JP7382850B2 - Floor inspection port and construction method for floor inspection port - Google Patents

Description

The present invention relates to a floor inspection port and a method for constructing a floor inspection port.

Floor inspection holes are provided on the indoor and outdoor floors to enable inspection of the area beneath the floor. The floor inspection port includes an outer frame and a lid fitted into the outer frame, the outer frame is placed and fixed on the floor surface, and the lid is removably attached to the inside of the outer frame. Placed.

In order to install such a floor inspection port on the floor surface, as shown in Patent Document 1, a plurality of anchor members are planted in the frame around the installation position of the floor inspection port, and a plurality of anchor members are installed as an outer frame. A structure with attached pieces is prepared, and each fixing piece of the outer frame is attached to each anchor member in the frame. Moreover, in this case, each of the plurality of fixing pieces is attached to each of the four corners of the outer frame, and each anchor member is configured to be able to adjust the mounting height position of the fixing piece, and the outer frame The height and posture (gradient) of the outer frame are adjusted using each of the fixing pieces and the plurality of anchor members. When the outer frame is adjusted and arranged in this way, a floor finishing material such as mortar is filled around the outer frame to finish the floor. As a result, the outer frame is installed on the floor surface, and a floor inspection port is constructed by assembling a lid body that opens and closes the opening of the outer frame to the outer frame.

By the way, recently, during the construction of buildings (especially large-scale buildings), even during the construction of floor inspection openings (when filling with mortar, etc.) or after construction (after filling with mortar, etc.), On the other hand, there is a tendency to maintain the opening of the outer frame open to the outside without inserting the lid. This is to allow the use of the space under the floor through the opening (inspection opening) in the outer frame.

Special Publication No. 3-11348

However, in the above case, in addition to the fact that the outer frame must have a basic configuration (a configuration with an opening) in which there is no bottom plate inside, the outer frame must also be external to facilitate adjustment of its height and posture (inclination). The structure is such that fixing pieces are provided at the four corners of the frame, and in this situation, as described above, after fixing each fixing piece of the outer frame to each anchor member, filling the area around the outer frame with floor finishing material such as mortar. (When placing mortar, etc.), the floor finishing material must be pushed in to prevent the formation of cavities within the floor finishing material, so a pressing force acts on the outer frame from the outside to the inside. For this reason, each outer frame constituent member of the outer frame is bent inward of the outer frame like a support beam at both ends, and the amount of deflection is greatest at the longitudinal center of each outer frame member (described later). (See also Figure 9). As a result, if the deflection of each outer frame component exceeds a predetermined limit, even if you try to insert the lid into the outer frame, the lid will not be able to be inserted into the outer frame. Moreover, even if the lid can be fitted into the outer frame, there is a possibility that the lid cannot be removed from the outer frame.

The present invention has been made in view of the above circumstances, and its first purpose is to form a floor surface by opening the opening of the outer frame to the outside and filling the periphery of the outer frame with a floor finishing material. To provide a floor inspection port which can prevent the opening and closing of a lid from an outer frame from being hindered even when the door is opened and closed.
The second purpose is to prevent the opening and closing of the lid from the outer frame even when the floor surface is formed by filling the underfloor finishing material around the outer frame while opening the outer frame to the outside. To provide a method for constructing a floor inspection port that can be used without causing any trouble.

In order to achieve the first object, the present invention has the following configurations (1) to (4).

(1) In a floor inspection port that is equipped with an outer frame that partitions a rectangular inspection opening and a lid that is removably inserted into the outer frame,
The outer frame members on at least two sides of the outer frame are each provided with a first fixing piece that is attached to a fixing member implanted in the frame and restricts inward warping of the outer frame member,
Each of the first fixing pieces is provided at a central portion in the longitudinal direction of each of the outer frame constituent members.

According to this configuration, in the outer frame constituent members on at least two sides of the outer frame, the longitudinal center portion of each outer frame constituent member is fixed to the frame via the first fixing piece and the fixing member. Even if mortar or the like is placed around the outer frame as a floor finishing material and the pressing force acts on the longitudinally inward portion of each outer frame component, the outer frame structure on at least two sides of the outer frame It is possible to suppress the material from bending inward of the outer frame, and to suppress deformation of the outer frame (inspection opening). For this reason, in the floor inspection port, even if the opening of the outer frame is opened to the outside and the outer frame is filled with mortar etc. as a floor finishing material, the outer frame allows the lid to be opened and closed. It is possible to prevent interference with the

(2) Under the configuration of (1) above,
A second fixing piece is provided on the outer frame constituent members on two opposing sides of the outer frame, and is attached to a fixing member implanted in the frame and adjusts the height and posture of the outer frame,
The second fixing pieces are provided on both sides in the longitudinal direction of the two opposing sides of the outer frame component.

