JP5208264B2 - Original plate material for heat exchange plate and method for producing original plate material for heat exchange plate - Google Patents

Description

  The present invention relates to a base plate material for a heat exchange plate and a method for manufacturing the base plate material for a heat exchange plate.

Conventionally, it is desired that a heat exchange plate incorporated in a heat exchanger or the like has high heat conductivity. In order to improve the heat transfer, it is preferable to form micron-order fine unevenness on the surface of the plate to enlarge the surface area. As a method for transferring such micron-order fine unevenness, for example, Patent Document 1 The technology shown in Fig. 2 has been developed.
In the transfer method to the metal plate surface of Patent Document 1, the metal sheet is transferred by rotating the transfer roll, and the uneven transfer portion transferred to the outer peripheral surface of the transfer roll is pressed against the transferred metal sheet. By doing so, a transferred portion having substantially the same uneven shape as the transfer portion of the transfer roll is formed on the surface of the metal sheet.

  On the other hand, Patent Document 2 forms a plate pattern with a predetermined pattern of holes formed on a plate, and stacks two plates by crossing the hole rows to form a plate set, and a partition plate and a plate set having communication holes at four corners. A plate type heat exchanger is disclosed in which fluid layers are alternately stacked to form a fluid circulation layer partitioned by a partition plate, and each circulation layer communicates with a circulation layer that is separated from the upper and lower layers. In order to improve heat transfer and strength, the heat exchange plate used in this heat exchanger has, for example, a plurality of chevrons of several mm to several cm in height called “herringbone”. The groove is press-molded and then incorporated into the heat exchanger.

JP 2006-239744 A JP 2009-192140 A (for example, FIG. 6)

As disclosed in Patent Document 1, in a heat exchange plate, fine irregularities of micron order are formed on the surface of a flat plate material, and the heat transfer is improved by increasing the surface area. A flat plate with fine irregularities formed on it is rarely used as it is as a heat exchange plate.
That is, as disclosed in FIG. 6 of Patent Document 2, a flat plate member on which fine irregularities are usually formed is a mountain-shaped groove having a height of several millimeters to several centimeters called a “herringbone” on its plane. Is press molded and then incorporated into a heat exchanger. Therefore, press formability is desired for the flat plate material after the formation of fine irregularities.

  In particular, when the flat plate is made of titanium, titanium is a material having anisotropy, and the anisotropy of the material affects the deformation behavior such as the reduction of the plate thickness and the strain gradient in the stress concentration part. Compared with other materials that do not have, the press formability is remarkably poor. Titanium is a material that tends to seize, and if the lubricating oil film breaks during pressing, wrinkles are likely to occur due to breakage of the material or contact with a press die or tool.

Naturally, the techniques disclosed in Patent Document 1 and Patent Document 2 do not disclose a technique for manufacturing a heat exchange plate after overcoming the difficulty of a flat plate made of titanium.
Therefore, in view of the above problems, the present invention is very excellent in heat transfer due to the formation of irregularities on the surface, and has very good workability in press forming as a post-treatment, and is easily used for heat exchange. An object of the present invention is to provide a base plate material for a heat exchange plate that can be formed into a plate, and a method for manufacturing the base plate material.

In order to achieve the above object, the present invention takes the following technical means.
That is, the base plate material of the plate for heat exchange in the present invention is composed of a titanium flat plate material having fine irregularities formed on the surface, and heat exchange is performed after the flat plate material is subjected to press working as post-processing. A base plate material used as a plate for an object, wherein the projections are circular in a plan view with a diameter of 400 μm or more, and the height of the projections has a 10-point average roughness of 5 μm or more. The thickness of the 0.1 × flat plate material is not more than μm, the pitch of adjacent protrusions is not less than 600 μm, the width of the recesses is not less than 200 μm, and the angle η of the protrusions is not less than 90 °, The shape parameter defined by the height of the convex portion (μm) × [the width of the concave portion (μm) / the pitch of adjacent convex portions (μm) / the angle of the convex portion (deg)] is 0.14 or more and 0.94 or less The unevenness of the surface of the base plate material is set so that A.

