Five Questions to Ask Before Instrumenting a Mold

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Putting a sensor anywhere in a tool can give you some form of data, but it may not be value added. The key is knowing upfront what you want the sensor to do for you before determining where to place it, and what type of sensor you want to use. Start by answering these five questions in chronological order.

 

There are a variety of sensor types and configurations to choose from, as well as different ways and different locations in which to mount them. What you want to accomplish helps determine your choices.

1. What Do You Want the Sensor to Do for You?

This is the most important question to ask before installing sensors in your mold. Most people stall right here because they&#;re not sure what functions a sensor can actually perform. A lot of people just want to instrument a tool because they&#;ve heard they should run Decoupled Molding processes or they want to try out process-control software. Others are curious about the ability to collect data, track a part to a molding cycle, resolve existing production challenges, or create a template to maintain or transfer processes. Whatever the answer, this single question needs one before proceeding so you can make decisions to work toward your goal moving forward.

Maybe you think you need a mold sensor, but are not sure why or for what purpose.

Once that question has been answered, we can begin to explore the many different functions sensors can serve if used correctly. Some examples are monitoring pressure at a specific area in the cavity, transferring the injection portion of the cycle to hold via pressure, detecting mold deflection, sequencing valve gates, automatically sorting bad parts, and the list goes on. Once you know what you want the sensor to achieve, you have some important decisions to make.

 

Where and how to mount mold sensors depends on a number of factors, including mold design and press capabilities.

2. Where Do You Want to Install the Sensor?

Conventional installation locations to consider include post-gate, mid-cavity, and end of fill, but there are a few other locations in addition to these. You may need one or a combination of these locations, depending on your particular project. In some cases, it&#;s not necessary to instrument every cavity.

It&#;s also important to note how hot the steel is where the sensors will be mounted. The electronics in the connectors of some sensor models are only rated to 140 F, although other electronics are rated higher, and there are techniques available to mount the electronics away from the heat on hot molds.

Post-gate sensors allow you to know the moment plastic enters the cavity and at what pressure. With this information, you can perform various studies, including pressure loss (from nozzle to gate), pack rate, and gate seal (pressure lost when the hold pressure is released). In addition, post-gate sensors are often the location of choice when using a &#;Decoupled III&#; process to transfer from pack to hold using cavity pressure; but other locations can work as well, depending on your machine and percentage of barrel usage for the shot.

Mid-cavity sensors also can aid in performing calculations like determining pressure loss through the cavity and cavity deflection. In addition, they can help with timing the firing pattern of hot-runner valve gates on larger parts, like car panels, especially when located near each gate. In such applications, sensors can help with moving or eliminating knit lines or reducing the flow-length/thickness ratio.

Mid-cavity sensors are also a good option for very small parts, as they can typically represent an average pressure in the cavity and may be the only location available if moving ejector pins are not located at the last point to fill.

End-of-fill sensors are the most common location used for automatically sorting bad parts, like short shots, based on cavity pressure. They can also monitor the pressure required to fill your part when used in conjunction with a post-gate sensor. By subtracting the end-of-fill pressure from the post-gate pressure, you can see the pressure loss through the cavity and observe the cooling behavior of the plastic, which is critical in semi-crystalline polymers.

In addition to pressure sensors, in-cavity temperature sensors also have roles to play.

In addition. cavity-temperature sensors can be used to detect the time at which the flow front passes over a particular area in the cavity, because the temperature rises rapidly as plastic flows over them. Like mid-cavity sensors, this can be useful in timing the opening of sequential valve gates when the sensors are located close to each gate. Cavity-temperature sensors can also measure the surface temperature of the steel, which affects part dimensions for semi-crystalline parts. They can even measure the relative melt temperature of the plastic that is passing over the sensor.

3. How Should You Install the Sensor?

The most common installation styles for pressure sensors are flush-mount and button styles. Flush-mount sensors are mounted in the cavity block so the sensing surface is in contact with the plastic. Button-style sensors are mounted away from the cavity, and the pressure is transferred to the sensor via ejector pin, transfer pin, static pin or ejector sleeve. The choice of sensor style depends on many factors, including the availability of ejector pins in the desired cavity location, the space available for the sensor, and the temperature of the mold.

Based on decades of sensor installs, customer feedback, and testing, we strongly believe that mounting the sensor in the clamping plate and utilizing a transfer pin to transfer the pressure is the most robust configuration for most applications. These are some of the benefits:

·&#;  Mitigating the chances of damaging the sensor due to the tool&#;s action or while it is serviced on the bench;

·&#;  Ease of access;

·&#;  Minimizing heat exposure to the sensor;

·&#;  Improving the sensor&#;s life by removing it from the motion and shock of the ejector plate.

4. What Type of Sensor Technology Do You Need?

The two major types of pressure-sensor technologies are strain-gauge and piezoelectric (both of which we offer). Strain-gauge sensors generally are more cost effective, require less maintenance, have more rugged cables, and are less susceptible to signal errors if water or other contaminants enter the connectors. Piezoelectric sensors are generally used in flush-mount applications and in certain applications where ultra-miniature sensors are required.