According to this configuration, the four corners of the outer frame are fixed to the frame via the second fixing pieces and anchor members provided on both sides in the longitudinal direction of each outer frame component on two opposing sides, and By using the second fixing pieces arranged at the four corners of the outer frame, the height and posture of the outer frame can be adjusted accurately.

(3) Under the configuration of (2) above ,
Each of the first fixed pieces and each of the second fixed pieces are formed in a band-like shape extending in a direction away from the outer frame,
A long hole or a notch through which the fixing member is inserted is formed at the tip of each of the first fixing pieces and the second fixing piece.

According to this configuration, by utilizing the long holes or notches formed in each of the first and second fixing pieces each having a band-like shape, and each of the first and second fixing pieces, Each first fixing piece and each second fixing piece can be attached to the fixing member, and the outer frame can be concretely and easily fixed to the frame.

(4) Under any of the configurations of (2) to (3) above ,
The fixing member is an anchor member implanted in the building frame,
Each of the first fixing pieces and the second fixing pieces is configured to be fixed to the anchor member by a connecting portion that is movable and adjustable in the vertical direction in the anchor member.

According to this configuration, the height and posture of the outer frame can be specifically adjusted by the second fixed pieces attached to the four corners of the outer frame and the connecting parts that connect the second fixed pieces to the anchor member. The first fixed pieces and the anchor members (connecting parts) connecting the first fixed pieces are used to maintain the adjusted height and posture of the outer frame while maintaining the adjusted height and posture of the outer frame. The longitudinal center portion of each outer frame component can be fixed to the frame. For this reason, it is possible to specifically adjust the height and posture of the outer frame, and while maintaining the adjusted height and posture of the outer frame, the bending of each outer frame component in the outer frame Changes in the outer shape of the outer frame can be suppressed.

In order to achieve the second object, the present invention has the following configuration (5).

(5) A method for constructing a floor inspection port configured as in (4) above, comprising:
implanting the anchor member in the frame, and attaching a first fixing piece and a second fixing piece of the outer frame to the anchor member through the connecting portion, respectively;
Next, the height and posture of the outer frame are adjusted by the second fixing piece and the connecting part,
Next, while maintaining the height and posture of the outer frame, the fixing position of the first fixing piece with respect to the anchor member is adjusted by the connecting portion ,
Next, a floor finishing material is filled around the outer frame to finish the floor.

According to this configuration, it is possible to provide a floor inspection port that can obtain the effect of (4) above, and when constructing the floor inspection port, each outer frame component material of the outer frame is used as an outer frame. Based on the fact that the first and second fixing pieces are provided in advance, the first and second fixing pieces can be placed in the predetermined positions at once by arranging the outer frame, which makes it easier to install the outer frame. Workability can be improved.

According to the present invention, even if the opening of the outer frame is opened to the outside and a floor surface is formed by filling the periphery of the outer frame with floor finishing material, the lid body can be opened and closed with respect to the outer frame. It is possible to provide a floor inspection port and a method for constructing the floor inspection port that can be used without causing any trouble.

FIG. 3 is a perspective view showing a state in which a lid closes an opening of an outer frame in the floor inspection port according to the first embodiment. FIG. 2 is a perspective view showing the floor inspection port according to the first embodiment in which the opening of the outer frame is opened by lifting the lid using the handle. FIG. 3 is a partial vertical sectional view showing the floor inspection port according to the first embodiment. A partially enlarged view of FIG. 3. FIG. 3 is an explanatory diagram illustrating attachment of the outer frame according to the first embodiment. FIG. 2 is a perspective view showing a state in which the outer frame according to the first embodiment is attached to an installation position (concrete base). FIG. 2 is an enlarged sectional view showing a state in which the outer frame according to the first embodiment is attached to a concrete base via fixing pieces and anchor bolts (before filling with mortar as a floor finishing material). FIG. 8 is a state explanatory diagram illustrating a transition from the state shown in FIG. 7 to a state in which mortar as a floor finishing material is filled around the outer frame. In the case where the longitudinal center part of each outer frame component of the outer frame is not fixed to the concrete base via a fixing piece, when mortar as a floor finishing material is filled around the outer frame, each outer frame FIG. 3 is an explanatory diagram illustrating how the constituent materials bend. Explanatory diagram explaining the second embodiment. FIG. 7 is a partial vertical sectional view showing a floor inspection port according to a third embodiment. FIG. 3 is an explanatory diagram illustrating a state in which the outer frame has been filled with mortar as a floor finishing material. FIG. 7 is an explanatory diagram for explaining, in a plan view, adjustment of the height and posture with respect to the outer frame according to the third embodiment. FIG. 14 is a vertical cross-sectional view of FIG. 13.

Embodiments of the present invention will be described below based on the drawings.

