RU207842U1 - Sanitary built-in module - Google Patents

Abstract

The utility model refers to building structures and can be used in the construction of residential and civil buildings using built-in sanitary-technical modules of factory readiness. The built-in sanitary-technical module is a three-dimensional block made with the possibility of being located inside the building and connecting to the utilities of the building, including walls, floor, ceiling and a doorway made in one of the walls, containing a plumbing box, utilities in the form of a ventilation channel and pipes of sewerage, cold and hot water supply, made with the possibility of connecting plumbing equipment, while the walls are made in the form of a frame structure, sheathed with sheet material, in which engineering communications are installed, the floor contains gripping elements for lifting and moving the module. According to the claimed technical solution, the floor is made in the form of a frame structure, sheathed with sheet material, along which waterproofing is made with an institution on the walls, and the gripping elements are rigidly fixed to the floor frame. The technical result is manifested in an increase in the manufacturability of the built-in sanitary module.

Description

The utility model refers to building structures and can be used in the construction of residential and civil buildings using built-in sanitary-technical modules of factory readiness.

In modern industrial housing construction, in order to reduce labor and time costs at the construction site, the construction of buildings from volumetric-spatial elements (modules) is used, which effectively increase the degree of prefabrication and prefabrication of prefabricated elements. The main prefabricated element of such buildings is a three-dimensional block, which is a completely finished room, room or even an apartment. In factory conditions, in these cases, in addition to the manufacture of building structures, it is possible to carry out finishing and equipment of premises, installation of floors, painting of walls, kitchen equipment, plumbing and electrical work, which in mass production significantly reduces labor and time costs. All work at the construction site is reduced to installing the unit in the design position and connecting it to external communications.

From the prior art, a three-dimensional sanitary-technical block of a building is known, which includes interconnected floor, wall and ceiling slabs and is equipped with cantilever protrusions for bearing on the supporting structures of the building formed by the continuation of the ceiling slab, while the protrusions are made in the form of discretely arranged beams perpendicular to the longitudinal wall block, the thickness of the protrusion is 1.5-3 times the thickness of the ceiling slab, and its length is 1.5-2 times the thickness of the walls of the block (inventor's certificate SU 897980 A1, IPC E04B1 / 348, publ. 01/15/1982).

From the prior art, a sanitary-technical cabin is known, which is a volumetric-spatial unit including walls, a floor, a ceiling and a doorway made in one of the walls, containing a plumbing box, utilities in the form of a ventilation duct and sewer pipes, cold and hot water supply , made with the ability to connect plumbing equipment, while the walls are made in the form of a frame structure sheathed with sheet material, and the floor is made of reinforced concrete in the form of a pallet and contains loops for lifting and moving the cab ("Construction of civil buildings: a textbook for students studying on direction "Architecture": stereotyped edition / [M. S. Tupolev and others]; under the general editorship of M. S. Tupolev. - Moscow: Architecture-S, 2007. p. 219-221).

Distinctive features of the proposed technical solution are, in particular, the implementation of the floor in the form of a frame structure, sheathed with sheet material, which is made of waterproofing with an institution on the walls; rigid fastening of the gripping elements to the floor frame.

The technical result of the proposed technical solution is manifested in an increase in the manufacturability of the built-in sanitary-technical module.

An increase in manufacturability, in particular, is determined by an increase in the convenience of production, installation, operation, as well as ensuring the maintainability of the built-in sanitary-technical module and is achieved, in particular, by reducing the weight of the structure and reducing the number of operations required to bring the module to a state of full readiness for immediate exploitation.

The technical result is achieved by the fact that in the built-in sanitary-technical module, which is a volumetric-spatial unit made with the possibility of being located inside the building and connecting to the utilities of the building, including walls, floor, ceiling and a doorway made in one of the walls, and contains a plumbing box, engineering communications in the form of a ventilation duct and sewer pipes, cold and hot water supply, made with the possibility of connecting plumbing equipment, the walls are made in the form of a frame structure sheathed with sheet material, the floor contains gripping elements for lifting and moving the module and is made in the form of a frame structure, sheathed with sheet material, along which waterproofing is made with an institution on the walls, and the gripping elements are rigidly fixed to the floor frame. As the sheet material with which the frame structure of the walls is sheathed, gypsum plasterboard sheets can be used, along which waterproofing and finishing are made. As a sheet material, with which the frame structure of the floor is sheathed, cement-bonded particle boards, on which the finish is made, can be used. Utilities can include drainage of the air conditioning system, and the plumbing box is made with inspection hatches or with removable panels. The frame structure of the module can be filled with heat and sound insulation material. The module can be made in full factory readiness, that is, contain plumbing fixtures connected to utilities.

The built-in sanitary-technical module, which is a volumetric-spatial unit, made with the possibility of being located inside the building and connecting with the utilities of the building, is characterized by its high manufacturability, including the possibility of quick and convenient installation until it is fully ready for immediate use. It is due to the fact that the module is a built-in object that the process of building a bathroom-room in a residential or administrative building is reduced to a minimum of operations: transportation and installation of the module, and connecting devices.

