Deformed joint integrated waterproof device
By installing an integrated waterproofing device as a single unit outside the utility tunnel, the problem of difficult installation of waterproofing components for expansion joints is solved, construction efficiency and quality are improved, and a double-layer waterproofing effect and leakage repair capability are achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CCFEB CIVIL ENG
- Filing Date
- 2025-04-15
- Publication Date
- 2026-07-03
AI Technical Summary
The installation of waterproof components for expansion joints in existing integrated utility tunnels is difficult, affecting construction progress and quality, and easily generates waste materials, making it difficult to install efficiently in confined spaces.
An integrated waterproofing device is adopted, including an installation frame, an embedded waterstop, a U-shaped plate, a connecting structure, an external waterstop, and a seamless pipe. All components are integrated and molded as one piece outside the construction site and installed outside the integrated utility tunnel by hoisting, forming a double-layer waterproof structure.
It improves the installation efficiency and precision of waterproof components, avoids construction site limitations, ensures construction progress and quality, provides a double-layer waterproof effect, and can be repaired by grouting through seamless pipes when leakage occurs in expansion joints.
Smart Images

Figure CN224451727U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of building engineering technology, and in particular, to an integrated waterproof device for expansion joints. Background Technology
[0002] Integrated utility tunnels, also known as common trenches or underground integrated utility tunnels, are a type of modern urban infrastructure that integrates various municipal pipelines such as electricity, communications, gas, water supply, drainage, and heating within a single underground tunnel space. Their core objective is to achieve intensive use of urban underground space and solve problems such as repeated excavation and maintenance difficulties caused by traditional direct burial methods.
[0003] In the construction of integrated utility tunnels, expansion joints are artificial gaps set along the longitudinal or transverse direction of the tunnel. By dividing the continuous structure into independent sections, each section is allowed to deform freely (expand or settle) within a certain range. This is used to alleviate structural stress caused by external factors such as temperature changes, uneven foundation settlement, and earthquakes, and to avoid structural cracking or damage caused by stress concentration.
[0004] Since integrated utility tunnels are built beneath the soil, groundwater can easily seep in and threaten their structural safety. Therefore, waterproofing is one of the core requirements in their design and construction. Waterproofing measures not only directly affect the safety of the tunnel structure, but also the stable operation of the internal pipeline system, maintenance costs, and the normal functioning of the city.
[0005] Existing expansion joints are mainly formed by binding and pouring on-site. The waterproof components are cut and adjusted according to needs, and the sponge boards used as expansion joints are fixed to the reinforcing bars to combine with the outer formwork. However, the above method has the following shortcomings:
[0006] 1) When the site is limited, the installation of waterproof components such as external waterstops, internal waterstops, seamless steel pipes and steel reinforcement structures is difficult, time-consuming and labor-intensive, and the installation efficiency is low.
[0007] 2) During concrete construction, expansion joints may shift out of alignment and have vertical deviations. Secondary cutting is required to widen the expansion joint to meet the verticality requirements. In addition, the depth of the sealing groove varies, requiring manual chiseling and correction, which greatly affects the construction progress.
[0008] 3) A large amount of waste will be generated during cutting and correction. If the waste is not cleaned up in time, it will cause serious quality problems in the later construction. Cleaning it up in time will consume a lot of manpower and delay the construction progress. Utility Model Content
[0009] This utility model provides an integrated waterproof device for expansion joints to solve the technical problems of existing expansion joint formation methods in integrated utility tunnels, which result in inefficient installation of waterproof components, affecting construction progress and quality.
[0010] According to one aspect of this utility model, an integrated waterproofing device for expansion joints is provided, comprising an installation frame for enclosing an integrated utility tunnel, a centrally embedded waterstop located at the center of the edge of the installation frame, two U-shaped plates arranged on the installation frame and respectively located on opposite sides of the centrally embedded waterstop to form U-shaped grooves to accommodate expansion joint filler material, a connecting structure arranged on the outside of the installation frame, an externally attached waterstop affixed to the connecting structure, and a plurality of seamless pipes connected to the installation frame. The seamless pipes pass through the U-shaped plates to communicate with the U-shaped grooves. The installation frame, the centrally embedded waterstop, the two U-shaped plates, the connecting structure, the externally attached waterstop, and the seamless pipes are integrated into one piece.
