KR101647758B1 - Prefabricated Panels and Fixed Position Calculation Method of Spacer Grid - Google Patents

Abstract

A prefabricated panel, comprising: a pair of outer finishing materials having a predetermined size; a reinforcing material fixed to inner surfaces of the pair of outer finishing materials; a heat insulating material provided between the pair of reinforcing materials; The thickness of the prefabricated panel can be freely adjusted by varying the length of the spacing holder fixed between the stiffeners by providing a spacing holder which is fitted and fixed to the stiffener by interference fit. It is possible to obtain an effect that the spacing holder is easily fixed.

Description

{Prefabricated Panels and Fixed Position Calculation Method of Spacer Grid}

More particularly, the present invention relates to a method of calculating a fixed position of a panel and a gap holding tool fixed between a panel and a prefabricated panel which are lightweight but have a high thermal insulation effect and are easily assembled during assembly work, And to a method for calculating a fixed position of a spacer panel and a spacer.

In general, meat, meat, and other foods that need to be stored at low temperatures prevent freezing and deterioration in the refrigerator. Refrigerators are generally used in the case of households, and large-sized refrigerators and refrigerators are usually used in large-sized restaurants or intermediate distributors and storage companies. Since the refrigerating and freezing facilities are large in size, the heat insulating panels of a certain size are assembled into a plurality of boxes and a freezing chamber is formed therein.

Background Art [0002] Conventional technologies for heat insulating panels applied to refrigeration and freezing facilities are disclosed in Patent Documents 1 to 3 below.

[Patent Document 1] Korean Patent Registration No. 10-0678416 (published on Mar. 2, 2007) discloses a heat insulating panel for a large-sized freezer refrigerator, which comprises a hollow portion formed inside, a protruding portion formed on one side thereof, and a fastening portion formed on the other side And a panel member joined to both surfaces of the fixing member. A first inclined surface formed to be inclined with respect to the projection of the fixing member, a second inclined surface formed in close contact with the first inclined surface in the fastening portion of the fixing member, and a second inclined surface formed between the protruding portion and the fastening portion as the first inclined surface and the second inclined surface are in close contact with each other. Thereby forming a space portion.

The heat insulating panel made of such a structure can be easily assembled by forming an inclined surface on the protruding portion and the fastening portion of the fixing member formed for assembling between the panels and a sufficient airtight structure .

Patent Document 2: Utility Model Registration No. 20-0168014 (published on Feb. 15, 2000) discloses a refrigeration panel for a refrigeration cabinet, in which foam-molded fixing members are disposed on the rims of upper and lower panel members, respectively, A plurality of protrusions and a plurality of fastening grooves are formed in the fastening member so that the fastening members can be coupled with the different freezing panels in a fitting manner.

The frozen panel produced with this structure increases the heat insulation effect and improves the productivity.

[Patent Document 3] Korean Utility Model Registration No. 20-0437928 (2008.01.08. Announcement) is a panel assembly for refrigeration and freezing, which forms a base portion with HIPS (High Impact Polystyrene) to increase strength and improve durability And a sealing member made of resin is formed to improve airtightness.

Korean Registered Patent Registration No. 10-0678416 (Notice of February 2, 2007) Korea Registered Utility Model Registration No. 20-0168014 (Notice of February 15, 2000) Korea Registered Utility Model Registration No. 20-0437928 (2008.01.08 Notice)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method of calculating a fixing position of a panel and a gap holding member provided with adjusting intervals (lengths) of stiffeners between external finishing materials fixed to both sides.

Another object of the present invention is to provide a method of calculating a fixed position of a prefabricated panel and a spacing holder, which are firmly fixed by interference fit of a reinforcement between external finishes.

In order to achieve the above object, the prefabricated panel according to the present invention comprises a pair of outer finishing materials having a predetermined size, a reinforcing material fixed to inner surfaces of the pair of outer finishing materials, a heat insulating material And a gap retaining hole formed in the reinforcement member so as to be fixedly inserted into the reinforcement member while keeping the gap between the pair of reinforcement members variable.

And a side surface finishing material that is fitted and fixed to an edge of the outer surface finishing material.

The spacing member may include a pair of side plates in a triangular or rhombic shape,

And a gap adjuster for varying the length of the pair of side plates.

Wherein the short adjuster comprises a tubular body fixed to the pair of side plates by a predetermined length and having a plurality of holes at regular intervals, the tubular body having a first tubular body having a predetermined diameter and a second tubular body having a smaller diameter than the first tubular body, And a two-tube body.

