Difference between revisions of "Ballistic Vests"

1) Technology Roadmap Sections and Deliverables

The selected technology that Team 6 will be spending the remainder of the semester on developing a technology road map is ballistic vest technology (specifically for military and law enforcement applications).

Clear and unique identifier:

• 2BV - Ballistic Vests

This indicates that we are dealing with a “level 2” roadmap at the product level.

1.1 Roadmap Overview

The working principle and architecture of Ballistic Vests is depicted in the below.

A ballistic vest works by absorbing the kinetic energy from a high-speed projectile (bullet or shrapnel from an explosion) at the point of impact over a wide area. The ballistic vest is meant to spread the kinetic energy by displacing it across the ballistic vest materials in a process called material deformation. The deformation occurs in two-fold, deformation of the ballistic vest materials as the bullet absorbs the kinetic energy and deformation of the bullet itself, called mushrooming. The remainder of the energy is consumed as heat.

This technology is a lifesaving technology to aid military personnel and law enforcement during their daily activities. A ballistic vest is typically worn on an individual’s chest and is meant to be replaced after it has taken an impact (from high speed projectile or mishandling of vest e.g. dropped) or date of manufacturing has expired. There are six levels of protection (Type I, Type IIA, Type II, Type IIA, Type III, and Type IV). The history of personal armor dates back to 500 BC when chain mail/coat mail was used as a form of individual protection from slashing blows by an edged weapon (e.g. swords). Modern day individual body armor is meant to protect from high speed projectiles. New fibers were discovered in the 1960’s for the possibility to make resistant vests and DuPont developed Kevlar ballistic fabric in the 1970s.

1.2 Design Structure Matrix (DSM) Allocation

The 2-BV tree that we can extract from the DSM above shows us that the Ballistic Vest (2BV) is part of a larger initiative on personnel protection (1PP), and that it requires the following key enabling technologies at the subsystem level: 3SA Soft Armor, 3HA Hard Armor.

1.3 Roadmap Model using OPM

We provide an Object-Process-Diagram (OPD) of the 2BV roadmap in the figure below. This diagram captures the main object of the roadmap (Ballistic Vest), its various instances including common ballistic vest products, its decomposition into components (front carrier/panel, rear carrier/panel, side carrier/panel, soft armor (front & rear), hard plate (front, back, & sides, etc.), its characterization by Figures of Merit (FOMs) as well as the main processes (Protecting with two states protected and unprotected).

An Object-Process-Language (OPL) description of the roadmap scope is auto-generated and given below. It reflects the same content as the previous figure, but in a formal natural language.

1.4 Figures of Merit

The table below show a list of FOMs by which ballistic vest can be assessed.

1.5 Alignment with Company Strategic Drivers

The table below shows our companies strategic drivers and alignment of 2BV technology with roadmap.

The two strategic drivers show that the company views the next generation of soft body armor as a potential new business product that will generate $X revenue by 2035. Strategic Driver 1 of a Type II level soft ballistic vest has the alignment and targets of 10 more kilograms of payload than current model. The companies new Level 2's payload will be greater than competitors Level 2 and Level 2a, thus increased value in payload compared to competitors). Strategic Driver 2 of a Type IIIa level soft ballistic vest has the alignment and targets of new Level 3a's payload will be the same as the competitors Level 2 payload, but with an increased value in protection level.

1.6 Positioning of Company vs. Competition

The tradespace below shows the position of our Company to the Competitors for various soft body armor protection models. Utopia is marked with a green dot. The competitor (red circles) is currently on the Pareto Front (denoted in below curve line) and our company (blue circles) is slightly off of the Pareto Front. In order to gain market share and provide added value to the customer, we need to push the pareto curve with our road map driven by our two strategic drivers and alignment of targets.

1.7 Technical Model

In order to assess the feasibility of technical (and financial) targets at the level of the 2BV roadmap it is necessary to develop a technical model. The purpose of such a model is to explore the design tradespace and establish what are the active constraints in the system. The first step can be to establish a morphological matrix that shows the main technology selection alternatives that exist at the first level of decomposition, see the figure below.

