NO154570B - PROCEDURE FOR MEASURING INVESTMENT QUANTITIES. - Google Patents

Description

The present invention relates to a method for measuring coating amounts in a coating layer that is deposited on both sides of paper, cardboard or a similar base material and which contains a component that emits the same characteristic fluorescence radiation, in which method excitation is carried out using primary radiation obtained from a radiation source of fluorescence radiation and the intensity of the radiation is measured with a detector.

There are previously known methods for measuring coating quantities based on the measurement of characteristic fluorescence radiation excited by means of a primary radiation, in one or more coating layers spread on cardboard or similar material. In these methods, the absorption of the primary radiation in the layer to be measured, and of the excited fluorescence radiation in the layer below the coating layer, has been utilized.

When the base material is coated on both sides with a coating layer containing components that emit the same characteristic fluorescence radiation, the above previously known methods are no longer usable. A typical example of such a case is a paper web that is coated on both sides with the same coating compound. The purpose of the present invention is to provide, in this case, an appropriate method for measuring coating amounts, and the method is characterized by the fact that the coated base material is introduced between two mutually functionally independent radiation source-detector pairs and that it is carried out separately with each of these radiation source-detector pairs excitation of fluorescence radiation in the coating layers on both sides of the base material as well as measurement of the combined intensity of the excited radiation, whereby the coating quantities can be calculated on the basis of the measurement results obtained and the surface weight of the base material which is known or separately

In the following, the invention will be described in detail with the help of an example with reference to the attached drawing which represents the measurement of the coating layers on a paper web coated on both sides.

The paper web according to the drawing comprises a coating layer 1 on the upper side, a paper layer 2 and a coating layer 3 on the underside. The coating layers 1 and 3 consist of coating mass which emits the same isotope or X-ray excited fluorescence radiation, and they are applied to the paper 2 with the same coating unit. For measuring the surface weight of the base material, a radiation source S ref,- is placed in front of the coating unit, which emits a primary radiation 4. The fluorescence radiation 5 that the primary radiation 4 has excited in the raw paper is measured with

re f o

the detector and the primary radiation 6 which has passed through

o re f the paper is painted with the detector Dtr . After the coating unit on both sides of the paper, the radiation source detector pairs S^, and D2> are placed, which are collimated in such a way that they do not interfere with each other during simultaneous measurements. The primary radiation 7 emitted by the radiation source excites

in the coating layer, the fluorescence radiation 8 which is observed by the detector D^. At the same time, the primary radiation 9 emitted by the radiation source S falls on the coating layer 3, and the fluorescence radiation 10 excited therein likewise goes to the detector D^. In a similar way, the primary radiation 11, 13 emanating from the radiation source S2 induces fluorescence radiation 12 in coating layer 3 and fluorescence radiation 14 in coating layer 1, and the resulting fluorescence radiation is observed with the detector. The primary radiation 15 passing through the paper web is further observed with the transmission detector <D>tr-

If a writer

m^ = amount of coating in coating layer 1 on the upper side m 9 = surface weight of paper layer 2

m^ = the amount of coating in the coating layer 3 on the underside

re f re f = the intensity of the fluorescence radiation measured by 1^ = the intensity of the fluorescence radiation measured by D,

I2 = the intensity of the fluorescence radiation measured by D2

= effective activity of the measuring sensor on the upper side C2 = effective activity of the measuring sensor on the lower side

-* ref = the ratio ^/^f-^ for a rough paper containing filler material

ref C2 = the ratio ^^fl ^or a raPaPir containing filler material

yg = the coating's "self-absorption coefficient"

pE£ = the combined mass absorption coefficient of the primary and secondary radiation in the coating

\ i P = the combined mass absorption coefficient of the primary and secondary radiation in the paper,

is the radiation's 8 intensity. m^ . e ml the radiation's 10 intensity. m^ . e '^c ml <+> lJp*in2^

the radiation's 12 intensity C2 . m^ . e <V>s <m>3

the radiation's 14 intensity C,, . m^ . g ^c'm3 + lJp*m2'

The coating quantities can then be determined in practice from the easily calibrated equations (1) and (2).

