JP5108647B2 - Curtain wall for water storage facilities - Google Patents

Description

  The curtain wall for a water storage facility of the present invention is used to configure the outer wall of a water storage facility such as an indoor pool facility or a bathing facility (including a hot spring facility, a hot bath facility, or a so-called spa facility).

  In recent years, indoor pool facilities have been widely used to perform swimming and the like comfortably regardless of weather and temperature. Moreover, the outer wall of such an indoor pool facility is being adopted as an outer wall having a curtain wall structure because it is excellent in design and advantageous in securing lighting.

  A curtain wall 1 used as an outer wall of an indoor pool facility is configured, for example, as shown in FIGS. 1 and 2 showing an example of an embodiment of the present invention. The curtain wall 1 has a plurality of vertices 2 and 2 arranged in the vertical direction (the vertical direction in FIGS. 1 and 2). In addition, between the adjacent vertical walls 2, 2, a plurality of upper frames 3, 3 are hung at the upper end, lower frames 4, 4 are hung at the lower end, and unfinished 5, 5 are hung at the middle. Handing over. These upper frames 3 and 3, lower frames 4 and 4, and blanks 5 and 5 are respectively arranged in the horizontal direction (the left-right direction in FIG. 1 and the front and back direction in FIG. 2), and both end portions thereof are adjacent to each other. It is butt-bonded to the sides of the verticals 2 and 2. And the glass panels 6 and 6 which are window members, and the sliding window 7 are provided in a part surrounded by the four sides by each of the verticals 2 and 2 and the upper frame 3 and the lower frame 4 and the seamless frames 5 and 5. Each is built. In the example shown in the drawing, the verticals 2 and 2, and the upper frame 3 and 3, the lower frame 4, 4, and the seamless 5 and 5 are each made of an extruded material of an aluminum alloy. The curtain wall 1 having such a configuration separates the indoor space 9 in which the pool 8 serving as a water storage tank is installed from the outdoor space 10.

  By the way, in the indoor space 9 of the indoor pool facility, water (or hot water) stretched in the pool 8 is present, and therefore the humidity on the indoor space 9 side is usually extremely high at 80 to 90% or more. For this reason, when the temperature of the outdoor space 10 is lower than the temperature of the indoor space 9 and the temperature difference is large, such as in winter, the members 2, 3, 4, 5, 6 constituting the curtain wall 1 are formed. 7, the surface of the portion existing on the indoor space 9 side (hereinafter referred to as “indoor side wall surface”. The same applies throughout the present specification and claims. Conversely, the surface of the portion existing on the outdoor space 10 side. (Hereinafter referred to as “outdoor side wall surface”), a large amount of condensation tends to occur. In addition to the dew condensation water due to dew condensation, water in the pool 8 may scatter on the indoor side wall surface, for example.

  In view of such circumstances, conventionally, even for curtain walls for indoor pool facilities, like general curtain walls used for buildings, etc., such as condensed water adhering to the indoor side wall surface, etc. A structure for discharging water (hereinafter, simply referred to as “condensed water” except for a part in this specification) to an outdoor space is employed. For example, in the conventional structure described in Patent Document 1, an inflow port 11 is formed on the upper surface on the indoor space 9 side of the seamless 5 and an outlet 12 is formed on the lower surface on the outdoor space 10 side as shown in FIG. is doing. And in the state which connected these inflow ports 11 and the discharge ports 12, the drainage channel 13 is formed in the inside of the said seamless 5, and dew condensation water is discharged | emitted to the outdoor space 10 through this drainage channel 13. Yes. Moreover, although illustration is abbreviate | omitted, condensed water is also discharged | emitted to outdoor space from this vertical or an invisible outdoor side surface, guiding it through the inside of a vertical.

