Rotary Security Seal

FIELD OF ART

The disclosure relates to the field of security seals, and more particularly to a rotary security seal assembly and a method for manufacturing a rotary security seal assembly.

BACKGROUND

Security seals for sealing container closures, meters, equipment and various other articles are used to reveal surreptitiously attempted or actual entry by damage to the seal. One conventional type of security seal includes a loop of locking filament that can seal an article when the loop of locking filament is threaded through the article and the loop is permanently secured at its opposite ends to the security seal by a one-way rotatable rotor within a socket of the housing body. Both of the free ends of the locking filament are irreversibly threaded and wound on the rotor through different bores.

Conventional rotary security seals such as these are typically made as an assembly of at least three pieces, namely a seal housing body having a socket, a rotor that is placed into a socket during assembly and a locking filament element of desired length that is initially separate from and independent of the security seal housing body and rotor. The rotor and socket in the housing body are arranged so that the rotor is irreversibly rotatable only in one direction within the socket.

For shipping to a customer, the manufacturer or shipper may irreversibly wind one end of the filament element on the rotor, and the customer is then expected to irreversibly wind the other end of the filament on the rotor. This can be problematic because irreversibly winding one end of the locking filament to the rotor prior to shipping can be labor intensive and time-consuming, increasing shipping and/or production costs. Moreover, because the manufacturer or shipper is partially assembling each security seal, the manufacturer or shipper typically packages, and/or ships the security seals as individual assemblies, which, in turn, can lower the efficiency of the production process.

If appropriate, the locking filament element may be shipped as a separate piece. Disadvantageously, this requires the person installing the security seal to irreversibly wind both ends of the filament on the rotor in the field to permanently secure both filament ends to the seal housing body. For instance, the person may be required to wind two ends of the filament sequentially or simultaneously through multiple bores through the housing and rotor to secure a container, closure, article or the like, which can be burdensome, frustrating and time consuming in the field.

In such known rotary seals, provision must also be made to enable two ends of the locking filament to be inserted through the housing body and the rotor and wound on the rotor, which requires extensive handling and manipulation to prepare the seals for shipment and for use in the field. Such a configuration thus typically requires two bores to be made in the housing body and the rotor to accommodate the two ends of the locking filament that must be inserted into and wound on the rotor.

In view of the shortcomings of conventional rotary seals, there exists a substantial need for a rotary security seal that is considerably improved in terms of actual handling in the field, production cost, and efficiency of shipping and packaging.

SUMMARY

Embodiments of the disclosure are related to an improved rotary security seal with a locking filament that is adapted to be threaded at least in part through a single receiving bore in a rotor and irreversibly wound on the rotor to properly seal an article or asset. This has the effect of making assembly and installation of the rotary security seal easier and faster than in the prior art. This also has the effect of reducing the complexity of the seal and lowering production costs.

In an embodiment of the present disclosure, the locking filament can be permanently secured to the seal housing body at one end thereof by hardenable molding material used to form the housing body. This process results in a molded housing body configured to receive the rotor of the seal assembly with a permanently captured locking filament secured at one end to the housing body by integrally formed molding material of the housing body, leaving only one free end area of the locking filament to be threaded through a closure or article to be sealed by an end user and irreversibly wound on the rotor to lock the seal.

The embodiment requires only a single bore to be provided through the socket of the housing body and rotor through which the free end area of the locking filament is to be inserted and irreversibly wound on the rotor by an end user to leave the loop of locking filament outside the housing body. Handling of a separately made filament after production of the housing body is thus avoided, as the locking filament is permanently secured at one end to the housing body during production. The end user is only required to manipulate the free end of the locking filament to create a loop that is threaded through the object to be secured by the security seal.

This embodiment and the process of its production can enable a producer to package the rotary security seal assemblies in an improved manner, so that multiple seal assemblies connected together temporarily by molding material used to form the seal housing bodies can be shipped and used in the field, with the end user breaking off each security seal assembly at the point of use and installation, leaving the other seal assemblies temporarily connected together. The locking filaments of the seal assemblies, permanently secured by molding material of the housing bodies to the housing bodies at one end of the filaments, can be configured during manufacture and packaging so that the free end areas of the locking filaments extend linearly or otherwise away from the seal housing bodies while the housing bodies are temporarily connected together by molding material to facilitate packaging of the seal assemblies by the producer, and handling and manipulation in the field of the seal assemblies as a group by the end user.

In another embodiment of the present disclosure, both ends of the locking filament are adapted to be threaded at least in part through a single locking filament receiving bore in the housing body and the rotor body. If desired, the end user, the producer, or shipper can thus handle the locking filament separately from the housing body prior to use. To seal an article, one end of the locking filament can be threaded through the article to be sealed and both ends of the locking filament can be threaded at least in part through the locking filament receiving bore and irreversibly wound on the rotor, leaving a loop of locking filament outside the housing body. This arrangement advantageously allows the locking filament to be handled separately from the housing body and avoids the difficulties and frustrations that can result when an end user attempts to thread a locking filament through multiple bores in both the housing body and the rotor body.

