• HQ 556225
• Jan 06, 1992

• Type : Classification • HTSUS :
•  Related:   071827; 556045   

CLA-2 CO:R:C:S 556225 WAW

John B. Rehm, Esq.
Dorsey & Whitney
1330 Connecticut Ave., N.W.
Washington, D.C. 20036

RE: Eligibility of telecommunication switching equipment for duty-free treatment under the GSP; C.S.D. 85-25; 556045

Dear Mr. Rehm:

This is in response to your letter dated August 16, 1991, on behalf of ADC Telecommunications, Inc. (ADC), requesting a ruling as to whether telecommunication switching equipment assembled in Mexico is entitled to duty-free treatment under the Generalized System of Preferences (GSP) (19 U.S.C. 2461-2466). A sample of the merchandise was included for our review.

FACTS:

ADC supplies parts of both U.S. and foreign origin to an unrelated Mexican company, Elamex S.A. (Elamex). Elamex takes the parts at no cost, and assembles them into telecommunication switching equipment known as "DS3," and charges ADC an assembly fee. Two types of switching coaxial jacks (SCJ's) - an "input" jack and an "output" jack - are used in the assembly of the DS3. The following is a list of the basic steps performed in Mexico in the assembly of the two different types of SCJ's:

(1) Assemble rear die-casting. This assembly is made up of two center conductors, two insulators, and a rear casting. The center conductors are positioned into a fixture with special orientation; the rear casting is positioned on the same fixture; and the insulators are located in the ports of the rear casting. By activating an air press, the insulators are pressed onto the center conductors and into the rear casting.

(2) Connect chassis crimp onto rear casting. The chassis crimp is a structural part of the SCJ, which provides access to the rear of the SCJ. The chassis crimp is connected to the rear casting by orbital rolling over one end with an orbital riveter, creating a rim on the chassis crimp, and locking it into the rear casting.

(3) Assemble front die-casting. This assembly includes a front casting, two insulators, a center conductor, and a dummy center conductor. The dummy center conductor is pressed into an insulator using a hand press. The center conductor is placed into a fixture; the front casting is placed in the same fixture; and the insulator and dummy center conductor assembly are positioned in the port of the casting. By activating the air press, the insulator is pressed onto the center conductor, and both insulator assemblies are positioned into the casting. At this time, an insertion and withdrawal test is performed using a tooled testing plug and force gauge.

(4) Solder inductors and resistors. This process includes two inductors or comparable components, front casting assembly, and two resistors (464 and 93 ohm) for the output jack only. The inductor and resistor leads are cut to length. The resistors are connected and soldered in a series configuration, with a center tap available for connecting the monitor jack lead. The 464 ohm resistor lead is wrapped around the inductor. This assembly is inserted into the open port center conductor and soldered into place. The other inductor is inserted into the closed port center conductor and soldered into place.

(5) Join front and rear casting assemblies. Using one shell half as a guide for orientation, the front and rear casting assemblies are fitted together. The inductors are soldered to the center conductors of the rear casting assembly. After verifying that the front and rear castings are in alignment, they are soldered together.

(6) Assemble Switch. The assembly of the switch and its positioning within the front casting are the most critical part of the entire assembly. It consists of a contact spring, normal spring, two half switch housing, and a 75 ohm chip resistor. The two springs are positioned into one switch housing, utilizing the built-in locking features which aid in the alignment of the two springs. The other housing is then snapped into place, sandwiching the springs between the two housings. Due to its fragility and size, the chip resistor will be positioned after the switch is located into the front casting.

(7) Insert Switch into SCJ. Using a hemostat, the switch is positioned with proper orientation within the SCJ so as to ensure its repaired function. If the orientation is incorrect, the SCJ will be rendered non- functional. The 75 ohm resistor is now positioned into the switch assembly with special oreintation to minimize failure. The ground clip is then snapped into position.

(8) Test SCJ. Each SCJ is tested by using a special attachment for an ohm meter to verify the functionality of the 75 ohm resistor. A functional gauging test is performed by using a tooled test plug to determine the concentricity between the center conductor and the barrel. A high frequency insertion loss test is performed by using a power meter, wave test signal generator, and power sensor.

Once the SCJ is complete, it is then further assembled into the final product - the DS3. There are several models of the DS3. Each model has the same function but varies to accommodate the type of mounting and connector required by the customer. The three types of input/output cross-connect connectors (CCC's) typically used are the bayonet naval connector (BNC), the threaded naval connector (TNC), and the single coaxial jack.

The typical DS3 consist of two SCJ's, coaxial cables, single coaxial jack, front panel, chassis, designation strips, light- emitting diode (LED), lamp socket, BNC/TNC connectors, switch, card edge connector, pin jacks, hardware, and wire.

ISSUE:

Whether a SCJ which is produced from U.S. and foreign materials in Mexico and assembled into a DS3 is a substantially transformed constituent material of the DS3 for purposes of the GSP.

