Jul. 07, 2025
The technical security device consists of a security module, a storage medium and a standardised digital interface.
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The technical security device receives information from the electronic record-keeping system (e.g. a cash register), protects the data to be recorded against modification or deletion, and stores the secured records in a standardised format. Financial authorities can then request the protected data and audit it for completeness and accuracy.
The contact person for the act is the Federal Ministry of Finance, which is the responsible body.
You can find up to date technical information under 'Act to prevent tampering with digital primary accounting records'. The relevant technical guidelines and protection profiles are also published here.
Contact details for further technical questions:
Contacts for further questions on the steps involved in the certification process can be found under Product Certification.
The aim of the technologically open approach is to find the most pragmatic possible way of integrating technical security devices into existing cash register systems. This includes in particular the possibility of connecting several cash register systems to a centralised security device.
In principle, there are various technical implementation options, for example local (e.g. using smartcards) or remote (as a 'cloud' solution), provided the necessary safety and inter-operability requirements of the BSI are met and this is demonstrated as part of the certification.
Anyone can manufacture technical security devices, and the principle of technological openness applies. For the use of a technical security device to comply with the legal requires, documentation must be provided that the security and interoperability requirements of the BSI are complied with.
There will not be an individual implementation of the guidelines that all users are required to adopt.
Examples of (potential) providers of security devices or security modules may include manufacturers that work in the development of security elements, smartcards, hardware security modules (HSM) or data recorders. For reasons of equal treatment, the BSI cannot provide the names of any manufacturers.
Information regarding certified technical security devices is published after a certification is completed on the pages of the BSI under Product Certification.
In general, you should contact the manufacturer of your till or record-keeping system and ask which devices are available for your system.
The technical security device uses cryptographic keys to sign recordings. Certificates (files), which "certify" the secure origin of the key, are not linked to a person, in accordance with the requirements of the BSI. However, it may be the case that this is required by the concept of the TSD manufacturer. In each case, the financial authorities must be aware of the keys used. In other words, they must be registered to a tax-paying entity with the financial authorities.
The technical security device contains a function to export stored data. This exported data can be securely retained in an appropriate location. The retention requirements of the tax authorities must be complied with. If the data is retained securely, then it can be deleted in other locations.
If the data is requested for auditing, you must provide it in the export format of the security device.
No. The technical security device receives data and places a 'security layer' (meta-data and signature) over it. How this security layer is to be formatted and how the secured data can be exported from the security device is set out by the BSI in its guidelines.
The content and format of the data that must be entered into the security device externally for the purposes of protection is stipulated by the Federal Ministry of Finance.
Information regarding certified technical security devices is published after a certification is completed on the pages of the BSI under Product Certification.
Cash register systems can, however, be updated before completion of the certification process, regardless of whether the security module is certified.
Information regarding certified technical security devices is published on the pages of the BSI under Product Certification.
The BSI is aware of several German/European manufacturers that are currently producing or have previously produced comparable security devices.
Unfortunately, in view of its equal treatment of manufacturers, the BSI cannot provide a list of these manufacturers. The question of when and to what extent a manufacturer discloses the relevant details to the market is subject to its own planning processes and responsibility.
If you wish to contact (potential) manufacturers of security devices and security modules directly and ask them for further information, you could direct your enquiries towards manufacturers of security elements / smartcards / HSMs / data recorders.
In principle, there are various technical implementation options, either local (e.g. using smartcards) or remote (as a 'cloud' solution), provided the necessary security and inter-operability requirements of the BSI are met and this is demonstrated as part of the certification. If using a remote TSE, it must fundamentally always be reachable by all connected electronic record-keeping systems.
Yes. As part of technological openness, it is possible to use remote technical security devices or components of technical security devices. With this type of technical security device, however, a certified security module application must also be implemented in the cash register or the cash register network that allows a secure connection to be established with the remote hardware security module. With this type of security module application (BSI PP-SMAERS), the certification requirements are low, meaning that they can also be implemented in software.
As per Section 5 of the German Cash Register Anti-Tampering Ordinance, requirements for technical security mechanisms are set out in the BSI's well-known technical guidelines and security profiles. Accordingly, a technical security mechanism only conforms to this Ordinance if it also complies with the BSI's technical guidelines and security profiles.