Additional features and advantages of embodiments of the present disclosure will be set forth in the description that follows, and in part will be obvious from the description, or may be learned by the practice of such exemplary embodiments. These and other features will become more fully apparent from the following description and appended claims, or may be learned by the practice of such exemplary embodiments as set forth hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

Reference is made to the appended drawings depicting illustrative embodiments of the inventive subject matter to be described in more detail below, wherein:

FIG. 1 is an exploded upper perspective view of a rotary security seal assembly according to an embodiment;

FIG. 2 is a view of the rotary security seal assembly shown in FIG. 1 in assembled form, with the rotor body inserted into the socket of the housing body;

FIG. 3 is a view of the security seal assembly shown in FIG. 2 with the free end area of the locking filament illustrated as extending through filament receiving bores in the assembled housing body and rotor of the assembly;

FIG. 4 is a view of the assembly of FIG. 3, with the rotor partially rotated to irreversibly wind the free end of the locking filament on the rotor body within the socket of the housing body to irreversibly secure the free end area of the locking filament to the housing body and rotor of the seal assembly;

FIG. 5 is a cross-section view of the assembly shown in FIG. 3 taken along line 5-5;

FIG. 6 is a cross-section view of the assembly shown in FIG. 3 taken along line 6-6;

FIG. 7 is a cross-section view of the assembly shown in FIG. 2 taken along line 7-7;

FIG. 8 is another cross-section view of the assembly shown in FIG. 7;

FIG. 9 is a simplified schematic illustration of a mold for molding multiple security seal housing bodies;

FIG. 10 shows the mold of FIG. 9 with the mold cavities closed and ready to receive hardenable molding material used to form the housing bodies of the rotary security seal assemblies;

FIGS. 11 and 12 shows molded housing bodies as removed from the mold shown in FIGS. 9 and 10, with the locking filament initially intact and later cut to leave free end areas on each locking filament;

FIGS. 13-16 show security seal assemblies with the housing bodies having locking filaments attached to the bodies by hardened molding material with the housing bodies shown in various stages of separation to provide individual rotary security seal assemblies and with the locking filaments cut to individual lengths according to another embodiment;

FIGS. 17 and 18 show a rotary security seal assembly and rotary security seal assemblies connected together with molding material according to another embodiment;

FIGS. 19 and 20 show a rotary security seal assembly and rotary security seal assemblies connected together with molding material according to another embodiment;

FIG. 21 is an exploded upper perspective view of a rotary security seal assembly according to another embodiment;

FIG. 22 is a view of the rotary security seal assembly shown in FIG. 21 in assembled form, with the rotor body inserted into the socket of the housing body; and

FIG. 23 is a cross-section view of the assembly shown in FIG. 22 taken along line 23-23.

DETAILED DESCRIPTION OF VARIOUS EMBODIMENTS

A better understanding of different embodiments of the disclosure may be had from the following description read with the accompanying drawings in which like reference characters refer to like elements.

While the disclosure is susceptible to various modifications and alternative constructions, certain illustrative embodiments are in the drawings and are described below. It should be understood, however, there is no intention to limit the disclosure to the specific embodiments disclosed, but on the contrary, the intention covers all modifications, alternative constructions, combinations, and equivalents falling within the spirit and scope of the disclosure.

It will be understood that unless a term is expressly defined in this patent to possess a described meaning, there is no intent to limit the meaning of such term, either expressly or indirectly, beyond its plain or ordinary meaning.

In the above description, the term “filament” is intended to mean any solid or stranded, thin, flexible element such as a plastic resin monofilament, metal wire, or thin cable that is appropriate for use in security seals that use filament loops to secure articles to be sealed.

Any element in a claim that does not explicitly state “means for”, performing a specified function, or “step for”, performing a specific function, is not to be interpreted as a “means” or “step” clause as specified in 35 U.S.C. §112, paragraph 6.

With reference to FIGS. 1-8, an exemplary embodiment of a rotary security seal assembly 10 is shown, comprising a housing body 12, a rotor body 14 and a locking filament 16.

As best seen in FIGS. 1 and 2, the housing body 12 can include an open socket 18 having a peripheral internal socket wall 20 and a socket central axis 22. The socket 18 may have any desired shape, but is shown having a generally circular or cylindrical shape. The housing body 12 can also include a housing top 24 and a housing bottom 26, and the socket 18 is arranged so that the top opening 28 of the socket 18 is located at or adjacent to housing top 24. The socket 18 includes an upper socket area 30 adjacent to the top opening 28 and a lower socket area 32 located towards the housing bottom 26.

The upper and lower socket areas 30, 32 can be concentric with socket central axis 22. The housing body 12 can be formed of a hardened molding material such as an initially liquid or flowable thermoplastic polymer resin or thermosetting plastic material that is injected or which otherwise flows into a mold cavity having a suitable form to create the desired housing body shape when hardened. While the housing body 12 is described comprising thermoplastic polymer resin or a thermosetting plastic material, it will be appreciated that other suitable materials are possible. For instance, the housing body 12 may comprise a rubber material, a metal material, a composite material, a polymer, a plastic material, a thermoplastic material, a resin, combinations thereof, or any other suitable material.

The housing body 12 optionally may include a tab portion 34. The tab portion 34 can help an end user manipulate the assembly 10 and/or can receive a tracking unit as described in more detail below.

The lower socket area 32 can include one-way detent features 36, for example, in the form of molded ratchet teeth 38 as illustrated. The ratchet teeth 38 can have sharply rising front rakes and less sharply rising rear rakes so as to present circumferentially spaced abutments for engaging pawl teeth on their front sides in a known manner.

The locking filament 16 can include a first end area 40 comprising a captured end area and a second end area 42 comprising a free end area. The locking filament 16 can be imbedded in hardened molding material forming the housing body 12 at the captured end area 40 terminating at a captured end (not shown), leaving the free end area 42 of the locking filament terminating at a free end 44.