  However, as described above, the following inconvenience has been caused by discharging condensed water to the outdoor space. That is, chemicals such as a chlorinated disinfectant (so-called chalk) are added to the water stored in the pool for the purpose of hygiene management, and there is a possibility that the chemicals are also dissolved in the condensed water. For this reason, when such dew condensation water is discharged to the outdoor space 10 as shown in FIG. 14 above, the water is then evaporated, so that the chemicals are deposited and the glass panels 6 and 6 are clouded. Will cause stains on the surface. As a result, the appearance of the indoor pool facility is significantly impaired. In order to keep the appearance clean, it is necessary to take measures such as greatly increasing the number of cleanings, resulting in an increase in management costs. Furthermore, since the dew condensation water in which the chemical is dissolved is passed through the interiors of the meshes and the verticals, there arises a disadvantage that corrosion is likely to occur in the interiors of the meshes and the verticals. In a cold region, the condensed water discharged to the outdoor space may freeze.

  Therefore, in order to eliminate such inconvenience, the present inventors have found that stains due to chemicals are generated on the indoor side wall surface on the indoor side wall surface because the humidity in the indoor space is high and difficult to dry. We focused on the points that are difficult to do. And the present inventors came to consider whether the dew condensation adhering to the indoor side wall surface could be drained only on the indoor space side without being discharged to the outdoor space. However, simply using a curtain wall for indoor pool facilities with a conventional structure and not using a structure for discharging condensed water to the outdoor space, as shown by the broken line in FIG. It hangs down to the floor through the indoor side, and the amount of water drops increases. For this reason, the appearance of the indoor side wall surface may be deteriorated and the comfort of the user of the indoor pool facility may be impaired. On the other hand, if a configuration is adopted in which condensed water is guided downward through the interior of a blind or vertical body and then discharged into the indoor space, the amount of water droplets dripping through the interior of the blind interior can be reduced. However, in this case, as in the case of discharging to the outdoor space, corrosion is likely to occur inside the above-mentioned invisible or vertical interior. In order to prevent the occurrence of such corrosion, it is necessary to apply surface treatment such as painting treatment, which is originally applied only to the external surface, to the invisible and vertical internal surfaces. The rise of is inevitable.

  In addition, chemicals such as the chlorine-based disinfectant as described above may be added to hot water in a bathing facility in addition to water in an indoor pool. And about this bathing facility, the amount of dew generation and the amount of water droplets accompanying the scattering increase more than the indoor pool facility. For this reason, even in such a bathing facility, it has been conventionally practiced to discharge the condensed water adhering to the indoor side wall surface to the outdoor space, and the same problem as in the case of the indoor pool facility described above. It was happening.

JP 2008-115662 A

  In view of the circumstances as described above, the present invention can ensure the comfort of the user of the water storage facility, and hang the outdoor side wall surface of the water storage facility over a long period of time without causing problems such as corrosion. It was invented to realize a structure that can be well maintained.

The curtain wall for a water storage facility according to the present invention is used to separate an indoor space provided with a water storage tank and an outdoor space, and includes a plurality of verticals, a plurality of blinds, and a window member. Prepare.
Of these, the uprights are made of, for example, an extruded material of an aluminum alloy, and are arranged in the vertical direction.
Further, each of the above-mentioned seamless pieces is made of, for example, an aluminum alloy extruded mold material, and is arranged in the horizontal direction, and butt-couples both end portions to adjacent side faces.
Moreover, the said window member is built in the part enclosed by four sides by the seamlessness which adjoins the up-down direction, and the vertical adjoining in a horizontal direction. In addition, the said window member is equivalent to a glass panel, a glass shoji, a decorative panel etc., regardless of a fixed window and a movable window, for example.

In particular, in the curtain wall for a water storage facility of the present invention, a concave drainage channel is formed on the side surface of each side of the indoor space, and a part of the lengthwise direction is connected to each of the above endless portions. It is provided in the up-down direction in a state of being opposed to. And water, such as condensed water adhering to an indoor side wall surface, is guide | induced to the downward direction of each said direction by guide | inducing to each said drainage channel through each said invisible upper surface, without discharging | emitting to outdoor space.
In addition, the water such as the dew condensation water includes the water (or hot water, hot water) stored in the water storage tank in addition to the dew condensation water.

