Concepts of Logistics System Design Richard C. Owens, Jr. Timothy Warner Concepts of Logistics System Design Richard C. Owens, Jr. Timothy Warner Contents Acronyms and Terms...................................................................................................................................v 1. Purpose of Logistics Systems ...............................................................................................................1 2. Physical Structure of the System ..........................................................................................................3 3. Management Structure of Logistics Systems........................................................................................5 4. Information Flow .................................................................................................................................7 5. Types of Inventory Control Systems .................................................................................................. 14 6. Storekeeping ...................................................................................................................................... 17 Figures 1. Minimal Logistics Information System................................................................................................. 8 2. Inventory Control Card ......................................................................................................................... 9 3. Requisition and Issue Voucher............................................................................................................ 11 4. Quarterly Report & Request for Contraceptives ................................................................................. 12 5. Daily Activity Register (Family Planning) ......................................................................................... 13 6. Model Warehouse ............................................................................................................................... 18 7. Guidelines for Proper Storage............................................................................................................. 19 Acronyms and Terms consumption records Log recording quantities dispensed to each client and regular report that summarizes these data for higher-level management use FEFO first-to-expire, first-out JSI John Snow, Inc. MCH maternal and child health outlet Facilities that dispense commodities to end users pull system requisition system primary supply point Facilities that receive supplies from a source push system allocation system sources Facilities outside the system from which commodities are supplied stock-keeping record Must include inventory control cards; may include additional records transaction records Records of the amount shipped from one facility to the next and records of amounts ordered (for requisition systems) USAID U.S. Agency for International Development A frequent problem in logistics system design is that projects are undertaken piecemeal, without an organized framework for analysis. Consequently, systems are developed that are too complex or too inflexible to change as the program environment changes. The following pages discuss some of the most important issues in the design of logistics systems and describe briefly several different types of systems. Purpose of Logistics Systems The purpose of a logistics system is simple: to obtain and move supplies and equipment in a timely fashion to the places where they are needed, at a reasonable cost. Matters are complicated by the fact that equipment and supplies usually cannot go directly from their source to the end user; they frequently must be held as inventory at one or more intermediate points along the way. There are only four reasons for holding inventory: 1. Transportation efficiency: It is not reasonable to ship single bottles of pills across the ocean or to deliver maternal and child health (MCH) kits to a clinic daily; thus, shipments are made in batches of a size and frequency dictated by the transportation system. 2. Safety stocks: Because trucks break down and roads wash out, and because actual demand usually cannot be predicted very accurately, facilities must maintain safety stocks to ensure that they do not run out in times of high demand or late resupply. 3. Storage capacity: If a facility close to the end user has limited storage space, then inventory must be held at the next higher level in the system, and must be delivered more often. 4. Anticipation: In a program that is growing or changing, it is necessary to store inventory in anticipation of demand that does not exist yet because of the length of time between ordering supplies and receiving them. Any system that stores inventory for reasons other than these is a candidate for streamlining. It is important to remember the overriding principle of logistics system design: the system must be simple. Its purpose is to move supplies, not to create paperwork. Physical Structure of the System A logistics system’s physical structure consists of two things: stationary facilities and the transportation links between those facilities. Logistics jargon further distinguishes those facilities that are outside the system (such as drug manufacturers) from which commodities are supplied; these are called “sources.” Facilities that receive supplies from a source (such as a central medical store) are called “primary supply points.” Facilities that dispense commodities to end users are called “outlets.” Whatever names are used, there are six important things to know about the facilities: 1. Where is the facility located? 