Transmission lines are used for transmitting power or data signals. One type of transmission line is a fiber optic cable that can be used to transmit digital data using light signals. The use of fiber optic cable for data transmission is popular, at least in part due to the high data transmission rate and very fast transmission speed.
Transmission lines can be used to carry power or data signals short distances, such as within a building, or long distances, such as between neighboring cities. For longer distance communication, transmission lines are often installed in underground ducts (also referred to as conduits), where continuous transmission lines as long as 0.5, 1, 2, 5 kilometers, or more, are desired between manhole or hand hole locations.
Installation equipment such as transmission line blowers and transmission line pullers have been developed that can be used to insert transmission lines into ducts over long distances. It is desired to have a transmission line installation equipment which can facilitate smooth and stable advancement of the transmission line that is being installed.
In general terms, this disclosure is directed to a transmission line conveying apparatus. In one possible configuration and by non-limiting example, the transmission line conveying apparatus includes an air block that has an integrated seal. The integrated seal can help create an airtight air block. In another possible configuration and by non-limiting example, the transmission line conveying apparatus includes a load cell that can be used to monitor the drive force generated by a transmission line drive assembly and applied to the transmission line. A drive system, including both the integrated seal and the load cell, can facilitate the smoothness and stability of the advancement of the transmission line that is being installed.
One aspect is an integrated seal used in an air block of a transmission line conveying apparatus comprising: a ring-shaped front sealing member; a hollow cylindrical rear sealing member, the hollow cylindrical rear sealing member and the ring-shaped front sealing member sharing a central axis; and a connecting sealing member connecting the ring-shaped front sealing member and the hollow cylindrical rear sealing member.
Another aspect is an air block of a transmission line conveying apparatus comprising: an air block housing; and an integrated seal located in the air block housing, the integrated seal comprising: a ring-shaped front sealing member; a hollow cylindrical rear sealing member, the hollow cylindrical rear sealing member and the ring-shaped front sealing member sharing a central axis; and a connecting sealing member connecting the ring-shaped front sealing member and the hollow cylindrical rear sealing member.
A further aspect is a transmission line conveying apparatus comprising: a transmission line drive assembly configured to apply a first component of a motive force to a transmission line by an engagement between the transmission line drive assembly and the transmission line; and an air block configured to apply a second component of the motive force to the transmission line generated by pressurized air, comprising: an air block housing; and an integrated seal located in the air block housing, the integrated seal comprising: a ring-shaped front sealing member; a hollow cylindrical rear sealing member, the hollow cylindrical rear sealing member and the ring-shaped front sealing member sharing a central axis; and a connecting sealing member connecting the ring-shaped front sealing member and the hollow cylindrical rear sealing member.
Yet another aspect is a transmission line conveying apparatus comprising: a transmission line drive assembly configured to apply a first component of a motive force to a transmission line by an engagement between the transmission line drive assembly and the transmission line; an air block configured to apply a second component of the motive force to the transmission line generated by pressurized air; a mount frame, wherein the air block is fixed to the mount frame, and the transmission line drive assembly is slidably mounted to the mount frame; a load cell having a first connector secured to the air block and a second connector secured to the transmission line drive assembly, the load cell being configured to measure the first component of the motive force; and a local controller, the local controller being connected to an output port of the load cell to receive the measured first component of the motive force, the local controller being connected to the transmission line drive assembly to adjust operation parameters of the transmission line drive assembly to adjust the first component of the motive force, based on the measured first component of the motive force.
A further aspect is a method of operating a transmission line conveying apparatus including a transmission line drive assembly, an air block, a mount frame, a load cell secured between the transmission line drive assembly and the air block, and a local controller, comprising: measuring, by the load cell, a first component of a motive force applied to a transmission line by an engagement between the transmission line drive assembly and the transmission line; determining, by the local controller, the first component of the motive force is equal to or larger than a maximum motive force; and adjusting, by the local controller, operation parameters of the transmission line drive assembly to decrease the first component of the motive force.
Various embodiments will be described in detail with reference to the drawings, wherein like reference numerals represent like parts and assemblies throughout the several views. Reference to various embodiments does not limit the scope of the claims attached hereto. Additionally, any examples set forth in this specification are not intended to be limiting and merely set forth some of the many possible embodiments for the appended claims.