In FIGS. 1 and 2, reference numeral 1 indicates a floor inspection hole installed on the floor surface 2. As shown in FIG. This floor inspection port 1 is equipped with an outer frame 3 that is placed and fixed on the floor surface 2 of a building/structure, and a lid body 4 that is removably inserted into the outer frame 3. . The outer frame 3 defines a square-shaped (quadrangular) opening 6 as an inspection opening facing the under-floor opening 5, and the lid body 4 has a square plate-shaped body corresponding to the opening 6 of the outer frame 3. It is formed as. In this case, the top surface of the lid 4 is provided with two screw holes 7 for handles, and a handle 8 is screwed into each of the screw holes 7, and the lid 4 is moved using both handles 8. By performing the opening/closing operation), the opening 6 of the outer frame 3 is opened/closed (see FIG. 2). Note that each screw hole 7 is closed during normal times by, for example, screwing a screw lid member into each screw hole 7.

The outer frame 3 is constructed using four outer frame constituent members 9, as shown in FIGS. 1, 2, 5, and 6. These four outer frame constituent members 9 are made of extruded aluminum or the like having a predetermined width and a constant length (one side length of the outer frame 3), and by connecting them to each other, the outer frame 3 forms a frame that partitions the square opening 6 therein.

The four outer frame constituent members 9 of the outer frame 3 constitute four side walls 10 of the outer frame 3, as shown in FIGS. 2, 3, 5, and 6. Each side wall portion 10 is formed by orienting the plate surface of each outer frame component 9 to the side of the outer frame 3, and each side wall portion 10 has an inclined wall portion 11 that forms the main body of the side wall portion 10. , an upper component part 12 provided continuously on the upper part of the inclined wall part 11 , and a lower part constituent part 13 provided continuously in the lower part of the inclined wall part 11 . At least the inner surface 11a of the inclined wall part 11 is inclined between the upper and lower parts of the outer frame 3 so that the opening 6 of the outer frame 3 widens upward, and the angle of inclination is different from that in the upright state (described later). The reference direction (line) is θ1 (see FIG. 4).

As shown in FIG. 3, the upper component part 12 includes a first support part 14 that extends from the upper end of the inclined wall part 11 toward the outside (side) of the outer frame 3, and a first support part 14 that extends from the tip of the first support part 14. It is provided with an upright wall section 15, an overhanging section 16 that extends further outward from the outer frame 3 from the upper end of the upright wall section 15, and a hanging section 17 that hangs downward from the tip of the overhanging section 16. . The first support part 14 has an upper surface 14a that plays a role of receiving the load of the lid 4 acting through the upper outer peripheral edge of the lid 4 (an annular groove 32 described later) and a packing material 33 described below. The 1 support part 14, the upright part 15, the overhang part 16, and the hanging part 17 work together to reinforce the strength of the upper part of the outer frame 3.

As shown in FIG. 3, the lower component part 13 includes a second support part 18 extending horizontally from the lower end of the inclined wall part 11 toward the inside of the outer frame 3, and a second support part 18 that is bent downward from the tip of the second support part 18. A bending portion 19 that is bent is provided. The upper surface 18a of the second support part 18 has the role of regulating the downward movement of the lid 4 at a predetermined position (as a stopper) as the packing material 33 described below deforms under the load of the lid 4. role). Further, the second support portion 18 and the bent portion 19 serve to reinforce the strength of the lower portion of the outer frame 3. In this case, from the viewpoint of increasing the strength of the lower part, it is more preferable to provide a new bent part from the tip of the bent part 19 so as to further oppose the first support part 14. The new bent part was omitted from the viewpoint of filling the (underfloor finishing material) smoothly without creating any nests inside.

As shown in FIGS. 3 to 6, a first fixing piece 20A is attached to the outer surface of each outer frame component 9 (each inclined wall portion 11) of the outer frame 3 at the longitudinal center thereof. . Each first fixing piece 20A has a band-like shape, and the base end plate surface of each first fixing piece 20A is fixed to the outer surface of the inclined wall portion 11. The distal end of each first fixing piece 20A is bent with respect to the proximal end, and is moved away from the outer surface of the inclined wall portion 11 while turning the plate surface vertically (in a horizontal state). A long hole 21A is formed at the tip of each first fixing piece 20A so as to be open to the outside from the tip of the first fixing piece 20A. Note that instead of the elongated hole 21A, a round hole, a loose hole, a notch, etc. can be used as appropriate.