Before Kitotsu section is a circular shape in plan view, it is preferably arranged in a staggered pattern on the front surface of the flat plate.

Also, the manufacturing method of the original sheet of the heat exchange plates in the present invention, the surface consists of a flat plate made of titanium fine irregularities are formed, pressing against the flat plate is applied as a post-treatment A method of manufacturing a base plate material to be a heat exchange plate after, with respect to the projections and depressions, the projections are circular in a plan view and the diameter thereof is 400 μm or more, and the height of the projections is an average of ten points. The roughness is 5 μm or more, 0.1 × thickness of the flat plate material is less than or equal to μm, the pitch of adjacent protrusions is 600 μm or more, the width of the recesses is 200 μm or more, and the angle η of the protrusions is 90 The shape parameter defined by the height of the convex portion (μm) × [the width of the concave portion (μm) / the pitch of the adjacent convex portion (μm) / the angle of the convex portion (deg)] is 0 or more. as it will be .14 to 0.94, the concave surface of the original plate To the point of forming a certain.

Also, the convex portion as well as a circular shape in plan view, it is preferable to form the staggered arrangement on the surface of the flat plate.

  By using the base plate material according to the technique of the present invention, it is possible to manufacture a heat exchange plate without causing cracks or the like during press working. The manufactured heat exchange plate is very excellent in heat transfer.

The manufacturing method of the plate for heat exchange is shown. It is explanatory drawing explaining the shape of a convex part. It is an arrangement plan of convex parts formed in the surface of a former board material. It is another arrangement | positioning figure of the convex part formed in the surface of the original board | plate material. It is the figure which showed the relationship between LxRz / P and a stress concentration rate. It is the figure which showed the relationship between the uneven | corrugated shaped dimension shape formed in the surface of the original board | plate material, and heat-transfer efficiency, and the relationship between the uneven | corrugated shaped dimension shape formed in the surface of the original board | plate material, and the good press-formability. It is the figure which showed the relationship between the angle (eta) of a convex part, and the flow of a fluid. It is the figure which showed the relationship between a shape parameter and a heat-transfer improvement rate. It is the figure which showed the relationship between a shape parameter, a heat-transfer improvement rate, and press moldability. It is the figure which showed the outline of the apparatus which forms uneven | corrugated shape on the surface of a base plate material. It is a reference figure for calculating a press formability score. It is the figure which showed the relationship between a shape parameter, a heat-transfer improvement rate, and press moldability.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First embodiment]
FIG. 1 is a conceptual diagram showing a method for manufacturing a heat exchange plate.
As shown in FIG. 1, when manufacturing a heat exchange plate, first, as shown in FIG. 1A, a flat plate 1 as a material is formed in a predetermined size. And as shown in FIG.1 (b), the plate base plate (original plate material) which formed the fine uneven | corrugated shape in the surface 1a of the flat plate material 1 by pressing the flat plate material 1 is produced. Next, as shown in FIG. 1 (c), heat is generated by forming, for example, a mountain-shaped groove 3 called a herringbone on the plate base plate 2 (base plate material) having fine irregularities formed on the surface 2a. The replacement plate 4 is manufactured.

A flat plate 1 shown in FIG. 1A is a titanium material, and its dimensions and plate thickness are determined in consideration of the desired size and plate thickness of the heat exchange plate 4 which is the final product.
A plate base plate 2 is formed on the surface 1a of the flat plate 1 by forming a fine uneven shape (a plurality of convex portions 5 and concave portions 6 sandwiched between the convex portions 5) by using a processing apparatus 10 described later. Is formed. The plate base plate 2 on which the concavo-convex shape is formed has very good heat conductivity (having a very high heat transfer rate). In addition, since the plate base plate 2 of the present invention is made of titanium, characteristics such as corrosion resistance, strength, and weight reduction are superior to other metals. Therefore, it is suitable for products that require corrosion resistance and strength, such as plates of plate heat exchangers.

