Like reference numerals in different figures indicate like elements.
Top part 114 and bottom part 116 are adjacent to the top and bottom portions of ledge 110. Ledge 112 also has an adjacent top part 118 and an adjacent bottom part 120. Sides 102 and 104 also include similar top and bottom parts.
Side 102 of frame 100 can be of length 122. Side 104 of frame 100 can be of length 124. Parallel sides of the frame may be of the same length. In one implementation of frame 100, length 122 may be equal to length 124. In another implementation, length 122 and length 124 may be different. In one implementation, in order to accommodate a PCBA that is of dimensions 16 inches by 18 inches, length 122 may be at least 16 inches and length 124 can be at least 18 inches. Frame 100 can be used for, but is not limited to, holding relatively large PCBAs, e.g., which are greater than 8 inches by 10 inches in size.
A constraint 128 can be placed on the top part 114. Constraints can be placed at various locations along each side of frame 100, e.g., along the top parts, in order to hold a PCBA in place. This can help in reducing the amount of flexing, or bending, of the PCBA that can occur in handling, e.g., from manufacturing through testing. The constraints can be, e.g., metal or non-metal clips that are placed at intervals along the top part of the frame to keep the PCBA substantially stationary within frame 100.
A ledge height 130 can be the distance from ledge 110 to the bottom of a constraint 128. The ledge height 130 can be determined from the thickness of the PCB. The ledge height 130 can then be used to determine the location of the constraints along the top part in the frame with respect to the ledge. The thickness of a PCB can vary depending, for example, on how many layers are included in the PCB.
A top part height 132 can be the length from the top of side 106 to the bottom of constraint 128. A bottom part height 134 can be the length from ledge 110 to the bottom of side 106. Top part height 132 and bottom part height 134 can be determined based on the height of the components on the PCBA. For example, top part height 132 and bottom part height 134 can be chosen to allow the PCBA to be mounted in frame 100 and placed on a flat surface without any of the PCBA components coming in contact with the flat surface. This is described in more below with respect to
Frame 100 can comprise, in part or whole, a material that exhibits anti-static properties. In this regard, static discharge during PCBA handling can cause damage to components on the PCBA, causing the board to fail during test or later-on, in the field. Therefore, frame 100 can be comprised of a material designed to eliminate all or some static discharge that may occur during handling. A metal, such aluminum, or a composite plastic material, such as Delmat™, may be used to construct frame 100.
PCBA 310 can be slid onto the ledges and below the constraints of sides 304, 306 and 308. Once in place, side 302 can be closed to connected to the remainder of the frame, and thereby contact the remaining side of PCBA 310 (the bottom of PCBA 310 rests on the ledge of side 302). Interlocking latches 314 and 316 can be connected to provide a closed frame 300 that engages and supports PCBA 310.
PCBA 502 can include components mounted on both sides of the PCBA. Here, components 514, 516, 518 and 520 are mounted on a top of PCBA 502, and component 514 is the tallest. Components 522, 524 and 526 are mounted on the bottom of the PCBA, and the tallest component there is component 524.
The PCBA holding structure can be customized to accommodate any type of PCBA. For example, top part height 532, bottom part height 534, ledge height 536, and ledge width 538 can be designed to accommodate any sized/shaped PCBA 502.
Ledge height 536 can be designed based on a PCBA thickness 540. Ledge width 538 can be designed based on the amount of area along the edges of the PCBA that does not contain any components, as well as how much of the unpopulated edge of the PCBA needs to be placed on the ledges of the PCBA holding structure to allow the PCBA to be adequately supported by the structure. For example, the ledge width 538 can be designed based on the overall size and weight of the PCBA 502.
The top part height 532 can be determined by adding a height 541 of the tallest component 514 on the top side of the PCBA 502 to the amount of clearance 542 needed from the top of the tallest component 514 to the top of the part 544. In a similar manner, the bottom part height 534 can be determined by adding the height 546 of the tallest component 524 on the bottom side of the PCBA 502 to the amount of clearance 548 needed from the top of the tallest component 524 to the bottom of the part 550.
The PCBA holding structure can be customized for a PCBA based on the dimensions, weight and width of the PCBA, as well as the amount of clearance needed from the tallest components on either side (top or bottom) of the PCBA.
The PCBA holding structure can provide protection to a PCBA by constraining the perimeter of the PCBA, and by providing clearance to components on the top and bottom of the PCBA. The PCBA holding structure limits flexural excitation of the PCBA, namely the flexing, bending or warping of the PCBA that can occur when handling the PCBA. The PCBA may be handled, for example, during intermediate manufacturing and test steps such as press-fit, manual assembly, and reworking. Constraining the perimeter of the PCBA can protect it from damage due to flexural excitation.
The PCBA holding structure can provide additional protection to a PCBA by limiting the amount of shear stress applied to the PCBA. Shear stress to a component can occur when the component is slid, for example, against a flat surface. Providing clearance to the tallest components on both the top side and the bottom side of the PCBA allows the PCBA to be placed on a flat surface on either side for, e.g., manual assembly or rework, without permitting the components to contact the flat surface.
Shear stress, as well as flexural excitation, can result in damage to the PCBA itself (e.g., the board can crack) and/or to components and/or the solder joints, or connections, on the PCBA. This damage can result in the immediate failure of the board during testing. This damage can also remain undetected, however, resulting in an early failure of the PCBA once in the field.
The PCBA holding structure can be designed, as described with reference to
The foregoing features of the PCBA holding structure permit its use from the time when the PCBA exits a reflow oven, through testing, and cleaning until the PCBA is secured in a box, or instrument. A lightweight design of the PCBA holding structure can enable a PCBA mounted in the PCBA holding structure to be shipped in a container, while keeping the PCBA relatively rigid and safe during shipping.
It is noted that the PCBA holding structure can be used during in-circuit and module level testing. That is, the structure can hold a PCBA during actual testing without requiring removal of the PCBA during testing. As a result, stability during testing is increased, and the chances of damage to the PCBA during testing are decreased.
Elements of different implementations described herein may be combined to form other implementations not specifically set forth above. Other implementations not specifically described herein are also within the scope of the following claims.