Patent Application
20080301964
The present invention relates generally to the manufacture of envelopes on a production line apparatus and more particularly to an apparatus and method to measure predetermined positions upon the envelope to determine whether the envelope is in or out of specification.
Envelope manufacturing machines which fold the closure, side and bottom flaps or panels of envelope blanks are well known in the prior art. Such machines which manufacture such envelopes on a production line basis are also well known, including such apparatus which automatically applies adhesive or gum to predetermined portions of the envelope blank during the manufacturing process and cuts windows in the envelope blank.
While it is known to make envelopes and apply adhesives to various flaps and other portions of the envelope in a continuous production line system, if the gum is incorrectly applied to the predetermined areas of the envelope, then the envelope will not function as designed. Such will in turn negatively affect the basic use of the envelope as well as cause problems with inserting equipment and postal sorting equipment. Traditional ways to validate the correct positioning of gum and the window at predetermined points on the envelope blank have been visual inspection, holding the envelope to a template manually measuring portions of the envelope or the like. Such methods rely on an interpretation of measurement apparatus and standards and specifications and requires a multiplicity of tools and is time consuming and subject to error.
There is a need for an apparatus and process which may be utilized by an operator to more quickly and easily validate that window and the gum exist and is in the proper position and length and which is reliable.
The present invention is directed to a measuring gauge for determining that an envelope meets predetermined specifications as well as a method of manufacturing envelopes in a high-speed production line utilizing the measuring gauge.
The measuring gauge is a flat, transparent “L” shaped body including an elongated first arm forming the long side of the “L” shaped body and a second shorter arm disposed at 90° to the first arm and at one end thereof. There is provided a notch in the second arm with the notch defining a triangle with the first leg angularly disposed with respect to the outer edge of the second arm. A first indicia is carried by the first leg of the triangle for indicating an in or out of specification of a first portion of an envelope, a second indicia is carried by the outer edge of the first arm for indicating an in or out of specification of a second portion of an envelope, a third indicia is carried by the inner edge of the first arm for indicating an in or out of specification of a third portion of an envelope and a scale is carried by the outer edge of the second arm for determining in or out of specification of a window formed in said envelope.
The method of manufacturing an envelope in accordance with the present invention comprises establishing a plurality of controllable manufacturing parameters providing a measuring gauge including a triangular element, the measuring gauge having indicia disposed on side edges thereof which may be read by a user to ascertain whether various portions of an envelope are within predetermined specification, selecting envelopes during a production run for measurement to determine whether they are within said predetermined specifications, inserting a first edge of the gauge between the side flap and back panel of an envelope and into engagement with the gum line and reading the depth of penetration of the first edge of the gauge, inserting the terminus of the triangular element of the gauge between the back flap and side flap at the bottom fold line and reading the depth of penetration of the triangular element, opening the side seam fold line of the envelope to expose the side flap on the inside of the envelope and inserting a second edge of the gauge between the back panel and the inside edge of one of the side flaps into engagement with gum and reading the depth of penetration of the second edge of the gauge, and placing the outermost part or tip of the triangular element at the bottom fold of the envelope and reading the distance from the bottom fold to the bottom of the window cutout, and adjusting one or more of the parameters to correct for any out of specification readings obtained.
The present invention is an improved process for manufacturing envelopes that utilizes a novel measuring gauge, and a methodology for using the gauge on samples of product at predetermined intervals. The novel measuring gauge is used manually to measure the location of the seam gum application and the address display window on an envelope. The gauge measures four different locations of seam gum, namely, top, outside, inside, and bottom. The gauge has four indices such as contrasting bands for these four measurements. The contrasting bands may be alternating bands of red and green. When the gauge is properly applied to the envelope, the red indicates the seam gum was applied to incorrect locations, and adjustments to the manufacturing parameters are needed. The green indicates that the seam gum application was in the correct region. The gauge also includes a scale along one side which is used to measure the position of the window and the size of the flap on the envelope.
Preferably, the margin of error is +/− 1/16 inch, which is reflected by the green width of the bands on the gauge. The monitoring measurement is preferably taken at least once every 30 minutes. Preferably, three consecutive envelopes are taken for measurement during each sampling for consistency, although any number may be taken, and such may be done randomly. If the results show that the seam gum is applied in the correct region, then no adjustment is needed. If the results show that the seam gum is not applied in the correct region, a corrective adjustment is taken to reduce or eliminate the error.
The improved process comprises initially establishing a plurality of controllable manufacturing parameters of an envelope making apparatus, including the fold locations for side panels or flaps of an envelope, the width of adhesive application from an adhesive applicator associated with the apparatus, the length of adhesive application from the adhesive applicator, the thickness of the applied adhesive from the applicator, the initial location for application of adhesive by the applicator, the distance from the edge of a side flap to a gum or adhesive line, pressure of exit rollers from the applicator and apparatus, the speed of movement of paper stock through the apparatus, and other parameters. The process further includes providing a measuring gauge (a “Go/No-Go” Gauge”) for use in measuring variations of said parameters on manufactured envelopes. The measuring gauge is preferably fabricated from Mylar, about 10 thousands of an inch thick, and is transparent, in the shape of an inverted “L”, and has several predetermined human-readable indicia operative to provide a measurement of in-spec and out-of-spec tolerance for various parameters. Each of the four sides of the gauge is labeled with an appropriate name for the part of an envelope to be checked against the measurements of the gauge, namely, top, bottom, inside, and outside. The gauge has colored regions or bands that are sized to represent an in-spec measurement and warn of out-of-spec measurements, plus or minus 1/16 inch.