[0011] As a further improvement to the above technical solution:
[0012] Furthermore, the mounting frame includes multiple transverse panels, multiple longitudinal panels connected end to end, multiple connecting ribs connected end to end, multiple first reinforcing ribs, and multiple second reinforcing ribs. The longitudinal panels are connected to the bottom of the multiple transverse panels, and the connecting ribs are connected to the top of the multiple transverse panels. The middle of the transverse panels in the horizontal direction has a vertically formed cavity for accommodating the embedded waterstop. The first reinforcing ribs are arranged vertically and connected to the outer side of the transverse panels and the outer side of the longitudinal panels respectively. The second reinforcing ribs are connected to the inner side of two adjacent longitudinal panels respectively. The connecting structure is arranged on the outer side of the transverse panels.
[0013] Furthermore, the transverse frame includes a transverse base frame arranged in an inverted trapezoidal shape, two transverse side frames arranged at intervals on the transverse base frame, and a transverse top frame arranged on the outer transverse side frames. The two transverse side frames and the transverse base frame enclose a central embedded cavity, and the transverse top frame and the outer transverse side frames are connected to the connecting structure.
[0014] Furthermore, the longitudinal frame includes a first longitudinal rib, a second longitudinal rib, and multiple longitudinal diagonal ribs. The first longitudinal rib is connected to the bottom of the transverse base frame, the second longitudinal rib is connected to the top of the transverse base frame, and the longitudinal diagonal ribs are connected to the first longitudinal rib and the second longitudinal rib, respectively.
[0015] Furthermore, the connecting structure includes a fixing plate abutting against the outside of the transverse top frame, a first fastener connected to the top of the fixing plate and the transverse top frame respectively, and a second fastener connected to the bottom of the fixing plate and the transverse side frame respectively.
[0016] Furthermore, the top of the fixing plate is bent and provided with a first mounting edge, and the top of the transverse top frame is provided with a connecting edge corresponding to the first mounting edge. The first fixing member is connected to the first mounting edge and the connecting edge respectively.
[0017] Furthermore, the first fastener includes a fixing bolt passing through the connecting edge and the first mounting edge, a limiting nut located on the inner side of the first mounting edge and threadedly connected to the fixing bolt, and a locking nut located on the outer side of the first mounting edge and threadedly connected to the fixing bolt.
[0018] Furthermore, the bottom of the fixing piece is bent to provide a second mounting edge, and the transverse side frame is provided with a second connecting edge corresponding to the second mounting edge. The second fixing member is connected to the second connecting edge and the second mounting edge respectively.
[0019] Furthermore, the second fastener includes a fixing bolt 2 passing through the connecting side 2 and the second mounting side, a limiting nut 2 located on the inner side of the second mounting side and threadedly connected to the fixing bolt 2, and a locking nut 2 located on the outer side of the second mounting side and threadedly connected to the fixing bolt 2.
[0020] Furthermore, the inner side of the transverse sheet holder is arranged at an acute angle relative to the horizontal plane; and / or the outer side of the transverse sheet holder is arranged at an acute angle relative to the horizontal plane.
[0021] This utility model has the following beneficial effects:
[0022] This utility model discloses an integrated waterproofing device for expansion joints. An embedded waterstop, two U-shaped plates, a connecting structure, and a seamless pipe are installed on an installation frame. An external waterstop is attached to the connecting structure. The installation frame, embedded waterstop, two U-shaped plates, connecting structure, external waterstop, and seamless pipe can be integrated into a single unit outside the construction site of the integrated utility tunnel. Because it is not limited by site constraints, the assembly of the embedded waterstop, seamless pipe, and external waterstop waterproofing components is simple, efficient, and precise. When installed outside the integrated utility tunnel by hoisting for concrete construction, the expansion joint will not experience eccentric displacement, eliminating the need for manual chiseling and correction, thus ensuring construction progress and preventing [unspecified issues]. The construction site generates waste materials, ensuring both construction quality and progress. After concrete pouring, a double-layer waterproofing is achieved through embedded and external waterstops. U-shaped plates with U-shaped grooves accommodate expansion joint filler material, ensuring the expansion joints can deform freely within a certain range and alleviating structural stress. In case of leakage at the expansion joints, seamless pipe grouting repairs the buffer layer formed after the filler material is injected. Compared to existing technologies, this solution integrates all components into a single unit, is not limited by the construction site, has high installation efficiency and assembly precision, which helps to accelerate construction progress, improve construction quality, and is highly practical, suitable for widespread promotion and application.