  The herringbone 3 formed on the plate base plate 2 is a plurality of chevron grooves having a skeleton shape, and the size of the grooves is several mm to several cm in height. The base plate 2 is incorporated into a heat exchanger. The oblique lattice shape represented by the herringbone 3 and the like is a wall in which the irregularities are perpendicular to the working fluid regardless of the flow from any direction even when the flow of the working fluid inside the heat exchanger is uneven. As a result, it contributes to the improvement of heat transfer by turbulent flow.

Hereinafter, details of the uneven shape on the surface of the plate base plate 2 will be described.
As shown in FIG. 2, the convex portion 5 formed on the surface 2 a of the plate base plate 2 includes a plurality of side walls 7 erected in the thickness direction (thickness direction of the plate base plate 2) and upper ends of the side walls 7 ( And an upper wall 8 connecting the upper edge). In other words, a flat portion is provided at the top of the convex portion 5. When the convex portion 5 has a cylindrical shape or a conical shape, the number of the side walls 7 is one. However, when the convex portion 5 has a prismatic shape or a pyramid shape, the side walls 7 are plural.

As shown in FIG. 3A, the convex portion 5 formed on the surface 2a of the plate base plate 2 is circular in plan view, and its diameter D is 400 μm or more. The arrangement of the projections 5 in a plan view is staggered. Here, the staggered arrangement (staggered arrangement) means that the centers of the convex portions 5 and 5 adjacent to either one are not aligned in a straight line in the vertical direction and the horizontal direction.
Specifically, in the plate base plate 2, the protrusions 5 and 5 adjacent in the vertical direction are shifted by a half pitch in the horizontal direction, and a straight line (one point) connecting the centers of the protrusions 5 adjacent in the horizontal direction. The convex portion 5 may be arranged so that the plane angle θ between the chain line A and the straight line (one-dot chain line) B connecting the centers of the convex portions 5 adjacent in the vertical direction is 60 °.

By adopting a staggered lattice arrangement in this way, the unevenness can be a wall perpendicular to the working fluid in any direction from the direction of flow when the working fluid flow in the heat exchanger is uneven. It contributes to the improvement of heat transfer by turbulent flow. Moreover, it is possible to cope with stress concentration caused by anisotropy with respect to an anisotropic material such as titanium.
The distance L between the convex portions 5 adjacent in the vertical direction or the horizontal direction (between the side walls 7 of the adjacent convex portions 5) (the width L of the concave portion 6) is preferably 200 μm or more. The width L of the concave portion 6 is the shortest distance between the convex portions 5 adjacent to each other in the horizontal direction or the vertical direction (side walls 7 of the adjacent convex portions 5). The pitch P of the part 5-(the diameter D / 2 of the convex part 5) x 2 ". Moreover, the pitch P of the adjacent convex parts 5 is the distance between the centers of the nearest convex parts 5 adjacent in the horizontal direction or the vertical direction (the center distance between the convex parts 5 at the shortest distance).

The width L of the concave portion 6 shown in FIG. 3A is the same value in both the vertical direction and the horizontal direction (the distance between the convex portions 5 adjacent in the vertical direction and the distance between the convex portions 5 adjacent in the horizontal direction. And the same value). The pitch P of the adjacent convex portions 5 (the distance between the centers of the convex portions 5, that is, the distance between the centers of the upper walls 8) is preferably 600 μm or more.
As shown in FIG. 3B, the convex portion 5 formed on the surface of the plate base plate 2 has an upper wall 8 that rises upward in a sectional view and a front wall that horizontally connects the upper edge of the upper wall 8. 9 and a trapezoidal shape. The height of the convex portion 5 (the upper wall 8, that is, the side wall 7) indicated by the ten-point average roughness Rz (hereinafter sometimes referred to as the height Rz) is 5 μm or more, It is 1/10 (1/10) or less of the plate thickness t. Rz of the convex portion 5 of the plate base plate 2 is, for example, about 25 μm (about 10 μm in terms of Ra).