For a transmission line blower, a motive force generated by the transmission line blower and applied to the transmission line drives the transmission line through the duct. The motive force may generally include two components. The first component is a drive force generated by frictional engagement of the transmission line with a moving drive assembly. The second component is a pull force (i.e., suction) generated by air pressure difference in the duct. Pressurized air may be generated by an air compressor and introduced into the duct through an air block of the transmission line blower to create the air pressure difference in the duct.
There are many variables that impact whether or not such an installation will be successful. The drive force and the air pressure are both among those variables. As to the drive force, an excessive drive force may damage the transmission line by, for example, causing the transmission line to bend (also known as transmission line buckling), whereas an inadequate drive force may not provide the intended advancement speed of the transmission line. As to the air pressure, it is desired to have an airtight air block and most of the pressurized air is not lost by leaking out of the air block. If a gap is formed somewhere in the air block, the pressurized air inside of the air block can leak out, which can undesirably and significantly reduce the air pressure and rate of air flow into the duct.
The present disclosure relates to a transmission line conveying system, which can be used to install a transmission line. The transmission line conveying system includes a transmission line conveying apparatus (also referred to as a line blower) which has a drive system. The drive system has both an integrated seal in an air block and a load cell that can be used to monitor the drive force. The drive system can facilitate smooth and stable advancement of the transmission line that is being installed.
The term “transmission line” is used herein as a generic term for any type of wire, cable, or other elongate structure capable of transmitting energy, whether in the form of a fiber optic cable, power line, electrical cable, telephone line (copper line), coaxial cable, or the like. For simplicity, the present disclosure may refer to a particular example of a transmission line, namely a fiber optic cable. However, the transmission line conveying system can be used in the same manner for installation of any other transmission line, and therefore the present disclosure should not be interpreted to be limited to installation of fiber optic cables. Instead, the transmission line conveying system can also be used for installing power lines, telephone lines, coaxial cables, and any other desired transmission line. In typical embodiments the transmission line conveying system is configured to install a transmission line within a conduit such as a duct. Additionally, a transmission line conveying system can also be used for other purposes, such as for installing a pull tape or other pull line, an inner duct, or other items within a conduit.
Although the term “transmission line” is sometimes used (such as in radio-frequency engineering) to refer to a specific type of line used to carry radio frequency signals, the term “transmission line” is not intended to be so limited in the present disclosure, but rather is intended to broadly include the transmission of any type of energy or signal (electricity, radio frequency, light, etc.) along an elongate and flexible structure. Specifically, examples of transmission lines include those that can transmit electricity, such as a wire; or light, such as a fiber optic cable including optical fibers.
One particular type of transmission line is an ultra-high fiber count (UHFC) fiber optic cable. Such a cable often contains thousands of optical fibers, housed within a protective enclosure. The transmission line conveying system can be used to install ultra-high fiber count fiber optic cables. In other embodiments the transmission line conveying system can be used to install various other types of transmission lines.
It should be noted that
Although the route of the duct D is illustrated in
Specifications of the duct include, for example, internal diameter of the duct, the composition of or frictional characteristics of the duct's interior coating or surface, whether the duct contains interior ribs, ridges, or other features or textures, the number of duct segments, the length of each duct segment, the quantity and location of hand holes, and the like. Specifications of the transmission line include, for example, type, outer diameter, specific weight, stiffness, minimum bend radius, break point, composition of or frictional characteristics of the transmission line's outer coating or surface, cross-sectional shape (circular, hexagonal, etc.).
The example transmission line source 102 includes a reel stand 106 for holding a transmission line reel 108 containing the transmission line 110. The transmission line source 102 is the source of the transmission line 110 that is to be installed at the site S. The line blower 118 operates to receive the transmission line 110 from the transmission line source 102 (reel stand 106 and transmission line reel 108) and to advance the transmission line 110 through the duct D, in cooperation with components such as the air compressor 114. The transmission line 110 is typically wound around the transmission line reel 108, and the reel stand 106 operates to elevate the transmission line reel 108 above the ground to allow the transmission line reel 108 to rotate and feed the transmission line 110 to the line blower 118.
The line blower 118 includes, among other things, a transmission line drive assembly 360, an air block 363, and a load cell 550 therebetween. The transmission line drive assembly 360 and the air block 363 are mounted on a mount frame 510. The transmission line drive assembly 360 frictionally engages the transmission line 110 so as to provide the first component of the motive force, namely the drive force generated by frictional engagement of the transmission line 110 with the transmission line drive assembly 360. The transmission line 110 advances through the transmission line drive assembly 360 and enters the air block 363.