Our technical model of the ballistic vest is the dimensionless composite ballistic performance index U* developed by Cunniff as mentioned in Q2. This composite index is:

Interestingly, every unit change of these 3 parameters get same unit of change of the first FOM, but increase in strength and strain increases Wabs and increase in specific gravity decreases Wabs.

Again, one unit of change in Young’s modulus and one unit of change in specific gravity lead to same unit of change in strain wave velocity, but increasing modulus increases Vs, and increasing specific gravity decreases Vs.

Therefore in Figure 4-1, a small change in strength, strain and specific gravity almost does not change the specific energy absorption at this design point.

One can see that in Figure 4-2, 1 unit increase in modulus increases 0.5 unit of strain wave velocity, and 1 unit decrease in specific gravity increases 0.5 unit of strain wave velocity. These are significant effects than those in the specific energy absorption. We can choose different design variables based on these,

Table 4 summarizes the morphological matrix for a soft body armor (optionally with hard plates).

Table 4 Morphological Matrix for Soft Body Armor Design

From Table 4, one can see that with increasing protection level, the payload is decreasing. A simple trade space is that one needs to choose trade off between the protection level and payload. If the customer needs more protection on body, then they have to choose to carry less equipment or ammunition, and vice versa.

(Note: the body armor weight is estimated from literature data, not the real product performance data which are difficult to access. These data include soft body armor made of different materials.).

1.8 Financial Model

The figure below contains a sample NPV analysis underlying the 2BV roadmap.

WORKING / UNDER-CONSTRUCTION - Assignment 4

List of R&T Projects and Prototypes

In order to select and prioritize R&D (R&T) projects we recommend using the technical and financial models developed as part of the roadmap to rank-order projects based on an objective set of criteria and analysis.

WORKING / UNDER-CONSTRUCTION - Assignment 4

1.9 Key Publications, Presentations and Patents

A thorough literature review of key publications, presentations, and patents was conducted for our technology of choice, ballistic vest material used in soft body armor.

The analysis focused on two particular areas:

Area 1: what materials can improve soft body armor’s ballistic performance? And getting a material, what structure of the body armor would maximize the material properties?

Area 2: what material properties governs the ballistic performance?

Patent Analysis When dealing with materials, it is necessary to analyze both the material and the process. In the soft body armor material history, two patents have been remarkably important.

Patent 1: Hill HW Jr, Kwolek SL, Morgan PW. Polyamides from reaction of aromatic diacid halide dissolved in cyclic nonaromatic oxygenated organic solvent and an aromatic diamine, US3,006,899, DuPont, 1957.

Patent 2: Blades H. Dry jet wet spinning process, US3,767,756, DuPont, 1972. The first patent, US3,006,899 disclosed how to make an aromatic amide polymer which is known later as Kevlar®. Before this patent, the strongest synthetic material is nylon fiber which is polymerized with aliphatic units. DuPont attempted to use aromatic units to replace the aliphatic units in nylon to improve its physical properties such as strength and thermal resistance. They were able to synthesize a wholly aromatic amide polymer as disclosed in this patent filed in 1957 and granted in 1961.

Patent 3: Leach J, Fash WG, Ballistic Vest, Burlington Industries, US3,891,996, 1974. Soon after the successful development of Kevlar® fiber (with the patent disclosure in 1974), a ballistic vest patent was filed in 1974 by using aramid (aramid is aromatic amide polymer) fiber. The independent claim (claim 1) in this patent is:

A ballistic vest comprising: at least one member formed of a plurality of layers of alternately placed woven fabric sheets of (1) ballistic nylon fiber and (2) aramid fiber, said member being sewn so as to prevent substantial relative movement between said layers; and means for securing said member to the torso of a person.

Patent 4: Harpell GA, Paelley I, Kavesh S, Prevorsek DC. Ballistic-resistance composite article, US4,748,064, 1985, Allied Corp.