As shown in FIGS. 3 to 6, a concrete base 22 serving as a frame is arranged at the lower part of the installation position of the outer frame 3 (around the underfloor opening 5), and a concrete base 22 serving as an anchor member is placed on the concrete base 22. A plurality of threaded rods 24A of the first anchors 23A are installed. When forming the concrete base 22, an insert nut is embedded and a threaded bolt (threaded rod 24A) is screwed into the first anchor 23A. Each first anchor 23A includes a threaded rod 24A with one end screwed into the concrete base 22 and the other end extending upward, and a pair of nuts 25A (connecting portion) screwed onto the threaded rod 24A. The first anchors 23A are installed on the outer side of each outer frame member 9 of the outer frame 3 at a position facing the longitudinal center of each outer frame member 9. has been done. As shown in FIG. 7, the threaded rods 24A of each of the first anchors 23A are attached to each of the first fixed pieces before mortar 27 as a floor finishing material is filled on the concrete base 22 (around the outer frame 3). Each of the first fixing pieces 20A is inserted into the elongated hole 21A in the elongated hole 21A from the tip opening thereof, and each of the first fixing pieces 20A is clamped ( connected). As a result, the outer frame 3 is fixed to the concrete base 22 via each of the first fixing pieces 20A and each of the first anchors 23A. Even if the fixed ends try to bend inward of the outer frame 3, the clamping force exerted by the pair of nuts 25A in each first anchor 23A holding each first fixed piece 20A pulls and stops the bending force.

As shown in FIGS. 5 and 6, the outer frame component 9 of the outer frame 3 has a second fixing member attached to one of the two outer frame components 9 constituting each of the four corners 26 of the outer frame 3. Piece 20B is attached. Each second fixing piece 20B is located closer to the corner 26 than the longitudinal center of the outer frame member 9 to which the second fixing piece 20B is attached. In the embodiment, second fixing pieces 20B are attached to both ends (both sides) of each pair of opposing outer frame members 9 (see FIGS. 5 and 6). Each of the second fixing pieces 20B has the same configuration as the first fixing piece 20A, and the only difference between these two fixing pieces 20A and 20B is the mounting position with respect to each outer frame component 9 in the outer frame 3. . Regarding each second fixing piece 20B, a second anchor 23B having the same configuration as the first anchor 23A is prepared, and the threaded rod 24B of each second anchor 23B is in a state opposite to each second fixing piece 20B. and are respectively planted on concrete foundations 22. The long hole 21B at the other end of each second fixing piece 20B is filled with mortar 27 before it is filled on the concrete base 22 (around the outer frame 3), as in the case of each first anchor 23A. The threaded rod 24B of each second anchor 23B is inserted, and the other end of each second fixing piece 20B in such a state is held by a pair of nuts 25B screwed onto the threaded rod 24A (see FIG. (see 7). In this case, the height of the second fixed piece 20B is adjusted by a pair of nuts (connecting parts) 25B screwed onto each threaded rod 24B, and the height and posture (gradient) of the outer frame 3 are adjusted by adjusting the height. ) adjustments are made. This is because each second fixing piece 20B is attached to the four corners of the outer frame 3, and the height and posture (gradient) of the outer frame 3 can be precisely adjusted. For this reason, it is preferable to connect and fix the first fixing piece 20A to the first anchor 23A described above after adjusting the height and posture (gradient) of the outer frame 3 using the second fixing piece 20B.

The periphery of the outer frame 3 (see FIGS. 6 and 7) positioned as described above is filled with mortar 27 as a floor finishing material, as shown in FIG. ). As is known, a mold is used for filling the mortar 27, and by filling the mortar 27, each of the first and second anchor bolts 23A, 23B, and each of the first and second fixing pieces are formed in the mortar 27. 20A and 20B are buried, and the upper surface of the mortar 27 is finished as the floor surface 2. When filling the periphery of the outer frame 3 with mortar 27 (when placing the mortar 27), the mortar 27 is pushed so as not to form cavities inside. Therefore, a pressing force based on this acts on the outer frame 3 from the outside to the inside, but the longitudinal center portion of each outer frame component 9 in the outer frame 3 is Since it is fixed to the concrete base 22 via the first anchor 23A, each outer frame component member 9 of the outer frame 3 is prevented from bending inward of the outer frame 3 with both ends thereof being fixed ends. be done. On the other hand, when the first fixing piece 20A is not provided on each outer frame component 9 of the outer frame 3 (when only the second fixing piece 20B is used), as shown in FIG. , each outer frame component 9 is bent inward of the outer frame 3. The arrows in FIG. 9 indicate the pressing force when placing the mortar.

As shown in FIGS. 1 to 4, the lid body 4 is formed of a box-shaped inner frame 28 and mortar 29 (hardened material) filled in the inner frame 28. The lid body 4 is made to have an appropriate weight (for example, about 30 kg in weight) with mortar 29 so that the opening 6 of the outer frame 3 cannot be opened without using the handle 8 described above, and the packing material 33 described later is This is to ensure sealing performance between the inner surface of the outer frame 3 and the side surface of the lid body 4 by compressing and deforming it.