[0023] In addition to the objectives, features, and advantages described above, this utility model has other objectives, features, and advantages. The present utility model will now be described in further detail with reference to the figures. Attached Figure Description
[0024] The accompanying drawings, which form part of this application, are used to provide a further understanding of the present invention. The illustrative embodiments of the present invention and their descriptions are used to explain the present invention and do not constitute an undue limitation of the present invention. In the drawings:
[0025] Figure 1 This is a structural schematic diagram of the expansion joint integrated waterproof device according to a preferred embodiment of the present utility model;
[0026] Figure 2 This is a schematic diagram of the positioning frame in the expansion joint integrated waterproof device according to a preferred embodiment of this utility model;
[0027] Figure 3 This is a schematic diagram of the first part of the integrated waterproof device for expansion joints according to a preferred embodiment of the present invention;
[0028] Figure 4 This is a schematic diagram of the first structure of the longitudinal frame in the expansion joint integrated waterproof device of the present utility model according to a preferred embodiment;
[0029] Figure 5 This is a schematic diagram of the second structure of the longitudinal frame in the expansion joint integrated waterproof device of the present utility model according to a preferred embodiment;
[0030] Figure 6 This is a schematic diagram of the second part of the expansion joint integrated waterproof device according to a preferred embodiment of this utility model.
[0031] Legend:
[0032] 100. Mounting frame; 110. Horizontal panel frame; 111. Horizontal base frame; 112. Horizontal side frame; 113. Horizontal top frame; 114. Connecting edge one; 115. Connecting edge two; 120. Longitudinal panel frame; 121. First longitudinal rib; 122. Second longitudinal rib; 123. Longitudinal diagonal rib; 130. Connecting rib; 140. First reinforcing rib; 150. Second reinforcing rib; 200. Embedded waterstop; 300. U-shaped plate; 400. Connecting structure; 410. Fixing piece; 411. First mounting edge; 412. Second mounting edge; 420. First fastener; 430. Second fastener; 500. External waterstop; 600. Seamless pipe. Detailed Implementation
[0033] The embodiments of the present invention will be described in detail below with reference to the accompanying drawings. However, the present invention can be implemented in many different ways as defined and covered below.
[0034] like Figure 1 and Figure 2As shown, the expansion joint integrated waterproofing device of this embodiment includes an installation frame 100 for enclosing the outside of the integrated pipe gallery, an embedded waterstop 200 located in the middle of the edge of the installation frame 100, two U-shaped plates 300 arranged on the installation frame 100 and located on opposite sides of the embedded waterstop 200 to form a U-shaped groove to accommodate the expansion joint filler material, a connecting structure 400 arranged on the outside of the installation frame 100, an external waterstop 500 attached to the connecting structure 400, and a plurality of seamless pipes 600 connected to the installation frame 100. The seamless pipes 600 pass through the U-shaped plates 300 to communicate with the U-shaped groove. The installation frame 100, the embedded waterstop 200, the two U-shaped plates 300, the connecting structure 400, the external waterstop 500, and the seamless pipes 600 are integrated into one piece.
