JP2017014786A - Foundation heat insulation building - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a dewatering device enabling a heat insulator inspection work to be easily implemented for a building in which the heat insulators of a concrete foundation are stacked and the dewatering device is disposed on the heat insulators.SOLUTION: A dewatering device 11 has a body fixed on a basis 4 and a cover body 15 that is horizontally slidably mounted on the body. The body has a groove type rail part 16. The cover body 15 has a slider part 24 engaged with the groove type rail part 16 and an eves-shaped part connecting to the slider part. When inspecting a top face of an insulator 2, the insulator 2 is exposed by sliding the cover body 15.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a foundation heat insulating building in which a heat insulating material such as foamed resin is disposed on the outer surface of a concrete foundation.

  In recent years, wooden houses often have a double wall structure with an inner wall made of wood or the like and an outer wall (siding) made of ceramics, etc., and the inner wall is directly on the top surface of the concrete foundation or via a spacer for sealing. In many cases, a heat insulating material is arranged on the inner surface or the outer surface thereof. There is a ventilation space between the inner wall and the outer wall.

  And in order to improve the heat insulation inside a building, sticking the heat insulating material which consists of foamed resin to the outer surface of a concrete foundation is performed. In this case, in order to prevent rainwater from splashing on the heat insulating material, the heat insulating material is covered with a drainer from above, and the drainer is fixed to the base with a nail or a screw.

  However, there is a problem that the foamed resin constituting the heat insulating material is soft and easily damaged by white ants, and there is a demand for checking whether the heat insulating material is damaged by white ants.

  In this regard, in Patent Document 1, the drainer is configured to be separated into a portion (main body portion) fixed to the base and an inclined portion (cover portion) covering the heat insulating material, and the cover portion is defined as a longitudinal direction thereof. It has been disclosed that the body portion can be attached and detached by moving in the orthogonal width direction, thereby enabling the inspection of the heat insulating material by removing the cover portion. Patent Document 1 also discloses a configuration in which the heat insulating material can be inspected by connecting the cover portion to the main body portion with a hinge and flipping the cover portion up and turning.

Japanese Patent No. 5192279

  In Patent Document 1, the heat insulating material can be easily inspected even when the cover is removed or flipped up. In particular, when the cover part is made removable, there is no obstacle in visually recognizing the upper surface of the heat insulating material, so that the inspection becomes very easy. However, since the cover part generally has a length of about 3 m, in Patent Document 1, it is easy to remove the cover part from the main body in the system in which the cover part is moved in the width direction and attached to the main body part. Even if it exists, it is very difficult to fit in a main-body part.

  In other words, the cover portion is greatly bent and deformed by its own weight, but the fitting groove of the main body portion is the same as the plate thickness of the cover portion, so it is actually impossible to position the cover portion and refit the main body portion. Close to. There are many sites where there is little space between the adjacent buildings and people are finally entering, but in such sites, the difficulty of attaching the cover portion becomes even higher.

  On the other hand, the flip-up method in Patent Document 1 is released from the difficulty of work such as the detachable type, but rainwater may leak from the hinge part to the heat insulating material, and the function as a drainer becomes incomplete. There is another problem that is likely.

  The present invention has been made in view of such a current situation, and intends to provide a technique capable of easily inspecting a heat insulating material while ensuring the reliability of the draining function.

  In the present invention, an inner wall is constructed via a base on a concrete foundation in which a heat insulating material is arranged on an outer surface, and a ventilation interval is provided between the inner wall and the inner wall. The outer wall is arranged, and the heat insulating material is intended for a building having a basic configuration in which it is covered from above with a horizontally draining device attached to the base portion.

  And in invention of Claim 1, the said draining device has the main body fixed to the said base, and the cover body with which the said main body was mounted | worn so that it could slide to the longitudinal direction of the said main body, By sliding the cover body, a human can visually recognize the top surface of the heat insulating material.

  As a development example of Claim 1, in Claim 2, the main body is formed with a groove-type rail portion having an opening groove in the downward direction over the entire length, while the cover body has the groove-type rail portion. An upward flange-like slider portion that fits into the downward opening groove is formed over the entire length.

  The invention of the present application also includes an improved technique of a flip-up rotation type configuration. This technique has the same basic configuration as that of claim 1, and the feature is that, as described in claim 3, the draining device is an extruded product of resin, and a main body fixed to the base, and A cover portion that covers the heat insulating material from above in a state of being integrally connected to the main body, and is a thin-walled hinge portion that is raised upward on the cover portion so that the upper surface of the heat insulating material can be visually recognized. Is formed over the entire length by forming a long groove on the lower surface.

