Method for soldering shape memory alloys
First Claim
Patent Images
1. A method of soldering a shape memory alloy (SMA) element to a component, the method comprising:
- tinning an end of the SMA element with a solder material and a predetermined flux material, wherein the flux material contains concentrated phosphoric acid or tin fluoride, and wherein the solder material has a liquidus temperature that does not exceed 500°
F.;
positioning the tinned end of the SMA element with respect to a surface of the component;
directly soldering the tinned end of the SMA element to the surface of the component using the solder material without crimping of the SMA element or using intervening structure between the SMA element and the component; and
controlling an amount of heat penetrating into a depth of the SMA element by attaching clip-on heat sinks to the SMA element such that the heat is locally retained and does not penetrate sufficiently into the depth of SMA element to cause shape memory abilities of the SMA element to be lost while tinning and directly soldering the SMA element.
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Accused Products
Abstract
A method of soldering a shape memory alloy (SMA) element to a component includes positioning a tinned end of the SMA element with respect to a surface of the component, and then directly soldering the tinned end to the surface using solder material having a low liquidus temperature of 500° F. or less when an oxide layer is not present on the SMA element. The end may be soldered using lead-based solder material at a higher temperature when an oxide layer is present. The end may be tinned with flux material containing phosphoric acid or tin fluoride prior to soldering the SMA element. The SMA element may be submersed in an acid bath to remove the oxide layer. The solder material may contain tin and silver, antimony, or zinc, or other materials sufficient for achieving the low liquidus temperature. Heat penetrating the SMA element is controlled to protect shape memory abilities.
10 Citations
19 Claims
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1. A method of soldering a shape memory alloy (SMA) element to a component, the method comprising:
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tinning an end of the SMA element with a solder material and a predetermined flux material, wherein the flux material contains concentrated phosphoric acid or tin fluoride, and wherein the solder material has a liquidus temperature that does not exceed 500°
F.;positioning the tinned end of the SMA element with respect to a surface of the component; directly soldering the tinned end of the SMA element to the surface of the component using the solder material without crimping of the SMA element or using intervening structure between the SMA element and the component; and controlling an amount of heat penetrating into a depth of the SMA element by attaching clip-on heat sinks to the SMA element such that the heat is locally retained and does not penetrate sufficiently into the depth of SMA element to cause shape memory abilities of the SMA element to be lost while tinning and directly soldering the SMA element. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
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12. A method of soldering a nickel titanium (NiTi) shape memory alloy (SMA) wire to a component, the method comprising:
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submersing the NiTi SMA wire in an acid bath for a calibrated duration sufficient to remove an oxide layer from the NiTi SMA wire, thereby producing a clean SMA wire; tinning an end of the clean NiTi SMA wire with a non-leaded solder material and a flux material; positioning the tinned end of the clean NiTi SMA wire with respect to a surface of the component; directly soldering the tinned end of the clean NiTi SMA wire to the surface of the component using the solder material without crimping of the NiTi SMA wire or using intervening structure between the NiTi SMA wire and the component, wherein the solder material has a liquidus temperature that does not exceed 500°
F.; andcontrolling an amount of heat penetrating into a depth of the NiTi SMA wire by attaching clip-on heat sinks to the NiTi SMA wire such that the heat is locally retained and does not penetrate sufficiently into the depth of NiTi SMA wire to cause shape memory abilities of the NiTi SMA wire to be lost while tinning and directly soldering the NiTi SMA wire. - View Dependent Claims (13, 14, 15, 16, 17)
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18. A method of soldering a nickel titanium (NiTi) shape memory alloy (SMA) wire to a contact pad of a printed circuit board, the method comprising:
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removing an oxide layer from the NiTi SMA wire using a concentrated mixture of hydrofluoric and nitric acid; tinning an end of the NiTi SMA wire with a flux material containing at least 80% phosphoric acid by weight; directly soldering the tinned end of the NiTi SMA wire to the contact pad of the printed circuit board without crimping of the NiTi SMA wire or using intervening structure between the NiTi SMA wire and the printed circuit board using a non-leaded solder material having a liquidus temperature that does not exceed 500°
F.; andcontrolling an amount of heat penetrating into a depth of the NiTi SMA wire by attaching clip-on heat sinks to the NiTi SMA wire such that the heat is locally retained and does not penetrate sufficiently into the depth of NiTi SMA wire to cause shape memory abilities of the NiTi SMA wire to be lost while tinning and directly soldering the NiTi SMA wire. - View Dependent Claims (19)
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Specification
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Current AssigneeGM Global Technology Operations LLC (General Motors Company)
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Original AssigneeGM Global Technology Operations LLC (General Motors Company)
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InventorsPinto, IV, Nicholas W, Johnson, Nancy L., Irish, Nicholas P., Balogh, Michael P., Haddad, Daad B
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Primary Examiner(s)Patel, Devang R
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Application NumberUS14/931,056Publication NumberTime in Patent Office693 DaysField of SearchNoneUS Class CurrentCPC Class CodesB23K 1/0016 Brazing of electronic compo...B23K 1/19 taking account of the prope...B23K 1/203 Fluxing, i.e. applying flux...B23K 2101/42 Printed circuitsB23K 2103/14 Titanium or alloys thereofB23K 2103/18 Dissimilar materialsB23K 2103/26 Alloys of Nickel and Cobalt...B23K 3/025 Bits or tipsB23K 3/027 Holders for soldering ironsB23K 3/047 electricB23K 3/082 Flux dispensers; Apparatus ...B23K 35/3605 FluoridesB23K 35/362 Selection of compositions o...H05K 2201/10287 Metal wires as connectors o...H05K 3/341 Surface mounted componentsH05K 3/3457 Solder materials or composi...H05K 3/3489 Composition of fluxes; Meth...