  When carrying out the present invention, for example, as in the invention described in claim 2, an inclined surface portion inclined downward toward the indoor side from the outdoor side is formed on the upper surface of each invisible indoor space side. A weir portion rising upward from the indoor side end of the inclined surface portion is provided.

Further, when carrying out the present invention, for example, as in the invention described in claim 3, each of the invisible ends has a shape that can enter each drainage channel, Guide guides that are close or at least partially in contact with the bottom surfaces of these drainage channels are provided.
In carrying out the invention described in claim 3, preferably, a V-shaped, U-shaped, semi-circular notch or the like is formed in the leading edge of the guide, and both side portions of the notch are formed on both sides. The abutment is brought into contact with the bottom surface of each drainage channel.

  When carrying out the present invention, for example, as in the invention described in claim 4, the cross-sectional shape of the bottom surface of each drainage channel is a sawtooth shape.

  Furthermore, when carrying out the present invention, for example, as in the invention described in claim 5, a closing material is provided in the state where the base end portion is closely fitted to each of the endless portions. And the front-end | tip part of this plugging material is closely_contact | adhered to the width direction both sides part of these each drainage channel among the said each side surfaces in the state which straddles each said drainage channel.

According to the present invention configured as described above, water such as condensed water adhering to an indoor side wall surface such as a window member is passed through an invisible upper surface to a drainage channel provided on the side surface of the vertical indoor space side. And by flowing down the drainage channel, it is possible to guide it downward in the above-mentioned direction.
That is, according to the present invention, the condensed water that has flowed down to the upper surface of the invisible water is guided to the drainage channel without dripping from the inner side surface of the invisible water. The amount can be reduced sufficiently. In addition, in the case of the present invention, water such as condensed water can be guided downward by using a side face which is difficult to be seen by the user of the water storage facility. For this reason, the appearance of the indoor side wall surface can be secured satisfactorily, and the comfort of the user of the water storage facility can be sufficiently secured.
Furthermore, since water such as dew condensation is not allowed to pass through the interior of the above-mentioned invisible or the above-mentioned vertical, the above-mentioned innocent or even without performing a surface treatment such as a coating treatment causing an increase in cost. Corrosion can be prevented from occurring inside the vertical.
In this way, according to the present invention, water such as condensed water can be appropriately drained only on the indoor space side without being discharged to the outdoor space. Stain stains can be prevented and the outdoor side wall surface of the water storage facility can be kept clean over a long period of time.

  In particular, in the invention according to claim 2, it is possible to effectively prevent water such as condensed water flowing down to the upper surface of the eyes from dripping through the inner side surface of the eyes. In addition, a certain amount of water such as this condensed water can be stored on this seamless upper surface, and this water such as condensed water can be guided to the drainage channel along the outdoor side surface of the weir. it can.

  In the invention according to claim 3, since water such as dew condensation water can be guided to the bottom surface of the drainage channel, the water such as dew condensation water flows along the bottom surface of the drainage channel (the bottom surface). It is easy to flow down. Furthermore, if a V-shaped notch is formed at the leading edge of the guide, a large contact area between water such as condensed water passing through the notch and the bottom surface of the drainage channel can be secured. For this reason, the surface tension acting on the water such as the dew condensation water can be reduced, and the surface tension can prevent the water such as the dew condensation water from flowing into the invisible lower surface side.

  Further, in the invention according to claim 4, since the cross-sectional shape of the bottom surface of the drainage channel is a sawtooth shape, contact between water such as condensed water and this bottom surface is simpler than in the case of a simple flat surface shape. The area can be increased. For this reason, the surface tension acting on the water such as dew condensation water is effectively used (the wet length between the water and the bottom surface can be increased), and the water remains in the state of water droplets on the bottom surface of the drainage channel. This makes it difficult for the water to remain, so that the water can flow smoothly along the bottom surface.