[0035] like Figure 1 and Figure 2 As shown, specifically, the integrated waterproofing device for expansion joints of this utility model comprises an embedded waterstop 200, two U-shaped plates 300, a connecting structure 400, and a seamless pipe 600 installed on an installation frame 100. An external waterstop 500 is attached to the connecting structure 400. The installation frame 100, embedded waterstop 200, two U-shaped plates 300, connecting structure 400, external waterstop 500, and seamless pipe 600 can be integrated and formed as a single unit outside the construction site of the integrated utility tunnel. Because it is not limited by site constraints, the assembly of the embedded waterstop 200, seamless pipe 600, and external waterstop 500 waterproofing components is simple, efficient, and precise. Therefore, when installed outside the integrated utility tunnel by hoisting for concrete construction, the expansion joint will not experience eccentric displacement. No manual chiselwork or repair is required, ensuring construction progress and preventing waste at the construction site. This guarantees both construction quality and progress. After concrete pouring, a double-layer waterproofing is achieved through an embedded waterstop 200 and an external waterstop 500. A U-shaped plate 300 with a U-shaped groove accommodates the expansion joint filler material, ensuring the expansion joint can deform freely within a certain range and relieving structural stress. In case of leakage at the expansion joint, grouting is performed through a seamless pipe 600 to repair the buffer layer formed after the expansion joint filler material has been filled. Compared to existing technologies, this solution integrates all components into a single unit, is not limited by the construction site, has high installation efficiency and assembly precision, which helps to accelerate construction progress, improve construction quality, and is highly practical and suitable for widespread promotion and application.
[0036] Optionally, the expansion joint filler material is a low-foaming polyethylene material. It should be understood that low-foaming polyethylene material is a material known to those skilled in the art.
[0037] Optionally, the U-shaped plate 300 is formed by cutting an aluminum plate, with its two edges bent upwards to form a U-shaped groove to accommodate expansion joint filler material.
[0038] like Figure 2 As shown, in this embodiment, the mounting frame 100 includes multiple transverse frame pieces 110, multiple longitudinal frame pieces 120 connected end to end, multiple connecting ribs 130 connected end to end, multiple first reinforcing ribs 140 and multiple second reinforcing ribs 150. The longitudinal frame pieces 120 are connected to the bottom of the multiple transverse frame pieces 110, and the connecting ribs 130 are connected to the top of the multiple transverse frame pieces 110. The middle part of the transverse frame pieces 110 in the horizontal direction has a vertically formed cavity for accommodating the embedded waterstop 200. The first reinforcing ribs 140 are arranged vertically and connected to the outer side of the transverse frame pieces 110 and the outer side of the longitudinal frame pieces 120 respectively. The second reinforcing ribs 150 are connected to the inner side of two adjacent longitudinal frame pieces 120 respectively. The connecting structure 400 is arranged on the outer side of the transverse frame pieces 110.
[0039] It should be understood that, in this embodiment, the horizontal direction of the horizontal frame 110 refers to the vertical direction of its length after it is installed in the construction site; the vertical direction of the longitudinal frame 120 refers to the horizontal direction of its length after it is installed in the construction site.
[0040] like Figure 2 As shown, specifically, the mounting frame 100 is rectangular in shape. Multiple transverse support frames 110 are spaced apart along any side of the mounting frame 100, with corresponding embedded cavities to accommodate the embedded waterstop strip 200. A connecting structure 400 is positioned on the outer side of the transverse support frames 110 to connect simultaneously with the multiple transverse support frames 110. Eight longitudinal support frames 120 are provided, arranged in pairs to connect to the outer bottom and inner bottom of the multiple transverse support frames 110 respectively. Eight connecting ribs 130 are provided, arranged in pairs to connect to the multiple transverse support frames 110 respectively. The outer top and inner top of the frame 110 are connected; there are four first reinforcing ribs 140, which are connected to the outer sides of the transverse frame 110 and the longitudinal frame 120 located at the four outer corners of the mounting frame 100, respectively; there are four second reinforcing ribs 150, which are connected to the inner sides of the two adjacent longitudinal frames 120 located at the four inner corners of the mounting frame 100, respectively; while ensuring the structural strength of the mounting frame 100 through the first reinforcing ribs 140 and the second reinforcing ribs 150, no reinforcing ribs are provided on the inner top of the mounting frame 100, so that the expansion joint can deform freely within a certain range, thus buffering the structural stress.
[0041] Optionally, in one embodiment, two adjacent transverse support frames 110 on any side of the mounting frame 100 are spaced 500mm apart.
[0042] like Figure 3As shown, in this embodiment, the transverse frame 110 includes a transverse base frame 111 arranged in an inverted trapezoidal shape, two transverse side frames 112 arranged at intervals on the transverse base frame 111, and a transverse top frame 113 arranged on the outer transverse side frames 112. The two transverse side frames 112 and the transverse base frame 111 enclose a central cavity. The transverse top frame 113 and the outer transverse side frames 112 are connected to the connecting structure 400.