  In the first aspect of the present invention, for example, when only one cover body exists corresponding to one wall of a building, first, the cover body is removed and the heat insulating material can be inspected. In this case, the removed cover body needs to be re-fitted to the main body after inspection of the heat insulating material. However, since the end surface of the cover body and the end surface of the main body have a slight size (area), the fitting is easy. . Therefore, the cover body can be easily reattached to the original state.

  Also, for example, if there is only one cover body corresponding to one wall of the building, keep the edge part slightly fitted in the main body without removing the cover body, and check in that state Can do. In this case, even if the end portion of the cover body slightly covers the heat insulating material, since the area covered by the end portion of the cover body is very small, it can be easily peeked. That is, the inspection can be performed reliably.

  When the inspection is completed, the cover body may be pushed back to the original state. In this case, since the fitting of the cover body to the main body is maintained, the pushing back can be performed very easily. Therefore, it can be said that it is actually excellent to inspect the cover with the end of the cover fitted in the main body.

  Next, a case where a plurality of cover bodies exist corresponding to one wall of the building (that is, a case where the cover body is divided into a plurality of lines with respect to the main body extending in a straight line) is taken as an example. Also in this case, the inspection work is divided into a case where the inspection is performed by removing the end cover, and a case where the end portion is held in a state fitted to the main body while the end cover is slid largely.

  And even if it removes the cover of an end, it slides large and leaves only the edge part in the state fitted to the main body, In any case, the part covered with the cover of the end can be inspected. Next, by sliding the remaining cover body, it is possible to inspect the portion that has been borne by the remaining cover body, but in this case, the remaining cover does not need to be removed and can simply be slid. Therefore, the work of returning the group of cover bodies after inspection can be easily performed.

  As in the embodiment, if each cover body is set to the same length, or the cover at one end is set to be slightly longer, the end is attached to the main body without completely removing the cover at one end. Since the exposed space can be formed substantially the same as the remaining cover body while being fitted together, the ease of inspection is further ensured.

  According to the first aspect of the present invention, since the cover body and the main body can be easily fitted in a state in which the sealing property is secured, a high seal can be secured. In particular, if the configuration of claim 2 is adopted, rainwater does not fall on the heat insulating material even if the cover body can be slid lightly with the fitting portion between the cover body and the main body being rough, so that it is particularly suitable. It is.

  In addition, when a cover body is divided into a plurality of parts with respect to a main body extending in a straight line, adjacent cover bodies can be connected while securing sealing properties by using a connecting member as exemplified in the embodiment. Accordingly, there is no problem with the sealing performance.

  If the structure of Claim 3 is employ | adopted, it can check easily by flipping up a cover part, However Since the cover body is the whole structure and the hinge part is formed by thinning, the problem of sealing performance Does not occur at all. In addition, since the thin portion is formed by forming the long groove on the lower surface, water does not accumulate on the upper surface of the cover portion, and there is no problem in drainage performance.

  The structure in which the inner wall is built on the base is often used in wooden houses, but white ants are a problem in wooden houses. In this regard, when ant-preventive material is mixed in the heat insulating material, the invasion of white ants can be prevented and the quality of the house can be greatly improved. And if it can be confirmed by periodic inspection that the heat insulating material is not damaged by white ants, it is very preferable, and it can be said that it can also contribute to the spread of the ant-proof heat insulating material. In this regard, in the present invention, even when the interval between buildings is narrow, the state of the heat insulating material can be easily inspected without impairing the function of the water draining device, so that it can greatly contribute to the spread of the ant-proof heat insulating material. Yeah.

It is a vertical side view of 1st Embodiment. (A) is a principal part enlarged view of FIG. 1, (B) is a typical top view which shows the example of arrangement | positioning of the draining device in a building. It is a figure which shows the connection structure of a cover body, (A) is a separate top view, (B) is a top view in the connected state. (A) is a cross-sectional view taken along the line IVA-IVA in FIG. 3 (B), and (B) is a cross-sectional view taken along the line IVB-IVB in FIG. 3 (B). It is a top view which shows the connection structure in the protruding corner part of a building. It is a figure which shows the example of an inspection procedure. It is principal part sectional drawing of 2nd Embodiment. It is the isolation | separation partial front view of 3rd Embodiment which is a connection structure example of a main body. It is principal part sectional drawing of 4th Embodiment. It is principal part sectional drawing of 5th Embodiment. It is sectional drawing of 6th Embodiment which is a specific example of Claim 4.