  Furthermore, in the invention according to claim 5, since the closing material is provided in the state where the base end portion of the closing material is closely fitted in the end portion, It is possible to reliably prevent water such as condensed water from entering from the upper surface of the invisible to the inside of the invisible. In addition, since the tip of the plugging material is in close contact with the both sides of the drainage channel in the width direction of the vertical side in a state of straddling the drainage channel, water such as dew condensation water is visible from the above. It is possible to effectively prevent the drainage channel from drooping in a state where the drainage channel is deviated indoors and outdoors, and this condensed water can be effectively guided to the drainage channel.

  An example of an embodiment of the present invention will be described with reference to FIGS. The curtain wall 1 is composed of the vertical walls 2 and 2, the upper frames 3 and 3, the lower frames 4 and 4, the invisible lines 5 and 5, the glass panels 6 and 6 that are window members, and the sliding window 7. And the basic structure of each of the members 2, 3, 4, 5, 6, and 7 are as described above. For this reason, the following description will focus on the features of this example.

  In the case of the curtain wall 1 of this example, the structure for discharging condensed water to the outdoor space 10 as shown in FIG. 14 is not adopted, and this condensed water is drained only on the indoor space 9 side. To process. For this reason, in the case of this example, as shown in FIGS. 3 to 7, 12, and 13, the grooved drainage channels 13 a and 13 a are provided on the side surfaces of the vertical spaces 2 and 2 on the indoor space 9 side. , Provided in the vertical direction. Further, each drainage channel 13a, 13a has a part in the length direction opposed to the end of each of the above-mentioned blinds 5, 5. Moreover, in the case of this example, the cross-sectional shape of the bottom face of each said drainage channel 13a, 13a is made into the sawtooth shape which continued the micro unevenness | corrugation in the indoor / outdoor direction.

  In addition, each of the above-mentioned seamless bodies 5 and 5 covers the above-described seamless body 14 and 14 for supporting each of the glass panels 6 and 6 and covers the upper surface and the indoor side surface of each of the above-described seamless body 14 and 14. There is a seamless cover 15, 15 coupled to each seamless body 14, 14. The end surfaces of the blind main bodies 14 and 14 are abutted against the verticals 2 and 2 and fixed with screws. In addition, inclined surface portions 16 and 16 and weir portions 17 and 17 are respectively provided on the upper surfaces of the seamless covers 15 and 15, and the inclined surface portions 16 and 16 are respectively shown in FIGS. As shown in Fig. 4, the slope is downward as it goes from the outdoor side to the indoor side. The dam portions 17 and 17 are provided in a state of rising upward from the indoor side end portions of the inclined surface portions 16 and 16. Moreover, as shown in FIGS. 3 and 6, the boundary between each of the inclined surface portions 16 and 16 and the weir portions 17 and 17 is located at a portion aligned with the indoor side end portion of each of the drainage channels 13a and 13a. .

  Further, dovetail-shaped locking grooves 18 and 18 are provided in the horizontal direction on the lower surfaces of the seamless covers 15 and 15, respectively. Guide guides 19 and 19 are locked. Each of these guides 19, 19 is made of a thermoplastic resin, and as shown in detail in FIG. 8, a rectangular plate-shaped substrate portion 20 and one side of the substrate portion 20 are directed to one side of the substrate portion 20. It is comprised from the guide part 21 provided in the state bent. The guide portion 21 has a shape that can enter the drainage channels 13a and 13a. In the case of this example, the guide portion 21 has a substantially trapezoidal plate shape that tapers as the distance from the substrate portion 20 increases. A V-shaped notch 22 is provided at the leading edge of the guide portion 21. As shown in FIGS. 5 and 7, the guide portions 19, 19 of the guide guides 19, 19 are engaged with the guide grooves 19, 18 in the engagement grooves 18, 18. 21 and 21 are made to enter the drainage channels 13a and 13a with their leading edges inclined downward. In addition, as a material of each said guide 19 and 19, the polyacetal copolymer {Duracon (trademark)} which is excellent in workability and is hard to produce rust and corrosion can be used preferably.