When the coating quantities are measured in the manner described above, the provision requires information to be entered into the computer regarding the surface weight (=m2) of the paper to be coated, which can be obtained e.g. from a 3-surface weight meter that measures the raw paper. However, it becomes easier and gives more accurate results if the continuous observation of the raw cardboard is carried out with a transmission detector which measures the primary radiation from sre^ and which is mounted in the measuring head which measures the raw cardboard. In the latter case, one does not achieve absolutely exact surface weights, but since both the device's calibration and the subsequent measurements are based

ref

pa I , the changes in the filler content and composition of the raw paper cannot appreciably affect the fluorescence yield obtained on the opposite side of the raw paper (the quantity variations of the coating present, such as filler, do not cause nearly as much variation in the secondary radiation as in the primary radiation). It is therefore profitable to determine in equations (1) and (2) the necessary m ? from equation (3) and the real weight of the raw paper separately according to another method.

re f *>ref

I, = the transmission intensity scaled by D_,_

tr J tr

I, o=I. is measured without intermediate paper with D^.

tr tr ? r r tr

p = the mass absorption coefficient of the paper for the primary radiation p . ref

in the direction D^_r •

The significance of the variations in the filler content of the raw paper and

-composition for the measurement result can even be eliminated in that one mounts a second transmission detector D in the measuring head that measures the coated area, which measures the primary radiation either from S or S2 and that one initially determines the total amount of coating (= m^ + rn^l using two transmission detector readings from equation (4).

L = the intensity measured by D.

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Uc = the coating's mass absorption coefficient for the primary radiation in the direction D and the ratio m^/m^ henceforth directly from the reduced ref equations for ^ and 1^ : 1^ = . + . If resp. with which m^ and m^ can be calculated from equations (5) and (6):

If the paper's filler distribution in the z-direction varies significantly, when seeking accurate results, it may in certain cases be necessary to mount a radiation source-detector pair on the other side of the raw paper in the reference measuring head.

Although the influence of moisture and surface weight variations on the measurement accuracy is extremely small, when one uses e.g. y isotopes, the errors arising from the point shape of the reference source are generally insignificant. When coating heavy raw paper or cartons, however, it pays to omit the determination of the total coating quantity and to carry out the measurements only on the basis of the fluorescence, because the fluorescence yield factor for the coating on the opposite side of the raw paper in equations 1 and 2 drops sharply with increasing surface weight of the raw paper , as well as because the measurement error caused by moisture variations has an almost exclusive effect on this factor.

It is clear to a person skilled in the industry that the various embodiments of the invention are not limited to the above example, but that they can vary within the scope of the subsequent patent claims.

Claims (3)

1. Method for measuring coating amounts in coating layers that are applied to both sides of paper, cardboard or similar base material (2), which coating layers contain the same component that emits characteristic fluorescence radiation, in which method by means of from a radiation source (S^,S2 ) obtained primary radiation (7,9,11,13), excitation of fluorescence radiation (8,10,12,14) is performed and the intensity of the radiation is measured with a detector (D-^D,,) , characterized in that the coated base material (2) is introduced between two functionally independent radiation source-detector pairs (S^,D^ and S2,D2) and that excitation of fluorescence radiation (8,10,12,14) is carried out separately with each of these radiation source-detector pairs in the coating layers (1, 3) on both sides of the base material as well as measurement of the combined intensity of the excited radiation, whereby the coating quantities can be calculated on the basis of the measurement results obtained and the surface weight of the base material which is known or separately determined. 2. Method according to claim 1, characterized in that the coating quantities are measured in connection with the coating process of the base material (2), in which the surface weight of the base material web is measured before the coating layers (1,3) are applied using a radiation source (sre^) placed on one side of the web o re f and a transmission detector (Dtr ) placed on the other side. 3. Method according to claims 1 or 2, characterized in that the intensity of the primary radiation (15) passing through the coated base material (2) is measured with a transmission detector (D^) placed in connection with the second radiation source-detector pair (S2, D2) , whereby the combined coating quantity of the coating layers (1,3) can be calculated from the measurement result.