As best seen in FIGS. 1 and 3-6, a housing locking filament receiving bore 46 can extend diametrically through the socket 18 of the housing body 12, intersecting the socket wall 20 at the upper socket area. 30 and, in the example illustrated, the socket central axis 22, although the housing locking filament bore 46 could be displaced somewhat on either side of the socket axis 22. The housing locking filament receiving bore 46 can be the only bore extending through the socket 18. It will be appreciated that the housing locking filament receiving bore 46 can extend axially through the socket 18 or in any other appropriate orientation relative to the socket central axis 22. It will also be appreciated that the housing locking filament receiving bore 46 can extend completely or at least in a part through the housing body 12. The free end area 42 of the locking filament 16 with the free end 44 are configured to fit into and extend at least in part through the housing locking filament bore 46 in a manner to be described below.

As shown in FIGS. 2-8, the rotor body 14 can be inserted in the socket 18. The rotor body 14 can have a circular cross-section and a circular top area 48, a circular rotor bottom area 50, and a circular rotor central area 52 between the top and bottom areas, all area being concentric with each other. The rotor central area 52 can have a smaller diameter than the rotor top and bottom areas 48, 50.

As best shown in FIGS. 1 and 5, a rotor locking filament receiving bore 53 can transverse the rotor central area 50. The rotor locking filament receiving bore 53 can be dimensioned to receive a portion or a length of the locking filament free end area 42 when the assembly 10 is to be used and locked, as will be discussed in more detail below. The rotor locking filament receiving bore 53 can extend completely or at least in part through the rotor central area 50. The rotor locking filament receiving bore 53 can be the only bore extending through the rotor body 14. Further, while the rotor locking filament receiving bore 53 is described within the rotor central area 50, it will be appreciated that the rotor locking filament receiving bore 53 can be located in the top area 48, in the bottom area 50, or in any other suitable location within the rotor body 14. The rotor locking filament receiving bore 53 can further extend transversely, axially, or in any other suitable direction through the rotor body 14.

The rotor lower area 50 can have one-way locking pawl features 54 that, with the rotor body 14 fully received in the socket 18, cooperate with the socket one-way detent features 36 of the lower socket area 32 so as to function as a one-way, irreversibly rotating ratchet and pawl arrangement.

The locking pawl features 54 in the exemplary embodiment illustrated comprise flexible, leaf, spring-like spiral or involute shaped arms 56 extending away from the rotor bottom area 50 of the rotor body 14 in a single direction and terminating at ends 58 that engage the ratchet teeth 38 for irreversible, one-way rotation once the rotor body 14 is fully received in the socket 18 with the arms 56 biased outwardly so the ends 58 of the arms 56 engage respective ratchet teeth 38 of the socket one-way detent features in a known manner.

As best shown in FIGS. 4, 7, and 8, the arms 56 can be flexible in a spring-like manner and may pivot or flex resiliently, radially, or inwardly during assembly of the rotor body 14 to the housing body 12 when the rotor body 14 is inserted into the socket opening 18. The arms 56 may comprise one arm, two arms, four arms, or any other suitable number of arms. The ratchet teeth 38 and pawl arm ends 58 when engaged will restrict rotation of the rotor body 14 relative to the socket 18 in a clockwise winding direction only in an irreversible manner.

As best shown in FIGS. 3-6, the rotor body 14 has an exemplary manipulating feature comprising a knob 60 at or adjacent to its top area 48 to enable rotation of the knob in a winding direction in a manner to be described below. The knob preferably is shaped to indicate “bore aligned” positions 180° apart in a rotational sense when the transverse housing locking filament bore 46 is aligned with the transverse rotor locking filament receiving bore 53 (shown in FIG. 6) to permit the free end 44 of the locking filament to be inserted through the housing body and the rotor at the rotor central area as seen in FIG. 3, with preferably a small length of free end area 42 of the locking filament extending beyond the housing body 12 on the other side from the entry side of the free end of the locking filament 16.

In the example shown, this “indexing” of the rotor body 14 relative to the housing body 12 can be enabled by dimensioning the ratchet teeth 38 in a manner such that they are unequally spaced circumferentially, with the arms 56 restricted to two beginning or starting positions 180° apart rotationally when the transverse bores 46 and 53 are aligned to receive a portion of the free end area 42 of the locking filament 16. Once the rotor is initially rotated away from the starting position seen in FIGS. 5 and 6, the ratchet teeth 38 and ends 58 of the arms 56 will determine the relative positions of rotation between the rotor body 14 and the socket 18 as seen in FIGS. 7 and 8.

As best seen in FIGS. 3, 5, and 6, the knob 60 can be a thin plate having flat sides lying in planes extending perpendicular to the transverse direction of the rotor locking filament receiving bore 53 in the rotor body 14, which will indicate when rotor locking filament receiving bore 53 is aligned with the housing locking filament bore 46 in the housing body by visual observation (comparing the position of the knob with the position of the housing locking filament bore 46).

In use, a person or end user installing the assembly 10 will thread a portion of the free end area 42 of the locking filament through the article to be sealed, for example, a hasp of a closure latch or aligned openings on a meter or article to be sealed, and then through the housing locking filament bore 46 and the bore 53 of the rotor body 14, with a portion of the locking filament 16 extending beyond the opposite side of the housing body 12 as shown in FIG. 3. Only one end of the locking filament 16 is threaded through the housing locking filament bore 46 and the rotor locking filament receiving bore 53. Such a configuration avoids the complications and frustrations that can result when two ends of a filament are required to be threaded through multiple bores in a housing body and a rotor.

In effect, a loop 62 of the locking filament 16 is formed to lock the assembly 10 to the article to be sealed. In this condition, the locking filament 16 intersects the rotor body 14 at its central area 52, which is surrounded by the socket wall 20 of the socket 18, with a volume between the rotor central area and the socket wall 20.

As best shown in FIG. 4, the person installing the assembly 10 then winds the knob 60 of the rotor body 14 in a clockwise or “winding” direction, so that the free end area 42 of the locking filament 16 is wound irreversibly clockwise and doubly around the rotor central area 52 in the volume between the central area 52 of the rotor body 14 and the socket wall 20 of the socket 18.