  In the case of this example, the guiding guides 19 and 19 having the above-described configuration are positioned at appropriate positions in the respective locking grooves 18 and 18 using a stopper member 23 as shown in FIG. Yes. The stopper member 23 includes a substantially disc-shaped locking plate portion 24 and a knob portion 25, and the locking plate portion 24 is provided in a state of being opposed to each other in the diametrical direction. A circular arc portion 26, 26 having a single circular arc shape, and a non-circular arc portion 27 having a portion projecting outward in the radial direction from both the circular arc portions 26, 26 are provided in a state where the circular arc portions 26, 26 are continuous with each other. , 27. Between these non-arc portions 27, 27 and the above-mentioned arc portions 26, 26, straight portions 35, 35 are formed which are parallel to each other at opposite positions in the diametrical direction (which are adjacent to each other in a substantially perpendicular direction). ing.

  Such a stopper member 23, as shown by the broken line at the left end of FIG. 7, has both the arc portions 26, 26 in the width direction of the locking grooves 18, 18 (vertical direction in FIG. 7). Inserted into the respective locking grooves 18 and 18 from the discontinuous portion 28 having a wide opening width in a state of being positioned on both sides. Then, the stopper member 23 is translated to the vicinity of the substrate portions 20 and 20 of the guide guides 19 and 19 while maintaining this posture, and then the locking portions are used using the knob portions 25. Rotate in grooves 18, 18. As a result, a pair of straight portions 35, 35 existing on the opposite side in the diametrical direction are stretched in the respective locking grooves 18, 18, thereby fixing the stopper member 23 and at the same time of another straight portion 35. The outer peripheral edge is brought into contact with the substrate portions 20 and 20 of the guide guides 19 and 19. Thereby, each of these guides 19 and 19 is positioned at an appropriate position.

  In the case of this example, between the side surfaces of the vertical spaces 2 and 2 on the side of the indoor space 9 and the end portions of the invisible lines 5 and 5 (invisible cover 15 and 15), FIGS. A plugging material 29 as shown in FIG. The closing material 29 is made of a material that does not absorb moisture, such as silicone sponge or rubber, and includes a fitting portion 30 and a pair of butting portions 31 and 31. Among these, the fitting part 30 has a shape that can be closely fitted into the end of each of the above-mentioned seamless 5, 5 (Seamless covers 15, 15). The abutting portions 31 and 31 are provided in a state of being separated by the same dimension as the width dimension of the drainage channels 13a and 13a. As shown in FIG. 6, the plugging material 29 having such a configuration is in the assembled state, with the abutting portions 31, 31 straddling the drainage channels 13 a, 13 a, and the vertical 2 Among the two side surfaces, the drainage channels 13a and 13a are in close contact with both sides in the width direction. Therefore, in the case of this example, the drainage channels 13a and 13a and the abutting portions among the side surfaces of the verticals 2 and 2 and the end portions of the seamless lines 5 and 5 are provided. Drain spaces 32 and 32 are formed in portions surrounded by four sides by the inner side surfaces of 31 and 31 and the fitting portion 30. The lower openings of the drain spaces 32 and 32 are closed by the guide guides 19 and 19, respectively.

  Furthermore, in this example, as shown in FIGS. 12 and 13, drainage grooves 33 and 33 are provided in the horizontal direction on the upper surfaces of the lower frames 4 and 4 constituting the curtain wall 1. Moreover, between the upper part of each edge part of each of these lower frames 4 and 4 and the side of each said stand 2 and 2, including the part in which each said drainage channel 13a, 13a was provided, Completely plugged with caulking material. Thereby, each said drainage channel 13a, 13a and each said drainage groove 33, 33 are connected in the orthogonal direction. Further, outflow ports 11a and 11a are provided in the vicinity of the verticals 2 and 2 among the bottom surfaces of the drain grooves 33 and 33, respectively. The inflow ports 11a and 11a and a sewage pipe (not shown) provided below the floor are communicated by a drain pipe 34.

