TWM519241U - Nitrogen blow detection apparatus for detecting a nitrogen blow event associated with a polymer production process and nitrogen blow arresting apparatus for arresting a nitrogen blow occurring during a polymer production process - Google Patents

Abstract

Apparatuses for detection of a nitrogen blow event during a polymer production process, such as a nylon 6,6 polymer production process, are disclosed and described. The nitrogen blow detection apparatus can include: (1) a microphone configured to detect sound information resulting from nitrogen gas passing through a dieplate that extrudes molten polymer; (2) a converter module electronically coupled to the microphone and configured to receive sound information from the microphone and convert the information into an electronic signal; and (3) a logic controller electronically coupled to the converter module and configured to evaluate a signal from the converter module at a frequency of at least once every 0.1 seconds. Apparatuses for arresting a nitrogen blow event during a polymer production process, such as nylon 6,6 polymer production processes, are also disclosed and described. The apparatuses may include a collection of components assembled and configured to detect a nitrogen blow event, and further an arrangement where the logic controller of such an apparatus is electronically coupled to an autoclave extrusion valve though which nitrogen gas passes. In such an arrangement, the logic controller can be configured to signal the automatic closure the autoclave extrusion valve upon detection of a signal indicating occurrence of a nitrogen blow.

Description

Nitrogen explosion detecting device for detecting nitrogen explosion phenomenon associated with polymer production process and nitrogen explosion suppressing device for suppressing nitrogen explosion in polymer production process

The utility model relates to a nitrogen explosion detecting device for detecting a nitrogen explosion phenomenon associated with a polymer production process.

In the process of producing a nylon polymer, the molten nylon polymer was removed from the autoclave using an autoclave pressure profile and extruded through a die plate. After extrusion, the molten nylon polymer is quenched in cooling water and cut into flakes or granules. The pressure profile for extrusion can be maintained using compressed nitrogen in the autoclave. Typical autoclave pressures can range from 3 to 9 bar (absolute) (barA).

If nitrogen is escaping through the stencil at the end of the casting (ie, the production process) or due to an unexpected large gap in the molten nylon polymer stream, a "nitrogen blast" phenomenon will occur. If this phenomenon is allowed to develop without testing for a period of time, it may be unsuitable and unsafe. Therefore, the autoclave extrusion valve should be quickly closed to quickly stop or prevent nitrogen explosion.

Traditionally, operators have been placed at the foundry pipeline and assigned to monitor the nylon polymer production process. After sensing the start of the nitrogen explosion, the operator quickly activates the switch to close the autoclave extrusion valve. In order to act quickly after the onset of a nitrogen explosion, the operator should not transfer to participate in other activities while monitoring the process. Therefore, the time and labor cost for monitoring the single purpose of the process and operating the autoclave extrusion valve is high.

In addition, even when the process is strictly observed, the operator may only succeed slightly The autoclave extrusion valve is closed in time to optimally avoid nitrogen explosion or minimize nitrogen explosion. This is due to the rapidity of this phenomenon compared to the operator's reaction time.

This creation is about devices that involve the production of polymers and the thorny issues associated with them. In one example, the nitrogen explosion detecting device can include 1) a microphone configured to detect sound information generated by nitrogen passing through a template of the extruded molten polymer; 2) electronically coupled to the microphone and grouped a converter module that receives sound information from a microphone and converts the information into an electronic signal; and 3) electronically couples with the converter module and is configured to evaluate the converter mode at a frequency of at least once every 0.1 second The logical controller of the group's signals.

Embodiments of apparatus for suppressing the occurrence of nitrogen explosions in a polymer production process are also disclosed herein. In one aspect, the apparatus can include a plurality of components that are assembled and configured as described herein to detect a nitrogen explosion phenomenon, and additionally include a configuration in which the logic controller of the apparatus is permeable to nitrogen The autoclave extrusion valve is electronically coupled. In this configuration, the logic controller can be configured to signal the automatic shutoff of the autoclave extrusion valve after detecting a signal indicating a nitrogen explosion.

Other features and advantages of the present invention will become apparent from the detailed description which follows.