This will be specifically explained with reference to FIGS. 3 and 4. The inner frame 28 of the lid body 4 includes a bottom plate part 30, an inclined wall part 31 that stands up in an inclined state from the peripheral edge of the bottom plate part 30, and an inner frame 28 outward (laterally) from the upper end of the inclined wall part 31. ) and an annular groove 32 that extends to form an upper outer peripheral edge, and a packing material 33 as an elastic sealing material that is housed and held within the annular groove 32. The bottom plate part 30 cooperates with the inclined wall part 31 to form a box with an open top, and plays the role of making it possible to fill the inside of the box with mortar 29. The bottom plate portion 30 has a size that allows the outer peripheral edge of the lower surface of the bottom plate portion 30 to be placed on the second support portion 18 of the outer frame 3.

The inclined wall portion 31 is inclined (erected) from the peripheral edge of the bottom plate portion 30 so as to widen the upper opening of the inner frame 28 as it goes upward. The angle of inclination is θ2 with reference to the direction (line) in the upright state (a state perpendicular to the bottom plate portion 30, which will be described later). (exaggerated display in FIG. 4). As a result, the outer surface 31a of the inclined wall portion 31 faces the inner surface 11a of the inclined wall portion 11 in the outer frame 3, and is inclined such that the distance between the outer surface 31a and the inner surface 11a of the inclined wall portion 11a increases as it goes downward. .

The annular groove portion 32 includes an inner side portion 34 that stands upward from the upper end of the inclined wall portion 11, an overhang portion 35 that extends horizontally to the outside of the inner frame from the upper end of the inner side portion 34, and an overhang of the overhang portion 35. and an outer side portion 36 depending downwardly from the end. This annular groove part 32 forms a downwardly directed annular groove 37 due to its configuration, and when the lid body 4 closes the opening 6 of the outer frame 3, the opening of the annular groove 37 is 1 support portion 14 (see FIGS. 3 and 4). In this case, the position of the corner formed by the sloped wall part 31 and the inner side part 34 in the lid body 4 is the position of the upper surface 14a of the first support part 14 (the position of the corner part formed by the sloped wall part 11 and the first support part 14 in the outer frame 3). (the position of the corner formed by). This makes it easy to fit the lid 4 into the outer frame 3 in a normal state, and when fitting the lid 4 into the outer frame 3, it is stored in the annular groove 37 of the annular groove 32. The held packing material 33 can be accurately brought into contact with the upper surface 14a of the first support portion 14, and the sealing performance between the inner upper part of the outer frame 3 and the upper outer peripheral edge of the lid body 4 can be accurately ensured. Further, the annular groove portion 32 serves as a reinforcing member that restricts outward curvature of each inclined wall portion 31.

The packing material 33 is held within the annular groove 37 of the lid 4 and protrudes downward from the annular groove 37. This packing material 33 ensures the sealing performance between the lid 4 and the outer frame 3 when the opening 6 of the outer frame 3 is closed by the lid 4. At that time, the packing material 33 Not only does it come into contact with the upper surface 14a of the first support part 14 of the frame 3, but it is also compressed and deformed by the weight of the lid body 4. This improves the sealing performance between the annular groove portion 32 forming the upper outer peripheral edge of the lid body 4 and the upper surface 14a of the first support portion 14, and prevents water, dirt, etc. from entering the outer frame 3. is suppressed. In addition, as the packing material 33 is compressed and deformed, the lid 4 is displaced downward within the outer frame 3, and the outer peripheral edge of the bottom plate 30 of the lid 4 comes into contact with the second support portion 18 of the outer frame 3. Further displacement of the lid body 4 is restricted. Therefore, a predetermined load (set load) is always applied to the packing material 33 via the annular groove 32 of the lid 4, and the sealing performance is maintained at a constant high level. At this time, since the packing material 33 is compressed and deformed using the load (self-weight) of the lid 4, there is no need to prepare a special pushing device for pushing the lid 4 into the outer frame 3, and the structure can be improved. It can be simplified.

Also, at this time, since the inclination angle θ2 of the inclined wall outer surface 31a of the lid body 4 is larger than the inclination angle θ1 of the inclined wall inner surface 11a of the outer frame 3, the opening 6 of the outer frame 3 is closed by the lid body 4. At this time, the sloped wall outer surface 31a of the lid 4 does not engage with the sloped wall inner surface 11a of the outer frame 3, and the lid 4 does not get caught in dust or the like. Therefore, the lid 4 is fitted into the outer frame 3 in a normal state, and the load of the lid 4 is accurately transmitted to the packing material 33. As a result, as described above, the lid body 4 is displaced based on the compressive deformation of the packing material 33 until it comes into contact with the second support part upper surface 18a, and a predetermined load (set load) is reliably applied to the packing material 33. (The sealing performance of the packing material 33 between the lid body 4 and the outer frame 3 is maintained at a constant high level).