Due to the high friction capturing of the free end area of the locking filament around the rotor central area 52 the locking filament 16 cannot be withdrawn from the bore 46 of the housing body 12 and the bore 53 of the rotor body 14 without damaging an element of the seal assembly 10, which would provide a visible indication of unauthorized tampering with the seal.

The socket one-way detents features 36 described herein as well as the arrangement of the ratchet teeth 38 are to be regarded as exemplary only, as any suitable one-way or irreversible connection between the rotor body 14 and the socket 18 may be envisioned.

The tab portion 34 is an optional feature, and not a necessity by any means, and the use of such tab will depend on the needs of the end user of the rotary security seals.

The rotor bodies 14 may be secured in their respective sockets 18 by appropriate friction or snap-in connections that are known in the art or any suitable connection that enables simple assembly and manipulation of the rotor body in the socket of the housing body. For instance, the socket wall 20 may include a radial flange 37 or other suitable locking mechanism configured to retain or secure the rotor body 14 within the socket 18. As best seen in FIGS. 5 and 6, the radial flange 37 can function as a one-way stop by engaging an upper surface formed on the rotor central area 52 when the rotor body 14 is inserted within the socket 18. This advantageously can help prevent the rotor body 14 from being pulled out or coming out of the socket 18 after insertion while still permitting rotation of the rotor body 14 within the socket 18.

The rotor central area 52 is dimensioned and configured to accommodate a suitable length of locking lament 16 to be irreversibly wound thereon during use.

FIGS. 9-12 illustrate a simplified exemplary method of making the rotary seal assembly of the present disclosure using a molding technique, wherein a continuous locking filament 64 is placed in a lower mold half 66 that has mold cavities 68 arranged to receive a hardenable, flowable or formable molding material that will form molded seal housing bodies.

As seen in FIG. 9, the continuous locking filament 64 spans several mold cavities 68 in this example, which enables efficient production of multiple housing bodies with a single common locking filament with a single injection of moldable material.

As shown in FIG. 10, an upper mold half 69 covers the lower mold half 66 to close mold cavities 68, with the continuous locking filament 64 spanning the mold cavities. Liquid or semi-liquid hardenable molding material (not shown) such as a thermoplastic or thermoset resin, for example, is injected into the mold cavities to form multiple seal housing bodies 12 (the cavities typically will be connected to enable the molding material to flow to all cavities), thereby producing the plurality of seal housing bodies 12 as seen in FIG. 11, all connected by the continuous locking filament 64. The continuous locking filament 64 thus is firmly bonded permanently at one captured end area to the housing bodies 12 by the molding material forming the housing bodies 12.

While the continuous locking filament is described being firmly bonded permanently to the housing bodies during an injection molding process, it will be appreciated that the continuous locking filament 64 can be firmly bonded permanently to the housing bodies 12 via any suitable method. For instance, the one captured end area of the continuous locking filament 64 may be firmly and permanently bonded to the housing bodies 12 via ultrasonic welding. In ultrasonic welding, high-frequency vibrations are directed at the locking filament 64 and the housing bodies 12 as they are held together. This can create a rapid build-up of heat that produces a weld or bond. This weld or bond can permanently secure the one captured end area of the continuous locking filament 64 to the housing bodies 12 and can be done during or subsequent to the molding process forming the housing bodies 12. In other embodiments, the one captured end area of the continuous locking filament 64 may be firmly and permanently bonded to the housing bodies 12 by mechanical connectors, soldering materials, adhesives, combinations thereof or any other appropriate method.

To form the separate seal assemblies 10, the continuous locking filament 64 is cut or parted next to a respective housing body 12 as shown in FIG. 12. This technique leaves the now separate locking filament 16 comprising a first end area comprising the captured end area 40 and a free second end area comprising the free end area 42. At least part of the captured end area 40 is firmly bonded to the individual seal housing body 12 by hardenable molding material used to form the housing body 12. The opposite free end area 42 can be available to be inserted into the housing body locking filament receiving bore 46 by an end user of the seal assembly 10.

Alternate molding and production methods are illustrated in FIGS. 13-16. The features of this embodiment are substantially similar to the embodiment discussed above.

In FIGS. 13 and 14, multiple housing bodies 12 have been molded in connected condition, with mutual locking filaments 72 each spanning at least a pair of respective housing bodies 12 as shown. Large groups of similar molded seal housing bodies and mutual locking filaments could be molded simultaneously for efficiency. The rotor bodies 14 are added after the molding step and are shown here assembled to the housing bodies for a better understanding of the molding and assembly processes.

The connected security seal housing bodies 12 may be packaged in adjoining pairs as shown in FIG. 13, with the rotor bodies 14 and mutual locking filaments 72 all connected together for convenience of the packaging and handling of the seal assemblies. For packaging, the filaments 72 are cut between the housing bodies 12 to leave the locking filaments 16 attached to the seal housing bodies at their captured end areas 40, while leaving free end areas 42 of the locking filaments for manipulation by end users in the field.

In the packaged condition, as best shown in FIG. 13, the housing bodies 12 may be connected together by weakened fracture lines 74 of molding material that enable the housing bodies 12 to be easily separated from each other for individual use of the sealing assemblies by breaking or cutting the housing bodies apart. In the field, when the seal assemblies are to be used, the individual seal assemblies 10 are broken apart and the locking filaments 16 are manipulated for securing objects to be sealed as described above.