2. How is it staffed? 3. What is the actual need for each commodity at the facility and how does this need vary over time? 4. What is the facility’s storage capacity? 5. What are the storage conditions, and are they suitable for the items being stored? 6. How is the inventory controlled, and is it secure? In describing the physical structure of the logistics system, it is important to note the number of links into each facility. The more links there are, the more confused the system is likely to be. At the top, the primary supply points probably will receive commodities from a number of sources. At lower levels of the system, however, it is usually desirable to limit each facility to receiving supplies through only one link (possibly with a different link for emergency backup). Similarly, there are five important things to know about transportation links: 1. What types of transportation are available? 2. What size batches of commodities are cost-effective to transport? 3. How long does it take to get from one facility to the next? 4. How often can shipments be made? 5. Are the answers to these questions different during different seasons of the year? With this basic information in hand, the logistics system’s management structure can be designed. Management Structure of Logistics Systems The essential questions in understanding the management structure of a logistics system are—Who decides what (and when and how many) commodities move through a link from one facility to the next, and how does he/she decide? There are two general types of logistics systems: 1. Allocation or “push” systems 2. Requisition or “pull” systems In an allocation system, the higher-level facility decides what commodities move down the system and when they move down. It “pushes” them through the system. In a requisition system, the lower-level facility orders commodities as the need arises, thus “pulling” supplies through the system. The advantages of a requisition or “pull” system are that it can be based on current information about actual needs, and thus, in theory, is more accurate and less wasteful than an allocation system. Decision making is decentralized to lower levels and each manager has a narrower scope of concern. The disadvantages of requisition systems are related directly to these advantages. Requisition systems will work only if accurate information about needs exists or can be obtained, and if lower level staff have sufficient management training and support to make appropriate decisions about ordering. Allocation or “push” systems are, therefore, appropriate when accurate information on needs is not available or where management skill is concentrated at higher levels of the service system. If demand significantly exceeds supply, an allocation system must be used to divide scarce commodities among competing facilities. Where allocation systems are used, every effort should be made to base allocations on appropriate estimates of actual need. This management structure may differ at different levels of the system; higher levels may requisition and then allocate to lower levels. Even at a single level, the system may be mixed. A regional warehouse might allocate stock to a health center every three months, but the health center may be able to request additional supplies, if needed, in the interim. Also, it may be desirable to use different procedures for equipment, which is essentially a one-time problem, than for supplies, which must be restocked on a continuing basis. In addition to the question of who makes the decisions to move commodities, there is the question of how the decision is made. It already has been stated that the decision should be based on a projection of actual need; such an assessment is called forecasting or quantification. A full discussion of forecasting is beyond the scope of these few pages; here it is only important to note that an adequate forecasting process must consider three things: 1. Historical data: The decision maker must consider the actual past use of commodities and how that use pattern has changed over time; this can be done simply by graphing the data. 2. Future program plans: The decision maker must know what the future plans for the program are and have some way of realistically estimating the effect of those plans on the demand for commodities. 3. Underlying assumptions: The decision maker must use proper assumptions about how demand varies over time; for example, in a new program, demand is usually slow at first, then increases rapidly, and finally levels off. Information Flow As the earlier discussion implies, only three things happen in a logistics system: commodities move down through the system, commodities are held in inventory at various points, and commodities are dispensed to users for subsequent consumption. Accordingly, there must be three different types of records in the logistics information system: 1. Stockkeeping records: These must include inventory control cards, but may also include additional records for accountability and prevention of theft. 2. Transaction records: These include records of the amount shipped from one facility to the next and records of amounts ordered (for requisition systems). 