This disclosure relates to the field of tools, and more particularly, to tools that remove panel inserts from panels.
Panels are used in a variety of applications as structural elements. When fastening a panel to another element, holes may be drilled or otherwise formed through the panel for a fastener or the like. Depending on the type of material used for the panel, it may be undesirable to install the fastener directly in the holes of the panel. Thus, panel inserts may be installed in the holes of the panel. One type of panel insert is a one-sided panel insert that includes a bushing that is inserted in a hole of the panel, and a flange on one end of the bushing that engages one side of the panel. The other end of the bushing may be flush with the other side of the panel, may be recessed in the hole, may project from the hole, etc. A one-sided panel insert also includes a thru-hole (threaded or non-threaded) for a fastener that is used to secure the panel to another element. A one-sided panel insert is typically bonded to the panel with an adhesive on the flange and/or bushing.
After installation, there may be a need to remove a panel insert from the panel, such as when the panel insert becomes corroded, damaged, or the like. However, it may be difficult to remove the panel insert without causing damage to the panel.
Provided herein is a removal tool that is configured to extract a panel insert from a panel. A removal tool as described herein is placed on one side of the panel to straddle the panel insert, and a puller rod is coupled to the panel insert. A biasing member of the removal tool applies an axial force to the puller rod as a heater applies heat to the panel insert to soften the adhesive. When the adhesive becomes sufficiently soft, the axial force on the puller rod causes the panel insert to pop out of the hole in the panel. The removal tool provides a technical benefit in that the panel insert may be effectively removed without damage to the panel. Also, processes of using the removal tool are repeatable by operators without need for specialized skills.
One embodiment comprises a removal tool configured to remove a panel insert installed in a panel. The removal tool comprises a tool frame to straddle the panel insert, and a puller rod slidably disposed through the tool frame perpendicularly to a bottom surface of the tool frame that contacts the panel. The puller rod has a first end to engage the panel insert. The removal tool further comprises a biasing member that applies an axial force to the puller rod away from the tool frame, and a heater to apply heat to the panel insert.
In another embodiment, the biasing member is disposed between the tool frame and a second end of the puller rod.
In another embodiment, the removal tool further comprises a loading member that preloads the biasing member by a predetermined amount.
In another embodiment, the heater includes one or more heating elements, and a temperature sensor that measures a temperature.
In another embodiment, the removal tool further comprises a heater controller electrically coupled to the heating elements and the temperature sensor. The heater controller selectively applies power to the heating elements based on the temperature output by the temperature sensor.
Another embodiment comprises a removal tool configured to remove a panel insert installed in a panel. The removal tool comprises a tool frame that supports the removal tool on a side of a panel, and straddles the panel insert. The removal tool further comprises a puller rod that extends through a guide opening in the tool frame and is slidable axially in relation to the tool frame. The puller rod has a first end to couple with the panel insert. The removal tool further comprises a housing having a rod opening coaxial with the guide opening in the tool frame. The puller rod extends through the rod opening, and the housing is coupled to the puller rod toward a second end of the puller rod. The removal tool further comprises a spring disposed between the tool frame and the housing that applies an axial force against the housing, and a heater to apply heat to the panel insert.
In another embodiment, the tool frame includes a base member defining a bottom surface of the tool frame that contacts the side of the panel, and having an insert opening to encircle the panel insert. The tool frame further includes a seat member having the guide opening of the tool frame that is coaxial with the insert opening of the base member. The tool frame further includes a plurality of legs disposed between the base member and the seat member. The puller rod passes through the insert opening and the guide opening. The seat member holds a first end of the spring.
In another embodiment, the housing includes a hollow, cylindrical body comprising an end wall having the rod opening coaxial with the guide opening of the seat member, and a plurality of side walls that project from the end wall with gaps separating the side walls. An inner surface of the end wall holds a second end of the spring.
In another embodiment, the legs of the tool frame are spaced radially around the insert opening of the base member, and the side walls of the housing are disposed between the legs when the spring is compressed.
In another embodiment, the removal tool further comprises a stopper that stops axial movement of the housing away from the tool frame due to the axial force from the spring after traveling a threshold distance.
