Combustion systems operate by converting a fuel source with air into thermal energy. The thermal energy is transferred to a material which undergoes a given process (e.g., material state change, chemical reaction, etc.).
Optimal conversion of the fuel and air into the thermal energy 106, and transfer of the thermal energy 106 to the process material in the process tubes 108 is important. To monitor said conversion and transfer of the thermal energy 106, a plurality of sight ports 110 are located within the heater housing 102.
As combustion system technology has developed, sensor-based monitor technology has also developed. For example, a variety of sensors have been developed to monitor the internal components of the combustion system 100. For example, internal components and conditions within the heater 102 are measured by one or more of temperature sensors, pressure sensors, flame scanners, thermal imagers, visible cameras, thermal cameras, gas analyzers (e.g., oxygen, combustibles, NOx, or other air composition sensors/analyzers), and laser-based analyzers (that detect air composition, temperature, and other measurements; such laser-based devices developed by ZOLO Technologies), as well as other devices known in the art.
Each of these devices and sensors requires access into the combustion system 100 via the heater housing 102. This access requires drilling or cutting into the heater housing 102, which occurs during shut-down periods of the combustion system 102. Furthermore, access points for these sensors provides susceptible areas for tramp-air (undesired ambient air that is pulled into the heater housing 102 via pressure differential between inside and outside of the heater housing 102) entrance into the heater housing 102.
The foregoing and other features and advantages of the disclosure will be apparent from the more particular description of the embodiments, as illustrated in the accompanying drawings, in which like reference characters refer to the same parts throughout the different figures. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the disclosure.
Embodiments herein acknowledge that, when retrofitting existing combustion systems with new devices, such retrofitting must occur during shut-down maintenance times resulting in loss of operating time of the combustion system. Certain embodiments herein address this problem by providing a sight port access hatch that can be retrofit onto existing sight ports thereby not requiring additional access points into the heater housing and allowing for installation of the new sensors without shut-down of the combustion system.
Embodiments disclosed herein acknowledge that, when adding additional sensors and monitor devices to a combustion system, a hole in the heater housing must be added resulting in potential tramp air access at the new hole. The embodiments disclosed herein address this problem by providing a multi-functional sight port hatch that is configured to utilize a single access point within the heater housing to provide multiple functions (e.g., visual, and device-based monitoring of the interior of the combustion heater).
The features of the embodiments discussed below are adaptable to sight ports of various sizes. Standard sight-ports are 11 inches by 14 inches, or 5 inches by 9 inches, but it should be appreciated that when “sight port” is referenced herein, it refers to a sight port of any size unless otherwise indicated.
The multi-function sight port 700 may include any number of sensor mounts 706 thereon, and each sensor mount 706 may accommodate a single sensor 708, or any number of sensors 708 without departing from the scope hereof. The sensor(s) 708 may include any one or more of temperature sensor(s), pressure sensor(s), flame scanner(s), gas analyzer(s) (e.g., oxygen, CO, NOx, Zirconia Oxide probe, Catalytic Bead or other gas composition sensor(s)/analyzer(s)), optical-based sensors (e.g., Pyrometer(s), Camera(s)) and laser-based analyzer(s) (that detect gas composition, surface or gas temperature, and other measurement(s); such laser-based devices developed by ZOLO Technologies).
The multi-function sight port 1100 includes a sight port base 1102 hingedly coupled with a port door 1104. The sight port door 1104 is an example of the sight port door 704 of
A sensor mount 1106 is coupled to the sight port door 1104. The sensor mount 1106 is shown in
In at least some embodiments, an insulating material 1302 (e.g., refractory) is coupled to an interior side of the port door 1104. The insulating material 1302 is sized and shaped to fit within aperture 1304 of sight port base 1102 and heater wall 206. In such embodiments, the sight tube 1112 further spans the width of the insulating material 1302 and is located in an aperture within the insulating material 1302. As shown in
The port door 1104 is coupled to the sight port base 1102 via a hinge 1114. The hinge 1114 may be one or more bolts. In at least some embodiments, the hinge 1114 is spring-loaded to assist in lifting the port door 1104, and/or such that the port door 1104 stays open, or stays closed, even with the weight of the TDL laser scanner 1202. The hinge 1114 may be located on the top, bottom, or either side of the multi-function sight port 1100. The hinge 1114 may be sized and shaped to couple with existing sight port bases to allow for retrofitting thereof by replacing the existing port door with the port door of the above described multi-function sight ports. There may be a single hinge or multiple hinges without departing from the scope hereof, based on the size of the sight port base 1102 (or other sight port bases discussed with respect to other embodiments herein). Furthermore, the hinged coupling(s) may be on any edge of the sight port base 1102, allowing the sight port door 1104 to open in any direction.