Patent 5: Harpell GA, Prevorsek DC, Li HL, Flexible multi-layered armor, US5,175,040, 1991. Allied-Signal. When a material breakthrough is achieved, it is hard to make next breakthrough in a short time. Most of the work is to optimized the use of the newly developed material. Soft body armor (ballistic vest) is an article with a structure. Most of the work has been focused on how to optimize the structure of the vest made of the newly developed material. Traditionally the textile soft body armor was made by interweaving. In this Allied Corp (later Honeywell) disclosed a non-woven structure that has improved ballistic performance by aligning fiber unidirectionally. The interweaving was removed from the structure. This structure is claimed in the dependent claim 4:

Claim 4: An article as recited in claim 1 where in said network of fibers comprises a sheet-like fiber array in which said fibers are arranged substantially parallel to one another along a common fiber direction. This kind of configuration is shown in Figure 2-4. This innovation structure improved the ballistic performance as opposed to the traditional interwoven structure. The results are extracted from the patent and compared in Table 2-2.

The improvement is 15.4% by simply changing the structure. This improvement seems not large, but it is indeed significant enough to make difference. Imagine if one soldier wears a vest of 10 lbs weight, and 15.4% reduction in weight is 1.5lbs. If this 1.5lbs are freed and he could carry 1.5lbs more ammunition, that can make a huge difference in time of needs.

Key Publications

Paper 1: Roylance D, Wilde A, Tocci G, Ballistic Impact of Textile Structures, Textile Research Journal, 1973, 43: 34-41. In this paper, Roylance et al described how the impact energy dissipated through longitudinal wave front and transverse wave front. They compared the ballistic performance of different fabrics made of fibers with different properties. And found that the fiber properties (the tensile properties) did not have correlation with the fabric ballistic performance. This indicates that the fiber properties are at least not the only governing factor for the ballistic performance.

Paper 2: Cunniff, PM, Dimensionless parameters for optimization of textile-based body armor systems. In: Proceedings of the 18th International Symposium on Ballistics, San Antonio, Texas, 15-19 Nov 1999. Pp 1303-1310. Since the invention of Kevlar® aramid fiber, people had been wondering what are the governing materials properties that contribute to the ballistic performance. It was believed that the material strength is the most critical property to ballistic performance. But carbon fiber has much higher strength than Kevlar® aramid fiber, it does not exhibit good ballistic performance. Then it is also believed that the most critical property is the total amount of energy at break which can be obtained on a tensile machine. However, nylon fiber has higher energy at break in tensile testing, but it does not have good ballistic performance. Table 2-3 compares the mechanical properties of carbon fiber, Kevlar® aramid fiber and nylon fiber.

Paper 3: Lim JS, Lee BH, Lee CB, Han IS, Effect of the weaving density of aramid fabrics on their resistance to ballistic impacts, Engineering, 2012, 4, 944-949.

In this paper, two different structure of aramid fabrics were compared. Both structures have very similar weight, but one (HT 600-1) has higher crimp ratio (the fiber is less straight) than the other (HT 600-2).

(a) A bottom view of the crushed bullets retrieved from HT600 fabrics

(b) Perforated regions of two HT-600 fabrics impacted by the projectile.

Figure 2-6 Ballistic testing performance of HT600 fabrics (Source: Lim JS, Lee BH, Lee CB, Han IS, Effect of the weaving density of aramid fabrics on their resistance to ballistic impacts, Engineering, 2012, 4, 944-949.) The testing results suggested that higher crimp in fabric leads to poorer ballistic performance. This indication supports the claim in the patent 4 mentioned above where the fiber is perfectly straight without any interweaving.

1.10 Technology Strategy Statement

A technology roadmap should conclude and be summarized by both a written statement that summarizes the technology strategy coming out of the roadmap as well as a graphic that shows the key R&D investments, targets and a vision for this technology (and associated product or service) over time.

WORKING / UNDER-CONSTRUCTION