[0043] like Figure 3 As shown, specifically, two transverse side frames 112 are installed through the transverse base frame 111, and a transverse top frame 113 is installed through the transverse side frames 112 located on the outer side. The embedded waterstop 200 is installed in the embedded cavity formed by the two transverse side frames 112 and the transverse base frame 111. The transverse top frame 113 and the transverse side frames 112 located on the outer side are connected to the connecting structure 400, so that the external waterstop 500 can be attached to the connecting structure 400 to form a double-layer waterproof after the expansion joint is cast and formed. The two U-shaped plates 300 are respectively installed on the two transverse side frames 112.
[0044] Optionally, in one embodiment, the distance between the two transverse side frames 112 is 50mm, the height of the transverse base frame 111 is 200mm, the height of the transverse side frames 112 is 400mm, and the height of the transverse top frame 113 is 600mm.
[0045] like Figure 3 As shown, optionally, in one embodiment, the transverse frame 110 consists of 5 horizontal ribs, 4 vertical ribs, and 2 diagonal ribs. The 4 horizontal ribs are arranged vertically at intervals, and another horizontal rib is arranged at the same horizontal level as the third horizontal rib and at intervals. Of the two diagonal ribs, one diagonal rib is connected to the inner side of the first, second, and innermost horizontal ribs of the first, second, and third horizontal ribs, respectively, while the other diagonal rib is connected to the outer side of the first, second, and outermost horizontal ribs of the first, second, and third horizontal ribs, respectively. Of the 4 vertical ribs, one vertical rib is connected to the middle of the first and second horizontal ribs of the second height. The middle of the highest horizontal rib is connected, and a vertical rib is connected to the outer side of the second highest horizontal rib and the third highest horizontal rib located in the inner part. A vertical rib is connected to the inner side of the second highest horizontal rib, the third highest horizontal rib located in the outer part, and the fourth highest horizontal rib. A vertical rib is connected to the outer side of the third highest horizontal rib located in the outer part and the fourth highest horizontal rib. That is, the horizontal base frame 111, two horizontal side frames 112 and a horizontal top frame 113 are formed by connecting the five horizontal ribs, four vertical ribs and two diagonal ribs. Two U-shaped plates 300 are respectively set on the two horizontal ribs of the third highest.
[0046] It should be understood that in this embodiment, "inside and outside" refers to the distance between each component and the integrated utility tunnel after the installation frame 100 is installed. The closer the distance, the inside; the farther the distance, the outside.
[0047] like Figure 4 and Figure 5 As shown, in this embodiment, the longitudinal frame 120 includes a first longitudinal rib 121, a second longitudinal rib 122, and a plurality of longitudinal diagonal ribs 123. The first longitudinal rib 121 is connected to the bottom of the transverse base frame 111, the second longitudinal rib 122 is connected to the top of the transverse base frame 111, and the longitudinal diagonal ribs 123 are connected to the first longitudinal rib 121 and the second longitudinal rib 122 respectively.
[0048] like Figure 4 and Figure 5 As shown, specifically, the length direction of the first longitudinal rib 121 is arranged horizontally, the length direction of the second longitudinal rib 122 is arranged horizontally, the first longitudinal rib 121 and the second longitudinal rib 122 are arranged at intervals in the vertical direction, the first longitudinal rib 121 can be connected to the bottom of multiple transverse base frames 111 respectively, and the second longitudinal rib 122 can be connected to the top of multiple transverse base frames 111 respectively, so as to connect multiple transverse frame 110 into a whole, and then by setting multiple longitudinal diagonal ribs 123 between the first longitudinal rib 121 and the second longitudinal rib 122, the overall structural strength is ensured.
[0049] like Figure 6 As shown, in this embodiment, the connecting structure 400 includes a fixing piece 410 abutting against the outside of the transverse top frame 113, a first fixing member 420 connected to the top of the fixing piece 410 and the transverse top frame 113 respectively, and a second fixing member 430 connected to the bottom of the fixing piece 410 and the transverse side frame 112 respectively. Specifically, the fixing piece 410 is fixed to the outside of the transverse top frame 113 by the first fixing member 420 and the second fixing member 430, so that the fixing piece 410 provides sufficient application area for the external waterstop 500, and the external waterstop 500 can be applied to the fixing piece 410.
