Packaging cushioning material, packaging and method for protecting products against damage

A packaging material which impart fragility capability and is easily manufactured and handled in preparing a product for shipment. The material is fabricated as a planar body having fold lines on which the body may be folded to encircle a product being packaged. The planar body is formed with locking features which enable a handler to easily secure the material about the packaged product and with defined openings facilitating handling.

FIELD AND BACKGROUND OF INVENTION

This invention relates to packaging materials, and more particularly to a material, packaging in which the material is used, and methods by which products are protected against damage otherwise possibly occurring due to shock loads.

In developing a package for product protection, some fundamental information about the product is needed. To protect the product for shock, a fragility level must be determined. Fragility is the maximum acceleration and velocity change the product can withstand before damage occurs. This information is charted to form a damage boundary curve. Ideally the fragility level is determined experimentally through a test procedure such as American Society for Testing Materials (ASTM) D 3332 “Test Method for Mechanical-Shock Fragility of Products, Using Shock Machines.” Fragility is usually expressed in units of “g's” (gravitational acceleration) and indicates the maximum acceleration the product can withstand without being damaged. Therefore, the more fragile a product is the lower its fragility level or g-factor. Ranges of a typical cushioning system include very delicate (25-40 g's), delicate (40-60 g's), and moderately delicate (60-85 g's)

Once the shock fragility is known for the product, a cushioning material and package configuration that will provide the necessary protection can be selected. Historically, the use of cushion curves helps a designer identify a material, thickness and loading range based on a pre-determined drop height and required acceleration level.

Packaging material and packages capable of handling determined loads are here referred to as having fragility capability. As will be understood, one of the tasks facing a packaging designer is to provide fragility capability suitable for the product to be packaged and the loads which may be imposed during handling. Another of the tasks facing the designer is that of providing material which can be easily fabricated and easily handled by persons preparing products for shipment.

SUMMARY OF THE INVENTION

With the foregoing in mind, it is one purpose of this invention to provide a packaging material imparting fragility capability and which is easily manufactured and handled in preparing a product for shipment. In particular, the present invention contemplates that a material be fabricated as a planar body of a bi-material having fold lines on which the body may be folded to encircle a product being packaged. The planar body is formed with locking features which enable a handler to easily secure the material about the packaged product and with defined openings facilitating handling.

DETAILED DESCRIPTION OF INVENTION

Referring now toFIG. 1, a planar body10is there shown which embodies the present invention. The body10is of a deformable material and can be produced by die cutting or other manufacturing process, preferably from a sheet of a bi-material which has a stiffening layer11and a cushioning layer12, visible inFIG. 2. The stiffening layer11may, for example, be high density foam, kraft board, a plastic sheet or some similar material. The cushioning layer12may, for example, be a low density foam material of choice depending upon the fragility capability desired. The foam may have a density and crush characteristics which impart to an assembled package the protection required for the product being handled, and may be a reticulated or closed cell foam made from any suitable plastic or the like. The body need not be of a bi-material, as a foam material of graduated density may function similarly and persons of skill in the applicable arts will be able to identify other alternatives.

The body10, as shown, has an irregular outline configuration, shown as a cruciform shape. That is, the body has a general configuration which has pairs of oppositely extending areas which appear somewhat as the arms of a cross. The body is divided by a number of fold lines, which may be defined by score lines or the like formed in the material at the time it is fabricated to shape. The fold lines define seven areas within the irregular configuration.

First and second areas14,15of the planar body10are defined on opposite sides of the outline configuration by fold lines20,21. Each of these areas14,15is divided by a defined one of the fold lines22,23into a proximal portion14a,15aand a distal portion14b,15b. Each proximal portion14a,15aof each of the first and second areas14,15is closer to the proximal portion of the other of the first and second areas than are the respective distal areas14b,15b. Each distal area portion14b,15bof each of the first and second areas14,15defines a lock portion14c,15cconfigured to engage the lock portion of the other of the distal area portions. As here shown, the lock portions are formed in the manner of a dovetail, a joint used in woodworking and to form splines in some machined metal components. The characteristic of the dovetail, as here used, is that as the body is folded and the lock portions engaged, the body is held in position encircling a product which has been place on the body as folding begins.

There are third and fourth areas16,17of the planar body10on opposite sides of the outline configuration, each extending between the first and second areas14,15and defined by fold lines25,26. Together the first and second areas14,15and the third and fourth areas16,17form the arms of the cruciform configuration. A fifth area19of the planar body10is bounded by the fold lines20,21,25,26which bound the first, second, third and fourth areas.

When folded along the fold lines with the lock portions engaged, the planar body forms a body of cushioning material encircling a product positioned on the fifth area. This is shown more particularly inFIGS. 2 through 4.FIG. 2shows the body10in a partial folded position, to make more clear the manner in which the body comes into a three dimensional form as it is folded up along the fold lines. As will be noted, the lock portions14c,15care drawn into proximity and engaged one with the other as shown inFIG. 3. When locked, a product30such as a hard disk drive is encircled by the body of cushioning material and cushioned against forces otherwise impinging on the product during handling and shipping.

In order to facilitate handling of the product and the cushioning material and the lessen the weight of the package, open areas are defined in certain of the defined areas of the body. More particularly, the fifth area19defines an open area which primarily provides for lessened package weight. Each of the first and second areas14,15defines an open area from which material has been removed, with the open areas extending along the fold lines delineating the proximal and distal portions of the areas. These openings provide for ready engagement with the wrapped product by the hand of a user, facilitating insertion of the wrapped product into an enclosing box or package40(FIG. 4).

As will be understood, the present invention contemplates methods of forming packaging materials as here described as well as folding the body into use configuration about a product and inserting the wrapped product into an appropriate box.

In the drawings and specifications there has been set forth a preferred embodiment of the invention and, although specific terms are used, the description thus given uses terminology in a generic and descriptive sense only and not for purposes of limitation.