In at least some embodiments, an additional lift assist device may be included to assist in opening the port door 1104 including the weight of the TDL laser scanner 1202. Furthermore, in at least some embodiments, a latch or other mechanism may be included on the port door 1104 that secures the port door 1104 in an open configuration when enacted.
In at least some embodiments, the sensor(s) 708, including the TDL laser scanner 1202 are designated Class 1 devices (e.g., “eye safe devices” that are capable of staying “on” while the port door 704 is open and the operator opening the port door 704 is within the operating field of view of the sensor 708). If the sensor 708 is not “safe” (e.g., would potentially harm the operator's eyes, or other damage, when the port door 704 is opened if the sensor 708 is still on), then there may be a disabling device (such as an electrical or mechanical sensor) that automatically turns the sensor 708 off when the port door 704 is opened. For example, a pressure switch coupled between the port door 704 and the sight port base 702 may indicate that the port door 704 is opened and automatically disable the sensor 708.
In block 2702, method 2700 inserts a filler into an existing sight port aperture. In one example of block 2702, a filler, such as K-wool or other insulating material, is inserted into sight port access aperture 208 (or aperture 1304) discussed above.
In block 2704, method 2700 removes the existing sight port door. In one example of block 2704, the sight port door 204 is removed.
In block 2706, the method 2700 installs a multi-function sight port door. In one example of block 2706, the multi-function sight port door 704 (or sight port door 1104) are installed on the existing sight port base 202 (or sight port base 1102).
In block 2708, the method 2700 installs a sensor onto the multi-function sight port door installed in block 2706. In one example of block 2708, the TDL laser scanner 1202, or any other sensor described above with respect to
In block 2710, the method 2700 removes the filler inserted in block 2702.
The multi-function sight port 2800 includes a sight port base 2802 hingedly coupled with a port door 2804. The sight port door 2804 is an example of the sight port door 704 of
A sensor mount 2806 is coupled to the sight port door 2804. The sensor mount 2806 is an example of the sensor mount 1106 of
As illustrated in
The insulating material 3102 is shown secured to the sight port door 2804 via one or more fasteners 3106. Alternatively, or additionally, although not shown in
Also shown in
The sight port base 2802 is coupled to the heater housing via one or more fasteners 2902. The port door 2804 is coupled to the sight port base 2802 via a hinge 2814. The hinge 2814 may include one or more bolts. In at least some embodiments, the hinge 2814 is spring-loaded to assist in lifting the port door 2804, and/or such that the port door 2804 stays open, or stays closed, even with the weight of the sensor 2801. The hinge 2804 may be located on the top, bottom, or either side of the multi-function sight port 2800. The hinge 2814 may be sized and shaped to couple with existing sight port bases to allow for retrofitting thereof by replacing the existing port door with the port door of the above described multi-function sight ports. There may be a single hinge or multiple hinges without departing from the scope hereof, based on the size of the sight port base 2802 (or other sight port bases discussed with respect to other embodiments herein). Furthermore, the hinged coupling(s) may be on any edge of the sight port base 2802, allowing the sight port door 2804 to open in any direction. The hinge 2814 is shown as an off-set hinge where, as shown in
In at least some embodiments, an additional lift assist device may be included to assist in opening the port door 2804 including the weight of the sensor 2801. Furthermore, in at least some embodiments, a latch or other mechanism may be included on the port door 2804 and the heater housing that secures the port door 2804 in an open configuration when enacted. A handle 2816 is shown attached to the sensor 2801, but it may be attached to a portion of the sight port door 2804 without departing from the scope hereof.
The multi-function sight port 2800 is further shown with a clamp 2818 to secure the port door 2804 in a closed position. The clamp 2818 may be a steel hold-down clamp, or other type of clamp, that achieves a consistent and repeatable pressure to maintain the sight port door 2804 in a consistent and repeatable position when closed. This provides the advantage, particularly when the sensor 2801 is a laser-based system, of providing a consistent position of the sensor 2801 when the port door 2804 is closed thereby allowing for consistent operating configuration of the sensor 2801.
The multi-function sight port 2800 may be configured to allow for one or more of X-axis, Y-axis, Z-axis, tilt, roll, and yaw positioning of the sensor as mounted to the sight port door 2804.