10‧‧‧ device

20‧‧‧ autoclave

25‧‧‧Agitator/Auger

30‧‧‧Autoclave extrusion valve

40‧‧‧ template

50‧‧‧ microphone

60‧‧‧ preamplifier

65‧‧‧ Converter Module

70‧‧‧ sound level monitor

80‧‧‧Process Control System or Unit

90‧‧‧Logic Controller

95‧‧‧Motors

100‧‧‧ Directional sound assembly/assembly

110‧‧‧Shell

120‧‧‧Sound insulation

130‧‧‧Support rod

140‧‧‧First directional shell

1 is a schematic diagram of an apparatus and logic assembly constituting a device for detecting a nitrogen explosion phenomenon in a polymer production process according to an embodiment of the present invention; and FIG. 2 is a directional sound assembly for improving the directional sensitivity of a microphone. A partial perspective view of an embodiment for obtaining sound information from a polymer manufacturing process in accordance with an embodiment of the present invention; FIG. 3 is a side view of the assembly of FIG. 2 with the outer insulating housing in a retracted position; 4 is a side view of the assembly of Figure 3, wherein the outer insulating housing is in the extended position Figure 5 is a graphical representation of the sound information obtained in a typical nitrogen explosion associated with an autoclave; Figure 6 is a graphical representation of the sound information obtained from the apparatus located in the autoclave of Figure 5, the sound Information is generated by nitrogen explosions occurring in adjacent autoclaves; and Figure 7 is a graphical representation depicting nitrogen explosion phenomena, valve opening and closing events, and microphone level values for an example of the present creation.

It should be noted that the figures are merely illustrative of several embodiments of the present invention and thus are not intended to limit the scope of the present invention.

While the following detailed description contains numerous specific embodiments, the embodiments of the invention

Therefore, the following examples are set forth without any loss of generality to any claimed invention and without any limitation. Before describing this creation in more detail, it should be understood that the present creation is not limited to the specific embodiments as it may vary. It is also understood that the terminology used herein is for the purpose of describing particular embodiments and is not intended to limit the invention, as the scope of the present invention is limited only by the scope of the accompanying claims. Unless otherwise defined, all technical and scientific terms used herein have the same meaning as the meaning

The singular forms "a", "an" and "the" are used in the <RTI ID=0.0> </ RTI> </ RTI> <RTIgt; Thus, for example, reference to "a microphone" includes a plurality of microphones, and reference to an autoclave includes a plurality of autoclaves.

In this creation, "comprise", "comprising", "contains" and "having" and the like may have the meaning attributed to them in US patent law and may mean "include", "including" and the like, and are generally interpreted as open-ended terms. The term "consisting of" is a closed term and includes only the devices, methods, compositions, components, structures, steps, or the like, which are specifically listed in accordance with the U.S. Patent. "consisting essentially of" or "consisting essentially of" a device, method, composition, component, structure, step, or the like, as used in the present invention. Or a similar term refers to an element as disclosed herein, but may contain other structural groups, component components, method steps, and the like. However, such other devices, methods, compositions, components, structures, steps, or the like, etc., do not materially affect the devices, compositions, etc., as compared to the corresponding devices, compositions, methods, etc. disclosed herein. Basic and novel features of the method and the like. In more detail, "consisting essentially of" or "substantially by:" of a device, method, composition, component, structure, step or the like contained in the present invention. "consist essentially" or the like has the meaning attributed to it in the U.S. Patent Law, and the term is open, thereby allowing the existence of the foreign matter as long as the basic or novel features are not excluded. Changes may be made to the presence of the object, but do not include prior art embodiments. When using open-ended terms (such as "contains" or "includes"), it should be understood that the language "consisting essentially of" and "composed of" should be directly supported, as expressly stated.

As used herein, "nitrogen explosion" and "nitrogen explosion" refer to the event of nitrogen exploding or expelling a template through which a molten polymer, such as nylon 6,6 polymer, is extruded. Nitrogen explosions are usually (but not always) indicative of the end of the casting event for the production of the polymer or a signal for the end of the casting event. In addition, it should be noted that the term "nitrogen explosion" also includes explosion phenomena that may occur due to nitrogen and/or other gases that may be present. Thus, in some cases, the nitrogen explosion may be caused by voids in the molten polymer, which is typically nitrogen, but may also include or be a vapor or degradation gas. Therefore, it is not important that the gas is nitrogen to make the device effective, and the term "nitrogen explosion" generally includes nitrogen and/or other gas explosions that may occur. phenomenon.