(1). Outline of First Embodiment Next, an embodiment of the present invention will be described with reference to the drawings. First, the structure of the first embodiment shown in FIGS. In the following description, the front / rear / left / right wording is used to specify the direction. As shown in FIG. 2 (B), with reference to one target wall, the direction toward the wall is changed to the front / rear direction. The horizontal direction facing the wall is defined as the action direction. The front view is the direction facing the wall. Since FIG. 1 is a longitudinal side view, the direction orthogonal to the paper surface is the left-right direction.

  In FIG. 1, the main part of a building (a wooden house) is displayed. The building has a concrete base 1 erected on the ground. On the outer surface of the concrete base 1, a heat insulating material 2 made of a foamed resin such as foamed polystyrene is overlaid. The upper surface of the heat insulating material 2 is flush with the upper surface of the concrete foundation 1.

  The heat insulating material 2 is non-detachably joined to the concrete foundation 1 by bonding with an adhesive or by integrating the heat insulating material 2 inside the mold and placing concrete. In addition, although the protective layer like a mortar layer is formed in the outer surface of the heat insulating material 2, it is abbreviate | omitting in the figure.

  In this embodiment, the heat insulating material 2 is mixed with an anti-anticide. As the termite-proofing agent, a neonicotinoid type such as thiamethoxam is suitable, and for example, it can be produced by the method described in Japanese Patent No. 5235666. Of course, various methods can be used for producing the ant-proof heat insulating material and the ant-proofing agent to be used.

  Examples of other anti-anticide components other than neonicotinoid drugs other than thiamethoxam include imiductopride, acetamiprid, clothianidin, dinotefuran and the like. Examples of other chemical anti-ants include pyrethroids vermethrin, tralomethrin, bifenthrin, ciphenothrin, praretrin, non-ester pyrethroid etofenbrox, silafluophene, phenylpyrrole chlorfenapyr, phenylpyrazole fipronil, Examples of carbamates include fenocarb. Natural products can be used.

  On the top surface of the concrete base 1, a wooden base 4 made of wood is placed with a resin seal spacer 3 interposed therebetween, and the base portion 5 is constituted by the seal spacer 3 and the base 4. Has been. Moreover, although illustration is abbreviate | omitted, on the base 4 is an inner wall which consists of a pillar, a wall panel, etc. Outside the inner wall, outer wall materials (siding) 6 such as ceramics and cement are arranged in multiple stages.

  The lower end of the outer wall material 6 is substantially the same height as the lower end of the base 4, and therefore, a gap 7 having an interval as large as the thickness of the seal spacer 3 is provided between the outer wall material 6 and the heat insulating material 2. Is vacant. When the seal spacer 3 is not provided or when the seal spacer 3 is sheet-like and thin, the lower end of the outer wall material 6 is positioned above the lower end of the base 4.

  Between the inner wall / base 4 and the outer wall material 6, a ventilation layer 8 with a slight gap is vacant. Further, a moisture-proof sheet 9 is overlapped on the outer surface of the inner wall, and the moisture-proof sheet 9 is pressed and fixed to the inner wall by a vertically long pressing member 10. The pressing members 10 are arranged at appropriate intervals in the lateral direction, and the outer wall 6 is in a state where it overlaps the outer surface of the pressing member 10.

  The heat insulating material 2 is covered from above with a horizontal draining device 11. This prevents rainwater from being applied to the heat insulating material 2 and allows condensed water that has flowed down through the moisture-proof sheet 9 to escape to the ground. The draining device 11 includes a main body (rail) 12 that overlaps the outer surfaces of the base 4 and the seal spacer 3 and a cover body 13 that is attached to the main body 12. In FIG. 1, the main body 12 is disposed with the lower end portion of the moisture-proof sheet 9 turned, but the lower end portion of the moisture-proof sheet 9 may be pressed and fixed by the main body 12.

(2) Main body of draining device The main body 12 is manufactured by bending a rust-proof metal plate such as a stainless steel plate, for example, and as shown in FIG. The groove-shaped rail portion 16 having a dovetail groove formed by the upward opening portion 15 is formed. Therefore, the groove-shaped rail portion 16 opens outward. The vertical width of the downward opening 14 is slightly larger than the vertical width of the upward opening. This is to prevent rainwater from entering, but these dimensions can be set arbitrarily.