  In the case of this example having the above-described configuration, the condensed water adhering to the indoor side wall surfaces of the glass panels 6 and 6 is drained into the sewer pipe as follows. First, the dew condensation water flowing down from the glass panels 6 and 6 to the top surfaces of the meshes 5 and 5 is an inclined surface portion provided on the top surfaces of the meshes 5 and 5 as shown in FIG. 16 and 16 to the indoor side. The condensed water thus induced is blocked by the respective weir portions 17 and 17 and stored between the outdoor side surface of each of the weir portions 17 and 17 and the upper surface of the respective inclined surface portions 16 and 16. To go. And when a certain amount of condensed water accumulates, this condensed water is along the outdoor side surface of each said dam part 17 and 17 in the length direction (end part side) of each said seamless 5 and 5. It flows out and hangs down into the drainage spaces 32, 32.

  In this way, the condensed water dripping into the drainage spaces 32 and 32 constitutes the guide guides 19 and 19 provided so as to close the lower openings of the drainage spaces 32 and 32. It is received by the board parts 20 and 20 (or the guide parts 21 and 21). Then, after flowing from the respective substrate portions 20 and 20 through the respective guide portions 21 and 21 toward the bottom surfaces of the respective drainage channels 13a and 13a, cuts formed at the leading edges of the respective guide portions 21 and 21 are formed. It passes through the inside of the notches 22 and 22 and is guided to the bottom surfaces of the drainage channels 13a and 13a. As a result, the water flows down the bottoms 2 and 2 along the bottom surfaces of the drainage channels 13a and 13a.

  In this way, the dew condensation water that has flowed down below the verticals 2 and 2 flows out into the drainage grooves 33 and 33 provided on the upper surfaces of the lower frames 4 and 4. And it flows down to the inflow ports 11a and 11a provided in these drainage grooves 33 and 33, passes through the drainage pipe 34, and drains into the sewer pipe. The condensed water that has flowed down to the upper surfaces of the lower frames 4 and 4 flows down directly into the drain grooves 33 and 33 and is drained into the sewer pipes.

  As described above, in the case of this example, the condensed water that has flowed down through the glass panels 6, 6, etc., onto the upper surfaces of the above-mentioned blinds 5, 5 does not sag from the indoor side surfaces of the respective blinds 5, 5. In addition, since the water is led to the drainage channels 13a and 13a, the amount of water droplets dripping through the indoor side surfaces of the seamless 5 and 5 can be sufficiently reduced. In addition, in the case of this example, it is difficult for the user of the indoor pool facility to use the side surfaces of the above-mentioned each side 2, 2 so that the dew condensation water can be guided downward. The appearance can be ensured well, and the comfort of the user of the indoor pool facility can be sufficiently ensured.

  Further, in the case of this example, the drainage provided on the side surfaces of each of the verticals 2 and 2 without allowing the condensed water to pass through the respective verticals 2 and 2 and the above-mentioned blinds 5 and 5. The waste water can be treated through the paths 13a and 13a and the upper surfaces of the above-mentioned seamless 5 and 5. For this reason, even if it does not perform surface treatments, such as a coating process which raises cost, on the inner surface of each of the above-mentioned verticals 2, 2, and seamless meshes 5, 5, each of these verticals 2, 2, seamless meshes 5, Corrosion can be prevented from occurring inside 5. In other words, in the case of this example, as the vertical 2, 2, and seamless 5, 5, the one having the conventional structure in which the surface treatment such as the painting treatment is performed only on the external surface can be used.

  As described above, in the case of this example, the condensed water can be appropriately drained only on the indoor space 9 side without being discharged to the outdoor space 10. For this reason, it is possible to prevent the stain on the outdoor side wall of the indoor pool facility from being stained with chemicals, and the outdoor side wall of the indoor pool facility can be kept clean over a long period of time. Moreover, it is possible to prevent the condensed water from freezing on the outdoor side wall surface even in a cold region.