And the second tubular body is movably coupled to the inner diameter of the first tubular body.

And the reinforcing member is formed in such a manner that a triangular or rhomboid fitting portion is alternately arranged.

Wherein the outer finishing material is made of one of a metal and a plastic sheet, and the reinforcing material and the gap maintaining member are formed of any one of metal casting and plastic injection molding.

According to another aspect of the present invention, there is provided a method of calculating a fixed position of a prefabricated panel spacing holder, comprising the steps of: (a) dividing a region of a prefabricated panel into a finite number of elements connected to each other at a node; (C) combining the stiffness matrix and the load vector with respect to the entire prefabricated panel, (d) determining a boundary condition of the prefabricated panel or (E) interpreting the degree of freedom of the entire area of the prefabricated panel, (f) transforming the joint displacements of the prefabricated panel into degrees of freedom for each element to determine stresses, And analyzing the member forces statically.

In the step (f), the prefabricated panel calculates a fixing position of the gap holding tool on the prefabricated panel by applying compressive force on one side or three sides.

As described above, according to the prefabricated panel according to the present invention, the thickness of the prefabricated panel can be freely adjusted by varying the length of the spacing member fixed between the stiffeners, and the spacing member is fixed to the fitting portion of the reinforcing member, An effect that the sphere can be easily fixed can be obtained.

According to the fixed position calculating method of the prefabricated panel spacing holder according to the present invention, it is possible to more firmly support the reinforcing member by fixing the fixing position of the spacing member fixed between the reinforcing members according to the stress analysis, It is possible to reduce the number of the space-retaining members to be installed.

1 is an exploded perspective view of a prefabricated panel according to a preferred embodiment of the present invention,
FIG. 2 is an exploded perspective view showing a state in which a gap holding hole is fixed to a prefabricated panel according to a preferred embodiment of the present invention, FIG.
FIG. 3 is an exploded perspective view showing a cavity-retaining aperture of a prefabricated panel according to a preferred embodiment of the present invention,
4 is a side view of a prefabricated panel according to a preferred embodiment of the present invention,
5 is a front view of a prefabricated panel according to a preferred embodiment of the present invention,
6 is a process diagram for explaining a step of calculating a fixing position of a gap holding member fixed to a prefabricated panel according to a preferred embodiment of the present invention.
7 is a view for explaining a stress analysis for calculating a gap holding hole fixing position of a prefabricated panel according to a preferred embodiment of the present invention.
8 is a view showing a state where a prefabricated panel according to a preferred embodiment of the present invention is subjected to stress,
9 is a view showing a deformed state according to a stress applied to one surface of a prefabricated panel according to a preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a prefabricated panel according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is an exploded perspective view of a prefabricated panel according to a preferred embodiment of the present invention, FIG. 2 is an exploded perspective view showing a state in which a spacing holder is fixed to a prefabricated panel according to a preferred embodiment of the present invention, Fig. 5 is an exploded perspective view showing a gap maintaining hole according to a preferred embodiment of the present invention.

The prefabricated panel according to the preferred embodiment of the present invention includes a pair of outer finishing materials 10 having a predetermined size, a reinforcing material 20 fixed to the inner surface of the pair of outer finishing materials 10, And a spacing holder 40 which is fixedly inserted into the stiffener 20 while keeping a gap between the pair of stiffeners 20. [

The prefabricated panel of the present invention is used as a heat insulation panel of a refrigerator and a refrigerator. That is, it is fixed to a wall surface of a freezing warehouse or a refrigerator and a wall surface of a ceiling or the like so as to keep the refrigerated state in the warehouse sealed for a long period of time and to keep the stored food at a low temperature safely .

The prefabricated panel of the present invention is preferably provided with a pair of outer finishing materials 10 having a predetermined size and the outer finishing material 10 is formed of one of metal and plastic sheets.

A stiffener 20 having a predetermined thickness is provided on the inner surface of the outer finishing material 10. The reinforcing member 20 has a predetermined thickness, and the fitting portion 21 is formed so that the gap holding hole 40 is fitted and fixed.

The fitting portion 21 is formed so as to stably fit the gap holding tool 40 at a desired position or a fixed position. As shown in FIGS. 1 to 3, the fitting portion 21 has a triangular shape, and is formed in any one of a quadrangle other than a triangle, a rhombus (including a diamond shape), and a hexagon shape.