  A forward upward lip 17 is formed at the opening edge of the downward opening 14, and a forward lip 18 is formed at the opening edge of the upward opening 14. These upper and lower lips 17 and 18 are inclined so as to become lower toward the front. The upper and lower lips 17 and 18 also have a reinforcing function.

  A portion of the main body 12 above the groove-type rail portion 16 is a two-layer overlapping portion 19, and the front and rear plates constituting the two-layer overlapping portion 19 are integrally joined by spot welding. And the screw hole 21 for fixing with the screw | thread 20 in the 2 sheet | seat overlap part 19 is left | separated at the space | interval with the right-left direction suitably. The screw 20 shown in the figure uses a countersunk screw, but other types of screws such as a pan head may be used. The main body 12 can also be nailed.

  Further, as shown in FIG. 2 (A) only by the dashed line 22, the groove-type rail portion 16 can be fixed to the seal spacer 3 with the screw 22 at the position of the opening. As the screw 23 in this case, it is preferable to use a countersunk screw whose head is not exposed in front of the grooved rail portion 16. In order to ensure high mounting strength, the main body 12 is preferably fixed to the base portion 5 at a location where the height is different.

(3). Cover body and connecting member of draining device As shown in FIG. 1 as a whole, the cover body 13 is located on the slider part 24 that enters the grooved rail part 16 of the main body 12 and the heat insulating material 2. It is composed of a hook-like portion 25 that is gently inclined toward the front and a downward wall portion 26 provided at the front end of the hook-like portion 25. The downward wall portion 26 enters below the heat insulating material 2. The cover body 13 of this embodiment is an extruded product of synthetic resin, and the whole is integrally connected. The upper end and the lower end of the slider portion 24 are rounded.

  In the drawing, the slider portion 24 is drawn in a state of being fitted tightly to the groove-type rail portion 16, but actually, between the slider portion 24 and the groove-type rail portion 16, in the vertical direction and the front-rear direction. A slight gap (clearance) is provided. For this reason, the cover body 13 can be slid easily (this point is the same also in other embodiments). In order to further improve the slidability, left and right longitudinal ribs and grooves may be formed on the front surface, the rear surface, or both front and rear surfaces of the slider portion 24. It is also possible to apply a lubricant that does not deteriorate over time, such as grease, to the overlapping surface between the slider portion 24 and the grooved rail portion 16.

  FIG. 2 shows the outer shape of the building, and the draining device 11 is arranged on each wall excluding the entrance 27. When the horizontal width of each wall (side) is short (for example, within 1.5 m), the cover body 13 of the draining device 11 is configured as a single unit, but if the horizontal width of the wall becomes larger than a certain level, The device 11 is composed of a plurality of cover bodies 13 arranged in a line. Therefore, it is necessary to connect adjacent cover bodies 13. Further, it is also necessary to connect the cover body 13 in an orthogonal posture at the corner of the building (outside corner, inset). Examples of connecting members for this purpose are shown in FIGS.

  3 and 4 show an example of the straight-line connecting member 28 for connecting the cover bodies 13 arranged in series (see also FIGS. 1 and 2A). The straight line connecting member 28 is basically formed on the outer surface portion 29 that overlaps the flange-like portion 25 and the downward wall portion 26 of the cover body 13 from the outside, and on the flange-like portion 25 and the downward wall portion 26 of the cover body 13. It is comprised by the inner surface part 30 which overlaps from the inner side, Therefore, both the inner surface part 29 and the outer surface part 30 have an inclination part and a downward part. The straight-line connecting member 28 of the present embodiment is an injection-molded product made of synthetic resin, and is integrally connected to the inner surface 29 and the outer surface 30 at the lower end of the downward portion.

  As shown in FIG. 3 (B), in the state where the cover bodies 13 are arranged in series, as shown in FIG. 3 (B), the hook-like portions 25 and the downward wall portions 26 of the adjacent cover bodies 13 are separated from each other. The end faces are set to contact each other. However, when the entire end surface of the hook-shaped portion 25 is brought into contact with each other, the inner surface portion 29 and the outer surface portion 30 of the linear portion connecting member 28 are freely separated from each other. Neither the clamping function nor the sealing function can be expected. However, this increases the size of the connecting member 28 for the straight portion, and the appearance is not good.