The air block 363 links both the transmission line 110 received from the transmission line drive assembly 360 and the air compressor 114 with duct D. In one example, the air block 363 includes an integrated seal 570, which helps make the air block 363 airtight. The integrated seal 570 will be described in detail with reference to
The air compressor 114 provides a source of pressurized air to the line blower 118, and in some embodiments also includes a compressor module that operates to detect qualities of the air and conditions the air prior to delivery to the line blower 118. In some embodiments the compressor module further includes air throughput ports that act like a bypass through which the pressurized air from the air compressor 114 can pass through. The compressor module may also sensors to analyze qualities of the air as it moves through the throughput ports and before it is delivered to the line blower 118, and to transmit the detected data to one or more other components of the transmission line conveying system 104, or remotely, such as to an installation monitoring and management system. In some embodiments the sensors detect one or more of air pressure, temperature, and humidity. Further, in some embodiments the compressor module can operate to modify the quality of the air, such as to adjust one or more of the air pressure, temperature, humidity, moisture, and lubrication.
The power source 116 is a source of energy for the transmission line conveying system 104. The power source 116 provides energy to components of the transmission line conveying system 104, including but not limited to the line blower 118, the air compressor 114, and the reel stand 106. In the example of
The air block 363 is fixed to the mount frame 510, whereas the transmission line drive assembly 360 is slidably mounted on the mount frame 510. In other words, the air block 363 cannot move relative to the mount frame 510, whereas the transmission line drive assembly 360 may move relative to the mount frame 510, either in the direction of the advancement of the transmission line 110 or in the direction of the retreat of the transmission line 110. Therefore, the transmission line drive assembly 360 may move relative to the air block, and a displacement of the transmission line drive assembly 360 exists. The load cell 550 is located between the transmission line drive assembly 360 and the air block 363. One end (e.g., one connector) of the load cell 550 is secured to the air block 363, and another end (e.g., another connector) of the load cell 550 is secured to the transmission line drive assembly 360. The displacement of the transmission line drive assembly 360 relative to the air block 363 results in either tension or compression of the load cell 550. Thus, the load cell 550 can measure the first component of the motive force, namely the drive force generated by frictional engagement of the transmission line 110 with the transmission line drive assembly 360, based on the tension or the compression of the load cell 550. The functioning of the load cell 550 will be described in detail below with reference to
The load cell 550 is connected to a local controller 160 of the line blower 118, which is also connected to the transmission line drive assembly 360. The local controller 160 can obtain the first component of the motive force by for example reading the output signals of the load cell 550. The local controller 160 of the line blower 118 can control the transmission line drive assembly 360 to adjust the operation parameters of the transmission line drive assembly 360 to adjust the first component of the motive force based on the measured first component of the motive force. For instance, when the measured first component of the motive force is equal to or larger than a maximum motive force, the local controller 160 of the liner blower 118 may adjust the operation parameters of the transmission line drive assembly 360 to decrease the first component of the motive force until it is below the maximum motive force. In another example, when the measured first component of the motive force is equal to or lower than a minimum motive force, the local controller 160 of the liner blower 118 may adjust the operation parameters of the transmission line drive assembly 360 to increase the first component of the motive force until it is above the minimum motive force. In another example, the local controller 160 of the liner blower 118 may adjust the operation parameters of the transmission line drive assembly 360, based on the measured first component, to maintain the first component of the motive force within an expected range. The expected range may be configured by an operator such as an installation technician. As such, the load cell 550, the local controller 160 of the line blower 118, and transmission line drive assembly 360 together may provide a negative feedback loop to regulate the first component of the motive force, therefore improving the smoothness and stability of the advancing transmission line 110 and avoiding potential buckling of the transmission line 110.
The transmission line conveying system 104 further includes a control unit 120. In one embodiment, the control unit 120 is a computing device that provides an interface between the installation technician and the transmission line conveying system 104. In some embodiments, the control unit 120 receives control inputs from the installation technician, such as to start and stop an installation. In some embodiments the control unit 120 provides status information to the installation technician, such as to convey the current status of the installation and to show the progress that has already been made.