[0050] like Figure 6 As shown, in this embodiment, the top of the fixing piece 410 is bent upward to form the first mounting edge 411, and the top of the transverse top frame 113 is provided with a connecting edge 114 corresponding to the first mounting edge 411. The first fixing member 420 is connected to the first mounting edge 411 and the connecting edge 114 respectively. Specifically, the top of the fixing piece 410 is bent upward to form the first mounting edge 411, and the top of the transverse top frame 113 is provided with a connecting edge 114 protruding upward. The first fixing member 420 is then connected to the first mounting edge 411 and the connecting edge 114 respectively to reliably fix the top of the fixing piece 410 to the transverse top frame 113.
[0051] like Figure 6As shown, in this embodiment, the first fixing member 420 includes a fixing bolt passing through the connecting edge 114 and the first mounting edge 411, a limiting nut located on the inner side of the first mounting edge 411 and threadedly connected to the fixing bolt, and a locking nut located on the outer side of the first mounting edge 411 and threadedly connected to the fixing bolt. Specifically, by having the fixing bolt passing through the connecting edge 114 and the first mounting edge 411, and then being threadedly connected to the fixing bolt by the limiting nut and the locking nut, the fixing bolt is fixed in place, thereby reliably fixing the top of the fixing piece 410 to the transverse top frame 113.
[0052] like Figure 6 As shown, in this embodiment, the bottom of the fixing piece 410 is bent to form a second mounting edge 412, and a connecting edge 115 corresponding to the second mounting edge 412 is provided on the transverse side frame 112. The second fixing member 430 is connected to the connecting edge 115 and the second mounting edge 412 respectively. Specifically, the bottom of the fixing piece 410 is bent downward to form the second mounting edge 412, and the connecting edge 115 is provided on the transverse side frame 112. The second fixing member 430 is then connected to the connecting edge 114 and the second mounting edge 412 respectively to reliably fix the bottom of the fixing piece 410 to the transverse side frame 112.
[0053] like Figure 6 As shown, in this embodiment, the second fixing member 430 includes a fixing bolt passing through the connecting edge 115 and the second mounting edge 412, a limiting nut located on the inner side of the second mounting edge 412 and threadedly connected to the fixing bolt, and a locking nut located on the outer side of the second mounting edge 412 and threadedly connected to the fixing bolt. Specifically, by having the fixing bolt passing through the connecting edge 115 and the second mounting edge 412, and then being threadedly connected to the fixing bolt by the limiting nut and the locking nut, the fixing bolt is fixed in place, thereby reliably fixing the bottom of the fixing piece 410 to the transverse side frame 112.
[0054] like Figure 3 As shown, in this embodiment, the inner side of the transverse frame 110 is arranged at an acute angle relative to the horizontal plane. When the installation frame 100 is hoisted and installed outside the integrated utility tunnel, it is initially clamped and fixed with the steel bars of the integrated utility tunnel to facilitate subsequent welding and fixing.
[0055] like Figure 3 As shown, in this embodiment, the outer side of the horizontal frame 110 is arranged at an acute angle relative to the horizontal plane so that the bottom of the horizontal frame 110 is relatively symmetrical and the structure is stable and reliable.
[0056] It should be understood that the above embodiments have been practically verified. The components are integrated and installed as a whole, requiring no on-site construction work. After hoisting and installation, only casting is needed to form the shape, which is convenient and quick. The expansion joint construction effect is good, and the waterproof effect is excellent.
[0057] The above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Various modifications and variations can be made to this utility model by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.
Claims
1. A deformation joint integrated waterproofing device, characterized by, The system includes an installation frame (100) for enclosing the integrated utility tunnel, an embedded waterstop (200) located in the middle of the edge of the installation frame (100), two U-shaped plates (300) arranged on the installation frame (100) and located on opposite sides of the embedded waterstop (200) to form a U-shaped groove to accommodate expansion joint filler material, a connecting structure (400) arranged on the outside of the installation frame (100), an external waterstop (500) attached to the connecting structure (400), and multiple seamless pipes (600) connected to the installation frame (100). The seamless pipes (600) pass through the U-shaped plates (300) to communicate with the U-shaped groove. The installation frame (100), the embedded waterstop (200), the two U-shaped plates (300), the connecting structure (400), the external waterstop (500), and the seamless pipes (600) are integrated into one piece.