LAW AND ANALYSIS:

Under the GSP, eligible products of a designated beneficiary developing country (BDC) which are imported directly into the U.S. qualify for duty-free treatment if the sum of (1) the cost or value of the materials produced in a BDC, plus (2) the direct costs involved in processing the eligible article in the BDC, is not less than 35% of the appraised value of the article at the time it is entered into the U.S. See section 10.176(a), Customs Regulations (19 CFR 10.176(a)).

As stated in General Note 3(c)(ii)(A), Harmonized Tariff Schedule of the United States Annotated (HTSUSA), Mexico is a designated BC. In addition, the products at issue are classifiable in subheading 8517.90.05, HTSUSA, which provides for electrical apparatus for line telephone or telegraphy . . . Parts: Of telephonic apparatus: Of telephone switching apparatus: of the switching apparatus of subheading 8517.30.15. Articles classified under this subheading are eligible for duty-free treatment under the GSP provided they meet all of the applicable requirements.

The cost or value of materials which are imported into the BDC to be used in the production of the article, as here, may be included in the 35% value-content computation only if the imported materials undergo a double substantial transformation in the BDC. That is, the non-Mexican components must be substantially transformed in Mexico into a new and different intermediate article of commerce, which is then used in Mexico in the production of the final imported article, the DS3. See section 10.177(a), Customs Regulations (19 CFR 10.177(a)), and Azteca Milling Co. v. United States, 703 F. Supp. 949 (CIT 1988), aff'd, 890 F.2d 1150 (Fed. Cir. 1989).

The test for determining whether a substantial transformation has occurred is whether an article emerges from a process with a new name, character or use, different from that possessed by the article prior to processing. See Texas Instruments Inc. v. United States, 69 CCPA 152, 681 F.2d 778 (1982).

You maintain that two separate substantial transformations take place during the assembly of the DS3. The first claimed substantial transformation results from the assembly and testing of the switching coaxial jacks (SCJ's).

In the instant case, we find that the production of the SCJ assemblies constitutes a substantial transformation. The separate components imported into Mexico acquire new attributes, and the SCJ assemblies differ in character and use from the component parts of which they are composed. The production of the SCJ assemblies involves substantial operations, and not simply the joining together of pre-made parts. For instance, the shape of the component parts of the SCJ is altered by various pressing and cutting operations. Moreover, other parts are affixed by soldering. Finally, once assebled, the SCJ must be tested using sensitive instruments to ensure the proper functioning of the SCJ assembly.

We also find that the SCJ is an "article of commerce." To be an "article of commerce," the new and different intermediate product "must be commercially recognizable as a different article, i.e., [it must] be readily susceptible of trade, and be an item that persons might well wish to buy and acquire for their own purposes of consumption or production." See Azteca Milling Co. v. United States, 703 F. Supp. 949 (CIT 1988), aff'd, Appeal No. 89-320 (Fed. Cir. 1989), quoting The Torrington Co. v. United States, 764 F.2d 1563, 1567-68 (Fed. Cir 1985). Moreover, "an 'article of commerce'. . . is one that is ready to be put into a stream of commerce, but need not have actually been bought-and- sold, or actually traded, in the past." In the instant case, the evidence submitted indicates that the SCJ is an article which is regularly bought and sold as such in the trade.

In C.S.D. 85-25, dated September 25, 1984 (HRL 071827), Customs considered the issue of whether the assembly of components can result in a substantial transformation. In that decision, Customs held that an assembly process will not constitute a substantial transformation unless the operation is "complex and meaningful." Whether an operation is "complex and meaningful" depends on the nature of the operation, including the number of components assembled, number of different operations, time, skill level required by the operation, attention to detail and quality control, as well as the benefit accruing to the BDC as a result of the employment opportunities generated by the manufacturing process.

The focus of C.S.D. 85-25 was a printed circuit board assembly (PCBA) produced by assembling in excess of 50 discrete fabricated components onto a printed circuit board (PCB). Customs determined that the assembly of the PCBA involved a large number of components and a significant number of different operations, required a relatively significant period of time as well as skill, attention to detail, and quality control, and resulted in significant economic benefit to the BDC from the standpoint of both value added to the PCBA and the overall employment generated thereby.