  The height Rz of the convex portion 5 is within this range. If the uneven shape is too large with respect to the plate thickness, the flatness (shape) cannot be ensured during rolling transfer in the processing apparatus 10 described later, and the rolling stability This is because sex cannot be obtained. Further, in a plate where flatness cannot be ensured, stress distribution is generated during press forming in a subsequent process, and thus cracks occur at locations where the stress is high. That is, if the height Rz of the convex portion 5 is too large during press working, it causes a crack (starting point) and causes wrinkles. On the other hand, if the height Rz is too small (5 μm or less), the heat transfer efficiency cannot be improved.

By the way, the convex part 5 includes not only a perfect circle but also an elliptical shape with a flatness ratio of about 0.2. In addition, regarding the planar view shape of the convex portion 5, various shapes such as a square shape are conceivable. However, from the viewpoint of avoiding stress concentration at the time of press processing performed in a subsequent process, a substantially circular shape is preferable. The staggered arrangement state of the protrusions 5 is not limited to that shown in FIG.
For example, as shown in FIG. 4, a straight line (dashed line) C connecting the centers of the convex parts 5 adjacent in the horizontal direction and a straight line (dashed line) connecting the centers of the convex parts 5 adjacent in the vertical direction. The convex portion 5 may be arranged so that the plane angle θ with respect to D is 45 °, or may be another angle.

The matter which becomes the basis regarding the uneven | corrugated shape of the above plate base plates 2 is demonstrated.
When the inventor manufactures the plate base plate 2, the height Rz of the convex portions 5 formed on the surface of the plate base plate 2, the number of the convex portions 5 (width L of the concave portions 6), and the pitch P of the adjacent convex portions. In order to optimize the angle η of the convex portion, the shape parameter of the concave-convex shape including these “height Rz of the convex portion 5 × (width L of the concave portion 6 / pitch P of the adjacent convex portion]) / convex portion We focused on the angle η.

  First, among the shape parameters described above, when the height Rz of the convex portion 5 is constant and the width L of the concave portion 6 / the pitch P (L / P) of the adjacent convex portions is changed, FIG. As shown, the stress concentration rate tends to increase as L / P increases. In other words, if the width L of the concave portion 6 is too large or the pitch P of the convex portion is too narrow, cracks occur when stress is concentrated and press molding (press processing for forming a herringbone or the like) is performed. It becomes easy to do.

On the other hand, among the shape parameters described above, considering the situation where the height Rz of the convex portion 5 is changed and the height Rz of the convex portion 5 is increased, the same as the width L of the concave portion 6 and the pitch P of the adjacent convex portions. In addition, when press molding is performed, there is a possibility that a non-uniform stress distribution occurs and cracks occur in places where the stress is high.
Therefore, considering the press formability of the plate base plate 2, it is optimal that the height Rz of the convex portion 5 or the width L of the concave portion 6 is not too large, and the pitch P of the convex portion is not too narrow. It is considered that there is an upper limit value for the parameter to be represented.

FIG. 6 shows the press formability when the parameter “height Rz of the convex part 5 × (width L of the concave part 6 / pitch P of the adjacent convex part)” except for the above-described rising angle η of the convex part is changed. It summarizes the relationship with heat transfer efficiency. The press formability score in FIG. 6 is expressed by normalizing the indentation amount shown below.
In the evaluation test for evaluating the formability (press formability) in the press working, first, as shown in FIG. 11, the herringbone (groove 3) is formed on the original plate base plate 2 to form the heat exchange plate 4. . In preparation, first, one mold for molding corresponding to the heat exchanger use conditions is prepared. Then, a plurality of heat exchange plates 4 are formed by forming the herringbone 3 on the original plate base plate 2 in each mold under different conditions for the forming height every 0.1 mm. In the prepared evaluation plate (heat exchange plate 4), the molding limit height (maximum molding height at which necking does not occur) of a mold that does not cause necking is evaluated as the indentation amount.