  In addition, in the case of this example, it is effective that the condensed water flowing down on the upper surfaces of the above-mentioned seamless meshes 5 and 5 is dripped from the indoor side surfaces of the seamless meshes 5 and 5 by the respective weir portions 17 and 17. Can be prevented. In addition, by storing a certain amount of condensed water on the top surfaces of each of these seamless members 5, 5, the condensed water is allowed to flow along the outdoor side surfaces of the respective weir units 17, 17. It is also possible to guide in the length direction (end side) and efficiently lead to the drainage channels 13a and 13a (drainage spaces 32 and 32).

  In the case of this example, since the V-shaped cutout portions 22 and 22 are formed at the leading edges of the guide portions 21 and 21 of the guide guides 19 and 19, the cutout portions 22 and 22 are formed. A large contact area can be secured between the condensed water that has passed through the inside 22 and the bottom surfaces of the drainage channels 13a and 13a. For this reason, the surface tension acting on the dew condensation water is effectively used (the dew condensation water wets the bottom surface surely) and this dew condensation water is prevented from flowing to the lower surface side of each of the above-mentioned seamless 5 and 5. it can. Thus, in the case of this example, by providing the notches 22 and 22, the guide guides 19 and 19 (guide portions 21 and 21) to the bottom surfaces of the drainage channels 13a and 13a. It is possible to efficiently deliver condensed water. Further, by passing the inside of each of the notches 22 and 22, the condensed water can be guided downward while the condensed water is gathered, so the condensed water is provided below. Further, it is possible to prevent dripping (falling) directly onto the seamless 5 and 5, and it is possible to prevent dripping sound and splashing.

  In the case of this example, since the cross-sectional shape of the bottom surface of each of the drainage channels 13a, 13a is a sawtooth shape, the contact area between the condensed water and the bottom surface is smaller than that of a simple flat surface shape. You can increase it. For this reason, the surface tension acting on the dew condensation water is effectively used (the wet length between the dew condensation water and the bottom surface can be increased), and the dew condensation water is passed along the bottom surfaces of the drainage channels 13a and 13a. It can be made to flow smoothly.

  Further, in the case of this example, the end portions of the above-described seamless members 5 and 5 are respectively provided with the plugging materials 29 and 29, and the fitting portions 30 and 30 which are the base end portions of the respective plugging materials 29 and 29 are tightly inserted. Since it is provided in the fitted state, it is possible to reliably prevent the dew condensation water from entering the inside of each of the meshes 5 and 5 from the upper surface of each of the meshes 5 and 5. For this reason, it can prevent effectively that corrosion etc. generate | occur | produce in these each inside 5 and 5. Furthermore, since the abutting portions 31 and 31 constituting the tip portions of the respective plugging materials 29 and 29 are provided across the respective drainage channels 13a and 13a, the dew condensation water is contained in the respective seamless 5, 5 Therefore, it is possible to effectively prevent the drainage channels 13a and 13a from drooping in a state where the drainage channels 13a and 13a are disengaged indoors and outdoors, and the dew condensation water can be efficiently guided to the drainage channels 13a and 13a.

Further, in the case of this example, since the guide guides 19 and 19 and the stopper members 23 and 23 are detachable, the guide guides 19 and 19 (stopper members 23 and 23) are cleaned and maintained. Etc. can be easily performed.
Further, in the case of this example, as described above, the drainage channels 13a and 13a provided on the side surfaces of the verticals 2 and 2 and the inclined surface portion 16 of the upper surfaces of the seamless surfaces 5 and 5 described above. , 16 and the weir portions 17 and 17, the condensed water can be concentrated and flowed. For this reason, when the indoor side wall surface cleaning operation (wiping off stains and stains caused by chemicals) is performed, the drainage passages 13a and 13a and the inclined surface portions 16 and 16 that serve as a dew condensation water flow path are provided. Therefore, the cleaning operation can be simplified and the cleaning time can be greatly shortened as compared with the case of cleaning the entire indoor side wall surface.
In the case of this example, as shown in FIG. 3 and FIG. 13, rainwater adhering to the outdoor side wall surface of the glass panels 6, 6, etc. passes through the insides of the blinds 5 and the lower frame 4 and moves downward. Adopting a structure that leads to However, since this rainwater does not contain chemicals such as the aforementioned chlorine-based disinfectant, problems such as stains and corrosion as in the case of passing condensed water do not occur.