It will be appreciated that various schemes of molding the seal housings and filaments together are contemplated, but the disclosure is not to be limited in any manner by any of the molding or packaging method or materials described. Another embodiment of rotary security seal 100 in accordance with the present disclosure is shown in FIGS. 15 and 16. The features of this embodiment of a rotary security seal assembly 100 are substantially similar to the embodiment discussed above. Like the assembly 10, the assembly 100 generally includes a housing body 80, a rotor body 82, and a locking filament 78. The internal construction of the assembly 100, including the housing locking filament receiving bore, the rotor locking filament receiving bore, the locking pawl features, and the detent features are generally the same as discussed above with respect to the assembly 10, and these features are not further discussed here.

Like the assembly 10, the locking filament 78 of the assembly 100 has been connected to the housing body 80 by housing body molding material. The locking filament 78 however is connected to the housing body 80 at a different section of the housing body 80. Such a seal assembly could be molded as a group with other seal assemblies in the manner shown in FIG. 16, for example. It will be appreciated that the rotor bodies 82 can be added after molding of the housing bodies 80.

The examples shown in FIGS. 13-16 are intended to provide several optional molding and packaging techniques among many alternative possibilities, some of which involve firmly bonding the captured end area of a locking filament to a molded seal housing body by using the molding material used to form the housing body as the filament bonding material. These embodiments provide various packaging and handling choices that can increase convenience and efficiency of making and using the rotary security seals of the present disclosure.

While the housing body is described being fabricated via injection molding seal housing body, it will be appreciated that the seal housing body may be fabricated using any suitable fabrication method. For instance, the housing body may be fabricated using plastic welding, compounding, plastic lamination, blow molding, rotational molding, injection molding, plastic extrusion, plastic foaming, combinations thereof, or any other suitable fabrication processes or methods.

Another embodiment of a rotary security seal assembly 200 in accordance with the present disclosure is shown in FIGS. 17 and 18. The features of this embodiment of a rotary security seal assembly 200 are substantially similar to the embodiments discussed above.

In particular, like the assemblies 10 and 100, the assembly 200 generally includes three components, a housing body 90, a rotor body 92, and a locking filament 88. The internal construction of the assembly, including the housing locking filament receiving bore, the rotor locking filament receiving bore, the locking pawl features, and the detent features are generally the same as discussed above with respect to the assemblies 10 and 100, and these features are not further discussed here.

As best seen in FIG. 17, an attachment feature comprising an attachment bore 94 is formed in the top area of the housing body 90. The attachment bore 94 can be formed in any suitable manner. For instance, the attachment bore 94 can be formed in the housing body 90 during a molding process using one or more core pins. Alternatively, the attachment bore 94 can be formed subsequent to a molding process using secondary boring or drilling operations.

The attachment bore 94 can be located in any suitable location within the housing body 90, although the attachment bore 94 is shown extending at least part through the housing body and is located outside of the socket. The attachment bore 94 can extend generally perpendicular to a central axis of the housing body 90.

The locking filament 88 includes a first end area comprising an attachable end area 96 and a second end area comprising a free end area 98. The attachment bore 94 can be dimensioned and configured to receive the attachable end area 96 of the locking filament 88. In an embodiment, the attachable end area 96 of the locking filament 88 can be selectively inserted in the attachment bore 94 and selectively secured therein, leaving the free end area 98 of the locking filament 88 terminating at the free end outside the housing body 90. This allows the locking filament 88 to be inserted and/or attached to the housing body 90 for convenience when packaging the assemblies 200 and/or using one of the assemblies 200.

It will be appreciated that the attachable end area 96 of the locking filament 88 can be secured in the attachment bore 94 in any suitable manner, such as, but not limited to, a weld, an adhesive, the size and/or shape of the attachment bore 94, the size and/or shape of the locking filament 88, detents, mechanical fasteners, and/or locking teeth.

As also shown in FIG. 17, the rotor body 92 can include a slot 93 at or adjacent to the top area of the rotor body 92 to enable rotation of the rotor body 92 in a winding direction as described above. A person installing the assembly 200 can use a tightening tool (or key) or fingernail within the slot 93 to wind the rotor body 92.

In an embodiment, an end user or person installing the assembly 200 inserts and secures the attachable end area 96 of the locking filament 88 within the attachment bore 94. A portion of the free end area 98 is then threaded through an object or article to be sealed and at least in part through the housing locking filament receiving bore 97 and the rotor locking filament receiving bore. Only one end of the locking filament 88 is threaded through the housing locking filament receiving bore 97 and the rotor locking filament receiving bore. Such a configuration conveniently allows the locking filament to be handled separate from the housing body and avoids the complications and frustrations that can result when two ends of a locking filament are required to be threaded through multiple bores in a housing body and a rotor.

To seal the article, the person installing the assembly 200 then winds the rotor body 92 using the slot 93 in a winding direction so that the free end area 98 of the locking filament 88 is wound irreversibly around the rotor body 92 in the volume between the rotor body 92 and the housing body 90.

Referring still to FIG. 17, the housing body 90 can include a tracking unit 91 containing security or other information associated with the assembly 300 and/or the sealed article (e.g., an article or asset associated with the assembly 200). As shown, the tracking unit 91 can be located on a tab portion of the housing body 90. It will be appreciated however that the tracking unit 91 can be located at any suitable location on the assembly 200 and in any form. For instance, the tracking unit 91 can be integral to the housing body 90, the rotor body 92, and/or the locking filament 88.

The tracking unit 91 can comprise a security tag, a RFID tag, a printing, a label, an engraving, bar code information, serial number data, a chemical tag, or any other indicia suitable of providing a unique identifier and/or other appropriate information. The tracking unit 91 can include a unique identifier associated with the assembly 200 and/or the sealed article. In an embodiment, the tracking unit 91 can link and/or integrate the rotary security seal assembly 200 and/or the sealed article with an inventory/asset management system, such as any of the systems disclosed in U.S. patent application Ser. No. 14/270,539, filed May 6, 2014, which is incorporated herein, in its entirety, by this reference. Of course, other inventory′asset management systems may be possible.