In addition, the fitting portion 21 is arranged so that triangular or rhombic shapes are alternately arranged in a row, and when the triangular shape is formed, the fitting portions 21 are alternately formed. Further, even when the fitting portion 21 is in a rhombic shape, the fitting portions 21 are continuously arranged in a line so as to be interlocked with each other.

That is, the fitting portion 21 is continuously arranged with a certain distance in the lateral direction and the longitudinal direction of the stiffener 20, So as to be fixed at a predetermined position calculated to fix the optical fiber.

The reinforcing member 20 is formed of any one of metal casting and plastic molding to reinforce the strength so that the outer finishing material 10 having a relatively thin thickness is stably fixed.

A heat insulating material 30 is preferably provided between the reinforcing materials 20 and the heat insulating material 30 is preferably formed by laminating a plastic thin film or aluminum thin film or plastic net made of plastic Do. In particular, it is more preferable that the plastic thin film and the mesh are alternately laminated.

Further, the prefabricated panel of the present invention is provided with a spacing holder 40 for adjusting the spacing of the stiffener 20. The spacing holder 40 is fitted and fixed to the fitting portion 21 of the stiffener 20 and adjusts the spacing of the stiffener 20 when the thickness of the prefabricated panel is to be different if necessary.

3, the gap holding tool 30 has a side plate 41 and a side plate 41, which are fixed to both sides of the fitting portion 21 by being fitted to the fitting portions 21, 42). The gap adjusting member 42 is formed of a tubular body having a predetermined length on one side of each of the side plates 41, and these tubular bodies include holes 45 formed at regular intervals.

That is, the tubular body includes a first tubular body 43 formed on one side of the side plate 41 and a second tubular body 44 formed on one side of the other side plate 41.

3 (a), the gap holding tool 40 may be formed in a triangular shape like the fitting portion 21, or may be formed in such a manner that each vertex portion of the triangle is formed with a predetermined diameter As shown in Fig.

Needless to say, the gap holding hole 40 is provided with a fixing pin (not shown) to be inserted into the hole 45. The fixing pin is fitted and fixed to the hole 45 in a state in which the length of the gap holder 40 is adjusted, thereby stably maintaining the variable length of the gap holder 40.

The side plate 41 is fixed to the fitting portion 21 by interference fit and has the same shape as the fitting portion 21, that is, when the fitting portion 21 is triangular, It may be formed in a rhombic shape.

Each of the side plates 41 is formed in the same shape as the fitting portion 21 so that each of the side plates 41 can be pressed against the fitting portion 21 or each corner portion is formed into a circular arc having a constant diameter .

The prefabricated panel is also provided with a side finishing material 50. 2 and 4, the side surface finishing material 50 is provided with a protruding portion 51 which is fitted into the inside of the reinforcing material 20 and covers the both side ends of the reinforcing material 20 and the external finishing material 10 The extension portion 52 extends in a predetermined width so as to cover or cover the opening portion.

The side surface finishing material 50 is sandwiched between a pair of stiffeners 20 and the side surface finishing material 50 is fixed to the square surface of the prefabricated panel or fixed to the edge of the wall surface of the freezing or cold storage, Can be fixed.

That is, the side finishing material 50 is selectively secured to the prefabricated panel adjacent to the wall edge of the refrigeration or refrigeration warehouse.

Next, the coupling relationship of the prefabricated panel according to the preferred embodiment of the present invention will be described in detail.

The prefabricated panel of the present invention is made of either a metal or a plastic sheet and has a relatively thin thickness. In addition, the reinforcing material 20 is formed of any one of metal casting and plastic injection molding, and its thickness is 5 to 10 mm.

It is needless to say that the thickness of the reinforcing member 20 is set so as to be stably fixed in a state where the gap holding tool 40 is fitted, and the thickness of the reinforcing member 20 can be made thicker.

Further, the fitting portion 21 is formed in the shape of a triangle, a quadrangle, a rhombus, or the like. The fitting portions 21 are continuously formed in a row so as to be able to fix the gap holding tool 40 at a predetermined position according to a desired position or a stress analysis.

That is, the fitting portion 21 is continuously formed in a row in the transverse direction and the longitudinal direction with respect to the entire surface of the stiffener 20.

A heat insulating material 30 is provided between the stiffeners 20. The heat insulating material 30 may be filled between the stiffeners 20 spaced apart at regular intervals or may be formed to have a predetermined thickness and be inserted between the stiffeners 20. [ As the heat insulating material, organic or inorganic insulating materials such as polystyrene, glass surface, rock surface, foamed polyethylene, polyurethane foam and the like can be used.