For one typical side seam gummed envelope, the bottom or lower leg of the “L” of the gauge is 1½ inches, while the long side or leg of the “L” is 4 inches, with a top 2½ inches wide. The dogleg or short leg of the “L,” is 1 inch long by 1 inch wide, with the remainder of the gauge being 2½ inches long. These dimensions may vary depending upon the size of the envelope to be measured.
One indicium on the gauge 10 indicates “Check at least 3 samples every 30 minutes”.
A first measuring indicia comprises a legend INSIDE, positioned proximate to a three-layer band along an outer edge of the “L”, and extending about ⅔ of the distance from the top of the “L.” The band includes a central band of 0.125 inches indicative of “in spec”, positioned between two outer bands of 0.125 inches indicative of “out of spec”.
A second measuring indicia comprises a legend OUTSIDE, positioned proximate to a three-layer “L” shaped band, along an inner edge of the longer leg of the “L”. The second band also includes a central outer band of 0.125 inches indicative of “in spec”, positioned between two-outer bands of 0.0625 & 0.125 inches indicative of “out of spec”.
A third measuring indicia comprises a legend TOP, positioned proximate to a three-layer “L” shaped band:, along an inner edge of the shorter leg of the “L”, and intersecting with the band of the longer leg. The third band also includes a central band of 0.125 inches indicative of “in spec”, positioned between two outer bands of 0.0625 & 0.125 inches indicative of “out of spec”.
A fourth measuring indicia comprises a legend BOTTOM, positioned proximate to a two-region triangular element, having an apex generally aligned with the edge of the shorter leg of the “L”, and having a triangular notch defined along the edge of the shorter leg of the “L” of the gauge. Along the hypotenuse edge of the triangle, the three-region colored element includes an inner or central bank which is preferably a green portion and an outer bank which is a preferably red portion on either side and extending to the apex. Measuring from the outside vertical edge and along the hypotenuse edge, the first red portion is 0.9375 inches indicative of “out of spec”, the inner green portion is 0.350 inches indicative of “in spec”, and the second red portion is 0.30 inches and indicative of “out of spec”.
A fifth measuring indicia includes a scale along the bottom of the shorter leg of “L” to measure the location of the address display window.
A user of the gauge uses the gauge preferably on three consecutive envelopes to ensure that clearances are within spec. If the gauge shows that the gum or adhesive line is within spec on the three consecutive envelopes, no adjustments are indicated.
All specs—top, bottom, outside, and inside clearance and window location—are checked preferably at a maximum interval of 30 minutes, during normal quality control inspections. Preferably, at least three sequential envelopes are checked before any settings are adjusted.
By way of illustration a side seam envelope upon which the apparatus and method of the present invention may be used is found in
Such a measuring gauge 40 is shown in
Along a first edge 62 of the elongated arm 42 of the gauge 40 there is provided an indicium 64 which is utilized to ascertain whether or not another portion of the envelope is within specification and such will be described more fully in conjunction with
A similar contrasting arrangement is used for the indicium 56 as is illustrated along the hypotenuse 48. The indicium 56 contains first and second bands 76 and 78 which sandwich a contrasting band 80, there between. As indicated above, when the band 80 appears during the utilization of the gauge to measure a particular portion of the envelope that portion of the envelope is within specification. If either band 76 or 78 appear then that portion of the envelope is out of specification.
Additional indicia also appear on the gauge 40 such as the legends top, bottom, inside and outside. These refer to various portions of the envelope that are to be measured by that part of the gauge. These indicia guide the user of the gauge 40 as to where that particular portion of the gauge is to be placed for a specific measurement. It should also be noted that there appears on the gauge the additional legend “check at least three samples every 30 minutes”. This is a reminder to the user of the gauge that at least three envelopes are to be secured from the production run taking place every 30 minutes and these three envelopes are to be measured to determine whether or not the production run is generating envelopes which meet the desired specifications.
It is also desirable to check the inside of the envelope to determine whether or not the adhesive line on the side flaps 18 and 20 is positioned properly. This can be accomplished by utilizing the gauge 40 in the manner shown in
As shown in
There has thus been described a measuring gauge and the method of using the same to measure various portions of an envelope to determine whether or not they are within specifications determined by the manufacturing parameters of an envelope manufacturing apparatus. It should be evident to those skilled in the art, that a single tool, the gauge, is used by the operator or to measure several portions of the envelope. This can be done quickly and easily and provides a reliable indication on a go/no go basis as to the in or out of specification status of a production run of envelopes. If the measurements illustrate that the portions of the envelope or any of them which are measured do not fall within the desired specifications as initially generated then the controllable parameters of the manufacturing apparatus are adjusted to bring the envelopes being manufactured within the specifications desired. As is indicated, this may require adjusting the fold locations for the side flaps, the width of the strip of adhesive which is being applied, the start or stop point of the strip of adhesive, the length of the adhesive, the distance from the edge of a side flap to the line of adhesive or the like to bring the envelope within the desired set of specifications.
While the fundamental novel features of the invention have been shown and described in accordance with the above-preferred embodiments thereof, it should be understood that various substitutions, modifications and variations made by made by those skilled in the art without departing from the spirit or scope of the invention. Accordingly, all such modifications or variations are included in the scope of the invention as defined by the claims.