In another embodiment, when the spring is compressed, a bottom portion of a pair of the side walls extend below the seat member of the tool frame. The stopper includes a securing pin inserted through coaxial holes in the bottom portion of the pair of the side walls.
In another embodiment, the heater includes a heater body having a rod opening, with the puller rod passing through the rod opening. The heater further includes one or more heating elements, and a temperature sensor that measures a temperature of the heater body.
In another embodiment, an outer diameter of the heater body is equal to or greater than a diameter of the panel insert.
In another embodiment, the removal tool further comprises a heater controller electrically coupled to the heating elements and the temperature sensor. The heater controller selectively applies power to the heating elements based on the temperature output by the temperature sensor.
In another embodiment, the puller rod comprises an elongated cylindrical shaft having a head at the first end, and threads at the second end. A diameter of the puller rod is less than a diameter of a thru-hole in the panel insert. A fastener is threaded on the second end with the housing disposed between the spring and the fastener.
In another embodiment, the puller rod comprises an elongated cylindrical shaft having a ball lock at the first end, and a cam lever at the second end. A diameter of the puller rod is less than a diameter of a thru-hole in the panel insert.
In another embodiment, the removal tool further comprises an insulation pad between the tool frame and the panel. The insulation pad includes an insert opening aligned with an insert opening of the tool frame.
In another embodiment, the removal tool further comprises an edge adapter having a top side that interfaces with a bottom surface of the tool frame, and a bottom side that includes a contact surface to rest on the panel, and a spacer block having a thickness that corresponds with a thickness of the panel. The edge adapter further includes an insert opening aligned with an insert opening of the tool frame.
Another embodiment comprises a method of extracting a panel insert from a panel. The method comprises placing a removal tool on the panel so that a tool frame of the removal tool straddles the panel insert, coupling a first end of a puller rod to the panel insert, coupling a biasing member between the tool frame and a second end of the puller rod, applying an axial force to the puller rod with the biasing member in a direction away from the panel, and applying heat to the panel insert while the axial force is applied by the biasing member to extract the panel insert from the panel.
In another embodiment, applying the heat comprises monitoring a temperature of a heater, and selectively applying power to the heater to stay within a temperature window.
The features, functions, and advantages that have been discussed can be achieved independently in various embodiments or may be combined in yet other embodiments, further details of which can be seen with reference to the following description and drawings.
Some embodiments of the present invention are now described, by way of example only, with reference to the accompanying drawings. The same reference number represents the same element or the same type of element on all drawings.
The figures and the following description illustrate specific exemplary embodiments. It will be appreciated that those skilled in the art will be able to devise various arrangements that, although not explicitly described or shown herein, embody the principles described herein and are included within the contemplated scope of the claims that follow this description. Furthermore, any examples described herein are intended to aid in understanding the principles of the disclosure, and are to be construed as being without limitation. As a result, this disclosure is not limited to the specific embodiments or examples described below, but by the claims and their equivalents.
One example of a panel 102 is a honeycomb panel, which is shown in
In
After installation, there may be a need or desire to remove panel insert 110 from panel 102. For example, a panel insert 110 may become corroded or damaged such that replacement is desired. When panel insert 110 is bonded to panel 102 as is illustrated in
In this embodiment, removal tool 500 is an assembly that includes a tool frame 502, a puller rod 504, a biasing member 506, and a heater 508. Tool frame 502 is a structural element that supports removal tool 500 on panel 102. Tool frame 502 has a bottom surface 512 that contacts (directly or indirectly) the top side 104 of panel 102. Bottom surface 512 may be generally flat to interface with the top side 104 of panel 102, which may also be generally flat. However, bottom surface 512 may be contoured to mirror a corresponding contour on the top side 104 of panel 102. When placed on panel 102, tool frame 502 is able to straddle panel insert 110 via an insert opening 514. Insert opening 514 is a void or aperture in tool frame 502 that may be placed over a panel insert 110 so that portions of tool frame 502 contact the top side 104 of panel on multiple sides of panel insert 110. Tool frame 502 therefore extends around and encompasses panel insert 110 on top side 104. This serves to distribute any pressure or stress from tool frame 502 around the panel insert 110.