In the evaluation test described above, it can be said that when the indentation amount is large, necking hardly occurs and the press formability is good, and when the indentation amount is small in the evaluation test, necking is likely to occur and the press formability is poor. Thus, in the evaluation test, it is possible to evaluate the forming depth at which constriction (necking) starts and the amount of strain that can withstand the forming.
As shown in FIG. 6, the press formability score decreases as the parameter increases, but if the parameter is 85 μm or less, the press formability score can be 1 or more to prevent the occurrence of necking. However, reliable press molding can be realized. That is, when the parameter is 85 μm or less, it is possible to avoid a situation where necking is prevented and press formability is lowered.

As described above, if the parameter is 85 μm or less, the situation where the press formability is reduced can be avoided, but the plate base plate 2 of the present invention is the source of the plate constituting the heat exchanger. And serves as a partition wall for heat exchange. Therefore, the plate base plate 2 of the present invention is also required to have a high heat transfer coefficient (high heat transfer efficiency).
Therefore, considering the heat transfer efficiency of the plate (heat exchange plate) with the uneven shape (heat exchange plate) assuming that the heat transfer efficiency of the “flat plate not forming the uneven shape” is 1.00, the heat transfer efficiency of the heat exchange plate is 1. Although it is necessary to be greater than 00, it is desirable that the heat transfer efficiency be 1.05 or more in order to achieve a remarkable effect in an actual heat exchanger.

  Here, the relationship between heat transfer efficiency and parameters is considered. As shown in FIG. 6, for example, the parameter is gradually reduced from 85 μm by reducing the height Rz of the convex portion 5, reducing the width L of the concave portion 6, or increasing the pitch P of the convex portion. . As described above, when the parameter is gradually reduced, the heat transfer efficiency is gradually reduced, and the heat transfer efficiency approaches a flat plate on which no unevenness is formed. However, if the parameter is 4 μm or more, the heat transfer efficiency (1.05 or more) required in an actual heat exchanger can be ensured. Therefore, in terms of heat transfer efficiency, in manufacturing the plate base plate 2, the parameter represented by “height Rz of the convex portion 5 × (width L of the concave portion 6 / pitch P of the adjacent convex portion)” is It is preferable to be 4 μm or more and 85 μm or less.

As described above, by setting the height Rz of the convex portion 5, the width L of the concave portion 6, and the pitch P of the adjacent convex portions, the plate base plate 2 having good press formability and excellent heat conductivity is manufactured. Can do.
Now, a high temperature fluid (high temperature fluid) is allowed to flow on the back surface (one side) across the heat exchange plate 4, and a low temperature fluid (low temperature fluid) is provided on the front surface (the other side where the irregular surface is formed). Suppose that Here, the low-temperature fluid may change (condense) from a gas to a liquid, or may remain a liquid. In any case, in order to increase the heat transfer efficiency of the heat exchange plate 4, it is important to generate turbulent flow and forced convection on the low temperature fluid (liquid) side.
Therefore, the inventors only consider the height Rz of the convex portion 5, the width L of the concave portion 6, and the pitch P of the convex portion 5 in manufacturing the plate base plate 2 that is the base material of the heat exchange plate. Not only the angle η of the convex portion 5 (the rising angle η of the side wall 7) was taken into consideration, but the shape of the convex portion 5 that easily causes turbulent flow or forced convection was verified.