As used herein, "sound information" and similar expressions refer to acoustic characteristics of sound, such as pitch, frequency, and volume (i.e., sound pressure or level). These characteristics, including their measurement, are well known to us.

The terms "device" and "system" are used interchangeably herein.

It should be noted that ratios, concentrations, amounts, and other numerical data may be expressed in a range format herein. It is to be understood that the scope of the invention is to be construed as being in a The scope is as if each value and sub-range includes "about "x" to about "y"". For purposes of explanation, the concentration range of "about 0.1% to about 5%" should be interpreted to include not only the concentration of about 0.1 wt% to about 5% by weight, but also individual concentrations within the specified range (eg, 1%, 2). %, 3%, and 4%) and sub-ranges (eg, 0.5%, 1.1%, 2.2%, 3.3%, and 4.4%). In one embodiment, the term "about" can include conventional rounding based on a significant numerical value of the value. In addition, the phrase "about "x" to "y"" includes "about "x" to about "y"". When referring to a numerical value or range, the term "about" as used herein is allowed in the value or range. The degree of change, for example within 10% of the specified limit value of the specified value or range, or within 5% of one aspect.

In addition, if the features or aspects of the creation are described in relation to the list or the Markush group, those skilled in the art should recognize that the creation is also related to any individual member or member of the Markusi group. Group description. For example, if X is described as being selected from the group consisting of bromine, chlorine, and iodine, the technical scheme in which X is bromine and the technical scheme in which X is bromine and chlorine are fully described, as listed separately. For example, if the features or aspects of the present description are described in relation to the list, those skilled in the art should recognize that the present invention also relates to individual members or subgroups of members of the list or members of the Markush group. Any combination description. Thus, if X is described as being selected from the group consisting of bromine, chlorine, and iodine and Y is described as being selected from the group consisting of methyl, ethyl And the group of propyl groups, fully described and supported the technical scheme that X is bromine and Y is methyl.

The individual embodiments described and illustrated herein have discrete components and features that can be easily described without departing from the scope or spirit of the present invention, as will be apparent to those skilled in the art after reading this disclosure. The features of any other several embodiments are separated or combined.

Embodiments of the present invention are integrated with a polymer (e.g., nylon 6,6) manufacturing process to provide greater automation and significantly reduce or eliminate the need for operator assistance in operating the process. Thus, by removing or at least reducing the time required by the operator to exist near the production facility, a number of advantages can be provided, including cost savings and efficiency, as well as safety improvements.

Referring now to Figure 1, a schematic diagram of an embodiment of an apparatus 10 for detecting and/or suppressing nitrogen blasting in a nylon polymer production process is shown. For example, this article will discuss nylon polymerization processes, and more specifically nylon 6,6. In the case described, it should be understood that when discussing nylon polymerization, the principles described herein may be as follows not only for nylon 6,6 but also for other nylon polymers, polyamide polymers or even other polymers not related to nylon. Any particular polymer of interest to the extent that extrusion and gas explosion phenomena may occur is fully described herein. Thus, in this process, autoclave 20 processes the material into a molten nylon polymer. In this example, the autoclave shown includes a stirrer or auger 25, but an autoclave without a stirrer or auger can also be used. At the designated point in the process, the autoclave was pressurized with nitrogen and the autoclave extrusion valve 30 was opened to allow the molten nylon to leave the autoclave under the pressure of nitrogen. After moving through the autoclave extrusion valve, the molten nylon continues to pass through the system until it reaches the extrusion die 40 where it is extruded (eg, cast) into strands and blocks via a stencil, which is then cooled. The water is quenched and cut into flakes or granules.

As the autoclave is emptied and the molten polymer supplied to the stencil is depleted, there is a situation in which the pressure of nitrogen in the apparatus can pass over the remaining molten nylon polymer and cause nitrogen to burst out of the stencil. This phenomenon can be vigorously and vigorously released and allows a few drops of molten nylon polymer to be splashed or uncontrolled to be sprayed into the environment surrounding the template. As mentioned earlier, this phenomenon is unsuitable and may even be dangerous to any operator in the immediate vicinity. It also causes significant confusion and may require To clean the device, including surrounding equipment.