On the other hand, the control unit 120 may operates as a global controller 121 in some embodiments. In the example of
In some embodiments the control unit 120 and the components (i.e., the line blower 118, the reel stand 106, the air compressor 114, and the power source 116 in the example of
In some embodiments the local controllers 160 may communicate with each other using peer-to-peer communication and are capable of independently controlling their respective components (i.e., the line blower 118, the reel stand 106, the air compressor 114, and the power source 116 in the example of
The local controller 160 controls the overall operation of the component, and communicates through the communication device 176 with other local controllers 160 and the control unit 120 in the transmission line conveying system 104. For example, in some embodiments the local controller 160 receives commands in the form of messages or instructions from the control unit 120 through the communication device 176. Examples of such commands include start, stop, and speed adjustments (a particular speed setting, an instruction to increase the speed, or an instruction to decrease the speed, etc.). Further, in some embodiments the local controller 160 also sends messages or instructions to other components through the communication device 176. For example, measured data or current or historical settings can be transmitted by the local controller 160 to other components.
The processing device 172 operates to process data instructions to perform functions of the component (e.g., the liner blower 118). The memory device 174 stores data instructions, which when executed by the processing device 172, cause the processing device to perform corresponding functions. The memory device 174 does not include transitory media carrying data signals. An example of the memory device 174 is a computer readable data storage device as described in further detail herein.
The communication device 176 is a device that communicates with other devices, including but not limited to the control unit 120 and other local controllers 160, via wired or wireless data communication. In some embodiments the communication device 176 communicates with all of the control unit 120 and other local controllers 160.
The communication device 176 can utilize wireless or wired communication devices. Examples of wireless communication devices include cellular communication devices, Wi-Fi (IEEE 802.11x) communication devices, and BLUETOOTH communication devices. Wired communication devices include modems, USB devices, serial and other I/O communication devices and techniques.
The intracomponent input/output communication device 178 operates to communicate with and control subsystems, sensors, or other electronic or controllable devices within the component (e.g., the line blower 118), utilizing wired or wireless communication or control signals. For example, the intracomponent input/output communication device 178 of the line blower 118 is coupled to the load cell 550 and the transmission line drive assembly 360 in some embodiments.
The line blower 118 in this example is located between a first duct D1 and a second duct D2 extending in the Z direction. The transmission line 110 is advancing in the Z direction, coming out of the distal end of the first duct D1, passing through the line blower 118, and eventually entering the proximal end of the second duct D2. Duct clamps 364 are configured to secure the distal end of the first duct D1 to the input of the line blower 118 and the proximal end of the second duct D2 to the output of the line blower 118.
In the example shown in
The line blower 118 includes, among other things, the transmission line drive assembly 360 and the air block 363. The transmission line drive assembly 360 further includes an upper tractor drive 322 and a lower tractor drive 324. The upper tractor drive 322 and the lower tractor drive 324 oppose each other and are aligned in the Y direction. It should be noted that the upper tractor drive 322 in
As shown in
In some embodiments the transmission line drive assembly 360 may further include a hold down system, such as a hydraulic clamp cylinder, linked to the hydraulic pressure source by a hydraulic line. The hydraulic clamp cylinder generates a predetermined normal force on the transmission line 110 between the upper and lower tractor drives 322, 324. Some slip is acceptable. Too much slip can cause transmission line jacket damage. The second duct D2 may contain some irregularities, joints and bends that can keep transmission line 110 from moving smoothly. Unless an appropriate normal force is generated (not too much slip), the first component of the motive force may be inadequate to overcome the irregularities, and slip may occur too often, causing unnecessary transmission line jacket damage or insufficient first component of the motive force. On the other hand, a normal force which is too high risks crush damage to the transmission line 110, and inadequate slippage, such that column damage will be more likely to occur as the transmission line drive assembly 360 continues to move the transmission line 110 when transmission line 110 is being slowed or stopped within the second duct D2. When slip does occur under high normal force loads, transmission line jacket damage may result. By providing for a predetermined normal force with the transmission line drive assembly 360, predetermined slip levels can be monitored. This results in an appropriate level of slip, so as to not cause too many shutdowns of the line blower 118 when transmission line damage is not significantly at risk, but excessive slip is noted, and can be used to shut off the line blower 118 to prevent damage.
In some embodiments the transmission line drive assembly 360 may further include a lower drive counter which monitors movement of the lower tractor drive 324, which is indicative of the speed of transmission line drive assembly 360. Such speed monitoring is important for preventing excessive relative speed between the transmission line drive assembly 360 and the transmission line 110 during slippage. The speed may be communicated from the lower drive counter to the local controller 160 of the transmission line drive assembly 360 which receives the speed. The speed can then be communicated to the local controllers 160 of other components (e.g., the reel stand 106, the air compressor 114, etc.) or the control unit 120.