Puller rod 504 is an elongated member that is slidably disposed through a guide opening 516 in tool frame 502. Puller rod 504 is configured to move axially (up and down in
Biasing member 506 is configured to apply an axial force 530 to puller rod 504 (i.e., along axis 518) away from tool frame 502, and toward the other end 522 of puller rod 504. The axial force 530 is therefore away from the panel insert 110/panel 102. Biasing member 506 may comprise a spring (e.g., a coil spring) or another elastic member that stores potential energy when loaded (i.e., compressed or stretched), and applies an axial force 530 in the opposite direction with the potential energy. Biasing member 506 may be disposed between tool frame 502 and the other end 522 of puller rod 504 as shown in
Heater 508 is configured to apply heat to panel insert 110. Heater 508 is positioned proximate to panel insert 110 so that heat generated by heater 508 acts to soften or melt the adhesive 420 used to bond panel insert 110 to panel 102. For example, heater 508 may contact panel insert 110, or may be positioned close to panel insert 110 to increase the temperature of panel insert 110 and/or the environment around panel insert 110. Heat transfer from heater 508 to panel insert 110 may be via conduction, convection, or radiation. Also shown is a heater controller 540 that controls the heat output of heater 508.
Removal tool 500 may include additional elements as desired. For example, removal tool 500 may include a loading member 510, which is configured to preload biasing member 506 by a predetermined amount. For example, loading member 510 may compress biasing member 506 by a predetermined amount to store potential energy. The potential energy in turn creates the axial force 530 applied by biasing member 506 to puller rod 504. In another embodiment, loading member 510 may stretch biasing member 506 by a predetermined amount to store potential energy.
Tool frame 502 is a rigid structure that supports removal tool 500 on a panel 102. Tool frame 502 may be made from a plastic material, a metal material, or another type of rigid material. Tool frame 502 may be formed from an additive manufacturing process (e.g., 3D printing) or a subtractive manufacturing process as a monolithic part, or as an assembly of parts connected together.
Seat member 804 is also shown as a generally annular body. The outer surface 826 of seat member 804 may be cylindrical as shown in
Legs 806 are disposed between base member 802 and seat member 804 so that seat member 804 is separated from base member 802 by a distance 830. Legs 806 may be spaced (e.g., equally) radially around insert opening 514 of the base member 802. Although three legs 806 are shown for tool frame 502, there may be more or less legs 806 in other embodiments.
In
Biasing member 506 is shown as a spring 710 in this embodiment. Spring 710 is a compression spring that provides resistance to a compressive force applied axially. Spring 710 has opposing ends 712-713. Tool frame 502 (through seat member 804) is configured to engage end 712 of spring 710. Thus, seat member 804 may be referred to as a spring seat member. Although a spring 710 is shown in
Heater 508 may include a heater body 728, one or more heating elements 720, and a temperature sensor 722. In this embodiment, heater 508 is configured to fit within insert opening 514 of tool frame 502, and to encircle puller rod 504. Thus, heater body 728 is an annular body having a rod opening 724. Heater body 728 may be made from a material that conducts heat, such as Aluminum. When assembled, puller rod 504 is disposed through rod opening 724 of heater body 728. Thus, rod opening 724 has a diameter (slightly) larger than the diameter 702 of puller rod 504. Heater body 728 has an outer diameter 726 that is less than the diameter 812 of insert opening 514 of tool frame 502. The outer diameter 726 of heater body 728 may be equal to or greater than the diameter 312 of flange 304 of panel insert 110.
Heating elements 720 (or heating rods) are configured to generate heat in response to power from a power source. Although three heating elements 720 are shown, there may be more or less heating elements 720 in other embodiments. Temperature sensor 722 is configured to measure a temperature of heater 508 (i.e., heater body 728), and generate output indicating the temperature. For example, temperature sensor 722 may comprise a thermocouple or another type of sensor. Heater controller 540 (see
Loading member 510 may include a housing 730 and a fastener 732. Fastener 732 is shown as a washer 734 and a nut 736 in this embodiment, but other types of fasteners are considered herein, such as a clamp, a cam lever, etc. Housing 730 is a rigid structure that at least partially surrounds spring 710, and is also configured to engage the other end 713 of spring 710. Thus, housing 730 may also be referred to as a spring housing. Housing 730 is also configured to engage puller rod 504, and is slidable or movable axially in relation to tool frame 502 as is puller rod 504. Housing 730 may be made from a plastic material, a metal material, or another type of rigid material. Housing 730 may be formed from an additive manufacturing process (e.g., 3D printing) or a subtractive manufacturing process as a monolithic part, or as an assembly of parts connected together.