The standards published by the BSI specify that the transaction number issued by a security module must be unique and sequential, and that it must be incremented by the security module each time a transaction is started. In particular, the security module must never issue an identical transaction number to two different transactions, even if these transactions originate in processes involving two separate cash registers.
The transaction number references the key within the security module. Following a key change, the transaction number starts again at '0'.
In order to comply with BSI standards, the transaction number in each SMAERS (Security Module Application for Electronic Recordkeeping Systems) instance must therefore be unique, and a separate signature key must be used within CSP for each SMAERS (Security Module Application for Electronic Recordkeeping Systems).
This unambiguous key assignment offers a significant advantage while also limiting the impact of a potential system compromise.
The certification costs for a technical security device consist of the costs of the evaluation for the appointed testing body and the fees payable to the BSI.
The BSI fees for the certification process are set by the BSI Cost Regulation.
The BSI cannot make any statements regarding the costs of the evaluation, as they are primarily based on the negotiations between a manufacturer and the relevant testing body.
In order to meet the legal requirement that all processes with mandatory recording are logged promptly, the security module must manage the system time independently to make manipulation at the recording times more difficult. There are no strict requirements with regard to the accuracy of the internal time source; in particular, the system time does not need to be updated in a deactivated state. Instead, the system time in the security module may be synchronised with external time sources manually or automatically. The setting of the system time is another process with mandatory recording that is triggered internally by the security module.
In the dynamic world of metal fabrication, the stamping press stands as a titan of transformation, shaping raw materials into intricate parts with the simple yet profound act of pressing. This guide is designed to walk you through the step-by-step journey of stamping press operation, from the initial setup to the final product. Whether you’re a seasoned professional or new to the field, this comprehensive overview will provide you with the insights and techniques needed to master the art of stamping. Join us as we delve into the heart of metalwork, exploring the precision and power of the stamping press, and uncover the secrets to efficient, high-quality production.
Stamping is not just a manufacturing process; it’s a sophisticated technique that transforms flat sheet metal into parts that are integral to countless products we use every day. From the delicate components inside your smartphone to the robust frame of your car, stamping is behind many of the metal parts in your life. The process involves placing metal sheets into a stamping press where they are shaped by a tool and die surface. This shaping must be precise, as even the slightest deviation can render a part unusable. The stamping process is a dance of force and control, requiring meticulous planning and execution to achieve the desired outcome.
The versatility of stamping presses is unparalleled. They are not limited to simple shapes; they can create parts with complex geometries and features that other manufacturing processes cannot achieve. This versatility is why industries from automotive to aerospace rely on stamping presses to produce parts that meet their exacting standards. The ability to work with a wide range of materials, from soft aluminum to hard titanium, further enhances the utility of stamping presses in manufacturing.
Mechanical stamping presses are a testament to human ingenuity in engineering. They harness the rotational energy of an electric motor, channeling it through a flywheel to generate the immense force needed for stamping. This conversion of energy is a key aspect of the press’s efficiency, allowing it to perform rapid, high-precision operations that are essential in today’s fast-paced manufacturing environment.
The high-speed capabilities of mechanical stamping presses make them suitable for large-scale production where time is of the essence. They are designed to perform complex tasks with a level of precision that manual processes cannot match. This makes them invaluable in industries where the volume is high, and the margin for error is low.
Hydraulic stamping presses operate on a different principle, using the power of fluid dynamics to exert force. These presses are masters of strength, capable of molding even the most resistant materials into the desired shapes. The hydraulic system multiplies the force applied, allowing for the manipulation of larger and thicker workpieces that mechanical presses cannot handle.
Hydraulic presses are the workhorses of the manufacturing world, ideal for applications that require both power and precision. They are particularly well-suited for custom, low-volume production where the flexibility of the press can be used to its full advantage.
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The bed of a stamping press is its foundation, providing a stable platform for the entire operation. It must be strong enough to withstand the forces of stamping without warping or shifting, as any movement could affect the quality of the parts being produced.
The construction of the bed is a critical consideration in the design of a stamping press. It is typically made from high-grade steel or iron, materials known for their strength and durability. The bed’s design often includes channels or slots for waste material to be ejected, keeping the work area clean and preventing damage to the press or the parts.
