JP5004047B2 - Pressure distribution sensor sheet calibration jig - Google Patents

Description

  The present invention relates to a calibration jig for a pressure distribution sensor sheet.

  For rolls used in film manufacturing processes, laminators, paper machines, ink kneading devices, dyeing hydraulic padders, etc., the management of pressure and pressure balance is indispensable for improving product quality and yield. It is one of the management items.

  Currently, the most commonly used pressure balance management methods are (1) a method of balancing the load by supplying equal pressure to the cylinders connected to the left and right bearings, and (2) the two rolls. There are a method of adjusting the balance by measuring the total load with a load cell mounted on the bearing part, and a method of (3) mechanically adjusting the gap between the two rolls.

  In the case of (1) above, it is difficult to accurately determine the actual load due to the roll's own weight and frictional resistance, and there is no guarantee that the roll load is actually balanced even if the internal pressures of the left and right cylinders are equalized. .

  Further, none of the above (1) to (3) can confirm the pressure distribution (pressure profile) over the entire length of the roll or squeegee. That is, the pressure profile is affected by the balance and crown amount of the roll, the material and hardness of the surface, and in the case of a squeegee, the balance cannot be obtained only by adjusting the left and right balances due to the deflection of the rubber.

  Therefore, it can be said that accurate control is insufficient only with the above-described mechanism measures. That is, a means for measuring the pressure profile directly applied to the roller or squeegee is required.

Here, as one method for simply measuring the pressure profile, there is a use of a pressure distribution sensor sheet coated with a special ink whose electric resistance changes according to pressure. In addition, the sensitivity of each pressure-sensitive element is not only slightly different due to uneven application of pressure-sensitive conductive ink during production, but also the sensitivity between sensor solids is different.
Since the sensitivity difference between the solids and the sensitivity difference between the pressure sensitive elements greatly hinders accurate measurement of the pressure balance of the roller and the squeegee, calibration is required.

  Conventionally, a dedicated member in which a member such as a roller or squeegee is attached to a weight such as brass, stainless steel, or iron has been used for calibration.

  However, as shown in FIG. 6, the conventional calibration jig has a structure in which a weight body 90 to which a flat squeegee rubber 91 is attached is supported by an edge portion of the squeegee rubber 91 and two support bars 92. Since the center of gravity of the main body 90 is closer to the side of the support rod 91 than the position extended in the vertical direction from the point where the edge of the squeegee rubber 91 contacts, there is the following problem.

  That is, in this conventional calibration jig, the weight load of the weight is distributed and supported by the edge of the squeegee rubber 92 and the two support rods 92, so that the weight main body 90 should not fall down. When the load applied to the two support bars 92 is increased, the effective load on the edge of the squeegee rubber 91 is decreased. On the contrary, when the effective load on the edge of the squeegee rubber 91 is increased, the load applied to the two support bars 92 is reduced, and the weight main body 90 is likely to fall down. That is, in the conventional calibration jig, the effective load on the edge of the squeegee rubber 91 is large, and the weight body 90 cannot be secured at the same time. The same applies when the squeegee rubber is replaced with a roller.

Note that, as a calibration jig for a pressure distribution sensor sheet capable of increasing the effective load on the edge of the squeegee rubber 91, for example, disclosed in Patent Document 1. This calibration jig is of a type in which a pressure distribution sensor sheet is pressurized by a fluid pressure cylinder, and includes a pressurized fluid source, a pressure gauge, a valve, and the like. Therefore, it is expensive and cannot be used where there is no fluid source.
JP2004-279351

  Therefore, in the present invention, a pressure distribution sensor sheet that is low in cost, does not require a pressurized fluid source (ease of use), has a large effective load on the edge and roller of the squeegee rubber, and can ensure that the weight body does not fall over It is an object to provide a calibration jig.

(Invention of Claim 1)
The calibration jig for a pressure distribution sensor sheet according to the present invention is a calibration jig for a pressure distribution sensor sheet for measuring the pressure or pressure balance of an object that is applied with force on a squeegee or roller line, and has a leg portion. A body, a weight body attached to the support body so as to be movable up and down, and a squeegee rubber or a roller provided at a lower portion of the weight body, and in an air space surrounded by a lower end portion of the leg portion in a top view. It is set so that the center of gravity of the weight body is located.
(Invention of Claim 2)
The calibration jig for the pressure distribution sensor sheet according to the present invention relates to the invention according to claim 1, wherein the center of gravity of the weight main body is positioned at a central portion surrounded by the lower end portion of the leg portion when viewed from above. The pressure distribution sensor sheet calibration jig according to claim 1, wherein:
(Invention of Claim 3)
The pressure distribution sensor sheet calibration jig according to the present invention relates to the invention according to claim 1 or 2, wherein the support body having the leg portion is formed of a pair of plate members having a reverse U-shape or V-shape in front view. ing.
(Invention of Claim 4)
The calibration jig for the pressure distribution sensor sheet according to the present invention relates to the invention according to claim 1 or 2, and the support body having the leg portion is constituted by a box body having an open bottom.
(Invention of Claim 5)
The pressure distribution sensor sheet calibration jig according to the present invention relates to the invention according to any one of claims 1 to 4, wherein the tip portion of the squeegee rubber placed on the pressure distribution sensor sheet has an angle of 30 to 90 degrees. have.