The tracking unit 91 can be an encrypted code/identifier, such as an encrypted textual code (e.g., using combinations of numbers, letters, and/or symbols), an encrypted linear barcode, an encrypted 2D/matrix barcode (e.g., QR code, Aztec code), an encrypted 3D barcode, etc. An encrypted code/identifier is one that is resistant to being read by an unauthorized third party and/or that is resistant to being generated by an unauthorized third party. For example, tracking unit 91 can include a code/identifier presented on the rotary security seal assembly 200 in an encrypted form (e.g., by being encrypted using public key, symmetric, asymmetric, etc., encoding), so that the actual code/identifier cannot be deciphered without the proper encryption key(s) and cryptographic algorithms.

The tracking unit 91 may be generated using a cryptographic algorithm, so that valid code/identifiers cannot be generated without access to the applicable cryptographic algorithms and/or encryption keys(s). The tracking unit 91 can be generated using a cryptographic algorithm (thus making it difficult for a third party to generate valid codes/identifiers), and then the generated tracking unit 91 is also encrypted (thus making it difficult for a third party to read the actual code/identifier), thereby providing multiple layers of cryptographic protection. As such, encrypted codes/identifiers are usable to prevent unauthorized reading of codes/identifiers, unauthorized duplication of codes/identifiers, and unauthorized creation of new codes/identifiers for fraudulent security seal assemblies.

The tracking unit 91 may include both a machine-readable code/identifier (e.g., an encrypted code/identifier), and a separate human-readable identifier that is linked to the machine-readable code/identifier. For example, using the tracking unit 91, the rotary security seal assembly 200 may be identified by a human end user through entry of an identification string by the human user (e.g., numeric, alphanumeric, etc.) and the assembly can be verified through scanning of the machine-readable code/identifier of the tracking unit 91.

The tracking unit 91 may include a primary code (e.g., an encrypted QR code) and a secondary code (e.g., an ASCII code) that can be read if the primary code cannot be read or is unreadable. In addition, the tracking unit 91 can include one or more tamper-evidence features. For example, the tracking unit 91 may comprise a label or tape that leaves a clearly visible multilingual writing or warning on the tab portion of the housing body 90 and/or destructs if the label or tape is removed from the tab portion. The label or tape may comprise a clear tape with code/identifier information laser etched or otherwise included on the underside of the tape. If the tape is removed from the tab portion, the tracking unit 91 is destroyed or otherwise rendered undecipherable. In other embodiments, the tracking unit 91 can comprise a label or tape including one or more features configured to block out the code/identifier information and/or exhibit a void marking if the label or tape is removed from the housing body 90.

It will be appreciated that the tracking unit 91 may include one or more features making the label or tape easier to authenticate and/or more difficult to counterfeit. For example, the tracking unit 91 can include watermarks, color-shifting inks, low-vision features, holograms, embedded metals, embedded microchips, combinations thereof, or any other suitable security feature that can help authenticate the code/identifier and/or deter counterfeiting.

Similar to the assemblies 10 and 100, the assembly 200 can be molded as a group with other seal assemblies in the manner as shown in FIG. 18, for example. It will be appreciated that the rotor bodies 92 can be added after molding the housing bodies 90. For instance, the rotor bodies 92 can be auto loaded into the sockets of the housing bodies 90 after molding.

As shown in FIG. 18, the housing bodies 90 may be connected together by weakened fracture lines 95 of molding materials that enable the rotary security seal assemblies 200 to be separated from each other for individual use by breaking and/or cutting the housing bodies 90 apart.

As discussed above, the assemblies 200 can be fabricated and/or packaged in adjoining pairs and/or batches. For instance, the assemblies 200 can be fabricated and/or packaged in batches of six, eight, ten, twelve, twenty-four, or in any other suitable number. In the field, when the assemblies 200 are to be used, the individual assemblies 200 can be broken apart and the locking filaments 88 (shown in FIG. 17) can be inserted into the attachment bore 94 and manipulated for securing objects to be sealed as described above.

It will be appreciated that the attachment bore is to be regarded as exemplary only, as the first end area of the locking filament can be attached to the housing in any suitable manner. While the housing body and rotor body are described including locking filament receiving bores, in other embodiments, the housing body and/or the rotor body may include locking filament receiving slots, grooves, cutouts, combinations thereof, or any other suitable receiving feature.

Another embodiment of a rotary security seal assembly 300 in accordance with the present disclosure is shown in FIGS. 19 and 20. The features of this embodiment of a rotary security seal assembly 300 are substantially similar to the embodiments discussed above.

In particular, like the assemblies 10, 100, and 200, the assembly 300 generally includes three components, a housing body 390, a rotor body 392, and a locking filament 388. The internal construction of the assembly, including the socket, the locking pawl features, and the detent features are generally the same as discussed above with respect to the assemblies 10, 100, and 200, and these features are not further discussed here.

The assembly 300 is configured such that the locking filament can be handled separately from the housing body and both ends of the locking filament 388 can be threaded through a single locking filament receiving bore. As shown in FIG. 19, the locking filament 388 can include a first end area 396 and a second end area 398. The housing locking receiving bore 397 and the rotor locking filament receiving bore (not shown) can be dimensioned and configured to receive both the first end area 396 and the second end area 398 of the locking filament 388.