On the other hand, once the transmission line 110 enters the air block 363 through the air block lead in guide structure 3010, the pressurized air that is produced by the air compressor 114 and enters the air block 363 through the air input port 302. The integrated seal 570, in addition with other components in the air block 363, help make the air block 363 airtight, and most of the pressurized air is not lost by leaking out of the air block 363. As such, the air pressure difference created in the second duct D2 results in the second component of the motive force, namely the pull force (i.e., suction) generated by the air pressure difference in the second duct D2.
In the example shown in
As shown in
On the other hand, as shown in
As stated above, the blower lead in guide structure 3030 and the air block lead in guide structure 3010 shown in
As will be described below, both the blower lead in guide structure 3030 and the air block lead in guide structure 3010 have a tapered (funnel-shaped) cross-sectional shape that is larger at the front and decreases in size toward the end. In other words, the tapered cross-sectional shape is facing the advancement direction of the transmission line 110. Therefore, the blower lead in guide structure 3030 and the air block lead in guide structure 3010 guide the leading end of the transmission line 110 toward the transmission line drive assembly 360 and the air block 363, respectively.
Due to the tapered cross-sectional shape of the blower lead in guide structure 3030 and the air block lead in guide structure 3010, the transmission line 110 may be fed in the transmission line drive assembly 360 and the air block 363 smoothly without manual intervention, thus reducing the risk of damaging structures such as the transmission line 110 itself, structures or components in the transmission line drive assembly 360 and the air block 363, and so on. The guide system composed of the blower lead in guide structure 3030 and the air block lead in guide structure 3010 may further improve the overall performance of a transmission line conveying system 104 with multiple line blowers, as the situation shown in
In some embodiments the air block lead in guide structure 3010 has two halves: a lower half 3010a and an upper half 3010b (alternatively referred to herein as a first half and a second half). As such, the air block lead in guide structure 3010 can be opened to separate the lower half 3010a and the upper half 3010b, such as to provide access into the interior of the air block lead in guide structure 3010, or to permit the transmission line 110 to be inserted or removed. For example, the lower half 3010a and the upper half 3010b can be separated during maintenance or in the event of a malfunction (e.g., damage of the transmission line 110). Additionally, the air block lead in guide structure 3010 may be replaceable. The air block lead in guide structure 3010 is made of a material that does not significantly deform with the impact of the transmission line 110. The material is more rigid than the seal 365 of
The air block lead in guide structure 3010 in this example include, among other things, a central portion 3016, a forward end 3012, and a rearward end 3014. The central portion 3016 has a larger size, in the X-Y plane, than those of the forward end 3012 and the rearward end 3014. As such, there is a securing flange 3017 formed at the place where the central portion 3016 and the forward end 3012 are joined. The securing flange 3017 can be used to secure the air block lead in guide structure 3010 to the transmission line input aperture of the air block 363. The rearward end 3014 has a gradual shape that may facilitate the air to flow smoothly inside the air block 363 toward the second duct D2. As a result, turbulence or laminar flow may be avoided.
The air block lead in guide structure 3010 further includes an inner body 3018. The inner body 3018 has a tapered sidewall 3020 and defines an inner aperture 3022 that extends from the forward end 3012 to the rearward end 3014. The inner aperture 3022 has a dimension at the forward end 3012 that is greater than the dimension at the place where the forward end 3012 and the central portion 3016 are joined together (i.e., the location of the securing flange 3017). A smooth gradually tapered shape, facing the advancement direction of the transmission line (for example, having a tapered cross-sectional shape that decreases in size in an advancement direction of the transmission line), of the inner aperture 3022 and the tapered sidewall 3020 acts like a funnel to direct the transmission line into the air block.
Similarly, the blower lead in guide structure 3030 has two halves: a lower half 3030a and an upper half 3030b. As such, the blower lead in guide structure 3030 can be opened for similar reasons as the air block lead in guide structure 3010 described above. The blower lead in guide structure 3030 may be replaceable. The blower lead in guide structure 3030 is made of a material that does not significantly deform with the impact of the transmission line 110. The material is more rigid than the seal 365 of
The blower lead in guide structure 3030 in this example include, among other things, a forward end 3032, and a rearward end 3034. The forward end 3032 has a larger size, in the X-Y plane, than that of the rearward end 3034. As such, there is a securing flange 3037 formed at the place where the rearward end 3034 and the forward end 3032 are joined together. In some embodiments the securing flange 3037 can be used to secure the blower lead in guide structure 3030 to a transmission line receptacle to prevent the blower lead in guide structure 3030 from moving rearward (along the advancement direction of the transmission line) as it passes therethrough.