2. The integrated deformed-seam flashing device of claim 1, wherein, The mounting frame (100) includes multiple transverse panels (110), multiple longitudinal panels (120) connected end to end, multiple connecting ribs (130) connected end to end, multiple first reinforcing ribs (140) and multiple second reinforcing ribs (150). The longitudinal panels (120) are connected to the bottom of the multiple transverse panels (110), and the connecting ribs (130) are connected to the top of the multiple transverse panels (110). The middle part of the transverse panels (110) in the horizontal direction has a vertically formed cavity for accommodating the embedded waterstop (200). The first reinforcing ribs (140) are arranged vertically and connected to the outer side of the transverse panels (110) and the outer side of the longitudinal panels (120) respectively. The second reinforcing ribs (150) are connected to the inner side of the two adjacent longitudinal panels (120) respectively. The connecting structure (400) is arranged on the outer side of the transverse panels (110).
3. The integrated deformed-seam flashing device of claim 2, wherein, The transverse frame (110) includes a transverse base frame (111) arranged in an inverted trapezoidal shape, two transverse side frames (112) arranged at intervals on the transverse base frame (111), and a transverse top frame (113) arranged on the outer transverse side frames (112). The two transverse side frames (112) and the transverse base frame (111) enclose a central cavity. The transverse top frame (113) and the outer transverse side frames (112) are connected to the connecting structure (400).
4. The integrated deformed-seam flashing device of claim 3, wherein, The longitudinal frame (120) includes a first longitudinal rib (121), a second longitudinal rib (122), and a plurality of longitudinal diagonal ribs (123). The first longitudinal rib (121) is connected to the bottom of the transverse base frame (111), the second longitudinal rib (122) is connected to the top of the transverse base frame (111), and the longitudinal diagonal ribs (123) are connected to the first longitudinal rib (121) and the second longitudinal rib (122) respectively.
5. The integrated deformed-seam flashing device of claim 3, wherein, The connection structure (400) includes a fixing piece (410) that abuts against the outside of the transverse top frame (113), a first fastener (420) that is connected to the top of the fixing piece (410) and the transverse top frame (113) respectively, and a second fastener (430) that is connected to the bottom of the fixing piece (410) and the transverse side frame (112) respectively.
6. The integrated deformed seam flashing device of claim 5, wherein, The top of the fixing piece (410) is bent and provided with a first mounting edge (411), and the top of the transverse top frame (113) is provided with a connecting edge (114) corresponding to the first mounting edge (411). The first fixing member (420) is connected to the first mounting edge (411) and the connecting edge (114) respectively.
7. The integrated deformed-seam flashing device of claim 6, wherein, The first fastener (420) includes a fixing bolt passing through the connecting edge (114) and the first mounting edge (411), a limiting nut located on the inner side of the first mounting edge (411) and threadedly connected to the fixing bolt, and a locking nut located on the outer side of the first mounting edge (411) and threadedly connected to the fixing bolt.
8. The integrated flashing and deformation joint of claim 5, wherein, The bottom of the fixing piece (410) is bent and provided with a second mounting edge (412). The transverse side frame (112) is provided with a connecting edge (115) corresponding to the second mounting edge (412). The second fixing piece (430) is connected to the connecting edge (115) and the second mounting edge (412) respectively.
9. The integrated flashing and deformation joint of claim 8, wherein, The second fastener (430) includes a second fixing bolt that passes through the second connecting side (115) and the second mounting side (412), a second limiting nut that is located on the inner side of the second mounting side (412) and threadedly connected to the second fixing bolt, and a second locking nut that is located on the outer side of the second mounting side (412) and threadedly connected to the second fixing bolt.
10. The integrated flashing and deformation joint of any of claims 1-9, wherein, The inner side of the transverse frame (110) is arranged at an acute angle relative to the horizontal plane; and / or The outer side of the horizontal frame (110) is arranged at an acute angle relative to the horizontal plane.