In an embodiment, a person installing the assembly 300 threads one of the first end area 396 or the second end area 398 through an object or article to be sealed. The first end area 396 and the second end area 398 of the locking filament 388 are then threaded through the housing locking receiving bore 397 and the rotor locking filament receiving bore, leaving a loop of the locking filament 388 extending beyond the opposite sides of the housing body 390. Both end areas of the locking filament 388 are threaded through the same locking filament receiving bore. This arrangement advantageously allows the locking filament 388 to be handled separately from the housing body 390 and avoids the difficulties and frustrations that can result when a person attempts to thread a locking filament through multiple bores in both the housing body and the rotor body.

The person installing the assembly 300 then winds the knob 360 of the rotor body 392 in a winding direction so that at least one of the first end area 396 or the second end area 398 is wound irreversibly around the rotor body 392 in the volume between the rotor body 392 and the housing body 390. Similar to the assembly 200, the housing body 390 can include a tracking unit 391 containing security or other information associated with the assembly 300 and/or the sealed article.

Similar to the other embodiments, the assembly 300 can be fabricated or molded as a group with other seal assemblies in the manner as shown in FIG. 20, for example. In the illustrated embodiment, the assemblies are fabricated in a batch of ten. However, it will be appreciated that the assemblies can be fabricated in batches of six, eight, ten, twelve, twenty-four, or in any other suitable number. It will be appreciated that the rotor bodies 392 can be added after molding or fabricating the housing bodies 390.

As shown, the housing bodies 390 may be connected together by weakened fracture lines 395 and discrete weakened fracture connectors 399 of molding material that enable the rotary security seal assemblies 300 to be separated from each other for individual use by breaking and/or cutting the housing bodies 390 apart.

With reference to FIGS. 21-23, another exemplary embodiment of a rotary security seal assembly 410 is shown, comprising a housing body 412, a rotor body 414, and a locking filament 416. The assembly 410 can be similar to the assembly 10 except that the housing body 412 defines one or more different axial locking structures to retain or secure the rotor body 414 within the socket 418.

As best seen in FIG. 21, the housing body 412 can include an open socket 418 having a peripheral internal socket wall 420 and a socket central axis 422. The socket 418 may have any desired shape, but is shown having a generally circular or cylindrical shape. The housing body 412 can also include a housing top 424 and a housing bottom 426, and the socket 418 is arranged so that the top opening 428 of the socket 418 is located at or adjacent to the housing top 424. The socket 418 can include an upper socket area 430 adjacent to the top opening 428 and a lower socket area 432 located towards the housing bottom 426. The upper and lower socket areas 430, 432 can be generally concentric. The housing body 412 can be formed of any the materials previously described.

The housing body 412 may include a tab portion 434. The tab portion 434 can help an end user manipulate the assembly 410 and/or receive information and/or a tracking unit as described above.

The tower socket area 432 can include one-way features 436, for example, in the form a molded ratchet teeth 438 as illustrated. The ratchet teeth 438 can have sharply rising front rakes and less sharply rising rear rakes so as to present circumferentially spaced abutments for engaging pawl teeth on their front sides. As seen, the ratchet teeth 438 can be integrally formed along the socket wall 420 such that the ratchet teeth 438 are substantially rigid and solid structures, which, in turn, reduces the likelihood of the ratchet teeth 438 breaking or bending. This has the effect of providing a more secure lock between the pawls and the ratchet teeth 438 and reducing the likelihood of tampering.

The locking filament 416 can include a first end area 440 comprising a captured end area and a second end area 442 comprising a free end area. The locking filament 416 can be imbedded in hardened molding material forming the housing body 412 at the captured end area 440 terminating at a captured end (not shown), leaving the free end area 442 of the locking filament 416 terminating at a free end 444. As seen, the captured end area 440 of the locking filament 416 extends through at least part of the tab portion 434 radially outside of the socket 418.

By extending the locking filament 416 through the tab portion 434 the connection surface area between the housing body 412 and the locking filament 416 is greater than simply having an a locking filament attached to the bottom of the housing body 412, helping to prevent the locking filament 416 from being pulled out or coming out of the housing body 412 after assembly.

Further, the locking filament 416 extending through the tab portion 434 can provide an indication of unauthorized tampering with the assembly 410. For instance, as noted above, the tab portion 434 can include information and/or a tracking unit. Because the locking filament extends through at least a portion of the tab portion 434, tampering with the captured end area 440 of the locking filament 416 could cause damage to the tab portion 434, which, in turn, could distort, destroy, or otherwise render the information and/or tracking unit on the tab portion 434 undecipherable, helping to revel unauthorized tampering with the assembly 410.

The locking filament can be firmly bonded permanently to the housing body 412 during the injection molding of the housing body 412. For instance, the locking filament 416 can be firmly bonded permanently at the captured end area 440 to the housing body 412 by the molding material forming the housing body 412 as described above.

Optionally, a relief notch 470 is provided in the top side of the housing body 412. As seen, the relief notch 470 intersects the captured end area 440 extending through the tab portion 434. The relief notch 470 advantageously serves to reduce bending of the housing 412 and/or the captured end area 440 caused by different coefficients of thermal expansion and/or internal stress, which, in turn, enhances control of undesired deformations.

While the locking filament is described being firmly bonded permanently to the housing body 412 during an injection molding process, it will be appreciated that the locking filament can be firmly bonded permanently to the housing body 412 via any suitable method.

A housing locking filament receiving bore 446 can extend diametrically through the socket 418 of the housing body 412, intersecting the socket watt 420 at the upper socket area 430. The free end area 442 of the locking filament 416 with the free end 444 are arranged to tit into and extend at least in part through the housing locking filament bore 446 in the manner described above.