The blower lead in guide structure 3030 further includes an inner body 3038. The inner body 3038 has a tapered sidewall 3040 and defines an inner aperture 3042 that extends from the forward end 3032 to the rearward end 3034. The inner aperture 3042 has a dimension at the forward end 3032 that is greater than the dimension at the place where the forward end 3032 and the rearward end 3034 are joined together (i.e., the location of the securing flange 3037). A smooth gradually tapered shape, facing the advancement direction of the transmission line (for example, having a tapered cross-sectional shape that decreases in size in an advancement direction of the transmission line), of the inner aperture 3042 and the tapered sidewall 3040 acts like a funnel to direct the transmission line into the transmission line drive assembly 360.
As shown in the example of
The air block lower housing body 612 has an air block lower chamber 622 extending in the Z direction. The air block lower chamber 622 generally has a U-shaped profile in the X-Y plane, though the cross sections in the X-Y planes across the Z direction vary. The air block lower chamber 622 has three portions: a front portion 622a, a middle portion 622b, and a rear portion 622c. The front portion 622a of the air block lower chamber 622 is configured to accommodate a portion of the air block lead in guide structure 3010, as shown in
The air block lower housing body 612 has corresponding front portion, middle portion, and rear portion. The air block lower housing body 612 has two sidewalls 613: a left sidewall 613a and a right sidewall 613b, each of which has corresponding front portion, middle portion, and rear portion. A lower housing seal accommodating recess 620 is located at the middle portion of the left sidewall 613a. The lower housing seal accommodating recess 620 is configured to accommodate the integrated seal 570, and more specifically a left strip 576a of a connecting sealing member 576 of the integrated seal 570, which will be described below in detail with reference to
The air block upper chamber 624 generally has a U-shaped profile in the X-Y plane, though the cross sections in the X-Y planes across the Z direction vary. The air block upper chamber 624 has three portions: a front portion 624a, a middle portion 624b, and a rear portion 624c, corresponding to the three portions of the air block lower chamber 622. The front portion 624a of the air block upper chamber 624 is configured to accommodate a portion of the air block lead in guide structure 3010, as shown in
The air block upper housing 610b has corresponding front portion, middle portion, and rear portion. The air block upper housing 610b has two sidewalls 625: a left sidewall 625a and a right sidewall 625b, each of which has corresponding front portion, middle portion, and rear portion. An upper housing seal accommodating recess 626 is located at the middle portion of the right sidewall 625b. The upper housing seal accommodating recess 626 is configured to accommodate the integrated seal 570, and more specifically a right strip 576b of a connecting sealing member 576 of the integrated seal 570, which will be described below in detail with reference to
As shown in
The front sealing member 572 is a ring-shaped sealing member. The front sealing member 572 fills a gap between the air block lead in guide structure 3010 and the air block housing 610. In the embodiments where the integrated seal 570 has the integrated seal lower half 570a and the integrated seal upper half 570b, the front sealing member 572 has the lower half 572a and the upper half 572b.
The rear sealing member 574 is a hollow cylindrical sealing member. The rear sealing member 574 and the front sealing member 572 share a central axis extending in the Z direction. The rear sealing member 574 fills a gap between the second duct D2 and the air block housing 610. The exterior of the rear sealing member 574 is a cylindrical surface. The interior of the rear sealing member 574 has a tapered (funnel-shaped) cross-sectional shape that is larger at the front and decreases in size toward the end. In other words, the tapered cross-sectional shape is facing the advancement direction of the transmission line. The rear sealing member 574 has an inner body 578, which has a tapered sidewall 580. A smooth gradually tapered shape and the tapered sidewall 580 acts like a funnel to direct the transmission line into the second duct D2. Therefore, the rear sealing member 574 is configured to guide the leading end of the transmission line toward the second duct D2. In the embodiments where the integrated seal 570 has the integrated seal lower half 570a and the integrated seal upper half 570b, the rear sealing member 574 has the lower half 574a and the upper half 574b.
