JPH03112613A - Manufacture of heat insulation material - Google Patents

Abstract

PURPOSE:To form a heat insulation plate of uniform seal structure without layers, skins or void sites by injection filling first synthetic resin agitation liquid into recessed sections of trapezoidal lines on the rear side of a metal hoop material below and spreading synthetic resin agitaion liquid into the recessed sections filled with injection of synthetic resin agitaion liquid just after said first injection and also into projected sections. CONSTITUTION:Synthetic resin agitation liquid 8 is transferred from a creamy state to the foamed state as conveyors move forward in recessed sections. A synthetic resin liquid agitator 12 for injection filling the whole face of a metal hoop material 4 below traverses as indicated by an arrow mark to form a uniform surface. Agitation liquid 8 injection filled into recessed sections is spread from the agitator 12 for coating the whole surface to recessed sections 9 and projected sections 11 in the creamy state 10. The same is entered an area between an upper face conveyor 16 and a lower face conveyor 15 by the rotation of an upper face roller 14 and a lower face roller 13, while the metal hoop material 3 is pressed and self-bonded in the given thickness between the metal hoop material 4 below a space where the synthetic resin agitation liquid 8 is foamed and filled and the upper face roller 14 and the lower face roller 13.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to a method for producing heat generating materials used for roofing members, wall members and flooring materials of buildings.

[Conventional technology]

Conventionally, as shown in Japanese Patent Publication No. 63-153368, the concave part of the lower metal hoop material was first injected and foamed, and after the foaming was completed, the space between the upper metal hoop material and the lower metal hoop material was then injected and foamed. I left insulation material for I3. This is the so-called two-stage foaming method.

[Problem that the invention seeks to solve]

In this method, the manufacturing equipment speed is 6 m/min. When using a hard urethane foam, its rise time (foaming completion time) is around 1 minute, and in the case of two-stage foaming, it is necessary to inject and fill with a stirring injection machine after about 6 m. There are two stirring injection points separated by more than 61I1, and problems remain in terms of cost and location. Apart from cost considerations, since two-stage foaming is performed after injection and foaming into the recesses, a skin layer is generated on the surface of the injection and foaming into the recesses. For this reason, there is a drawback that the adhesive force between the foams (11 foam and 2nd foam) becomes weak and the structural strength is inferior.

[Means of solution]

The inventors have arrived at the present invention as a result of their earnest efforts to produce a foamed heat insulating material without a skin layer by bringing the stirring injection machine as close as possible. Even if you simply traverse (repeatedly cross) multiple stirring injectors onto the metal hoop material below,
The depressions of the trapezoidal veins are not filled with sufficient liquid, leaving voids, and a skin layer is formed on the surface of the voids. The present invention was developed in order to solve the problems of skin layer formation and insufficient foaming in recessed areas.

That is, in the present invention, a lower metal hoop material is continuously supplied to continuously form trapezoidal veins using a trapezoidal vein forming roll, and an upper metal hoop material is continuously supplied to form the trapezoidal veins. The lower metal hoop material and the upper metal hoop material are conveyed facing each other vertically, and a plurality of independent grooves corresponding to (the same number of) the recesses are placed in the recesses on the back side of the trapezoidal veins of the lower metal hoop material. Inject into the recessed area using a stirrer and injector, make the trapezoid in a wet state (cream state, unfoamed state71), and before foaming the injection liquid, mix the lower metal hoop material and the upper metal hoop material. This method of manufacturing a heat insulating material is characterized in that the synthetic resin liquid is injected and filled into the depressions and projections on the surface of the metal hoop material below using a single or a plurality of independent synthetic resin liquid stirring and injection machines, and then foamed.

As a method of separation, a lower metal hoop material was continuously supplied to continuously form trapezoidal veins using a trapezoidal vein forming roll, and an upper metal hoop material was continuously supplied to form the trapezoidal veins. The lower metal hoop material and the upper metal hoop material are conveyed vertically facing each other, and an independent synthetic resin liquid stirrer is passed through a supply pipe to the recesses on the back side of the trapezoidal veins of the lower metal hoop material to form the number of recesses. The trapezoidal veins are pre-wetted (creamed) with synthetic resin liquid, and the injection liquid is mixed with the metal hoop material below before foaming. While traversing (repeatedly crossing) the surface of the lower metal hoop material (concave and convex portions) from multiple injection distribution pipes drilled in the supply pipe directly connected to the independent synthetic resin liquid agitator between the upper metal hoop materials. A method of manufacturing a heat insulating material characterized by injection filling and foaming is also included in the present invention.