FIG. 7A schematically shows the flow of fluid when the angle η of the convex portion 5 is large, and FIG. 7B shows the angle η of the convex portion 5 as compared with FIG. 4 schematically shows the flow of a fluid when is small.
As shown in FIG. 7A, when the angle η of the convex portion, in other words, the angle η formed by the bottom wall 6a and the side wall 7 constituting the concave portion 6 is relatively large (when the side wall 7 rises gently), The fluid tends to get over the convex portion 5 and is less likely to generate turbulence. On the other hand, as shown in FIG. 7B, when the angle η of the convex portion is relatively small (when the side wall 7 rises steeply), the fluid easily collides with the convex portion 5 and easily generates turbulence. Thus, the angle η of the convex portion 5 affects the turbulent flow and the heat transfer property changes. That is, when the angle η of the convex portion 5 increases, the heat transfer tends to decrease, and conversely, the heat transfer improves when the angle η of the convex portion 5 decreases. The optimum shape parameters were examined by adding not only the height Rz of 5, the width L of the recesses 6 and the pitch P of the projections 5, but also the angle η of the projections 5 affecting the heat transfer.
That is, the above-described parameter “height Rz of the convex portion 5 × (width L of the concave portion 6 / pitch P of the adjacent convex portion)” divided by the angle η of the convex portion 5 is “height Rz of the convex portion 5 × ( The width L of the recess 6 / the pitch P of the adjacent protrusions / the angle η (deg) of the protrusions 5 ”was used as the shape parameter.

FIG. 8 summarizes the relationship between the shape parameter and the heat transfer improvement rate.
As shown in FIG. 8, when looking at the tendency of the heat transfer efficiency of condensation and the tendency of the heat transfer efficiency of forced convection when the shape parameter is increased or decreased, the above-mentioned shape is the same because both tendencies are the same. It can be said that the parameters are most suitable for expressing the heat transfer characteristics of condensation and forced convection.
Here, as described above, press formability is also taken into consideration for the shape parameters that can well represent the heat transfer characteristics of condensation and forced convection. FIG. 9 shows changes in the shape parameter “height Rz of the convex portion 5 × (width L of the concave portion 6 / pitch P of the adjacent convex portion) / angle of the convex portion 5 (deg)” including the rising angle η of the convex portion. The relationship between the press formability and the heat transfer efficiency is summarized.

  As shown in FIG. 9, the press formability score decreases as the shape parameter increases, but if the shape parameter is 0.94 μm / deg or less, the press moldability score can be 1 or more, Reliable press molding can be realized while preventing the occurrence of necking. That is, if the shape parameter considering the condensation and forced convection is 0.94 or less, the situation where the occurrence of necking is prevented and the press formability is reduced can be avoided.

  That is, the shape parameter obtained by multiplying the parameter represented by “height Rz of the convex portion 5 × (width L of the concave portion 6 / pitch P of the adjacent convex portion)” by the angle η of the convex portion is 0.94 or less. As described above, if the projections and depressions are formed, the plate base plate 2 having excellent heat conductivity and good press forming can be manufactured. In addition, as described in the parameters other than the angle η of the convex portion, when considering the lower limit value for the shape parameter (to ensure a heat transfer efficiency of 1.05 or more), as shown in FIG. It is necessary to make it 0.14 μm / deg or more. The shape parameter is preferably 0.16 or more, more preferably 0.2 or more.

Therefore, the shape parameter “height Rz of the convex portion 5 × (width L of the concave portion 6 / pitch P of the adjacent convex portion) / angle of the convex portion 5 (deg)” is set to 0.14 or more and 0.94 or less. Is preferred.
Now, if deformation prevention is considered in forming the convex portion 5, the pressure-bonding area ratio S in the plate base plate 2 should satisfy the formula (1) in the concave-convex shape of FIG. preferable.