Housing 730 further includes a rod opening 1008 that is coaxial with guide opening 516 of tool frame 502 when assembled. Rod opening 1008 has a diameter 1014 (slightly) larger than the diameter of puller rod 504. Thus, housing 730 is slidable onto the puller rod 504 from end 522 via rod opening 1008 so that puller rod 504 may pass through rod opening 1008.
Removal tool 500 may further include a stopper 1202 that stops movement of housing 730 in the axial direction away from tool frame 502 due to the axial force 530 from spring 710 after traveling a threshold distance. When a panel insert 110 is extracted from a panel 102, it may tend to “pop” out of a hole 402 in a panel 102 instead of slowly extracting. Stopper 1202 is used to prevent housing 730, puller rod 504, spring 710, etc., from being cast upwardly or to come apart when the panel insert 110 is extracted.
Additional features of removal tool 500 may include a part that protects a panel 102 from heat generated by heater 508.
There may be situations where one or more panel inserts 110 are installed close to an edge of a panel 102. Thus, tool frame 502 may not be able to sit entirely on a surface of the panel 102 for extraction of a panel insert 110. Additional features of removal tool 500 may include an edge adapter that assists in extraction of panel insert 110 proximate to an edge of a panel 102.
The configuration of puller rod 504 as shown in
It is assumed for method 1700 that a panel insert 110 is installed in a panel 102 and bonded to the panel 102 as illustrated in
Puller rod 504 is configured in removal tool 500 to pull the panel insert 110 generally perpendicular to the top side 104 of the panel 102. Thus, a biasing member 506 (e.g., spring 710) is coupled between tool frame 502 and the other end 522 of puller rod 504 (step 1706). Biasing member 506 applies an axial force 530 to puller rod 504 in a direction away from the panel 102 (step 1708). A heater 508 also applies heat to the panel insert 110 (step 1710) while the axial force 530 is applied by biasing member 506. For example, heater controller 540 may monitor a temperature of heater 508 (step 1712), and selectively apply power to heater 508 to stay within a temperature window (step 1714). When the heat softens or melts the adhesive 420 to a certain point, the axial force 530 will overcome the bond formed by the adhesive 420, and extract the panel insert 110 from the panel 102. The extracted panel insert 110 is removed from puller rod 504, and removal tool 500 may be moved to another panel insert 110 on the panel 102. Method 1700 may be repeated for a number of panel inserts 110.
One benefit of method 1700 is that it is an automated process for applying consistent force and controlled heat to remove panel inserts 110 from a panel 102. Method 1700 is less likely to damage the panel 102 when extracting a panel insert 110, and is easily repeatable by operators without need for specialized skills.
Any of the various elements shown in the figures or described herein may be implemented as hardware, software, firmware, or some combination of these. For example, an element may be implemented as dedicated hardware. Dedicated hardware elements may be referred to as “processors”, “controllers”, or some similar terminology. When provided by a processor, the functions may be provided by a single dedicated processor, by a single shared processor, or by a plurality of individual processors, some of which may be shared. Moreover, explicit use of the term “processor” or “controller” should not be construed to refer exclusively to hardware capable of executing software, and may implicitly include, without limitation, digital signal processor (DSP) hardware, a network processor, application specific integrated circuit (ASIC) or other circuitry, field programmable gate array (FPGA), read only memory (ROM) for storing software, random access memory (RAM), non-volatile storage, logic, or some other physical hardware component or module.
Also, an element may be implemented as instructions executable by a processor or a computer to perform the functions of the element. Some examples of instructions are software, program code, and firmware. The instructions are operational when executed by the processor to direct the processor to perform the functions of the element. The instructions may be stored on storage devices that are readable by the processor. Some examples of the storage devices are digital or solid-state memories, magnetic storage media such as a magnetic disks and magnetic tapes, hard drives, or optically readable digital data storage media.
Although specific embodiments were described herein, the scope is not limited to those specific embodiments. Rather, the scope is defined by the following claims and any equivalents thereof.