table 8). The oxidizer to fuel blend feeding ratio into the Star Laminator pre-mixer unit was maintained at 1:1.
The experimental work has shown that the Micro-orifice mixer can be employed to produce good quality emulsion when different formulations of oxidizer solution and fuel blend are used.
The conversion of flow energy into mixing in the micro-orifice mixer was as efficient as in Example 4, as reflected in the similar pressure drop across the unit for both oxidizer solution and fuel blend feeds.
The oxidizer solution used in this example was the same as the ones used in Example 6 and 7 while the fuel blend was more viscous than the fuel blends in Examples 6 and 7.
The material produced in the Example 8 was a stable emulsion with a Brookfield viscosity of 19,200 cP (spindle #7, 50 rpm) that was more viscous than the sample shown in Examples 6 and 7. The higher emulsion viscosity was attributable to a more viscous fuel blend and the higher oxidiser solution to fuel blend ratio in the emulsion.
The viscosity measurement was taken within 1 minute of its formation at sample temperature of 55° C. Sample was an excellent water-in-oil emulsion that was not phase separating for at least 90 days.
The experiment in Example 9 followed mixing procedures that were used in Example 5, however, the oxidizer and fuel blend were modified as shown in table 9 below. The oxidizer to fuel blend feeding ratio into the pre-mixer unit was maintained at 2:1.
The experimental work has shown that the Micro-orifice mixer can be employed to produce good quality emulsion when different formulations of oxidizer solution and fuel blend are used.
The conversion of flow energy into mixing in the micro-orifice mixer was as efficient as in Example 5, reflected in the similar pressure drop across the unit for both oxidizer solution and fuel blend feeds.
The material produced in Example 9 was a stable emulsion with a Brookfield viscosity of 21,600 cP (spindle #7, 50 rpm). It is more viscous than the emulsion in Examples 6 and 7. The higher emulsion viscosity was attributable to a more viscous fuel blend and the higher oxidiser solution to fuel blend ratio in the emulsion. The viscosity measurement was taken within 1 minute of its formation at sample temperature of 55° C. Sample was an excellent water-in-oil emulsion that was not phase separating for at least 90 days.
The experiment in Example 10 was following the mixing procedures that were used in Example 4, however modified oxidizer and fuel blend formulation was employed (Table 10). The oxidizer to fuel blend feeding ratio into the Star Laminator pre-mixer unit was maintained at 1:1.
The experimental work has shown that the Micro-orifice mixer can be employed to produce good quality emulsion when different formulations of oxidizer solution and fuel blend are used. In this case an oxidizer solution based on Ammonium Nitrate and Sodium Nitrate was used. Furthermore, also combination of a two different emulsifiers and different oils was employed.
The conversion of flow energy into mixing in the micro-orifice mixer was as efficient as in Example 4 and is reflected in the similar pressure drop across the unit for both oxidizer solution and fuel blend feeds.
The material produced in Example 10 was a stable emulsion with a Brookfield viscosity of 19,600 cP (spindle #7, 50 rpm). The viscosity measurement was taken within 1 minute of its formation at sample temperature of 60° C. Sample was an excellent water-in-oil emulsion that was not phase separating for at least 90 days.
The experiment in Example 11 was following the mixing procedures that were used in Example 4, however modified oxidizer, fuel blend and phase ratio of the components was used as per table 11 below. The oxidizer to fuel blend feeding ratio into the Star Laminator pre-mixer unit was maintained at 1:1.
The experimental work has shown that the Micro-orifice mixer can be employed to produce good quality emulsion when different formulations of oxidizer solution and fuel blend are used. In this case an oxidizer solution based on Ammonium Nitrate and Sodium Nitrate was used. Furthermore, also combination of a two different emulsifiers and different oils was employed.
The conversion of flow energy into mixing in the micro-orifice mixer was as efficient as in Example 4 and is reflected in the similar pressure drop across the unit for both oxidizer solution and fuel blend feeds.
The material produced in Example 11 was a stable emulsion with a Brookfield viscosity of 15,200 cP (spindle #7, 50 rpm). The viscosity measurement was taken within 1 minute of its formation at sample temperature of 60° C. Sample was an excellent water-in-oil emulsion that was not phase separating for at least 90 days.
The experiment in Example 12 was following the mixing procedures that were used in Example 4, however modified oxidizer, fuel blend and phase ratio of the components was used as per table 12 below. The oxidizer to fuel blend feeding ratio into the Star Laminator pre-mixer unit was maintained at 1:1.
The experimental work has shown that the Micro-orifice mixer can be employed to produce good quality emulsion when different formulations of oxidizer solution and fuel blend are used. The oxidizer solution used in this example was mainly comprised of chemically pure ammonium nitrate (77%) and water. The fuel blend comprised of mineral oil, canola oil and emulsifier.
The conversion of flow energy into mixing in the micro-orifice mixer was as efficient as in Example 4 and is reflected in the similar pressure drop across the unit for both oxidizer solution and fuel blend feeds. However, those pressure numbers were also affected by setting the production rate at lower value of 100 g/min.
The material produced in the Example 12 was a stable emulsion with a Brookfield viscosity of 15,000 cP (spindle #7, 50 rpm). The viscosity measurement was taken within 1 minute of its formation at sample temperature of 55° C. Sample was an excellent water-in-oil emulsion that was not phase separating for at least 90 days.
The Example 13 was prepared following the mixing procedures of Example 3, with an exception that the precursor material was taken directly from the outlet of the Star Laminator mixer and conducted to an inlet of the Micro-orifice mixer as used previously in the Example 4.