Due to the sound produced when nitrogen begins to leave the stencil, it is possible to know when the nitrogen blast phenomenon begins. Referring again to FIG. 1, a microphone 50 is shown for receiving sound information generated by nitrogen gas passing through the template 40. The microphone can be any microphone that can fully receive the desired sound information.

In one embodiment, the microphone 50 can be a condenser microphone. Such microphones are known, such as the Bruel and Kjaer type 4189 microphone, which has a sensitivity of 50 mV/Pa. You can also choose another microphone to use. A typical condenser microphone includes a metal casing and a metal film as a measuring device. Under the film is a back sheet. The microphone receives sound information (such as sound waves) and vibrates the metal film. These vibrations cause a change in the distance between the film and the backing plate. The combination of the film and the back sheet forms a capacitor. The vibration of the film changes the dielectric value between the film and the back sheet. This change in dielectric value is expressed as a change in capacitor capacity. Therefore, the input sound information and its characteristic measurements are a function of the change in the capacitance value in the capacitor. While the capacity depends on the diameter of the film, in some embodiments, the diameter can range from 2 to 60 pF (i.e., pico farad).

Converter module 65 is electronically coupled to microphone 50 and is configured to receive sound information from the microphone and convert it to an electrical signal. The converter module can include a preamplifier 60 and a tone level monitor 70. In the example shown in Figure 1, the preamplifier is integrated into the microphone and the level monitors are shown in separate modules. For the case described, it is only one illustrative example of a possible configuration. Other configurations can be used as would be appreciated by those skilled in the art after considering this creation. Thus, in some embodiments, the preamplifier can be an integral unit with a microphone. The preamplifier is generally used to convert or change the sound information or signal received from the microphone from a high impedance value to a low impedance value. For example, the capacitor microphone can have an impedance value of about 1 G Ω and the preamplifier can reduce the value to about 50 Ω or less. An example of this preamplifier is the Bruel and Kjaer Model 2671. The B&K Microphone Preamplifier Model 2671 has a sensitivity of 1 mV/mV. The actual output signal is a constant 12V DC, where The microphone signal is superimposed on this 12V DC.

As noted, the tone level monitor 70 can be part of the converter module 65 and can be electronically coupled to the preamplifier 60. In some particular embodiments, the two devices can be coupled to a coaxial cable. The tone level monitor performs at least three basic operations on the signals received from the preamplifier. First, the tone level monitor filters the received signal. It has been found that nitrogen explosions produce sounds with frequencies mainly in the range of 15 to 40 kHz. Thus, in one aspect, the sound level monitor can be configured to filter out substantially all of the sound information that does not belong to the range indicating that nitrogen passes through the template 40. In one embodiment, the sound level monitor may filter out all or substantially all frequencies that do not fall within the range of about 15 kHz to about 40 kHz.

In addition to filtering, the level monitor 70 can be configured to perform the function of linearizing signals. This function can be accomplished using, for example, a Logarithmic Mean Square (LMS) detector component (not shown) within the tone level monitor. Other mechanisms or components that can linearize the signal can also be used. In addition, the sound level monitor can additionally be configured to normalize the signal before it is output. In some aspects, the signal can be normalized to a standard 4-20 mA signal.

Still referring to FIG. 1, a logic controller 90 electronically coupled to converter module 65 is shown, which in some embodiments can be coupled directly to sound level monitor 70. The logic controller is configured to evaluate the signals from the converter modules. In some embodiments, the logic controller can also be electronically coupled or in communication (directly or indirectly) with the autoclave extrusion valve 30. After sensing a signal from the converter unit indicating that a nitrogen explosion may begin, the logic controller can signal the autoclave extrusion valve to close. The closing of the autoclave extrusion valve blocks the flow of nitrogen to the template 40, thereby terminating or otherwise arresting the nitrogen explosion or at least the complete nitrogen explosion.