The slide, or ram, is the moving part of the press that delivers the force to the workpiece. It must move with precision, as any variation in speed or position could result in defects. The slide’s movement is controlled by a complex system of gears, cams, or hydraulics, depending on the type of press.
Controlling the slide’s movement is a sophisticated task that requires advanced technology. Modern presses often use computerized systems that allow for precise adjustments to be made quickly and easily. These systems ensure that each part is stamped with the same force and position, maintaining the consistency of the production run.
The flywheel is a critical component in mechanical stamping presses, acting as an energy storage device. It smooths out the power delivery, ensuring that the slide receives a consistent amount of energy with each stroke. This consistency is vital for maintaining the rhythm of the stamping process and producing uniform parts.
Regulating the flywheel’s energy is a delicate balance. Too much energy could damage the press or the part, while too little could result in an incomplete stamp. The regulation is typically handled by a combination of mechanical and electronic systems that monitor and adjust the energy flow as needed.
The clutch and brake system is what gives the operator control over the stamping press. The clutch engages to start the stamping motion, while the brake stops the slide at the right moment. This system must be responsive and reliable, as it is often used to prevent accidents or damage to the press.
Safety is a paramount concern in any manufacturing process, and the clutch and brake system is a key safety feature of a stamping press. It allows the press to be stopped quickly in an emergency, protecting both the operator and the equipment. Modern presses often include multiple safety systems, such as light curtains or pressure-sensitive mats, that work in conjunction with the clutch and brake to ensure a safe working environment.
This expanded content provides a deeper insight into the basics of stamping presses, highlighting their importance in modern manufacturing and the intricate details of their operation. Each component plays a crucial role in ensuring the efficiency, precision, and safety of the stamping process, making it a fascinating subject for those interested in industrial manufacturing technologies.
Preparation is the precursor to successful stamping press operations. It encompasses a series of meticulous steps that pave the way for a seamless and secure production process. This section delves into the critical preparatory measures, from rigorous safety protocols to precise material handling.
The precision of parameter settings in stamping operations cannot be overstated. It is the cornerstone of producing high-quality parts that meet stringent specifications. Incorrect settings can lead to material waste, increased tool wear, and even damage to the stamping press itself. Therefore, it is crucial to understand the relationship between the material being used, the design of the part, and the capabilities of the press. This understanding allows operators to make informed decisions about the pressure, speed, and stroke required for each job. By doing so, they ensure the production process is both efficient and effective, resulting in a high yield of parts that are consistent in quality and appearance.
Materials used in stamping processes vary widely, from soft metals like aluminum to hard, abrasion-resistant alloys. Each material has its own set of properties, such as tensile strength, ductility, and hardness, which influence how it behaves under the stress of stamping. For instance, softer materials may require less pressure but could be more prone to warping, requiring careful speed adjustments. Conversely, harder materials might need higher pressure levels to form correctly but can tolerate faster speeds without compromising the integrity of the part. Understanding these nuances is essential for setting parameters that align with the material’s characteristics, ensuring optimal outcomes.
Pressure requirements are a critical aspect of the stamping process, directly impacting the quality of the finished part. The necessary force is calculated based on the material’s yield strength and the area over which the force is applied. The formula
P=F×A
, where ( P ) represents pressure, ( F ) is force, and ( A ) is the area of the die, is fundamental in this calculation. Operators must consider factors such as material thickness and the complexity of the part design when determining the force required. This calculation ensures that the press exerts enough power to shape the material without causing damage or defects.
Speed is a pivotal factor in stamping operations, influencing both the production rate and the quality of parts. While higher speeds can lead to increased output, they may also introduce errors or inconsistencies if the material cannot be formed accurately at such rates. On the other hand, slower speeds enhance precision but may not be feasible for high-volume production due to reduced throughput. Finding the right balance is a matter of understanding the material’s behavior at different speeds and the tolerances required for the part being produced. Operators must adjust the speed settings to achieve a harmonious balance between efficiency and accuracy.
Stroke calibration is the process of setting the correct stroke length for the press, which is essential for ensuring that the die forms the material properly. The stroke length must be long enough to allow the die to close completely and shape the part without causing undue stress on the material or the press. However, it should not be so long that it leads to unnecessary wear on the machine or increases the cycle time. Calibrating the stroke requires a thorough understanding of the part dimensions and the material’s properties, as well as the press’s capabilities. Proper calibration ensures that each stroke is executed with precision, contributing to the overall efficiency and longevity of the stamping operation.