Yield stress σy of flat plate material (titanium)> Surface pressure applied to convex part during pressing (P / S) (1)
Here, S1 = P · P · tan (θ / 180 · π) / 4
S2 = π / 4 · D · D / 2
S = crimp area ratio = S2 / S1
P = Load at the time of press work S1 of Formula (1) is the area of the plane in FIG. 3 (the area of the triangle surrounded by the straight lines A and B shown in FIG. 3). S2 in Expression (2) is the area of the protrusions in FIG. 3 (the area of the protrusions existing in the above-described triangle).

  In this way, by using the base plate 2 that is made of titanium and has unevenness formed on the surface such that the shape parameter is 0.14 to 0.94, without causing cracks or the like during press working, The heat exchange plate 4 constituting the heat exchanger can be manufactured. The heat exchange plate 4 manufactured in this way has a very excellent heat transfer property and can be used as a heat exchange plate for liquid and liquid as well as a heat exchange plate for gas and liquid.

By the way, the above-mentioned plate base plate 2 can be formed using the processing apparatus 10 as shown in FIG.
The processing apparatus 10 includes a transfer roll 11, a processing roll 12, and a support roll 13. The transfer roll 11 is for transferring the flat plate 1 and is arranged on the upstream side and the downstream side as viewed from the processing roll 12.

  The processing roll 12 forms unevenness of micron order (several μm to several hundred μm) on the surface of the flat plate 1 being transferred. Specifically, the processing roll 12 forms the convex portion 5 and the concave portion 6 on the surface 1a of the flat plate 1 so that the shape parameter of the processed plate base plate 2 is 0.14 to 0.94. It is. In other words, the height Rz of the convex portion 5, the width L of the concave portion 6, and the adjacent portion for forming the convex portion 5 and the concave portion 6 so that the shape parameter is 0.14 to 0.94 on the processing roll 12. The pitch P of the convex portions and the angle η of the convex portions are set.

  On the entire circumference of the outer peripheral surface of the processing roll 12, a processing portion 14 having a convex shape (trapezoidal convex) is formed by etching or discharge dull. The height of the processed portion 14 is set so that the height Rz of the convex portion 5 in the plate base plate 2 after processing is 5 μm or more and 0.1 × thickness of the flat plate material is less than μm. The surface layer of the work roll 12 is preferably subjected to Cr plating or tungsten carbide treatment from the viewpoint of load resistance and wear resistance.

  In this processing apparatus 10, the processing portion 14 provided on the processing roll 12 is pressed against the surface of the flat plate 1 while rotating the processing roll 12, thereby reversing the processing portion 14 on the surface of the flat plate 1. The same convex part 5 and concave part 6 can be formed. In other words, the processing apparatus 10 forms the plate base plate 2 having irregularities having a shape parameter of 0.14 to 0.94, a height Rz of 5 μm or more and 10% or less with respect to the plate thickness t. Can do. In addition, formation of the convex part 5 is not limited to an above-described processing apparatus.

[Second Embodiment]
In the first embodiment described above, the shape parameter including the rising angle η of the convex portion is set to 0.14 to 0.94. However, in the second embodiment, verification of the shape parameter is further advanced by experiments or the like. The description of the same configuration as that of the first embodiment is omitted.
FIG. 12 shows changes in the shape parameter “height Rz of the convex part 5 × (width L of the concave part 6 / pitch P of the adjacent convex part) / angle of the convex part 5 (deg)” including the rising angle η of the convex part. The relationship between the press formability and the heat transfer efficiency is summarized.

  As shown in FIG. 12, the press formability score decreases as the shape parameter increases, but if the shape parameter is 0.94 μm / deg or less, the press moldability score can be 1 or more, Reliable press molding can be realized while preventing the occurrence of necking. That is, if the shape parameter considering the condensation and forced convection is 0.94 or less, the situation where the occurrence of necking is prevented and the press formability is reduced can be avoided. In other words, as a result of the verification, the upper limit value of the shape parameter needs to be 0.94 or less, and the second embodiment has the same result as the first embodiment.