Due to the rate at which the nitrogen explosion occurs (usually within 1 second or less than 1 second), it is desirable for the logic controller 90 to evaluate, sample, receive or sense the signal from the converter module 65 at a high frequency so that the autoclave can be sent The extrusion valve closes the signal or command and is received by the autoclave extrusion valve 30 and closed in time to reduce, prevent, or minimize nitrogen explosion. In some aspects, the logic controller can evaluate the signal from the converter module every 0.1 second (i.e., one tenth of a second) at least once (i.e., at intervals). In another aspect, the frequency or interval can be from 0.1 second to every 0.001 second. In another aspect, the frequency or interval can be from 0.08 seconds to every 0.02 seconds. In another aspect, the frequency or interval can be about every 0.04 seconds.

The nylon polymer casting or manufacturing process is controlled by a process control system or unit (i.e., process controller) 80. This unit or system controls the basic operation of the autoclave 20 and other process components. An example of such a unit or system is the TDC3000 DCS manufactured by Honeyville. In some cases, the process control system may fully or partially include or integrate the nitrogen explosion detection device of the present invention. In other configurations, the nitrogen explosion detection device can be separated from the process control system.

Where the process control system or unit 80 includes or incorporates a nitrogen explosion detection device, the logic controller 90 can control the autoclave extrusion valve 30 via the process control system or communicate commands to the autoclave extrusion valve 30 (ie, signal) ). However, in other cases, the logic controller can directly control or communicate with the autoclave extrusion valve.

As shown in FIG. 1, in some embodiments, the process control system or unit 80 can also be electronically coupled to the converter module 65 as shown and further electronically coupled directly to the sound level monitor 70. However, even in this case, the process control system or unit generally does not or cannot be evaluated satisfactorily or optimally to stop the nitrogen explosion interval (usually only about once per second) in a manner sufficient to properly close the autoclave extrusion valve in time. Process, sense or monitor signals from the sound level monitor. However, when coupled to the converter module, the process controller can act as a logic controller 90 to assist or supplement. In this way, if the logic controller fails, the process control unit can still close the autoclave extrusion valve if necessary. In embodiments where the process control unit can be fabricated to communicate more quickly with the converter module, the logic controller may not be used.

When the autoclave extrusion valve 30 is closed, nitrogen explosion can be prevented or prevented. Due to the speed and efficiency of the authoring apparatus, the autoclave extrusion valve through which nitrogen gas passes can be automatically closed within less than one second from the start of the nitrogen explosion. In some cases, the valve can be closed at a rate of 0.1 from the nitrogen explosion. Occurs from seconds to 0.6 seconds. In other aspects, the valve can be closed within about 0.54 seconds or less. The closing of the extrusion valve can be performed by using a motor device 95 (such as a solenoid or other similar device) that can be adapted to receive signals from the logic controller and after receiving a signal from the logic controller to close the autoclave extrusion valve Do this.

Referring now to Figures 2-4, a directional sound assembly 100 is shown in accordance with one aspect of the present teaching. In some embodiments, the microphone can be sensitive to the direction to focus sufficiently on the sound from the template. In an attempt to further promote or enhance the directionality of the microphone and further attenuate or remove the sound from the surrounding environment, such as other batch autoclaves from nearby operations, an assembly as shown in Figure 2 can be used.

As shown, the microphone 50 is present in a first directional housing 140 that is configured to direct sound to the microphone. The first directional outer casing is shown in the shape of a tube. However, a variety of other shapes that can enhance or promote the sound receiving directionality of the microphone are suitable. A variety of suitable durable materials can be used for the first directional outer shell, such as a plastic material, including, for example, PVC. In one aspect, the materials may be selected for their low cost. Alternatively, the material can be selected for the particular sound attenuating properties of the material.

The outer casing 110 and the sound insulation layer 120 may be included in the assembly 100 as appropriate. In use, the directional sound assembly is located adjacent the template and has an opening toward the template. To facilitate placement of the assembly, a support rod 130 can be used. The support bar can be coupled to the first directional outer casing 140 and extend within the assembly and through the assembly with the sound insulation layer and the outer casing resting thereon. As further shown in Figures 3 and 4, the outer casing and/or acoustic insulation layer may be shrunk as needed to address any problems with the assembly, such as facilitating placement or removal of the microphone 50.