We are of the opinion that a second substantial transformation occurs as a result of the assembly of the SCJ's with other materials to create the DS3. In Headquarters Ruling Letter (HRL) 556045 dated July 24, 1991, Customs held that the production of telephone bantam jacks (TBJ's) involves substantial operations (reforming metal springs, peen pushing rod to spring, stacking springs and spacers, stacking parts to frame, adjusting springs, and quality control testing), which transforms the components into an article with a new distinct commercial identity. In addition, the TBJ's assembled from imported materials were held to be further substantially transformed when they were assembled with other components to create the final articles, referred to as the DS1 and wired assembly. In HRL 556045, the DS1 was produced by various complex operations which included: inserting the TBJ's into the front cabinet panel, securing with thread-forming metal screws, cross-connecting (jumpering resistoring, and bussing) TBJ's with wire by wire- wrapping to the tails of TBJ's, preparing the wire harness by cutting to proper length, stripping, and pre-bending wires, connecting the wire harness to TBJ's by wire wrapping, fixing the terminal blocks to rear panel of cabinet with metal screws, connecting the wire harness to terminal blocks by wire wrapping, organizing and assembling wire with cable ties, fixing lamp strips to front cabinet panel with metal screws, connecting wire harness to the lamp strip/lamp socket by wire wrapping, and connecting the other end of the lamp strip harness to the terminal blocks by wire wrapping. Finally, the assembly was completed by securing the designation strips, cable rings, and other hardware to the cabinet panel, and performing electrical breakdown, continuity, and functional tests.

The assembly operations used to assemble the DS1 in HRL 556045, described above, are similar to the facts in the instant case. First, the basic assembly of the DS3 involves attaching the coaxial cable to the rear casting assembly by means of crimp and solder-type connections. Next, the mid-size jack is assembled by inserting the finger spring into the barrel, crimping the center conductor, positioning the center conductor in a fixture, and then locating the insulator to the center conductor, inserting the center conductor and insulator assembly into the bushing, and rolling the flange of the bushing to secure the insulator. The assembly of the standard jack involves locating and pressing the insulators onto the center conductor, positioning the insulator/center conductor assembly into the chassis assembly, and placing it into an air press fixture, activating the air press, and rolling the edge of the chassis over to secure the insulator/center conductor assembly into place. Next, the chassis assembly is inserted into the barrel, the shell retainer is screwed into the rear of the barrel, and the position of the center conductor is tested for concentricity.

In the next stage of the assembly process, if the BNC or TNC is used as the cross-connect connectors, the cable is terminated, the cable conductor is inserted into the center conductor, the cable conductor is crimped into place using an air press, the ferrule is slid over the cable, the center conductor is inserted into the housing, and the ferrule is crimped into place using an air press. If the single coaxial jack is used as the connector, the cable is terminated, the shell retainer is slid over the cable, the cable and chassis assembly are attached together, the crimping sleeve is slid over the ferrule, the sleeve is crimped into position over the ferrule, the cable and chassis center conductor are soldered together, and the shell retainer is screwed into position. If the BNC or TNC is used as the connector, it is attached to the rear chassis. If the single coaxial jack is used, it is attached to the front panel or rear chassis, using a thread-forming metal screw. Next, the SCJ's are attached to the front panel using metal screws, the designation strips and front panel are attached to the chassis using metal screws, the monitor jack is positioned in the front panel using metal screws, the switch and lamp socket is attached to the front panel with metal screws, and the LED is installed into the lamp socket. Next, the interior is wired with a "jumper" wire between the switch and lamp socket terminals, the card edge connector is attached to the rear of the chassis frame with metal screws, and wires are routed from the card edge connector to the lamp socket and switch. Finally, the finished assembly is tested.

Athough the final assembly operations at issue may not achieve the level of complexity contemplated by C.S.D. 85-25, in view of the overall processing operations in Mexico, we do not believe that this is the minimal, "pass-through" operation that should be disqualified from receiving the benefits of the GSP. C.S.D. 85-25 distinguished operations which involve only the simple joining or combining of prefabricated components from operations which require the further manufacture of materials prior to assembly. See also 555532 dated September 18, 1990, which held that in view of the overall processing done in the BDC, materials are determined to have undergone a double substantial transformation, although the second substantial transformation is a relatively simple assembly process which, if considered alone, would not confer origin.

Your submission indicates that the assembly of the DS3 requires attention to detail and quality control. You state that the assembly of the DS3 involves considerably more than the simple joining of parts and includes such other types of processing as cutting, wire-wrapping, crimping, soldering, heat- shrinking, pressing, rolling, and testing. For these reasons, and in view of the creation of a new and distinct intermediate article of commerce, we find that the SCJ's are substantially transformed constituent materials of the DS3.

In addition, in determining whether the combining of parts or materials constitutes a substantial transformation, a consideration, in addition to the extent of operations performed, is whether the parts lose their identity and become an integral part of the new article. See Belcrest Linens v. United States, 741 F.2d 1368, 1373 (Fed. Cir. 1984). In the final assembly of the article at issue, there is a real integration of the SCJ's with the DS3 to the point where the SCJ's lose their separate identity.

HOLDING:

Based on the reasons set forth above, we are of the opinion that the SCJ's are substantially transformed constituent materials of the DS3. Therefore, the cost or value of the SCJ's may be included in the 35% value-content requirement of the GSP.

Sincerely,

John Durant, Director
Commercial Rulings Division