Small batch testing is a vital step in the stamping process, serving as a bridge between theoretical settings and real-world production. A well-structured test plan outlines the objectives of the testing, such as verifying the accuracy of the press settings or assessing the quality of the parts produced. It also sets the criteria for what constitutes a successful test, which may include dimensional accuracy, surface finish, and structural integrity. By establishing clear goals and success metrics, operators can conduct tests that provide meaningful data and insights, guiding any necessary adjustments before full-scale production commences.
Choosing the right samples for small batch testing is crucial for obtaining representative results. The selected samples should encompass the range of variations that might occur in full production, including extremes in material properties and part dimensions. This diversity ensures that the testing accounts for all potential scenarios, providing a comprehensive assessment of the stamping process’s capabilities. By carefully selecting samples, operators can identify and address any issues early on, reducing the risk of problems during full production.
Conducting small batch tests involves a controlled trial run of the stamping press, during which operators closely observe the material’s behavior and the performance of the die. This observation phase is critical for identifying any immediate issues, such as misalignment or incorrect pressure settings. Operators must also listen for unusual sounds or vibrations that could indicate problems with the press. Throughout the testing, detailed records of the process parameters and observations are kept, providing valuable data for analysis and future reference.
Measuring the outcomes of small batch tests is a meticulous process that involves using precision instruments like calipers or coordinate measuring machines (CMMs) to assess the dimensions and shapes of the parts produced. These measurements are compared against the specifications to determine if the parts meet the required standards. Visual inspection is also performed to check for surface defects or irregularities. The data collected during this phase is analyzed to understand how well the press settings align with the desired outcomes, informing any necessary adjustments.
When discrepancies arise during small batch testing, it’s essential to troubleshoot the issues systematically. Common problems can often be traced back to incorrect parameter settings, die alignment, or material inconsistencies. Operators must use the data gathered during testing to identify the root cause of the issue and make informed adjustments to the press settings. This problem-solving approach ensures that the stamping process is refined and optimized before moving on to full production.
Before transitioning to full production, it is imperative to validate the test results to ensure they are repeatable and indicative of a stable process. This validation involves conducting additional tests and comparing the results to the initial batch to confirm consistency. It also includes a review of the entire testing procedure to ensure that all variables have been controlled and accounted for. Once the process has been validated, operators can confidently scale up to full production, knowing that the press settings and procedures will yield high-quality parts.
Setting up for full production involves a series of final checks and preparations to ensure the stamping press and all associated systems are ready for increased output. This includes verifying the alignment of materials, ensuring the lubrication systems are functioning correctly, and conducting a final safety review. These preparations are critical for a smooth transition from testing to production, minimizing the risk of downtime or quality issues.
Continuous monitoring of the stamping press during production is essential for maintaining consistent part quality. This involves regular checks of the pressure, speed, and stroke settings to ensure they remain within the specified parameters. Operators must also be attuned to the press’s performance, listening for any changes in sound or operation that might signal wear or impending failure. By staying vigilant, they can address potential issues before they impact the production process.
Quality assurance protocols, such as statistical process control (SPC), play a crucial role in maintaining part quality throughout production. SPC involves collecting and analyzing data on various process parameters to detect any deviations from the norm. By implementing these protocols, operators can identify and correct variations early in the production cycle, ensuring that the parts produced meet the required standards consistently.
Accurate documentation and record-keeping are vital components of the stamping process. Detailed records of operations, adjustments, and maintenance activities provide a wealth of information for process improvement and troubleshooting. They also serve as evidence of compliance with industry standards and regulations. Maintaining thorough documentation ensures that the stamping operation runs smoothly and efficiently, with a clear history of actions taken and their outcomes.
This detailed expansion of each point provides a comprehensive overview of the operation process for stamping presses, offering practical insights and technical guidance for professionals in the field. The information is presented in a structured format, making it accessible and informative for readers seeking to enhance their understanding and execution of stamping operations.