  Therefore, in the present embodiment, the inner surface portion 29 and the outer surface portion 30 are connected by the bridge portion 31 at the front and rear intermediate portions of the inclined portion, while the collar portion 25 of the cover body 13 is prevented from colliding with the bridge 31. A notch 32 is formed. Thereby, the connection member 28 for linear parts can connect the cover bodies 13 firmly, making the whole the thin structure which follows the cover bodies 13. FIG. The bridge portion 31 is located at the left and right intermediate portion of the linear portion connecting member 28. It is also possible to fix the straight line connecting member 28 and the cover body 13 with screws.

  Further, leg portions 33 that contact the upper surface of the heat insulating material 2 protrude downward from the left and right intermediate portions of the straight line connecting member 28. Thereby, it is possible to prevent the cover body 13 from falling and improve the stability. It is also possible to provide the cover body 13 with an upward stopper that is in contact with or close to the lower end of the outer wall material 6.

  As shown in FIG. 2 (A), the rear end portions of the inner surface portion 29 and the outer surface portion 30 of the linear portion connecting member 28 are formed between the flange portion 25 of the cover body 13 and the forward facing lips 17 and 18 of the main body 12. It is set to fit in between. Thereby, the clamping function of the cover body 13 by the connecting member 28 for linear parts improves, and a sealing performance becomes still more reliable. Further, the rear ends of the inner surface portion 29 and the outer surface portion 30 are formed in a wedge shape (tapered shape) so that the insertion between the flange-shaped portion 25 and the forward-facing lips 17 and 18 becomes smooth.

  In FIG. 5, the connecting member 35 for the projected corner portion disposed at the projected corner portion of the building is indicated by a one-dot chain line. The corner connecting portion 35 is different from the straight portion connecting member 28 in that the shape in plan view is L-shaped in plan view, and the basic structure is the same as that of the straight portion connecting member 28. It is.

  However, since the end faces of the cover bodies 13 adjacent to each other are not in contact with each other at the exit corner portion, and the square space is vacant, the bridge portion 31 is adjacent to the connecting member 31 for the exit corner portion. It has a quadrangular shape corresponding to the space between the end faces of the cover body 13. Note that the end faces of the adjacent cover bodies 13 are not in contact with each other (not abutted) at the corner of the protruding corner because the cover bodies 13 cannot be slid when they abut each other.

  The connecting member at the corner of the corner is also formed in an L shape in plan view, and basically has the same structure as the connecting member 28 for the straight portion. However, since the end surfaces of the adjacent cover bodies 13 abut each other at the corner of the entrance corner, a notch 32 is formed at the end of the cover body 13, and the bridge portion 31 is small enough to fit into the notch 32. It is a thing.

(4). Summary When the draining device 11 for one wall is composed of only one cover body 13, the cover body 13 should be pulled out largely after removing the connecting member 31 for the corner section. As shown in FIG. 6E, the upper surface of the heat insulating material 2 can be visually recognized. Thereby, it can be checked whether the heat insulating material 2 is damaged by the white ants.

  In this case, it is not necessary to completely remove the cover body 13 from the main body 12, and a part of the cover body 13 may be left fitted in the main body 12. This is because there is a slight gap between the cover body 13 and the heat insulating material 2, so that the upper surface of the heat insulating material 2 can be seen even if it is fitted to some extent. Then, by leaving the end portion fitted to the main body 12, it is only necessary to push back the cover body 13 after the inspection, so that the operation of returning the cover body 13 can be performed very easily.

  6 (A) to 6 (D) show an example of an inspection method in the case where one draining device 11 is constituted by three cover bodies 13 at one wall portion. First, in this example, of the three cover bodies 13, the left two cover bodies 13 have the same length L1, and the right end cover body 13 has a slightly longer length L2.

  First, as shown in (B), the right end cover body 13 is largely slid in the pulling direction so that only the end portion is fitted to the main body 12, so that the right end cover body of the heat insulating material 2 is placed. Check the part covered with 13.

  Next, as shown in (C), the portion of the outer wall material 6 covered with the central cover body 13 is inspected by shifting the central cover body 13 to the right. Next, as shown in (D), the portion of the heat insulating material 2 covered with the left cover body 13 is inspected by shifting the left end cover body 13 to the right. When the inspection is completed, the cover body 13 is returned in order from the left end cover body 13 and the adjacent cover bodies 13 are fixed by the connecting members 28 and 31.