  According to the calibration jig for the pressure distribution sensor sheet of the present invention, it is low-cost and does not require a pressurized fluid source (ease of use), has a large effective load on the edge and roller of the squeegee rubber, and the weight does not fall over Can be secured at the same time.

  Embodiments as the best mode for carrying out the calibration jig for pressure distribution sensor sheets of the present invention will be described in detail below.

  1 is a side view of a calibration jig (hereinafter referred to as calibration jig) for a pressure distribution sensor sheet according to Embodiment 1 of the present invention, and FIG. 2 is a front view of the calibration jig.

(Basic configuration of calibration jig J)
1 and 2, the calibration jig J is a calibration jig for the pressure distribution sensor sheet S for measuring the pressure and pressure balance of an object to which a force is applied on the line of the squeegee rubber 30. It comprises a body 1, a weight main body 2 attached to the support body 1 so as to be movable up and down, and a squeegee rubber 30 provided at the lower part of the weight main body 2. The center of gravity G of the weight body 2 is set so as to be positioned at the center of the enclosed airspace.

(Specific configuration of calibration jig J)
As shown in FIG. 1 and FIG. 2, the support body 1 is composed of a pair of plate materials 1 a and 1 a having an inverted V shape (or an inverted U shape). It is covered with rubber material 11, 11 (or resin material). In this embodiment, the support body 1 is formed of a metal material such as a steel plate other than the rubber materials 11 and 11.

As shown in FIGS. 1 and 2, the weight body 2 is formed in a long bar shape that is a pentagon in a side view, and a handle 4 is provided on the support body 1. Here, the plate members 1 a and 1 a are provided. As shown in FIGS. 1 and 2, the weight main body 2 is mounted between the two rivets R into the weight main body 2 through the longitudinal long holes 12 formed on the center line on the plate 1 a side. (Or bolts are screwed in). At this time, the position where the rivet R is driven is set so that the weight body 2 can move up and down with respect to the support body 1. In this embodiment, the vertically long hole 12 and the center of the weight body 2 are located on the same circular straight line.

  As shown in FIGS. 1 and 2, the squeegee rubber 30 has a pointed bottom end, and its width is slightly larger than the width of the pressure sensitive portion of the pressure distribution sensor sheet S. The surface hardness of the squeegee rubber 30 is JIS K6253 durometer type A80, and the angle of the tip is 30 to 90 °.

(About the excellent effect of the calibration jig J)
When this calibration jig J is used, the following excellent effects are obtained.
“A large effective load on the edge (pointed portion) of the squeegee rubber 30”
As described above, the weight main body 2 is attached between the plate members 1a and 1a, as shown in FIGS. 1 and 2, through the two elongated rivets R through the longitudinal hole 12 formed on the center line on the plate member 1a side. The weight body 2 can be moved up and down relative to the support body 1 at a position where the rivet R is driven.

Accordingly, only the amount of the falling moment of the weight body 2 that acts on the legs 10, 10 of the weight body 2 is applied to the pressure distribution sensor sheet S via the squeegee rubber 30. That is, it is possible to increase the effective load at the edge (the sharp portion at the lower end) of the squeegee rubber 30.
"The weight body 2 is unlikely to fall."
As described above, the center of gravity G of the weight body 2 is set at the center of the airspace surrounded by the lower ends of the legs 10 and 10 when viewed from above.

Therefore, the weight body 2 can be reliably prevented from falling.
"Low cost and no need for fluid source"
From the configuration described above, it is clear that the pressurized fluid source is not required at low cost.
"Summary of effects"
From the above, according to this calibration jig J, it is clear that a low-cost and no pressurized fluid source is required, the effective load applied to the edge of the squeegee rubber 30 is large, and the weight can be secured at the same time. is there.

  FIG. 3 shows a side view of a calibration jig J according to Embodiment 2 of the present invention.

  As shown in FIG. 3, the calibration jig J is basically the same as that of the first embodiment, except that the weight body 2 is inclined.