Burrs, the small protrusions or spikes on metal parts, are more than an aesthetic issue; they are a critical quality concern. These imperfections can compromise the integrity of a component, leading to potential failure in its application. Burrs are typically formed during the cutting or shaping process when the tool tears or displaces material rather than making a clean cut. The presence of burrs can interfere with the assembly process, cause parts to fit improperly, and even pose a risk to users handling the parts. Therefore, identifying and removing burrs is a non-negotiable step in the manufacturing process.
The method chosen for deburring is contingent upon the part’s intended use, the material from which it is made, and the nature of the burrs themselves. Mechanical methods, such as tumbling or vibratory finishing, are common for general applications and are effective for removing burrs from large batches of parts. Thermal energy methods, like electrochemical deburring, are particularly useful for parts with complex geometries or hard-to-reach areas. These methods use controlled chemical reactions or thermal energy to precisely remove burrs without affecting the rest of the part.
The presence of burrs can significantly impact a part’s functionality. They can create weak points where stress is concentrated, leading to premature failure under normal operating conditions. In applications where parts must fit together with tight tolerances, burrs can prevent proper assembly, leading to additional labor costs as parts require reworking or replacement. Removing burrs is thus essential for ensuring that parts function correctly in their intended applications, maintaining safety and reliability.
In industries where the visual appearance of components is critical, such as consumer electronics or automotive manufacturing, deburring plays a vital role in product quality. A well-deburred part has a smooth, clean finish that meets the high aesthetic standards expected by consumers. This attention to detail can significantly impact customer satisfaction and brand perception, making deburring an essential step in the manufacturing process.
To ensure parts meet their design specifications, advanced measuring techniques are employed. Laser scanning and 3D imaging provide detailed insights into a part’s geometry, allowing for precise measurements of dimensions, angles, and even surface topology. These techniques enable manufacturers to verify that each part adheres to the strict tolerances required for high-quality products.
Tolerance checking is a critical aspect of quality control. It ensures that parts will perform reliably in their operational environment, which may include dynamic conditions such as temperature fluctuations and mechanical loads. By verifying that parts are within tolerance, manufacturers can guarantee consistent performance, reducing the risk of failure in the field.
Surface inspection goes beyond identifying visible imperfections; it involves assessing the part’s potential performance in real-world conditions. Scratches, pits, or other surface anomalies can become sites for stress concentration or corrosion initiation, potentially leading to part failure. A thorough surface inspection helps predict and prevent these issues.
Assembly testing is a practical approach to quality control, where parts are tested in the context of their final application. This includes fitting the part into assemblies or conducting functional tests to ensure that it not only fits but also performs as expected. This step is crucial for verifying that the part will function correctly with other components in its end-use environment.
The selection of packaging materials is a critical decision that affects the part’s integrity during transport and storage. Materials are chosen based on their protective qualities, such as cushioning against impacts or shielding from electrostatic discharge. Sustainable packaging options are also considered to minimize environmental impact and align with corporate sustainability goals.
Accurate labeling is essential for maintaining traceability throughout the part’s lifecycle. Labels often include information such as part numbers, batch codes, and manufacturing dates, which are crucial for quality control and regulatory compliance. In industries with strict regulations, such as aerospace and medical devices, labeling is especially important for ensuring that parts can be traced back to their source if issues arise.
For parts sensitive to environmental conditions, storage in controlled environments is necessary. Regulated humidity and temperature help preserve the integrity of the parts, preventing issues such as corrosion or material degradation. This ensures that parts remain in optimal condition until they are ready for use.
Efficient storage is about more than just keeping parts organized; it’s about optimizing the flow of materials through the manufacturing process and supply chain. Proper organization reduces handling times, minimizes the risk of damage or loss, and can lead to improvements in overall efficiency and productivity.
By thoroughly addressing each aspect of post-processing and quality control, manufacturers can ensure that their stamped parts are of the highest quality and ready for use in various applications. This meticulous attention to detail is what distinguishes superior manufacturing processes and leads to products that are trusted and valued by customers. If you have any further questions or need additional information, please let me know.
In the realm of metal fabrication, the stamping press stands out as a marvel of mechanical precision and efficiency. This guide has meticulously charted the journey from understanding the core principles and machinery, through the diligent preparation and setting of parameters, to the execution of small batch tests and full-scale production. It has underscored the importance of post-processing and the stringent measures of quality control that ensure each part meets the highest standards.
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