  Although the length of each cover body 13 may be the same, the length of the cover body 13 at the right end that is largely slid in the removing direction is slightly longer than the other cover bodies 15 as in the present embodiment. By sliding the cover body 13, the portion covered with the cover body 13 can be completely exposed, so that there is an advantage that visibility is enhanced. As shown by a dotted arrow in FIG. 6C, it is also possible to inspect by sliding the cover bodies 13 at both ends outward.

  In any case, since the heat insulating material 2 is exposed and visible, the inspection can be performed reliably. Further, since it is not necessary to remove the cover body 13, the operation of returning it to the original state is very simple. Since the extent to which the cover body 13 can be slid to the outside varies depending on the site, the length of the cover body 13 may be set according to the site. In the case where the slidable length is shortened because a building is formed next to the building, it may be replaced with a plurality of cover bodies 13 at that stage.

(5). Second embodiment (FIGS. 7 to 8)
In the embodiment shown in FIG. 7, a processed product pushed out to the main body 12 is adopted, and a sheet metal processed product is adopted as the cover body 13. The main body 12 is basically the same as that of the first embodiment, and includes upper and lower downward openings 14 and 15. The main body 12 may be made of a metal such as aluminum, or may be made of a rigid resin.

  As in the first embodiment, forward lips 17 and 18 may be provided. The slider portion 24 of the cover body 13 is formed by folding back two sheets, and a downward piece 36 that overlaps the lower surface of the hook-like portion 25 is projected forward from the slider portion 24. For this reason, the slider part 24 has high rigidity. It is also possible to configure the entire cover body 13 in a two-ply structure. In addition, as shown with a dashed-dotted line in FIG. 7, it is also possible to form the upper surface of the heat insulating material 2 in the inclined surface which falls toward this side. In this case, it becomes easy to visually recognize the joint surface of the heat insulating material 2 with the concrete foundation 1.

  The main body 12 is preferably as long as possible in view of the nature of guiding the slide of the cover body 13, and in the draining device 11 at one wall portion of the building, it is ideal that the main body 12 has a single structure. . However, there are many cases where it is necessary to divide into multiple pieces and connect them from the viewpoint of transportation problems and ease of handling. Also in this case, it is preferable that the adjacent main bodies 12 are connected in a straight line. Therefore, in the present embodiment, as shown in FIG. 8, an engagement protrusion 37 is formed at one end of the back surface of the main body 12, and the engagement protrusion 37 is fitted to the other end so that it cannot be displaced vertically. A joint groove 38 is formed.

  Thereby, the unity of the some main body 12 can be improved and the cover body 13 can be slid smoothly. Such a connection structure can also be applied to other embodiments. Further, when the engagement protrusion 37 is exposed outwardly from the main body 12 located at the end, the engagement protrusion 37 is cut off.

(5). Third to fifth embodiments (FIGS. 9 to 11)
In the third embodiment shown in FIG. 9, the main body 12 is an extruded product and has a downward opening 14, but does not have an upward opening 15, and the base end portion of the hook-shaped portion 25 is formed. A support lip 39 is provided to support from below. Since its own weight acts on the cover body 13 so that the front end portion moves downward, there is no problem even with such a fitting structure. The cover body 13 may be made of sheet metal or a resin extruded product. In the case of a sheet metal product, the slider portion 24 is preferably configured in a two-ply structure.

  In the fourth embodiment shown in FIG. 10, the main body 12 is formed with a forward opening 40 having upper and lower lips, which is used as the grooved rail portion 16. The back of the forward opening 40 is a bulging portion 40a having a larger groove width (cross-sectional area), and the slider portion 24 of the cover body 13 is also swelled correspondingly. For this reason, the cover body 13 is held so that it cannot be removed. Although the illustrated cover body 13 is an extruded product, the slider portion 24 can be formed by curling as a sheet metal processed product.

  In this embodiment, since the forward opening 40 has a pocket shape, even if rainwater blows on the upper surface of the cover body 13, it will enter the forward opening 40 and hang down on the heat insulating material 2. There is no.