Also, a plurality of holes (not shown) may be formed at predetermined positions in the heat insulating material 30 having a predetermined thickness so as to penetrate the gap holding tool 40.

The gap holding tool 40 is formed of a pair of side plates 41 having the same shape as the fitting portion 21 of the stiffener 20 and fixed to the stiffener 20 spaced at a certain distance.

Each of the pair of side plates 41 is formed with a gap adjusting member 42 having a predetermined length and the gap adjusting member 42 is a circular tube member. 43, and the second tube 44 is formed on the other side plate 41.

The first tubular body 43 is formed in a circular shape having a predetermined diameter and the second tubular body 44 is fitted on the inner surface of the first tubular body 43 so as to be slidable. And the length of the second tubular body 44 can be varied to easily adjust the interval of the stiffener 20. [

A plurality of holes 45 are formed in these tubes 43 and 44 at regular intervals. Each of the side plates 41 is formed to have the same size as the fitting portion 21 and is made to be inseparable, and each corner is formed into a round shape so as to facilitate detachment.

The side surface finishing material 50 covers each side surface of the assembled panel and forms a protrusion 51 protruding to fit into the inner surface of the stiffener 20. The outer surface finishing material 10 and the reinforcing material 20 are covered with an extended portion 52.

The projecting portion 51 and the extending portion 52 are integrally formed.

FIG. 6 is a process diagram for explaining steps of calculating a fixed position of a prefabricated panel-interval holding tool according to a preferred embodiment of the present invention.

FIG. 6 is a process diagram for explaining a step of calculating a fixing position of a gap holding member fixed to a prefabricated panel according to a preferred embodiment of the present invention. FIG. FIG. 7 is a view showing a stress analysis for calculating a fixing position of a gap holding hole of a prefabricated panel according to a preferred embodiment of the present invention. FIG.

6 and 7, a method for calculating the fixed position of a prefabricated panel space retaining tool includes the steps of (a) dividing the area of the prefabricated panel into a finite number of elements connected to each other at a node, (b) (C) combining the stiffness matrix and the load vector with respect to the entire prefabricated panel, (d) combining the stiffness matrix with the load vector at the boundary condition or initial condition of the prefabricated panel, (E) analyzing the degree of freedom of the entire area of the prefabricated panel, (f) transforming the joint displacements of the prefabricated panel into degrees of freedom for each element, .

The entire area of the prefabricated panel is discretized into finite elements connected to each other at the nodes (S10).

The division into these elements is accomplished by locating the nodes and establishing connectivity between the elements.

Information such as the type and number of elements composing the prefabricated panels, the number of nodes, the boundary conditions and the characteristic values of the materials according to the types of elements and the node numbers in the elements are required for calculation of the next step.

The element stiffness matrix for each divided element and the load vector applied to the node of the element are constituted (S20).

The stiffness matrix is a matrix showing the relationship between the node displacement and the external force expressed in the local table in the element, and represents the relationship between the node displacement expressed by the global coordinates (x, y, z) and the force in the global coordinate system.

Also, since the load vector can be defined only at each node, all types of external forces are converted into node loads. In other words, various types of external forces are calculated as node loads.

These load vectors include initial strain, volume force, surface force, or distributed load, and the initial strain is a strain already existing before the deformation of the member due to the external force. The deformation is caused by the temperature expansion and contraction, Shape. That is, since the deformation does not cause stress, the stress in the element becomes a function of the elastic strain.

The volume force is the load per unit volume, which is the energetic volume force and the dynamic volume force. The surface force or the distribution load has a work equivalent load and a static equivalent load.

The equivalent equivalent load means that the load converted into the distributed load and the crystal load has the same amount of work under the virtual displacement, and the static equivalent load means that the load converted into the distributed load and the node load becomes the energetic equilibrium .

The stiffness matrix obtained for each element of the prefabricated panel and the load vector are combined (S30).

Such a combination is a combination of elemental equations to form a whole matrix, as well as a boundary condition, which is used to form a determinant in a combined global coordinate system using the principle of superposition.

In other words, the joint load vector in the global coordinate system consists of the stiffness matrix and unknown or known node displacement in the global coordinate system of the prefabricated panel. In addition, the boundary condition is a singular matrix in which the value of the stiffness matrix becomes 0 in the entire coordinate system. In order to eliminate such a singularity, a boundary condition (constraint or support) is imposed.

At the end of the process, the finite element equations for the entire area of the prefabricated panel, namely the simultaneous equations for load-displacement, are constructed.