  The curtain wall for a water storage facility of the present invention is not limited to an indoor pool facility as shown in the example of the embodiment described above, and can also be used as an outer wall of a bathing facility such as a hot spring facility.

The partial front view which shows an example of embodiment of this invention in the state which looked at the curtain wall for indoor pool facilities from the indoor side. Similarly AA sectional drawing of FIG. The B section enlarged view of FIG. 2 similarly. Similarly, the partial cut perspective view which looked at the butting | matching part of a vertical and invisible from the indoor space side upper direction. The partial cut perspective view similarly seen from the indoor space side lower part. CC sectional drawing similarly of FIG. DD sectional drawing similarly of FIG. Similarly, a plan view (A), a front view (B) and a side view (C) of the guide. Similarly, a bottom view (A), a front view (B), and a side view (C) of the stopper member. The perspective view shown in the state which looked at the blocking material from the inside of the eyeless. The perspective view shown in the state seen similarly from the exterior side. Similarly EE expanded sectional drawing of FIG. The F section enlarged view of FIG. 2 similarly. The figure equivalent to FIG. 3 which shows an example of the conventional structure for discharging condensed water to outdoor space.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Curtain wall 2 Standing 3 Upper frame 4 Lower frame 5 No mesh 6 Glass panel 7 Sliding window 8 Pool 9 Indoor space 10 Outdoor space 11, 11a Inlet 12 Outlet 13, 13a Drainage channel 14 Main body 15 No mesh Cover 16 Inclined surface portion 17 Weir portion 18 Locking groove 19 Guide guide 20 Substrate portion 21 Guide portion 22 Notch portion 23 Stopper member 24 Locking plate portion 25 Knob portion 26 Arc portion 27 Non-arc portion 28 Discontinuous portion 29 Closing material 30 Mating part 31 Abutting part 32 Drainage space 33 Drainage groove 34 Drainage pipe 35 Straight line part

Claims (5)

  Adjacent in the vertical direction, a plurality of verticals each arranged in the vertical direction, and a plurality of blinds, each arranged in the horizontal direction and abutting and joining each end to the side of the adjacent vertical. It is a curtain wall for a water storage facility that has a window member built in a part surrounded by four sides by a blind and a horizontal stand, and separates an indoor space provided with a water tank from an outdoor space. On the side surface of each side of the indoor space, a groove-like drainage channel is provided in the vertical direction with a part of the length direction facing the endless part. In addition, water such as condensed water adhering to the indoor side wall surface is guided to each drainage channel through each above-mentioned invisible surface without being discharged to the outdoor space, and is guided to the lower side of each side. Curtain wall for water storage facilities.   On the upper surface of the invisible indoor space side, an inclined surface portion that is inclined downward as it goes from the outdoor side to the indoor side, and a weir portion that rises upward from the indoor side end of the inclined surface portion are provided, respectively. The curtain wall for water storage facilities according to claim 1.   An inductive guide having a shape capable of entering a drainage channel at its endless end and having a tip edge thereof adjacent to or at least partially in contact with the bottom surface of the drainage channel is provided. Item 3. A curtain wall for a water storage facility according to any one of Items 1 and 2.   The curtain wall for water storage facilities according to any one of claims 1 to 3, wherein a cross-sectional shape of a bottom surface of the drainage channel is a sawtooth shape.   A closing member is provided at the end of the joint with the base end closely fitted therein, and the distal end of the closing member straddles the drainage channel, The curtain wall for water storage facilities according to any one of claims 1 to 4, which is in close contact with both side portions in the width direction of the drainage channel.

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