The oxidizer to fuel blend feeding ratio into the Star Laminator unit was maintained at 1:1. Modified oxidizer and fuel blends were used and phase ratio between the two components was also modified.
In this example, micro-orifice mixer was also used in combination with Star Laminator micromixer to further mix the water-in-oil dispersion produced by the Star Laminator. The oxidizer solution used in this example comprised of chemically pure ammonium nitrate (79.7%), urea and water, while the fuel blend comprised of mineral oil, canola oil and emulsifier.
The conversion of flow energy into mixing in the micro-orifice mixer was more efficient in comparison to the previous examples. It was reflected in the lower pressure drop across the unit for both oxidizer solution and fuel blend feeds. However, those pressure numbers were also affected by setting the production rate at lower value of 100 g/min.
The material produced in Example 13 was a stable emulsion with a Brookfield viscosity of 16,200 cP (spindle #7, 50 rpm). The viscosity measurement was taken within 1 minute of its formation at sample temperature of 60° C. Sample was an excellent water-in-oil emulsion that was not phase separating for at least 90 days.
Example 14 was performed following the mixing procedures of Example 3, with an exception that the precursor material was taken directly from the outlet of the Star Laminator mixer and conducted to an inlet of the Micro-orifice mixer as used previously in the Example 4. The oxidizer to fuel blend feeding ratio into the Star Laminator unit was maintained at 1:1.
The oxidizer solution and fuel blend used in this example is shown in table 14 above.
In order to test the capability of the Micro-orifice mixer unit to produce stable emulsion, a very high mass phase ratio of the oxidizer solution to fuel blend was selected. It is well known in the art that about 2% continuous organic phase in water in oil emulsion is the practical minimum to allow formation of stable emulsions.
The experiment employed phase ratio of 98% oxidizer solution and 2% fuel blend, which is close to the critical point of a stable w/o emulsion. In the experiment the production flow rates were lowered to 40 g/min in order to increase the residence time of mixing. It has been shown that it is advantageous to select the lower end of the flow rates (from the available flow range) in the micromixer process to ensure formation of stable emulsions, when critical ratios of oxidizer to fuel are used.
The material produced in Example 14 was a stable emulsion with a Brookfield viscosity of 16,400 cP (spindle #7, 50 rpm). The viscosity measurement was taken within 1 minute of its formation at sample temperature of 60° C. A good quality water-in-oil emulsion remained stable for at least 90 days was produced.
Example 15 was performed following the mixing procedures of Example 3, with an exception that the precursor material was taken directly from the outlet of the Star Laminator mixer and conducted to an inlet of the Micro-orifice mixer as used previously in the Example 4.
The oxidizer to fuel blend feeding ratio into the Star Laminator unit was maintained at 1:1. Modified oxidizer and fuel blends were used and phase ratio between the two components were also modified as seen in table 15 below.
Example 15 has shown that the Micro-orifice mixer unit is capable to produce a high quality emulsion regardless of the oxidizer or fuel materials selection. The oxidizer solution used in this example comprised of chemically pure ammonium nitrate, calcium nitrate and water. The fuel blend comprised of paraffinic oil and emulsifier.
The widely known type emulsifier, the Sorbitan Monooleate was used in this experiment. The conversion of flow energy into mixing in the micro-orifice mixer was slightly more efficient in comparison to the previous examples. It was reflected in the lower pressure drop across the unit for both oxidizer solution and fuel blend feeds. However, the lower pressure drop in the fuel blend line might be a result of lower viscosity of the fuel blend.
The material produced in Example 15 was a stable emulsion with a Brookfield viscosity of 6,900 cP (spindle #7, 50 rpm). The viscosity measurement was taken within 1 minute of its formation at sample temperature of 63° C. Even though the viscosity of the sample was lower compared to the other example, the sample was a good water-in-oil emulsion that was not phase separating for at least 30 days.
Example 16 was performed following the mixing procedures of Example 3, with an exception that the precursor material was taken directly from the outlet of the Star Laminator mixer and conducted to an inlet of the Micro-orifice mixer as used previously in the Example 4. The oxidizer to fuel blend feeding ratio into the Star Laminator unit was maintained at 1:1.
Example 16 demonstrates that the Micro-orifice mixer unit can be used to produce good quality emulsion with different formulations of oxidizers and fuels, while also have the phase ratio between the components varied.
The oxidizer solution used in this example comprised of chemically pure ammonium nitrate and water. The fuel blend comprised of paraffinic oil, canola oil and emulsifier. The conversion of flow energy into mixing in the micro-orifice mixer was as efficient as in previous examples and this is reflected in the similar pressure drop across the unit for the oxidizer solution and fuel blend feeds.
The material produced in this example was a stable emulsion with a Brookfield viscosity of 15,800 cP (spindle #7, 50 rpm). The viscosity measurement was taken within 1 minute of its formation at sample temperature of 60° C. The sample was a good water-in-oil emulsion that was not phase separating for at least 90 days.
The sample was converted into emulsion explosive by sensitizing the intermediate emulsion by adding 6-8 mm diameter polystyrene beads to reduce its density to 0.8 g/cc. Explosive characteristic in terms of velocity of detonation (VOD) was recorded at 2.55 km/sec by employing fibre optic cable and fast timer detection.
Number | Date | Country | Kind |
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201005918.6 | Aug 2010 | SG | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/AU2011/001037 | 8/12/2011 | WO | 00 | 4/16/2013 |