  When the heat exchange plate 4 is used for various purposes, it is necessary to set the heat transfer efficiency to 1.05 or more as described above. For example, the heat exchange plate 4 is used for heat exchange for gas and liquid. When used also as a plate or a heat exchange plate for liquid and liquid, it is said that the heat transfer efficiency should be 1.03 or more. As shown in FIG. 12, if the shape parameter is set to 0.028 or more, the heat transfer efficiency can be set to 1.03 or more. Therefore, the lower limit value of the shape parameter is preferably 0.028. Note that “●” of forced convection and “◯” of condensation shown in FIG. 12 are overlapped and have substantially the same value.

Further, when the plate base plate 2 is manufactured, the unevenness may be formed by using the processing apparatus 10 (processing roll 12) so that the shape parameter is 0.028 to 0.94. Details of the manufacturing method Since this is the same as that of the first embodiment, description thereof is omitted.
By the way, it should be thought that embodiment disclosed this time is an illustration and restrictive at no points. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

For example, the plate 4 for heat exchange is manufactured by pressing the plate base plate 2, but the press processing of the plate base plate 2 may be anything and may not form the herringbone as described above. .
Moreover, regarding the unevenness formed on the plate base plate 2, the range in which the shape parameter is 0.14 to 0.94 may be at least part of the plate base plate 2, and preferably the whole.

  The base plate material of the heat exchange plate of the present invention is suitable as a base plate of a plate constituting a heat exchanger used for temperature difference power generation or the like.

DESCRIPTION OF SYMBOLS 1 Flat plate material 1a Flat plate surface 2 Plate base plate (original plate material)
2a Surface of plate base plate 3 Groove 4 Heat exchange plate 5 Convex part 6 Concave part 8 Upper wall 9 Front wall 10 Processing apparatus 11 Transfer roll 12 Work roll 13 Support roll

Claims (4)

It is composed of a flat plate made of titanium in which fine irregularities are formed on the surface, and is a base plate that becomes a plate for heat exchange after being subjected to press processing for the flat plate as post-processing,
Concerning the irregularities, the convex portion has a circular shape in a plan view, the diameter thereof is 400 μm or more, the height of the convex portion has a 10-point average roughness of 5 μm or more, and the thickness of 0.1 × flat plate material μm or less, the pitch of adjacent protrusions is 600 μm or more, the width of the recesses is 200 μm or more, and the angle η of the protrusions is 90 ° or more,
The shape parameter defined by the height of the convex portion (μm) × [the width of the concave portion (μm) / the pitch of adjacent convex portions (μm) / the angle of the convex portion (deg)] is 0.14 or more and 0.94 or less The base plate material of the heat exchange plate is characterized in that the unevenness of the surface of the base plate material is set. The said convex part is arrange | positioned on the surface of a flat plate in zigzag form, The base plate material of the plate for heat exchange of Claim 1 characterized by the above-mentioned. It is composed of a flat plate made of titanium with fine irregularities formed on the surface, and is a method for producing a base plate that becomes a heat exchange plate after being subjected to press processing on the flat plate as post-processing,
Concerning the irregularities, the convex portion has a circular shape in a plan view, the diameter thereof is 400 μm or more, the height of the convex portion has a 10-point average roughness of 5 μm or more, and the thickness of 0.1 × flat plate material μm or less, the pitch of adjacent protrusions is 600 μm or more, the width of the recesses is 200 μm or more, and the angle η of the protrusions is 90 ° or more,
The shape parameter defined by the height of the convex portion (μm) × [the width of the concave portion (μm) / the pitch of adjacent convex portions (μm) / the angle of the convex portion (deg)] is 0.14 or more and 0.94 or less The manufacturing method of the base plate material of the plate for heat exchange characterized by forming the said unevenness | corrugation in the surface of the said base plate material so that it may become. The said convex part is formed in the staggered arrangement | positioning on the surface of a flat plate material, The manufacturing method of the base plate material of the plate for heat exchange of Claim 3 characterized by the above-mentioned.

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