Such a floor inspection port 1 is constructed by the following procedure. First, while preparing the aforementioned outer frame 3 (which includes a plurality of first and second fixing pieces 20A, 20B), a plurality of first and second fixing pieces are placed on the concrete base 22 around the outer frame installation position (predetermined position). 1. Plant the second anchors 23A and 23B. Next, the outer frame 3 is placed at the outer frame installation position, and the first and second fixing pieces 20A and 20B of the outer frame 3 are attached to the first and second anchors 23A and 23B, respectively (see FIG. 5). Thereafter, mortar 27 as a floor finishing material is filled around the outer frame 3 to finish the floor. In this case, even if the mortar 27 is filled around the outer frame 3 with the opening 6 of the outer frame 3 open, each outer frame component 9 of the outer frame 3 will not bend due to the first fixing pieces 20A, etc. This is as stated above. After completing this floor finishing process, it becomes possible to fit the lid 4 into the outer frame 3.

Therefore, in such a floor inspection opening 1, since the longitudinal center portion of each outer frame component 9 of the outer frame 3 is fixed to the concrete base 22 via the first fixing piece 20A, the outer frame 3 Mortar 27 as a floor finishing material is cast around the opening 6 in the open state (not closed by the lid 4), and the pressing force is applied to the inner side in the longitudinal direction of each outer frame component 9. Even if it acts on a portion, it is possible to suppress each outer frame component member 9 from bending inward of the outer frame 3. As a result, there is no problem in opening and closing the lid 4 with respect to the outer frame 3, and even if the opening 6 of the outer frame 3 is opened during construction of a building or structure, the lid 4 with respect to the outer frame 3 This eliminates the problem of hindrance to opening and closing.

In addition, in this floor inspection opening 1, since the inclination angle θ2 of the inclined wall outer surface 31a of the lid body 4 is larger than the inclination angle θ1 of the inclined wall inner surface 11a of the outer frame 3, the outer frame When closing the opening 6, dust or the like may get caught between the outer surface 31a of the sloped wall of the lid 4 and the inner surface 11a of the sloped wall of the outer frame 3, or the outer surface 31a of the sloped wall and the inner surface 11a of the sloped wall may , the lid body 4 will not engage with the outer frame 3 depending on how it is inserted into the outer frame 3. Therefore, when the lid 4 is inserted into the outer frame 3, the insertion is in a normal state, and the load of the lid 4 acts on the packing material 33 via the annular groove 32 of the lid 4. The packing material 33 is reliably compressed and deformed. As a result, when the lid body 4 is inserted into the outer frame 3, the sealing performance between the outer frame 3 and the lid body 4 can be ensured accurately at any time. It is possible to prevent deterioration depending on the insertion state (incorrect state).

Moreover, in this case, as the packing material 33 is compressed and deformed, the bottom plate part 30 of the lid body 4 is displaced until it comes into contact with the second support part 18, and the packing material 33 is loaded with a predetermined load of the load of the lid body 4. (set load) is applied reliably. Therefore, when the lid body 4 is inserted into the outer frame 3, the compressive deformation of the packing material 33 can be kept constant, and its sealing performance can be maintained at a constant high level.

Furthermore, since the inclined wall part 11 of the outer frame 3 is inclined and the inclined wall part 11 is supported by the mortar 27, the outer frame 3 has a wider surface area than when the inclined wall part 11 is not inclined (in the case of being upright). Therefore, even if the lid 4 is heavy, the lid 4 can be accurately supported by the outer frame 3 (preventing the outer frame 3 from falling off).

FIG. 10 shows the second embodiment, and FIGS. 11 to 14 show the third embodiment. In each embodiment, the same components as those in the first embodiment are given the same reference numerals, and the explanation thereof will be omitted.

A second embodiment shown in FIG. 10 shows a case where a wooden frame 22B is used instead of the concrete base 22 to partition the underfloor opening 5. In this second embodiment, a plurality of first and second anchors 23A and 23B are attached to the wooden frame 22B around the underfloor opening 5, and each of the outer frame components 9 of the outer frame 3 It is fixed to the wooden frame 22B via the second fixing pieces 20A, 20B and the first and second anchors 23A, 23B. In this case, the second support part 18 and the bent part 19 of the outer frame 3 are applied to the upper inner corner part 40 of the wooden frame 22B, and the second support part 18 And the bent portion 19 is used as a guide. Thereby, construction of the floor inspection port 1 can be facilitated. In this case as well, after positioning the outer frame 3, the floor surface 2 is formed by various methods, such as filling the periphery of the outer frame 3 with mortar 27.

The third embodiment shown in FIGS. 11 to 14 shows a modification of the method of attaching the outer frame 3 to the concrete base 22. Also in this third embodiment, like the first embodiment, a band-shaped first fixing piece 20A and a second fixing piece 20B are used (see FIG. 13).