  However, also in the second embodiment, from the contents described in the column of (the excellent effect of the calibration jig J) of the first embodiment, the cost is low and no pressurized fluid source is required, and the squeegee rubber 30 is further reduced. It is clear that the effective load applied to the edges of the main body 2 is large and the weight body 2 can be prevented from falling over simultaneously.

  4 is a side view of a calibration jig J according to Embodiment 3 of the present invention, and FIG. 5 is a front view of the calibration jig J.

(Basic configuration of the calibration jig J)
4 and 5, the calibration jig J is a calibration jig for the pressure distribution sensor sheet S for measuring the pressure and pressure balance of an object applied on the line of the roller 31. It comprises a body 1, a weight body 2 attached to the support body 1 so as to be movable up and down, and a roller 31 provided at the lower part of the weight body, and is surrounded by the lower ends of the leg portions 10 and 10 in a top view. The center of gravity G of the weight body 2 is set at the center of the airspace.

(Specific configuration of the calibration jig J)
As shown in FIGS. 4 and 5, the support body 1 is configured by a box-like body having a rectangular shape in plan view with only the lower end open, and two holes 14 and 14 are formed in the upper wall thereof. . In addition, in this support body 1, the peripheral wall lower part of the said box-shaped body is functioned as the leg parts 10 and 10. FIG.

As shown in FIG. 1 and FIG. 2, the weight main body 2 is formed in a long rod shape that is a pentagon in a side view, and a handle 4 is provided at the upper portion and a roller 31 is provided at the lower portion. In the calibration jig J, as shown in FIGS. 4 and 5, the rising portions 40 and 40 of the handle 4 are formed in the holes 14 and 14 as means for allowing the weight body 2 to move up and down with respect to the support body 1. It has a form that allows it to be tightly inserted.

(About the excellent effect of the calibration jig J)
When this calibration jig J is used, the following excellent effects are obtained.
“The effective load of the roller 31 can be increased”
In this calibration jig J, as shown in FIGS. 4 and 5, as a means for allowing the weight body 2 to move up and down with respect to the support body 1, the rising portions 40, 40 of the handle 4 are formed in the holes 14, 40. 14 is closely inserted. Thereby, most of the weight of the weight body 2 is applied to the pressure distribution sensor sheet S via the roller 31. That is, the load on the roller 31 can be increased.
“The body of the spindle is unlikely to fall.”
As described above, the center of gravity G of the weight body 2 is set at the center of the air space surrounded by the lower end of the leg 10 in the top view.

Therefore, the weight body 2 can be reliably prevented from falling.
"Low cost and no need for pressurized fluid source"
From the configuration described above, it is clear that the pressurized fluid source is not required at low cost.
"Summary of effects"
From the above, according to this calibration jig J, it is clear that it is low-cost, does not require a pressurized fluid source, has a large effective load applied to the roller 31, and can ensure that the weight body 2 does not fall over at the same time. is there.

(Other embodiments)
The squeegee rubber 30 of the first and second embodiments can be changed to the roller 31.

  The roller 31 of the third embodiment can be changed to the squeegee rubber 30.

Side view of the calibration jig of the pressure distribution sensor sheet of Example 1 of the present invention, The front view of the said calibration jig. The side view of the jig | tool for calibration of Example 2 of this invention. The side view of the calibration jig | tool of Example 3 of this invention. The front view of the said calibration jig | tool J of FIG. The side view of the conventional calibration jig.

Explanation of symbols

J Calibration jig S Pressure distribution sensor sheet G Center of gravity R Rivet 1 Support body 1a Plate material 10 Leg part 11 Rubber material 12 Long hole 14 Hole 2 Weight body 30 Squeegee rubber 31 Roller 4 Handle 40 Standing part

Claims (5)

A pressure distribution sensor sheet calibration jig that measures the pressure and pressure balance of an object that exerts a force on a squeegee or roller line, and is attached to a support body having legs and a vertical movement with respect to the support body The weight body and a squeegee rubber or roller provided at the lower part of the weight body, and the center of gravity of the weight body is set in the air space surrounded by the lower end of the leg portion when viewed from above. A pressure distribution sensor sheet calibration jig characterized by 2. The calibration jig for a pressure distribution sensor sheet according to claim 1, wherein the center of gravity of the weight body is set at a central portion surrounded by the lower end portion of the leg portion in a top view. The pressure distribution sensor sheet calibration jig according to claim 1, wherein the support body having the leg portion is formed of a pair of plate members having a reverse U-shape or V-shape when viewed from the front. The pressure distribution sensor sheet calibration jig according to claim 1, wherein the support body having the leg portion is formed of a box body having an open bottom. 5. The pressure distribution sensor sheet calibration treatment according to claim 1, wherein the tip portion of the squeegee rubber placed on the pressure distribution sensor sheet has an angle of 30 to 90 degrees. Ingredients.

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