Referring now to Figures 5 and 6, a graphical representation of the recorded signals is shown using a microphone and assembly of the present invention. In Figure 5, the sound level of a typical nitrogen explosion phenomenon from a nylon production system is provided, to which the microphone of the present invention is assigned. In Fig. 6, the sound level obtained after the occurrence of the nitrogen explosion at the adjacent autoclave is shown. As can be seen, the sound levels recorded for adjacent autoclaves are significantly different, so the devices described herein can be programmed. A distinction is made between these profiles. Thus, such devices can be used in which adjacent autoclaves can also be in operation.

It should be noted that the connections and wiring of the components and modules of the authoring device should be carefully performed to ensure that the possibility of any phantom positive signals or other signal interference is minimized or prevented. In one example, the microphone can be grounded only on one side of the line connecting the components of the microphone to the logic controller and especially between the microphone and the sound level monitor. With this grounding configuration, the occurrence of false positive signals can be reduced.

In some cases, the nitrogen explosion may be unexpected. In other cases, it is predicted that a nitrogen explosion may occur at the end of the nylon polymer batch or casting (ie, production) event. In the latter case, the nitrogen explosion detection device of the present invention can be used to positively identify the end of the casting or processing event and end the event itself. In such cases, the parameters of the event are monitored and in some cases monitored by the process control system or unit 80. As the event reaches its final phase and final phase, the subsequent detection of the start of the nitrogen explosion can be used to positively identify the end of the batch event and in some cases terminate the function of the processing device and thereby end the event.

To further improve the accuracy of the detection and minimize errors, especially when using a nitrogen explosion detection device to indicate the end of a batch or casting event, it may be useful to calibrate the detection device for the environment and equipment it is monitoring. Once the microphone is properly placed near the autoclave and other equipment and oriented toward the template, initial sound readings can be taken and information collected. The alarm limit can be set based on these initial readings. Alternatively, the alarm limit values can be set based on a general prior knowledge of the casting process or in view of a given casting device. In one aspect, the general alarm limit can be about 90 db or more.

Instance

The following examples are presented to provide the general practitioner with a description of the process for detecting and/or suppressing the nitrogen explosion according to the present teachings and as described herein. The specific steps, devices, materials, or values should not be construed as being limited to the details.

One of the steps of operating the nitrogen explosion detection and/or suppression device disclosed in the present disclosure The implementation is as follows:

明确 Before starting the casting, the high-high (HH) and high (H) alarm limits of the microphone signal in the process control system are clarified. This prevents the nitrogen explosion detection device from being activated as air flows out of the extrusion valve actuator (air is also used to close the valve, which is typically released to open the valve).

The process control system prevents the explosion detection start signal from reaching the logic controller. Therefore, the logic controller cannot perform extrusion valve control.

Some time after the start of the casting, the process controller writes the HH-alarm limit value (for example, 92 dB) and the H-alarm limit value (for example, 90 dB) to the microphone signal library point.

At the end of the casting, nitrogen is released via the template and produces sound in a range of frequencies (eg, 15 kHz to 40 kHz).

̇ Measure the intensity of the sound and use electronic signals (such as analog signals) to continuously report to the process controller and logic controller. This signal is in the range of 34dB to 94dB.

The microphone signal in the process controller is configured such that the extrusion valve is closed or interlocked when the measured sound level exceeds the HH value.

̇ During the last few minutes of casting, the logic controller or process controller or both also close the extrusion valve when the microphone signal exceeds the H value.

Figure 7 depicts an illustrative diagram of temporal real-time data for sound level rendering. In this example, the detection limit can be set higher than the normal operating sound of the casting equipment, but below the level experienced or generated prior to the nitrogen explosion or nitrogen explosion. Additionally, as noted, the microphone and sound device can be configured to filter out frequencies outside the range of 15 kHz to 40 kHz, which is an exemplary frequency range indicative of a nitrogen blast phenomenon. In the particular example shown, the extrusion valve is partially closed prior to the nitrogen explosion phenomenon as indicated in the figure. This process is typical for autoclave nylon production. For example, the top layer of molten polymer in the autoclave may have quite different characteristics relative to the rest of the polymer, as the top layer typically has a greater chance of exchanging water with the upper atmosphere. Thus, the viscosity of the polymer exiting the template may be quite different from that of the other partial polymers, resulting in an abnormally high throughput during the last 1-2 minutes of casting. To stop this sudden For high throughput problems, the valve can be partially closed to reduce throughput. This early partial closure also helps to close the extrusion valve more quickly after detecting the nitrogen explosion in advance. Therefore, at the lower valve position, only a small amount of air needs to be expelled in the valve actuator to close the valve. As shown in Figure 7, the actual reaction to the detected nitrogen explosion is shown after a short horizontal portion of the graph associated with the extrusion valve output profile.