Since there are a boundary condition or an initial condition of the prefabricated panel, these conditions are obtained (S40).

These simultaneous equations are modified by reflecting the simultaneous equations obtained by these conditions.

The degrees of freedom of the entire area of the prefabricated panel are analyzed according to the simultaneous equations obtained in step S40 (S50).

The static analysis procedure is performed by the finite element method of the prefabricated panel by converting the node displacements of the assembled panel thus obtained into the joint point displacements (degrees of freedom) for each element and obtaining the stress or member force of each element (S60).

The prefabricated panel is subjected to a compressive force on one side or three sides to calculate the fixing position of the gap holding tool in the prefabricated panel.

Fig. 7 is a view according to a stress analysis for calculating a fixing position of a gap holding hole in a panel of a prefabricated panel. Thus, the gap holding tool 40 is fixed to a portion where stress is concentrated on the prefabricated panel.

That is, the spacing holder 40 is fixed to a portion of the reinforcing member 20 which is about 1/3 of the entire length of both sides of the reinforcing member 20. Accordingly, all of the four spacing holders 40 are fixedly fitted to the fitting portion 21 of the reinforcing member 20 in the prefabricated panel.

It is a matter of course that as the size of the prefabricated panel is increased or decreased, the fixing position of the gap holder 40 can be changed.

FIG. 8 is a view showing a state where stress is applied to a prefabricated panel according to a preferred embodiment of the present invention, and FIG. 9 is a view showing a deformed state according to stress applied to one surface of a prefabricated panel according to a preferred embodiment of the present invention.

As shown in FIG. 8, the stiffener 20 of the prefabricated panel of the present invention shows a state in which an external force is applied to calculate the fixed position of the strength or spacing holder 40 according to the stress applied from the external force.

Fig. 9 shows a state in which the stiffener 20 of the prefabricated panel is deformed as an external force is applied in Fig. 9, an external force may be applied to one surface to grasp the degree of deformation of the stiffener 20. An external force may be applied to three surfaces and all surfaces of the stiffener 20 as well as one surface thereof, The fixing position of the sphere 40 can be appropriately calculated.

Although the present invention has been described in detail with reference to the above embodiments, it is needless to say that the present invention is not limited to the above-described embodiments, and various modifications may be made without departing from the spirit of the present invention.

10: exterior finish 20: stiffener
21: fitting portion 30: insulating material
40: spacing holder 41: side plate
42: gap adjusting member 43: first tube member
44: second tube 45: hole
50: side surface finishing material 51:
52: Extension part

Claims (9)

A pair of exterior finishes having a certain size,
A pair of reinforcing members fixed to the inner surface of the pair of outer finishing materials,
A heat insulating material provided between the pair of reinforcement members,
And a spacing holder for holding the pair of stiffener spacings in a variable state and being fixedly fitted to the stiffener by interference fit,
And a side surface finishing material that is fitted and fixed to an edge of the outer surface finishing material,
Wherein the spacing holder comprises a pair of side plates in a triangular or rhomboid shape, and spacing adjusters that vary in length between the pair of side plates. delete delete The method according to claim 1,
The spacing adjusting member may include a tubular body fixed to the pair of side plates by a predetermined length and having a plurality of holes at regular intervals,
Wherein the tubular body includes a first tubular body having a predetermined diameter and a second tubular body having a smaller diameter than the first tubular body. 5. The method of claim 4,
And the second tube is movably coupled to the inner diameter of the first tube. The method according to claim 1,
Wherein the reinforcing member is arranged in such a manner that a triangular or rhomboidal fitting is interlaced. The method according to claim 1,
Wherein the outer finishing material is made of one of a metal and a plastic sheet,
Wherein the reinforcing member and the spacing member are formed of one of a metal casting and a plastic injection molding. (a) dividing the area of the prefabricated panel into a finite number of elements connected together at a node,
(b) constructing a divided stiffness matrix for each element and a load vector at a node of the element,
(c) combining the stiffness matrix and the load vector with respect to the entire prefabricated panel,
(d) obtaining a simultaneous equation from a boundary condition or an initial condition of the prefabricated panel,
(e) interpreting a degree of freedom for the entire area of the prefabricated panel,
(f) converting the node displacements of the prefabricated panel into degrees of freedom for each element, and statically analyzing the stress and member forces of each element,
Wherein in the step (f), the fixing position of the gap holding tool is calculated on the prefabricated panel by applying compressive force on one side or three sides of the prefabricated panel.
delete

Images