In this embodiment, as shown in FIG. 11, unlike the first and second embodiments, each base end portion 41 of the first fixing piece 20A and the second fixing piece 20B is the first support in the outer frame 3. They are attached to the lower surface of the section 14, respectively. From each base end portion 41 to the distal end portion 42, an intermediate portion 43 of a certain length is bent from each base end portion 41 to extend below the first support portion 14, and the intermediate portion 43 A distal end portion 44 extending beyond the outer frame 3 is bent so as to extend outward in the lateral direction of the outer frame 3. Therefore, when such an outer frame 3 is placed at the installation position (before filling the mortar 27), each of the first fixing pieces 20A and each of the second fixing pieces 20B, as shown in FIGS. 11 and 12, The intermediate portion 43 extends in the vertical direction, and the tip end portion 44 extends laterally outward of the outer frame 3 along the concrete base 22.

As shown in FIG. 11, a concrete base 22 is arranged at the lower part of the installation position of the outer frame 3 (around the underfloor opening 5), and a plurality of threaded rods 24 as fixing members are mounted on the concrete base 22. It is planted. Each of the plurality of threaded rods 24 serves as an object to which the tip end portion 42 of each first fixed piece 20A (each second fixed piece 20B) in the outer frame 3 is fixed, and the plurality of threaded rods 24, the threaded rods 24A, 24B of the first and second anchors 23A, 23B according to the first and second embodiments are used from the viewpoint of standardizing parts. Therefore, when the outer frame 3 is in a predetermined state at the installation position (in FIGS. 11 and 12, the state before filling with mortar 27), each first fixing piece 20A (each first fixing piece 20A in the outer frame 3) The tips 42 of the second fixing pieces 20B) reach each threaded rod 24, and the long holes 21A in the tips 42 of each first fixing piece 20A (each second fixing piece 20B) are connected to each other through the tip openings. A threaded rod 24 will be inserted. Under this state, the tip portion 42 of each first fixing piece 20A (each second fixing piece 20B) and each threaded rod 24 are fixed. In this case, in this embodiment, attention is paid to the use of the first and second anchors 23A, 23B (threaded rods 24A, 24B) according to the first embodiment, and the nuts 25, 25 are screwed onto the threaded rod 24. With the nuts 25, 25, the fixation of each first fixing piece 20A (each second fixing piece 20B) to each threaded rod 24 is reinforced. When reinforcing the nuts 25, 25, after fixing the tip 42 of each first fixing piece 20A (each second fixing piece 20B) to the threaded rod 24, each first fixing piece is tightened with the nuts 25, 25. 20A (each of the second fixing pieces 20B) may be clamped, or after the tips 42 of each of the first fixing pieces 20A (each of the second fixing pieces 20B) are clamped with the nuts 25, 25, The tips 42 of the first and second fixing pieces 20A and 20B may be fixed to the threaded rod 24. Of course, in this case, the nuts 25, 25 may be omitted.

Prior to fixing the tip portions 42 of each of the first fixing pieces 20A (each of the second fixing pieces 20B) to each threaded rod 24, the height and posture of the outer frame 3 are adjusted. Specifically, this will be explained based on FIGS. 13 and 14.

The underfloor structure in which the floor inspection opening 1 is provided generally has a recess 47 formed in the floor 46, and the underfloor opening 5 smaller than the recess bottom 47a is formed in the bottom 47a of the recess 47. . A step 48 is formed between the top surface of the floor 46 and the bottom surface 47a of the recess, and the bottom surface 47a of the recess is formed as the top surface of the concrete base 22. As described above, a plurality of threaded rods 24 are installed around the periphery.

Under such an underfloor structure, in order to adjust the height and posture of the outer frame 3, the outer frame 3 is placed above the underfloor opening 5 in a predetermined state using a pair of elongated support members 49. be done. Specifically, a pair of elongated support members 49 are attached to the upper side of the outer frame 3 so as to straddle a pair of opposing outer frame constituent members 9, and each of the support members 49 is then , are arranged so as to straddle the recess 47. Thereby, the ends of each support member 49 can be positioned on the upper surface of the floor part 46, and the outer frame 3 can be arranged in a predetermined state above the underfloor opening 5 (see FIG. 14). In this case, the pair of elongated support members 49 straddles a pair of opposing outer frame members 9, unlike in the case of other opposing pairs of outer frame members 9. This is because the second fixing pieces 20B are not provided on both sides of each outer frame component 9 and do not interfere with the arrangement of each support member 49.