In addition to the above two methods, it is also possible to inject and fill the concave and convex parts on the back side of the lower metal hoop material from an independent single or multiple synthetic resin liquid agitator, or from an independent synthetic resin liquid agitator. A plurality of independent synthetic resin liquids corresponding to the recesses are injected and filled from a plurality of injection distribution pipes drilled into the supply pipe, and the synthetic resin stirring liquid is sprayed over the entire surface of the lower metal hoop in a wet state. Pour through the stirrer. Alternatively, a method of injecting and filling from an independent synthetic resin liquid stirrer through a supply pipe through a plurality of injection distribution pipes bored in the supply pipe at positions corresponding to the recesses is also included in the present invention.

The present invention will be explained in detail based on the drawings.

FIG. 1 is a new surface view immediately after foaming, and 1 is the contact surface with the upper metal hoop material 3 of the upper conveyor, and 2 is the contact surface with the lower metal trapezoidal hoop material 4 of the lower conveyor. 5 is a side sealing material. Reference numeral 6 is a foamed synthetic resin heat insulating member mainly made of hard urethane foam.

In FIG. 2, independent synthetic resin liquid stirrers 7 are installed in the lower metal hoop material 4 corresponding to (the same number of) the recesses 9 of the metal hoop material, and the synthetic resin rPa stirring liquid 8 is mixed into a plurality of synthetic resin liquid stirrers 7. The stirred liquid 8 injected into the recess from the resin liquid stirrer becomes a cream state 10 as shown in the figure.

FIG. 3 is a schematic perspective view illustrating the present invention, in which the synthetic resin stirred liquid 8, which is first stirred by an independent synthetic resin liquid Wt stirrer 7, is transferred from a plurality of stirrers 7 to the corresponding lower metal hoop material. 4
The concave portion 9 is filled with injection.

The synthetic resin stirred liquid 8 changes from a cream state to a foaming state as the conveyor advances in the recessed portion. Synthetic resin liquid stirrer 12 for injecting and filling the entire surface of the lower metal hoop material 4
(in Fig. 3, there is one plane, but there may be more than one plane) traverses (crosses repeatedly) as shown by the arrow to form a uniform surface. Stirring to inject and fill the recessed part 9 of the lower metal hoop material [7
The distance of the agitator 12 that sprays the entire surface is 50c+s~20
0 cm, the stirring liquid 8 injected and filled into the recessed portion is in a cream state 10 and is sprayed onto the recessed portion 9 and the convex portion 11 from the stirrer 12 for entire surface application. and the upper roller 14
The upper metal hoop material 1 enters between the upper surface conveyor 16 and the lower surface conveyor 15 by the rotation of the lower surface roller 13, and the lower metal hoop material whose space is foamed and filled with the synthetic resin stirring liquid 8, the upper surface roller 14, and the lower surface roller. 13 to a predetermined thickness.

In FIG. 4, synthetic resin liquid is injected and filled from a synthetic resin liquid agitator 17 through a supply pipe 18 into an injection distribution pipe 19 into a concave portion 9 of a metal hoop material 4 below. The number of injection distribution pipes 19 is preferably the same as the number of recesses 9. The synthetic resin stirring liquid 20 is injected and filled into the recessed portion 9 .

FIG. 5 is a new view showing the cream state of the synthetic resin agitation injection filling liquid 21 and the state of the synthetic resin agitation whole surface spraying liquid 22 into the recessed portion of the lower metal hoop material 4.

FIG. 6 is a schematic diagram of the synthetic resin liquid agitator 23, the supply pipe 18, and the injection pipe 19 branched from the supply pipe for spraying the entire surface of the metal hoop below. The number of injection and distribution pipes 19 for the synthetic resin stirring liquid is the same as the number of convex parts of the lower metal hoop 4, or
The sum of the number of concave portions and convex portions is desirable. The supply pipe is traversed (repeatedly crossing) to inject and fill the metal hoop with the synthetic resin stirred liquid.
The synthetic resin stirring liquid 20 is sprayed onto the top from the injection distribution pipe 19.

Figure 17 shows a synthetic resin liquid stirrer 17, a supply pipe 18, and an injection distribution pipe 19 branched from it for the lower metal hoop material 4.
Injection filling into the recessed part 9 and stirring of synthetic resin liquid @23
FIG. 2 is a schematic diagram showing uniform dispersion of the synthetic resin stirring liquid from the supply pipe 18 and the injection/distribution pipe 19 branched from the supply pipe into the concave portions and convex portions which have been injected and filled in advance. The distance between the agitators 17 and 23 is preferably from 50 CI11 to 200 c+m, and the supply pipe 18 connected to the agitators 17 and 23
are each traversed (repeatedly crossing) with an operating width of 5 to 15 cs to produce a uniform foamed synthetic resin heat insulating member 6.