Ability of one or more of X-axis, Y-axis, Z-axis, tilt, roll, and yaw positioning of the sensor is advantageous, particularly where the sensor 2801 is a laser-0based sensor. The emitted laser may be required to hit a reflector, or be received by a catch head on an opposing wall of the heater. By allowing for one or more of X-axis, Y-axis, Z-axis, tilt, roll, and yaw positioning of the sensor 2801, the multi-function sight port enables accurate alignment with the reflector or catch head. When combined with the clamp 2818, as discussed above, not only is this alignment achievable, but it is repeatable throughout use of the multi-function sight port to visually inspect the heater.
The multi-function sight port 2800 may include features described above with respect to
In block 3402, method 3400 inserts a filler into an existing sight port aperture. In one example of block 3402, a filler, such as K-wool or other insulating material, is inserted into sight port access aperture 208 (or aperture 1304) discussed above.
In block 3404, method 3400 removes the existing sight port door. In one example of block 3404, the sight port door 204 is removed.
In block 3406, the method 2700 installs a multi-function sight port. In one example of block 3406, the multi-function sight port 2800 is installed on the heater. Block 3406 may implement one or more of the following sub-blocks.
In sub-block 3408 a sight port door is mounted to a sight port base. In one example, the sight port door 2804 is installed on an existing sight port base 202. In another example, a new sight port base 2802 is installed in place of the existing sight port base 202. Block 3408 may include utilizing hinge 2814 that allows for greater than 90-degree opening range (e.g., 100 degrees as shown in
In sub-block 3410, a mounting plate is mounted to the sight port door. In one example of sub-block 3410, mounting plate 2808 is secured to sight port door 2804 using one or more of translation fasteners 3304 and orientation fasteners 3306.
In sub-block 3412, a sensor is mounted to the mounting plate. In one example of sub-block 3412, sensor 2801 is secured to mounting plate 2808.
In sub-block 3414, one or more of X-axis translation, Y-axis translation, Z-axis translation, tilt, roll, and yaw of the sensor is selected. In one example of sub-block 3414, the mounting plate 2808 and sensor 2801 are configured along one or more of X-axis, Y-axis, Z-axis, tilt, roll, and yaw using one or more of translation fasteners 3304 and orientation fasteners 3306.
In sub-block 3416, insulating material is installed on the sight port door. In one example of operation of sub-block 3416, insulating material 3102 is installed onto sight port door using fasteners 3106. In another example of operation of sub-block 3416 a mounting flange (similar to mounting flange 1306) is additionally or alternatively used to secure insulating material 3102 to the sight port door 2804. Sub-block 3416 may include creating aperture 3002 on-site (e.g., to match the desired shape and configuration of the attached sensor 2801 and sight tube 2812).
In block 3418, the method 3400 removes the filler inserted in block 3402.
The above-described multi-function sight ports allow for visual inspection interior the heater, when the port door is opened, as well as sensor-based inspection interior the heater via the same hardware. Furthermore, the above-described multi-function sight port allows for installation of the hardware without requiring turndown of the heater system, thereby reducing maintenance time and increasing profits made because the system does not need to shut down.
Changes may be made in the above methods and systems without departing from the scope hereof. It should thus be noted that the matter contained in the above description or shown in the accompanying drawings should be interpreted as illustrative and not in a limiting sense. The following claims are intended to cover all generic and specific features described herein, as well as all statements of the scope of the present method and system, which, as a matter of language, might be said to fall therebetween.
Features described above as well as those claimed below may be combined in various ways without departing from the scope hereof. The following examples illustrate possible, non-limiting combinations of features and embodiments described above. It should be clear that other changes and modifications may be made to the present embodiments without departing from the spirit and scope of this invention:
(A1) In a first aspect, a multi-function sight port system for monitoring an interior of a heater, includes: a sight port base; and a sight port door coupled to the sight port base, the sight port door having a sensor mount attached at an aperture of the sight port door, the sensor mount configured to allow a sensor to monitor the interior of the heater.
(A2) In the multi-function sight port system of (A1), the system further includes a hinge to hingedly mount the sight port door to the sight port base.
(A3) In either the multi-function sight port system of (A1)-(A2), the hinge being offset and allowing opening of the sight port door at least 100 degrees.
(A4) In any of the multi-function sight port systems of (A1)-(A3), the sight port door being configured to install to the sight port base without turndown of the heater.
(A5) In any of the multi-function sight port systems of (A1)-(A4), the system further includes at least one sensor mounted to the sensor mount.
(A6) In any of the multi-function sight port systems of (A1)-(A5), the at least one sensor including at least one sensor selected from the group of sensors including temperature sensor, pressure sensor, flame scanner, gas analyzer, optical-based sensor, thermal imager, thermal camera, and laser-based analyzer.