3. Consumption records: While some programs do without these, it is much better to have log books to record quantities dispensed to each client and a regular report that summarizes these data for higher-level management use in forecasting and resupply decisions. Decisions regarding the level of accountability and control in the logistics system should weigh the level of effort and the amount of paperwork required. In some cases, it may be less expensive to permit a certain amount of theft or shrinkage rather than to create a complex and unwieldy information system. Figure 1 shows a minimal logistics management information system. The inventory file is preferably an individual card for each item in stock, but could also be a page for each item in a ledger book. Regardless of the format of the inventory file, it must contain the following four items of data in an easily retrievable form: 1. Current stock level 2. Amount of stock on order (for requisition systems) 3. Historical data on times and shipment quantities, both into and out of the facility 4. Losses/adjustments In addition, it may be convenient to show ordering rules for requisition systems directly on the inventory file, including items such as order point and order size, which are discussed in section 5. For products with a limited shelf life, expiration or manufacture dates, lot identifiers, or quality control data may be needed. Figure 2 is a sample idealized inventory control card. Any data beyond these basic items should be included in the inventory file only if a good justification for their use can be made. Routine reporting of any of these data to higher levels of the system must be carefully justified in terms of immediate utility for ordering or allocation decisions. Figure 1. Minimal Logistics Information System Figure 2. Inventory Control Card INVENTORY CONTROL CARD Commodity Number Description Unit Maximum Stock Minimum Stock Location Date Transaction Reference Quantity Received Quantity Issued Losses/ Adjustments Quantity on Hand Quantity on Order Transaction records are quite simple; they need to specify only what is being ordered or shipped, by whom, and when. The purposes of transaction records are to— 1. Specify amounts being ordered (requisition systems only). 2. Provide authorization to ship/receive commodities. 3. Provide proof that goods shipped are actually received, and to initiate corrective action if they are not. Figure 3 shows a sample idealized transaction form suitable for use in a pull system. Again, additional information should be included only if a definite use for it can be specified. Beyond the inventory file and transaction records, inventory systems with many levels will have some sort of summary reporting for management control purposes. The summary report could include only stock balances, but also may include information on issues and receipts, stock destroyed or expired, and so forth. Again, only information that will actually be used for decision making should be reported. A sample of such a summary report is shown in figure 4. The consumption records from which such reports are generated will vary from program to program depending on what services are provided and tracked. Figure 5 shows a sample consumption log from a comprehensive family planning program. With the dramatic recent decreases in the prices of computer hardware and software, now it is possible for even small organizations to consider automation of their logistics information systems. A variety of commercial and public sector general software programs have been written for this purpose, including several designed specifically for logistics management in health and family planning programs. Any organization desiring to automate should investigate the applicability of these packaged programs before attempting to develop customized software on its own. Organizations should also remember two essential facts: the price of computer programmers (as opposed to programs) continues to go up, not down, and automation should be considered only after a rational, streamlined commodity distribution system has been designed. Figure 3. Requisition and Issue Voucher REQUISITION AND ISSUE VOUCHER Requisition and Issue Voucher No.: Date: Ship to: REQUISITION ISSUE Article Quantity on Hand Quantity Requested Shipped Received Remarks Remarks REQUISITION Requested by: Date: Approved by: Date: ISSUE: Approved by: Date: Shipped by: Date: RECEIPT: Received by: Date: (make 4 copies) Figure 4. Quarterly Report & Request for Contraceptives QUARTERLY REPORT & REQUEST FOR CONTRACEPTIVES Province:_________________________ District_____________________ Location: Facility type: Depot: District Store: SDP/Clinic: Other: Report for Quarter Beginning: ____________, 20 Ending , 20 Contraceptive Beginning Balance Received This Quarter Dispensed/ Issued Losses/ Adjustments Ending Balance Quantity Needed Microgynon Neogynon Microlut Nordette Trinordial Depo-Provera Noristerat NORPLANT Copper T Multiload Condoms Foaming Tablets Gloves Submitted: Date: Explanation of losses: Figure 5. Daily Activity Register (Family Planning) DAILY ACTIVITY REGISTER (FAMILY PLANNING) SDP/Clinic Month: Name: Number: Year: Client Type Contraceptives Dispensed at this Visit Referrals Oral Contraceptives Injectables IUDs Date Name of Client Client Number New Revisit Microgynon Neogynon Eugynon Microlut Nordette Logynon Trinordial Depo-Provera Norsterat NORPLANT NORPLANT Copper T Nova T Multi-load Condoms Condoms Foaming Tablets Sterilization Natural FP Gloves Gloves Comments/Remarks Types of Inventory Control Systems As the earlier discussion implies, there are two primary questions to answer in logistics system design. (1) Who will make the ordering decision? (2) What is the smallest amount of information on which those decisions can be based? The ordering decision must answer two questions: 1. How much should be ordered? 