Although the subject matter has been described in language specific to structural features and/or operation, it is to be understood that the subject matter defined in the appended claims Rather, the specific features and acts described above are disclosed as examples of the scope of the invention. Many modifications and other configurations are conceivable without departing from the spirit and scope of the technology.

10‧‧‧ device

20‧‧‧ autoclave

25‧‧‧Agitator/Auger

30‧‧‧Autoclave extrusion valve

40‧‧‧ template

50‧‧‧ microphone

60‧‧‧ preamplifier

65‧‧‧ Converter Module

70‧‧‧ sound level monitor

80‧‧‧Process Control System or Unit

90‧‧‧Logic Controller

95‧‧‧Motors

Claims (16)

A nitrogen explosion detecting apparatus for detecting a nitrogen explosion phenomenon associated with a polymer production process, comprising: configured to detect sound information generated by nitrogen passing through a template of an extruded molten polymer a converter module electronically coupled to the microphone and configured to receive sound information from the microphone and convert the sound information into an electrical signal; and electronically coupled to the converter module and configured to A logic controller that evaluates the electronic signal for a nitrogen explosion phenomenon at a specific frequency at least once every 0.1 second. The device of claim 1, wherein the converter module further comprises: a preamplifier electronically coupled to the microphone and configured to receive sound information from the microphone and change the information from a high impedance value to a low impedance value And electronically coupled to the preamplifier and configured to receive signals from the preamplifier and filter out sound level monitors that are not part of any signal frequency indicative of nitrogen passing through the template. The device of claim 2, wherein the sound level monitor is further configured to linearize the signal using a log-squared detector. The device of claim 3, wherein the sound level monitor is further configured to normalize the linearized signal to a standard 4-20 mA signal. A device as claimed in claim 1, wherein the microphone is sensitive to the direction. The device of claim 5, further comprising a housing coupled to the microphone, the housing configured to have an opening to enhance sound receiving directivity of the microphone. The device of claim 6 wherein the outer casing has a substantially tubular shape and the microphone is positioned inside the tube. The device of claim 6, wherein the outer casing is isolated to further attenuate Sound in the enclosure that is configured to allow sound to enter the opening in the enclosure. The device of claim 6 wherein the opening of the outer casing is oriented toward the template. The device of claim 5, wherein the microphone measures sound information received as a function of a capacitance value in the capacitor. The device of claim 5, wherein the microphone is grounded only on one side of the pipeline between the microphone and the logic controller to reduce the occurrence of a false positive signal. The device of claim 1, wherein the polymer is a nylon 6,6 polymer. A nitrogen explosion suppression device for suppressing the occurrence of nitrogen explosion in a polymer production process, comprising: a microphone configured to detect sound information generated by nitrogen passing through a template of an extruded molten polymer; and the microphone a converter module electronically coupled and configured to receive sound information from the microphone and convert the sound information into an electronic signal; and electronically coupled to the converter module and configured to be at least once every 0.1 seconds a logic controller for evaluating the electronic signal for a nitrogen explosion phenomenon, wherein the logic controller is electronically coupled to the autoclave extrusion valve through which the nitrogen gas passes, and configured to detect the occurrence of the nitrogen explosion The electronic signal is followed by a signal that automatically turns off the autoclave extrusion valve. The apparatus of claim 13 further comprising a motor device adapted to receive the signal from the logic controller and to perform the operation after receiving the signal from the logic controller to close the autoclave extrusion valve. The device of claim 13 wherein the polymer is a nylon polymer. The device of claim 13, wherein the nylon polymer is a nylon 6,6 polymer.