The connecting sealing member 576 is configured to connect the front sealing member 572 and the rear sealing member 574, therefore forming an integral sealing structure (i.e., the integrated seal 570). The connecting sealing member 576 fills potential gaps between the air block lower housing 610a and air block upper housing 610b. In the example shown in
In some embodiments, the integrated seal 570 is a one-piece (i.e., integral) structure. As shown in
As mentioned above, the left strip 576a of the connecting sealing member 576 is configured to engage with the lower housing seal accommodating recess 620, as shown in
As mentioned above, the line blower 118 includes, among other things, the transmission line drive assembly 360, the air block 363, and the load cell 550. The air block 363 is fixed to the mount frame 510, whereas the transmission line drive assembly 360 is slidably mounted on the mount frame 510. The transmission line drive assembly 360 may move relative to the mount frame 510, either in the direction of the advancement of the transmission line 110 or in the direction of the retreat of the transmission line 110. Therefore, the transmission line drive assembly 360 may move relative to the air block, and a displacement of the transmission line drive assembly 360 exists.
As mentioned above, both the second component F2 of the motive force, namely the pull force (i.e., suction) generated by the air pressure difference in the duct D, and the first component F1 of the motive force, namely the drive force generated by frictional engagement of the transmission line 110 with the transmission line drive assembly 360, are applied to the transmission line 110. It should be noted that the directions and relative magnitudes of the first component F1 and the second component F2 shown in
As shown in
Likewise, when the first component F1 is in the opposite direction as shown in
In general, a load cell is a force transducer and it is configured to convert a force such as tension, compression, pressure, or torque into an electrical signal that can be measured and standardized. As shown in
The second connector 588 is configured to be secured to a housing of the lower tractor drive 324 through a connecting nut 594 and an inserting nut 596. In the example shown in
The load cell body 584 includes inside, among other things, a strain gauge. In some embodiments, the strain gauge is constructed of very fine wire, or foil, set up in a grid pattern and attached to a flexible backing. When the shape of the strain gauge is altered, a change in its electrical resistance occurs. The wire or foil in the strain gauge is arranged in a way that, when force is applied in one direction, a linear change in resistance results. Tension force stretches a strain gauge, causing it to get thinner and longer, resulting in an increase in resistance. Compression force does the opposite. The strain gauge compresses, becomes thicker and shorter, and resistance decreases. The strain gauge is attached to a flexible backing enabling it to be easily applied to the load cell 550. In some embodiments, a set of four strain gauges are set in a specific circuit called Wheatstone bridge, which is a configuration of four balanced resistors with a known excitation voltage applied. The Wheatstone bridge arrangement of the strain gauges can magnify the relatively small changes in resistance into a voltage value that is more measurable. In some embodiments, the load cell body 584 is made of stainless steel which makes it sturdy but also minimally elastic, though it can also be made of other materials such as aluminum, alloy steel, or the like.
The output port 590 is configured to be connected to the output cable 592. The electrical signal, either a voltage signal or a current signal, is output to the local controller 160 as shown in
In one non-limiting example, the load cell 550 is a miniature sealed stainless steel load cell. The capacities of the load cell 550 may range from 1000 to 10000 lbf (pound force), namely from 4500 N to 45000 N. In another non-limiting example, the load cell 550 may operate under temperatures ranging from −54° C. to 121° C. and has the temperature compensation function between −10° C. and 45° C. It should be noted that load cells of other types, makes, or models are within the scope of the disclosure. The load cell 550 are replaceable.
The present disclosure and claims sometimes utilize the words “first,” “second,” “third,” etc. as labels to particularly identify particular objects. Unless required by the context, such terms are used only as labels and do not require any particular order or arrangement with respect to each other or with respect to other objects. For example, a first segment of a duct does not need to be at the beginning of the duct and the second segment does not need to come after the first.
The various embodiments described above are provided by way of illustration only and should not be construed to limit the claims attached hereto. Those skilled in the art will readily recognize various modifications and changes that may be made without following the example embodiments and applications illustrated and described herein, and without departing from the true spirit and scope of the following claims.
This application is being filed on Feb. 4, 2022, as a PCT International application and claims the benefit of and priority to U.S. Application No. 63/146,459, filed on Feb. 5, 2021, titled TRANSMISSION LINE BLOWER WITH A DRIVE SYSTEM, the disclosure of which is hereby incorporated by reference in its entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/US2022/015350 | 2/4/2022 | WO |
Number | Date | Country | |
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63146459 | Feb 2021 | US |