(A7) In any of the multi-function sight port systems of (A1)-(A6), the sensor mount including a plurality of sensor mounts each coupled to a respective sensor.
(A8) In any of the multi-function sight port systems of (A1)-(A7), the system further including insulating material attached to the sight port door.
(A9) In any of the multi-function sight port systems of (A1)-(A8), the insulating material being refractory mounted to the sight port door via fasteners.
(A10) In any of the multi-function sight port systems of (A1)-(A9), the insulating material being refractory mounted to the sight port door via a mounting flange.
(A11) In any of the multi-function sight port systems of (A1)-(A10), the sensor mount including: a mounting plate coupled to the sight port door; a sensor base, the sensor removably coupled to the sensor base; and, a sight tube spanning between the mount plate and the sensor base.
(A12) In any of the multi-function sight port systems of (A1)-(A11), the sensor mount further including a mounting flange on the interior side of the sight port door.
(A13) In any of the multi-function sight port systems of (A1)-(A12), the system further including refractory located at least partially between the mount flange and the sight port door.
(A14) In any of the multi-function sight port systems of (A1)-(A13), the sight tube spanning between the mount flange and the sensor mount.
(A15) In any of the multi-function sight port systems of (A1)-(A14), the sensor being a tunable diode laser absorption spectroscopy (TDL) system.
(A16) In any of the multi-function sight port systems of (A1)-(A15), the sensor mount including: a mounting plate coupled to the sight port door via one or more of translation fasteners and orientation fasteners.
(A17) In any of the multi-function sight port systems of (A16), the translation fasteners providing translation of the mounting plate along at least one of an X-axis, Y-axis, and Z-axis with respect to the sight port door.
(A18) In any of the multi-function sight port systems of (A16)-(A17), the orientation fasteners providing configuration of tilt, roll, and yaw of the mounting plate with respect to the sight port door.
(A19) In any of the multi-function sight port systems of (A1)-(A18), the system further including a lift-assist mechanism that aids in opening the sight port door.
(A20) In any of the multi-function sight port systems of (A1)-(A19), a hinge coupling the sight port door to the sight port base being a spring-loaded hinge.
(A21) In any of the multi-function sight port systems of (A1)-(A20), the system further including a latch configured to retain the sight port door in an open configuration.
(A22) In any of the multi-function sight port systems of (A21), the latch being a steel hold-down clamp.
(A23) In any of the multi-function sight port systems of (A1)-(A22), the system further including a disabling device configured to disable the sensor when the sight port door is in an open configuration.
(A24) In any of the multi-function sight port systems of (A1)-(A23), a gasket between the sight port door and the sight port base.
(A25) In any of the multi-function sight port systems of (A25), the gasket being a ceramic braid gasket.
(B1) In a second aspect, a method for retrofitting a sight port, includes: removing an existing sight port door; installing a multi-function sight port door.
(B2) In the method of (B1), the method further includes inserting a filler into an existing sight port aperture.
(B3) In either method of (B1)-(B2), the method further including installing a sensor onto a sensor mount of the multi-function sight port door.
(B4) In any of the methods of (B1)-(B3), the method being performed while a heater to which the sight port is installed is running.
(B5) In any of the methods of (B1)-(B4), the installing a multi-function sight port door including mounting the sight port door to a sight port base via a hinge.
(B6) In any of the methods of (B5), the hinge being offset to allow for opening of the sight port door at least 100 degrees
(B7) In any of the methods of (B1)-(B6), the method further including mounting a mounting plate to the sight port door, the mounting plate configured to mount a sensor thereto.
(B8) In any of the methods of (B7), the mounting a mounting plate including securing the mounting plate with one or more of translation fasteners and orientation fasteners.
(B9) In any of the methods of (B8), the translation fasteners providing translation of the mounting plate along at least one of an X-axis, Y-axis, and Z-axis with respect to the sight port door.
(B10) In any of the methods of (B8)-(B9), the orientation fasteners providing configuration of tilt, roll, and yaw of the mounting plate with respect to the sight port door.
(B11) In any of the methods of (B1)-(B3), the method further including securing the sight port door in a closed position using a steel hold-down clamp.
(B12) In any of the methods of (B1)-(B11), the method further including installing any of the features described in the embodiments (A1)-(A25) of the first aspect.
The present application claims priority to U.S. Provisional Patent Application No. 62/900,364 filed Sep. 13, 2019. The entire contents of the aforementioned provisional patent application are incorporated herein by reference.
Number | Date | Country | |
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62900364 | Sep 2019 | US |