5. What Load Capacity Do You Need?

For button-style sensors, you need to determine the load capacity required of the sensor. The load capacity is determined by the predicted force that will be exerted on the sensor. To do this, you need two pieces of information: the projected area of the sensing pin; and the pressure you expect the plastic to see at the sensing location. Multiplying pressure × area gives you the expected force. The sensor you choose must have a load capacity higher than the expected force but not so high that the sensor signal gets &#;lost down in the mud.&#;

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There are several ways to determine the expected pressure. The preferred method is to use flow simulation with predictions of the pressure in your chosen sensor area. If this is not available, you can resort to the material datasheet, which often gives a pressure or tonnage factor. This gives you the recommended pressure per square inch required within the cavity to mold that particular resin properly.

If the tool under consideration for instrumentation is already built and simulation is not an available option, you can perform a short-shot study to determine the pressure required during filling. To do this, you fill the part gradually at your preferred linear speed or volumetric flow rate and observe the filling pattern. Determining post-gate pressure is fairly straightforward, but determining mid-cavity and end-of-fill pressures can be a little trickier, depending on the material, flow rate, and geometry. The key is to not make too many assumptions without supporting your decisions with actual data.

About the Author: Brad Harvey has been in the plastics industry since . He has worked in toolrooms at various medical injection molding companies, servicing production tools, managing spare tooling, and participating in design review of new molds. Harvey joined RJG in ; as engineering lab technician, he is able to utilize his experience in tooling, processing, and training. Contact: ; rjginc.com.

Stamping is a pressure processing method that uses a mould installed on a press to apply pressure to the material at room temperature to separate or plastically deform it to obtain the desired parts. Stamping mould is special process equipment that processes materials (metal or non-metal) into parts (or semi-finished products). The performance of the stamping mould determines the workpiece accuracy and process efficiency. The following describes the performance characteristics that the stamping mould should have.

Characteristics of Stamping Mould Performance

The performance of the stamping mold mainly includes strength, hardness, toughness, wear resistance, fatigue resistance, etc.

The manufacture of precision stamping molds generally has to go through several processes such as forging, cutting, and heat treatment, which are difficult to process and require high manufacturing materials.

1. Wear resistance

The wear resistance of the material is one of the most basic and important properties of the mold.

When the blank is plastically deformed in the mold cavity, it both flows and slides along the surface of the cavity, causing severe friction between the surface of the cavity and the blank, resulting in the failure of the mold due to wear.

2. Hardness

The hardness of the material will directly affect the service life of the stamping mold and have an important impact on the quality of the mold.

3. Strength

In order to prevent sudden brittle fracture of mold parts during operation, the mold must have high strength and toughness. Strength is an indicator of a material&#;s ability to resist deformation and fracture. Toughness reflects the ability of materials to resist brittle fracture under the action of strong impact load and is also an important performance index of die steel, especially cold work die steel for stamping.

Because most of the working conditions of the mold are very bad, some often bear a large impact load, which leads to brittle fractures.

4. Fatigue fracture properties

The stamping mould needs to have good fatigue fracture properties. Fatigue resistance refers to the performance index of the material&#;s resistance to fatigue damage under repeated loading conditions.

During the working process of the mold, fatigue fracture is often caused by the long-term action of cyclic stress. Its forms include small energy multiple impact fatigue fracture, tensile fatigue fracture, contact fatigue fracture, and bending fatigue fracture.

5. High-temperature performance

When the working temperature of the mold is high, the hardness and strength will decrease, resulting in early wear of the mold or plastic deformation and failure.

6. Cold and thermal fatigue resistance

The stamping mold needs to have a good cold and thermal fatigue resistance.

Because some molds will be in a state of repeated heating and cooling during the working process. This will cause the surface of the cavity to be subjected to tension, pressure, and variable stress, causing surface cracking and spalling increasing friction, and hindering plastic deformation. As a result, the dimensional accuracy is reduced, and even the mold fails.

7. Corrosion resistance

When some molds, such as plastic molds, are in operation, due to the presence of chlorine, fluorine, and other elements in the plastic, after heating, strong corrosive gases such as HCI and HF are decomposed. This aggressive gas will erode the surface of the mold cavity, increase its surface roughness, and aggravate wear failure.

8. Geometric parameters

The shape, fit clearance, and fillet radius of the die not only have a great influence on the forming of stamping parts but also have a great influence on the wear and life of the die.

9. Good process performance

Process performance mainly includes forging performance and heat treatment performance.

Forging performance refers to the process performance of the material when it is subjected to forging.

The heat treatment process has a great influence on the quality of the stamping mould. In the actual application process, the material must have good hardenability to ensure the hardness and wear resistance of the mold. Through the above, we have learned the characteristics that a high-quality stamping die should have.

KENENG can open molds according to your needs, provide you with the most suitable stamping moulds, and carry out mass production. If you need it, please feel free to contact us. As a source manufacturer, KENENG can provide you with high-quality and low-cost services and products.

For more Precision Stamping Moldinformation, please contact us. We will provide professional answers.

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