When positioning the end of each support member 49 on the upper surface of the floor 46, a wedge member 50 is interposed between the end of each support member 49 and the upper surface of the floor 46. Each wedge member 50 has a slope 50a whose height decreases as it goes inward in the longitudinal direction of the support member 49, and by sliding each wedge member 50 in the longitudinal direction of the support member 49, each wedge member By adjusting the position of the end of the support member 49 with respect to the slope 50a of the outer frame 3, the height and posture of the outer frame 3 are adjusted. After the height and posture of the outer frame 3 are adjusted based on the pair of support members 49 and the wedge member 50, each of the first fixing pieces 20A (each of the second fixing pieces 20B) is attached to each of the threaded rods 24 described above. The distal end portion 42 of is fixed. As a result, the height and posture of the outer frame 3 have been adjusted with respect to the floor surface, and the pair of support members 49 are removed from the outer frame 3.

As shown in FIGS. 11 and 12, the area around the outer frame 3 whose height and posture have been adjusted is filled with mortar 27 as a floor finishing material, as in the first and second embodiments. (The mortar 27 is hardened after filling). Even when the mortar 27 is filled around the outer frame 3 (when placing the mortar 27), the pressing force acts on the outer frame 3 from the outside to the inside, as described above, but the outer frame 3 The longitudinal center portion of each outer frame component 9 in is fixed to the concrete base 22 via each first fixing piece 20A fixed to each threaded rod 24 before filling with mortar 27. Each of the outer frame constituent members 9 of the frame 3 is prevented from bending inward of the outer frame 3 with both ends thereof being fixed ends. Therefore, even in this case, even if the mortar 27 is filled around the outer frame 3 with the opening 6 of the outer frame 3 open, opening and closing of the lid 4 with respect to the outer frame 3 will be hindered. There isn't.

Although the embodiments have been described above, the present invention includes the following aspects.
(1) Filling the periphery of the outer frame 3 with concrete instead of the mortar 27 as a floor finishing material.
(2) As described in the above embodiment, it is preferable that each outer frame component 9 is provided with a first fixing piece, but two or three outer frame components 9 forming the corners of the outer frame 3 The first fixing pieces 20A may be provided at the central portions in the longitudinal direction.
(3) The inclined wall portion 11 of the outer frame 3 is made to stand upright.
(4) In the third embodiment, when fixing the tip portion 42 of each first fixing piece 20A (each second fixing piece 20B) to each threaded rod 24, welding is used.

The present invention provides a cover body 4 for the opening 6 of the outer frame 3 even when the floor surface 2 is formed by opening the opening 6 of the outer frame 3 to the outside and filling the surrounding area with mortar 27 or the like. It can be used to avoid hindrance to opening and closing.

1 Floor inspection opening 2 Floor surface 3 Outer frame 4 Lid body 6 Outer frame opening (inspection opening)
9 Outer frame constituent material 10 Side wall portion 20A First fixed piece (fixed piece)
20B Second fixed piece (fixed piece)
22 Concrete foundation (framework)
23A First anchor (anchor member)
23B Second anchor (anchor member)
25A Pair of nuts (connection part)
25B Pair of nuts (connection part)
26 Corner of outer frame 27 Mortar (floor finishing material)
30 Bottom plate part of the lid body 31 Slanted wall part of the lid body

Claims (5)

A floor inspection port is provided with an outer frame that partitions a rectangular inspection opening, and a lid that is removably inserted into the outer frame,
The outer frame members on at least two sides of the outer frame are each provided with a first fixing piece that is attached to a fixing member implanted in the frame and restricts inward warping of the outer frame member,
Each of the first fixing pieces is provided at a central portion in the longitudinal direction of each of the outer frame components;
A floor inspection port characterized by: In claim 1,
A second fixing piece is provided on the outer frame constituent members on two opposing sides of the outer frame, and is attached to a fixing member implanted in the frame and adjusts the height and posture of the outer frame,
The second fixing pieces are provided on both longitudinal sides of the two opposing sides of the outer frame component, respectively.
A floor inspection port characterized by: In claim 2,
Each of the first fixed pieces and each of the second fixed pieces are formed in a band-like shape extending in a direction away from the outer frame,
A long hole or a notch through which the fixing member is inserted is formed at the tip of each of the first fixing piece and the second fixing piece, respectively.
A floor inspection port characterized by: In any one of claims 2 to 3 ,
The fixing member is an anchor member implanted in the building frame,
Each of the first fixing pieces and each of the second fixing pieces is fixed to the anchor member by a connecting portion that is movable and adjustable in the vertical direction in the anchor member.
A floor inspection port characterized by: The method for constructing a floor inspection port according to claim 4,
implanting the anchor member in the frame, and attaching a first fixing piece and a second fixing piece of the outer frame to the anchor member by the connecting portion,
Next, the height and posture of the outer frame are adjusted by the second fixing piece and the connecting part,
Next, while maintaining the height and posture of the outer frame, the fixing position of the first fixing piece with respect to the anchor member is adjusted by the connecting portion ,
Next, a floor finishing material is filled around the outer frame to finish the floor.
A construction method for a floor inspection port characterized by the following.

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