  The fifth embodiment shown in FIG. 11 is a specific example of claim 3. In this embodiment, the draining device 11 is entirely composed of a resin extruded product, and includes a main body portion 41 fixed to the base 4 with a fastener such as a screw 20 and a cover portion 42 integrally connected thereto. It is configured. And the thin hinge part 43 is formed in the cover part 41 near the base and the lower part of the front end of the outer wall material 6. The hinge portion 43 is provided by forming a triangular or trapezoidal long groove 44 on the lower surface. Further, a foot piece 45 that is in contact with the upper surface of the heat insulating material 2 is integrally provided in a portion of the cover portion 40 that is closer to the front side.

  In this embodiment, the cover body 13 can be largely raised and rotated upward by bending at the two hinge portions 44. Thereby, the upper surface of the heat insulating material 2 can be inspected. In this embodiment, since the draining device 11 has a single structure and is an extruded product, the cost can be significantly reduced. In addition, when the foot pieces 45 are provided as in the embodiment, the hinge portion 43 is configured, and high stability can be ensured. Moreover, if the foot piece 45 is provided, insects can be prevented from entering. The provision of the foot pieces 45 can also be applied to other embodiments.

  In the present embodiment, the two hinge portions 43 are formed, but the number of the hinge portions 43 may be one or three or more. It is also possible to reduce the thickness of the lower part of the outer wall material 6 over a wide range in the front-rear direction. That is, the hinge portion 43 can be configured in a band shape. In the example of FIG. 11, when the upper surface of the heat insulating material 2 is tilted forward as indicated by the alternate long and short dash line in FIG. 7, the ease of inspection of the heat insulating material 2 is further enhanced.

(6). Others The present invention can be embodied in various ways other than the above embodiment. For example, in the first to third aspects, various modes can be adopted for the fitting structure of the main body and the cover body. For example, by forming the main body into a crank shape with its lower part protruding in front of the base, a downward opening groove is formed between the main body and the base, while the slider part of the cover body is formed as a downward opening groove. As a form to be fitted from below, the slider portion can be slidably supported by the main body. In this case, the slider part of the cover body slides in a state where it overlaps the front surface of the base.

  There are a plurality of types of heat insulating materials having different thicknesses. However, in the invention of claim 1 of the present invention, since the main body can be used as a common product regardless of the thickness of the heat insulating material, the cost can be reduced accordingly. There is. As the connecting means for the adjacent cover bodies, it may be configured to overlap the inside and outside of the cover body with a metal plate or resin, and the end of the cover body may be sandwiched between the inside and outside plates with screws. In this case also, it is possible to provide a foot piece that rests on the upper surface of the heat insulating material.

  The draining device of the present invention can be embodied and applied to a building. Therefore, it can be used industrially.

DESCRIPTION OF SYMBOLS 1 Concrete foundation 2 Thermal insulation material 3 Seal spacer which comprises a base part 4 Base (square material) which is the core of a base part
DESCRIPTION OF SYMBOLS 5 Base part 6 Outer wall material 11 Draining device 12 Main body 13 Cover body 14 Downward opening groove 15 Upward opening groove 16 Groove-type rail part 24 Slider part 25 Gutter-like part 26 Downward wall part 28 Straight part connection member 41 Main body part 42 Cover part 43 Hinge 44 Long groove

Claims (3)

An inner wall is constructed through a foundation on a concrete foundation with heat insulating material arranged on the outer surface, and the outer wall is arranged outside the inner wall with a ventilation space between the inner wall and the inner wall. And the heat insulating material is configured to be covered from above with a horizontally elongated drainer attached to the base portion,
The draining device has a main body fixed to the base and a cover body attached to the main body so as to be slidable in the longitudinal direction of the main body, and by sliding the cover body, A person can visually recognize the upper surface of the heat insulating material,
Basic insulation building. The main body is formed with a groove-type rail portion having an opening groove in the downward direction over the entire length, while the cover body has an upward flange-like slider that fits in the downward opening groove in the groove-type rail portion. The part is formed over the entire length,
The basic heat insulation building according to claim 1. An inner wall is constructed through a foundation on a concrete foundation with heat insulating material arranged on the outer surface, and the outer wall is arranged outside the inner wall with a ventilation space between the inner wall and the inner wall. And the heat insulating material is configured to be covered from above with a horizontally elongated drainer attached to the base portion,
The draining device is an extruded product of resin, and is composed of a main body fixed to the base, and a cover that covers the heat insulating material from above while being integrally connected to the main body. In addition, a thin-walled hinge portion that is raised upward so that the upper surface of the heat insulating material can be visually recognized is formed over the entire length by forming a long groove on the lower surface,
Basic insulation building.

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