2. When should it be ordered? A full discussion of the types of logistics systems is beyond the scope of this paper. In theory, however, there are only three different types: 1. Fixed order size, variable order interval systems 2. Fixed order interval, variable order size systems 3. Combination systems In a fixed order size, variable order interval (or order point) system, a specific fixed amount of a commodity is ordered whenever inventory falls below a certain level, called the reorder point. Thus, for example, the decision rule might be, “Whenever there are fewer than 500 capsules of tetracycline, order 1,000 more.” The trick is to choose the reorder point so the new shipment is guaranteed to arrive before the remaining supply is exhausted. The advantage of this type of system is that it gives control on an item-by-item basis and thus minimizes excess stock. The disadvantage is that it is difficult to predict the transportation schedule and to batch many items for shipment. Therefore, where transportation is difficult or time-consuming, such systems are less appropriate. A simple version of a fixed order size, variable order interval system is a two-bin system, in which goods are packed in standard-sized bins that correspond to the reorder point. Each outlet initially is issued two bins. Supplies are drawn from one bin until it is empty, and then a new order is placed (preferably using a preprinted order form packed at the bottom of the bin). Supplies are then drawn from the second bin until it is exhausted, by which time the replacement bin should have arrived, and the procedure is repeated. The advantage of the two-bin system is that it requires no record keeping at the facility using it. In a fixed order interval, variable order size system, the ordering time is fixed at, for example, once per quarter, with the size of the order depending on stock remaining and projected use. The advantage of this type of system is that many items can be batched and shipped at the same time, thus reducing transportation problems and costs. A mixed, or combination system uses both strategies at the same time. Stocks are reviewed on a fixed schedule, but an order is placed only if inventory has fallen below a fixed reorder point. In logistics jargon, such systems are known as (s,S) systems, where s is the reorder point, and S is the amount that is requisitioned. S may be a predetermined absolute quantity, but it is more common to order the difference between the stock on hand and the desired maximum amount the facility wishes to store. This latter case is called a min-max inventory control system. A special version of the mixed system is called the regular replenishment system, in which the higherlevel facility visits its outlets on a regular basis, replenishing or “topping off” stock up to the maximum amount S. This system also does not require record keeping at the lower level. Storekeeping The systems for physical control of inventory at each facility will vary depending on staff and storage space available. A number of general concerns should be addressed at each location, however. The first consideration is security of the physical inventory. Minimum security measures include— 1. Ensuring that all stock movement is authorized by locking the storeroom, limiting access to persons other than the storekeeper and his/her assistants, and ensuring that both incoming and outgoing stock matches documentation. 2. Verifying authenticity of documentation by spot-checking signatures and so forth. 3. Periodically verifying inventory records by a systematic count of physical inventory. The second consideration is the facility’s physical layout. The ideal storeroom should have— 1. Two different points for receipt and dispatch of goods to provide for orderly flow of materials and to reduce opportunities for clerical error or theft. 2. A fixed location for each stocked item, with appropriate conditions (temperature, humidity) for the items being stored. 3. Adequate space for unpacking received material and for packing outgoing shipments. 4. A separate secure area for valuable items. 5. Adequate access to all items in the storeroom to allow for first-to-expire, first-out (FEFO) handling. Beyond these considerations, storage and handling of materials are governed by the characteristics of the products. Items with high turnover should be most easily accessible. Heavy items should be stored near the ground. Expensive items should be stored in the most secure area. For drugs and other perishables, temperature and humidity requirements must be considered. Perishable items must be appropriately dated, preferably with the expiration date. If the manufacturer does not include the expiration date, it should be estimated from the manufacturing date or, if no other date is available, from the delivery date. Many logistics systems include the expiration date on the inventory file card. While this may be convenient, it is much more important to include the expiration date directly on the item itself, and to strictly enforce a FEFO issue system. These storekeeping procedures are common sense. Nonetheless, it is usually helpful to develop simple storage guidelines, wall charts, or checklists for warehouse staff. Figures 6 and 7 provide examples. In summary, the storekeeping function, like any other function of the logistics system, requires little more than orderliness and efficiency. A warehouse that looks neat and organized probably is well managed; a warehouse that does not appear to be so certainly is not. Figure 6. Model Warehouse Figure 7. Guidelines for Proper Storage