〔effect〕

Injecting and filling the first synthetic resin stirred liquid into the recesses of the trapezoidal veins on the back side of the lower metal hoop material, and immediately after that, injecting the synthetic resin stirring liquid into the filled recesses and convex parts. As a result of the spraying, the heated portion of the foamed synthetic resin of the heat insulating board was formed into a heat insulating board with a uniform cell structure without layers or skins and no voids.

[Brief explanation of drawings]

FIG. 1 is a new view of manufacturing the heat insulating board of the present invention. FIG. 2 is a schematic diagram showing the state of independent synthetic resin liquid stirrers in each recessed portion of the lower metal hoop material. FIG. 3 is a perspective view showing a method of manufacturing a heat insulating material using an independent synthetic resin liquid stirrer. Figure 14 shows the synthetic resin 'l! FIG. 2 is a schematic diagram illustrating injection and filling of a synthetic resin stirring liquid into a recessed portion of a trapezoidal vein on the back side of a lower metal hoop using a plurality of injection distribution pipes branched into a supply pipe connected to a stirrer. FIG. 5 is a new view showing a state in which the synthetic resin stirring liquid is injected, filled, and scattered into the concave and convex portions of the trapezoidal vein on the back side of the lower metal hoop. Figure 6 shows a synthetic resin liquid agitator connected to a single synthetic resin liquid agitator that sprays the concave and convex areas immediately after the synthetic resin agitation liquid is injected and filled into the concave parts of the trapezoidal veins on the back side of the lower metal hoop material. Schematic diagram showing tubing and multiple branched injection distribution lines. The mt diagram shows a supply pipe connected to one synthetic resin liquid stirrer that injects and fills into the recesses of the trapezoidal vein on the back side of the metal hoop material below, multiple injection distribution pipes that branch out, and recesses and protrusions. FIG. 2 is a schematic diagram showing a supply pipe connected to one synthetic resin liquid agitator for dispersing liquid into a liquid and a plurality of branched injection distribution pipes. 1. Upper conveyor 2, lower conveyor 3, upper metal hoop 4, lower trapezoidal metal hoop 5, synthetic resin stirring liquid supply pipe stopper tape (1 part sealing material) 6, foamed synthetic resin MIlli thermal member 7 , Independent synthetic resin liquid stirrer 8, Synthetic resin stirring liquid 9, Recessed part 10 of the trapezoidal vein on the back side of the lower metal hoop material, Injection filling of synthetic resin stirring liquid into the recessed part (cream state) 11, Lower part Convex part 12 of the trapezoidal vein on the back side of the metal hoop, independent synthetic resin liquid agitator 13 for dispersing the entire surface of concave and convex parts, lower conveyor roll 14, upper conveyor roll 15, lower conveyor 16, upper conveyor 17, synthetic resin liquid agitator Machine (for injecting and filling recesses) 18, Synthetic resin stirring liquid supply pipe 19, Synthetic resin stirring liquid injection distribution pipe 20, Synthetic resin stirring liquid 21, Synthetic resin stirring liquid injection filling (cream state) 22, Synthetic resin stirring liquid Spray material 23, synthetic resin liquid stirrer (for spraying all over the concave and convex areas)

Claims (2)

[Claims] (1) The lower metal hoop material is continuously supplied to continuously form trapezoidal veins using a trapezoidal vein forming roll, and the upper metal hoop material is continuously supplied to form the trapezoidal veins. The metal hoop material and the upper metal hoop material are conveyed vertically facing each other, and into the recesses on the back side of the trapezoidal veins of the lower metal hoop material, independent stirring and injection machines corresponding to the number of recesses are used. Inject into the recessed part, pre-wet the trapezoidal veins with the synthetic resin stirring liquid (cream state), and before foaming the injection liquid, place one or more metal hoops between the lower metal hoop material and the upper metal hoop material. A method for producing a heat insulating material, which comprises injecting and filling the lower metal hoop surface (recessed and convex parts) while traversing (repeatedly crossing) using a stirring injection machine, and foaming the material. (2) The lower metal hoop material was continuously supplied to continuously form trapezoidal veins using a trapezoidal vein forming roll, and the upper metal hoop material was continuously supplied to form the trapezoidal veins. The lower metal hoop material and the upper metal hoop material are conveyed vertically facing each other, and a supply pipe is passed from an independent synthetic resin liquid stirrer into the recessed part of the lower metal hoop material on the back side of the trapezoidal vein. Inject and fill from the injection distribution pipe drilled into the supply pipe corresponding to the number of injection pipes, and pre-wet the concave part of the trapezoidal vein with synthetic resin liquid (cream state), and before the injection liquid foams, the metal underneath is filled. Traverse (repeatedly crossing) the surface of the metal hoop material below (concavities and convexities) from multiple injection distribution pipes drilled in the supply pipe directly connected to the independent synthetic resin liquid agitator between the hoop material and the metal hoop material above. ) A method for producing a heat insulating material, which is characterized by injection filling and foaming.