As in FIGS. 21-23, the rotor body 414 can be inserted in the socket 418. The rotor body 414 can have a circular cross-section and a rotor top area 448, and a rotor bottom area 450, and a rotor center area 452 between the top and bottom areas. In an embodiment, the top, center, and bottom areas are concentric with each other. The rotor top area 448 can form a top radial flange 449 and the rotor bottom area 450 can define a bottom radial flange 451. A rotor locking filament receiving bore 453 can transverse the rotor central area 452. The rotor locking filament receiving bore 453 can be dimensioned to receive a portion or a length of the locking filament free end area 442 when the assembly is to be used and locked, as described above.

The rotor central area 452 is dimensioned and configured to accommodate a suitable length of locking filament 416 to be irreversibly wound thereon during use. For instance, upon insertion of the free end area 442 of the locking filament 416 at least in part through the housing locking filament receiving bore 446 and the rotor locking filament receiving bore 453 and with rotation of the rotor body 414 in a winding direction within the socket 418, the free end area 442 is irreversibly secured to the rotor body 414 by forming a winding or windings around the rotor body 414 within the socket 418, with the locking filament loop remaining outside of the housing body 412.

The rotor lower area 450 can define one-way locking pawl features 454 that, with the rotor body 414 fully received in the socket 418, cooperate with the socket one-way detent features 436 of the lower socket area 432 so as to function as a one-way, irreversibly rotating ratchet and pawl arrangement. It will be appreciated that the one-way locking pawl features 454 can be configured similar to any of the one-way locking pawl features described above. The rotor body 414 can include a manipulating feature comprising a knob 460 at or adjacent to its top area 448 to enable manipulation of the rotor body 414.

Referring to FIG. 22, the rotor body 414 can be secured in the socket 418 by one or more axial locking structures 480 within the socket 418. For instance, with the rotor body 414 fully inserted in the socket 418, a compressive force 482 can be applied to the outer surface of the housing body 412, which, in turn, forces or crimps at least a portion of the outer surface radially inward.

As seen in FIG. 23, this can result in the formation of indentations 484 within the outer radial surface of the housing body 412 and axial locking structures 480 comprising protrusions 486 integrally formed on the peripheral socket wall 420. The protrusions 486 can extend radially inward from the socket wall 420 in between the top and bottom flanges 449, 451 of the rotor body 414. The protrusions 486 can be sized and arranged to engage at least the bottom flange 451 to effectively prevent axial movement of the rotor body 414 relative to the housing body 412, locking the rotor body 414 in the socket 418. The protrusions 486 can be knob-like structures. The indentations 484 can be substantially aligned with the protrusions 486.

This advantageously can help prevent the rotor body 414 from being pulled out or coming out of the socket 418 after insertion while still permitting rotation of the rotor body 414 within the socket 418, providing another layer of security to help reveal surreptitious entry or attempted access into a sealed area or article sealed by the assembly 410. Further, the socket of the housing body can be molded without the radial flange described above, simplifying and making the manufacturing process more cost-effective.

Moreover, the top flange 449 can be arranged to effectively close the top opening 428 when the rotor body 414 is fully inserted into the socket 418 to thereby prevent tampering with the axial locking structures 480, the ratchet teeth 438, and/or the locking pawl features 454 without damaging an element of the assembly 410. This advantageously provides yet another layer of security to help reveal surreptitious entry or attempted access to a sealed area or article.

It will be appreciated that the axial locking structures 480 can be formed subsequent to or during the molding process forming the housing body 412 via any suitable technique. For instance, subsequent to the molding process, an automated pneumatic system can load the rotor body 414 into the socket 418 and then crimp the housing body 412 to form the axial locking structures 480 within the socket 418 and between the flanges of the rotor body 414, locking the rotor body 414 in the socket 418.

While two axial locking structures are described, it will be appreciated that the housing body can include one, three, four, or any other suitable number of axial locking structures. Further, the housing is shown including axial locking structures in the form of protrusions but may include any feature capable of locking the rotor body in the socket such as, but not limited to, detents, ridges, teeth, bumps, mounds, rims, flanges, protrusions, nubs, and/or any other feature. Moreover, in other embodiments the top flange may be omitted. For instance, the axial locking structures can cooperate with the bottom flange of the rotor body to lock the rotor body in the socket.

The foregoing detailed description describes the disclosure with reference to specific exemplary embodiments. However, it will be appreciated that various modifications and changes can be made without departing from the scope of the present disclosure as set forth in the appended claims. The detailed description and accompanying drawings are to be regarded as merely illustrative, rather than as restrictive, and all such modifications or changes, if any, are intended to fall within the scope of the present disclosure as described and set forth herein.

More specifically, while illustrative exemplary embodiments of the disclosure have been described herein, the present disclosure is not limited to these embodiments, but includes any and all embodiments having modifications, omissions, combinations (e.g., of aspects across various embodiments), adaptations and/or alterations as would be appreciated by those in the art based on the foregoing detailed description.

The limitations in the claims are to be interpreted broadly based on the language employed in the claims and not limited to examples described in the foregoing detailed description, which examples are to be construed as nonexclusive. Moreover, any steps recited in any method or process claims may be executed in any order and are not limited to the order presented in the claims, unless otherwise stated in the claims. Accordingly, the scope of the disclosure should be determined solely by the appended claims and their legal equivalents, rather than by the descriptions and examples given above.

	Number	Date	Country
	61936257	Feb 2014	US
	61823124	May 2013	US

	Number	Date	Country
Parent	14276128	May 2014	US
Child	14718712		US

Rotary Security Seal

Information

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Date Filed

Date Published

Inventors

Original Assignees

CPC

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Abstract

Description

Claims

CROSS-REFERENCE TO RELATED APPLICATIONS

Provisional Applications (2)

Continuation in Parts (1)