NL8200112A - ELASTOMER ADDITION FOR SUPPORTED BARS. - Google Patents

Description

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Elastomeric complement for cantilevered rods.

The invention relates to spring forces generated in a compliant material by a deflection force and to means for supplementing such forces.

There is no known "prior art 5" to the applicant which relates to the use of an elasto more as an additional spring force in a spring housing with cantilever rods. U.S. Pat. No. 3,877-769 indicates the use of a viscous liquid silicone rubber in the opening of a sleeve. During vulcanization, the rubber 10 forms a barrier which prevents flux, melted solder or other contaminants from entering the interior of the sleeve. The rubber plug is limited to the facing surfaces of the spring arms.

The invention shows a means by which the resilience of a cantilevered rod can be changed.

In particular, the invention is characterized by placing an elastomer behind the bar so that spring forces are generated both in the bar and in the elastomer by a load.

The invention will be explained in more detail below with reference to the drawing.

Figure 1 shows in perspective a spring housing for a printed circuit board, the invention being explained.

Figure 2 is a perspective view of a pair of the sleeves of Figure 1 after they are encapsulated in an elastomer material.

Figure 3 is a longitudinal section of a sleeve of Figure 2 after soldering in a hole in a panel with printed wiring.

Figure 1c shows the same cross-section as Figure 3, but with a pin or guide inserted into the sleeve causing deflection of the cantilever rod and compression in the typhel elastomer.

Figure 5 shows in perspective another type of spring housing.

Figure 6 shows the sleeve of Figure 5 encapsulated in an elastomer material.

Figure 1 shows a spring housing 10 with a cylindrical body 12, a flared rim 1 at the top of the body and three fingers 16 which form a ball-shaped top 18 at the bottom of the body.

Three cantilever bars 20 are formed from the body 12 and the free ends 22 are pressed into their interior. The top end of the bars remains attached to the body. Three short protrusions 2b are also formed from the body and their free ends 26 are pressed outwardly therefrom.

Figure 2 shows a pair of sleeves 10 which are filled and partially encapsulated in an elastomer indicated by 28. Preferably, the elastomer is a liquid injectable silicone rubber.

The elastomer is applied to the sleeves with the sleeves in a mold (not shown). When a plurality of sleeves incorporate the elastomer in a continuous casting process, a bonding strip 30 of the elastomer for bonding adjacent encapsulated sleeves can be provided. Such a carrier strip will provide many advantages in handling, storing and placing the sleeves in printed circuit boards.

As shown in Figures 2 and 3S, the elastomer completely fills and encapsulates the top portion of the sheath, with the outer sheath 32 extending downwardly 30 to a free end 26 of the protrusions 2k. The presence or absence of an outer sheath apparently depends on the nature of the device receiving the elastomer. Additionally and for the present application, a plurality of ribs 3U (of elastomeric material) extend downwardly along the sheath 32. The ribs and the outer sheath support the elastomeric 82 0 0 1 1 2 3 - if * material supporting the rods. The rides butt against the walls of a through plated hole 36 in the printed circuit board 38 (Figures 3 and k) so that the walls can form a firm support for the elastomeric material. When the elastomeric material is thick enough, this thickness itself forms the support.

As can be seen in Figures 3 and *), the elastomer fills the interior of the sleeve 10 and in particular behind the cantilever bars 20.

Figures 3 and I also show the encapsulated sleeve placed and soldered into the hole 36. The solder is generally indicated by Uo. The soldering and cleaning operations (not shown) did not decompose the elastomer.

Figure U shows a pin b2 inserted into the encapsulated sleeve 10. The pin has pierced the elastomer and has additionally displaced it from the cantilever bars 20 at the point of contact to form an electrical path between the pin and the sleeve. When the pin is driven into the sleeve, it interacts with the rods and deflects outwardly. The deflection is also sensed by the elastomer, which is compliant as indicated above. The importance of this is that the bars 20 can be made thinner than if they should have included only the deflection caused by the pin b2. Other parameters that can be changed are the bar length, the bar material and the size of the bar deflection.

The invention offers other advantages. In order that the elastomer does not tear when a pin or guide is inserted, it recoils together when a pin is withdrawn. Thus, the interior of the sleeve and the contact between the pin and the bars are closed off from the environment despite the number of times the elastomer is pierced. Warping of the printed circuit board by handling or thermal shock will be absorbed by the elastomer and 8200112-u-will not be transferred to the electronic member inserted into the sleeves.

Figure 5 shows a second type of sleeve bb with a pair of spring arms h e attached to a body 5 near a bottom end 50. The free ends 52 of the arms extend outwardly to define a bell-shaped opening 5 to the interior. of the sleeve. Downward from the free ends, the arms converge to form a narrow opening in the sleeve. The body also carries a pair of spring fingers 56 which center and hold the sleeve in a hole 36 during the soldering operation.

Figure 6 shows the sleeve after being filled with and partially encapsulated by an elastomer 28. As with the sleeve. 10, the elastomer encapsulates the top portion 15 of the sleeve. In this case, the enclosure closes the opening and provides additional suspension for the spring arms. Thus, when a pin (not shown) is inserted into the sleeve, it contacts the spring arms at the nearest point of convergence and expands them. each other. This pressure-20 force is also absorbed by the elastomer as indicated above.

The preferred elastomer is a liquid injectable silicone rubber having a durometer hardness after vulcanization of about forty (bo).

25. It will be clear that changes are possible within the scope of the invention.

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Claims (3)

Cantilevered rod (20) characterized by a compliant elastomeric material (28) placed against one side of the rod (20) such that the elastomeric material (28) 5 complements the power of the rod (20) for energy storage communicated on the bar (20) by a deflecting force against the opposite side of the bar (20). A method of replenishing the power of a cantilevered energy storage rod 10 imparted thereto by a deflection force, characterized by the steps of applying a layer of compliant elastomeric material (28) to the side of the rod (20) opposite to the side that absorbs the deflection force, and supporting the layer of elastomeric material (28) such that the deflection forces are absorbed by the combination of the cantilever bar (20) and the elastomeric material (28). 3. Device and method substantially as described in the description and / or shown in the drawing. 82 0 0 1 1 2