Due to the fact that the module already contains a plumbing box, utilities in the form of a ventilation duct and sewage pipes, cold and hot water supply, made with the possibility of connecting plumbing equipment, there is no need for additional delivery of equipment, fasteners for fixing it to the construction site. In addition, the implementation of these means after the installation of the module, far from the factory conditions, significantly complicates the construction and installation work, since their arrangement must be performed already in a limited space, with the involvement of additional qualified personnel, using specific means and conditions. The declared built-in module is fully assembled, and for its readiness for direct operation, it is only necessary to connect the engineering communications of the built-in sanitary-technical module to the communications of the building, which is a simple and not laborious operation that does not require high-tech equipment.

The execution of walls and floors in the form of frame structures allows not only to reduce the total weight of the structure to 1500 kg, but also to place engineering communications inside the frame, made in the form of sewer pipes, cold and hot water supply, ventilation, as well as electrical wiring and attach plumbing fixtures, lighting devices, sockets and diffusers, which is the most technologically advanced in assembly, since no slitting of concrete structures is required, and fixing all engineering communications is possible on the frame profiles, which is also the most technologically advanced, reliable and convenient, since additional wall reinforcements are not required and floor in the place of attachment of utilities. The floor contains gripping elements for lifting and moving the module, the gripping elements are rigidly fixed to the floor frame, which is technologically advanced, convenient and reliable, since no additional reinforcement of the floor structure is required at the place where the gripping elements are attached. As a result, a sanitary-technical module of full factory readiness can be created with the possibility of transporting it to the object and installing it on the floor without additional revision at the construction site. The implementation of the walls and the floor with frame allows to reduce the mass of the module in relation to solid ones, including concrete slabs of partitions and the floor, as well as to place and fix engineering communications in the frame structures as technologically as possible. And the placement of all utilities as part of the module, full or partial equipping of the module with plumbing fixtures connected to the communications, allows you to perform all work as technologically as possible in the factory, reduce construction time with an increase in the quality of finishing work.

The frame of the walls and floor is made mainly of metal, for example, from an aluminum or steel profile of various cross-sections, fastened by any method known from the prior art, riveting, welding, bolting, etc.

Due to the fact that the frame structures of the floor and walls are sheathed with sheet material, there is no need to carry out additional work, including the transportation of packages with cladding material, fasteners and tools for sheathing the frame, as well as sheathing work at the construction site, which can significantly reduce manufacturability. In addition, any building sheet material is characterized by its low weight, unlike, for example, concrete, and work with light frame structures increases the manufacturability of the module assembly, since the frame walls and the floor can be conveniently deployed and turned over when they are fastened together and placed in them engineering communications.

The frame structure of the floor is sheathed with sheet material, mainly cement-bonded particle boards, along which waterproofing is performed with an institution on the walls. Cement particle boards combine high rigidity and strength, and at the same time, this material is very convenient in cutting and attaching it to the frame, which also increases the manufacturability of the module assembly, and cement particle boards are lighter than concrete slabs of the same size.

The implementation of waterproofing on the sheet material of the frame structure with an institution on the walls is important for fulfilling the purpose of the declared technical solution, since the sanitary-technical premises must contain waterproofing, and its implementation in the factory improves the quality of such a coating, the application is technological in compliance with all required standards and with factory quality control. Also, the implementation of a waterproofing layer allows you to reduce the weight of the built-in module, since there is no need to use heavy waterproof plates, and it is possible to use light sheet materials that are protected by waterproofing. Due to the waterproofing, manufacturability, ease of installation and maintainability of the built-in module is ensured, since in the process of connecting plumbing fixtures and their operation, water leakage to the floor is a common situation, and waterproofing on sheet material frees builders from additional preparatory work on the device of temporary waterproofing during commissioning module, prevention of accidents, as well as dismantling of temporary waterproofing structures.

Waterproofing can be done, for example, by coating or pasting and installed on the walls to a height of at least 20 cm, which allows you to comply with the requirements for waterproofing the premises. As materials for waterproofing can be used "TERRAKO" Flexicoat or analogs (coating) and TECHNOELAST or analogs (coating).

The walls of the module, sheathed with sheet material along the frame, can also be made with waterproofing and finishing, for example, coated with ceramic tiles and / or facing panels. Since the frame of the walls is made at the factory, it has minimal linear deviations from the given shape, which makes it possible to increase the manufacturability of the module, to simplify the production of ceramic tiles with a minimum amount of adhesive solution, which also leads to a decrease in the weight of the module.

The use of gypsum plasterboard sheets as a sheet material, with which the frame structure of the walls is sheathed, also characterizes the built-in module with high manufacturability, since this material is easy to cut and has a reduced weight.

The ceiling can be, for example, made of a multilayer combined PVC-EPPS (XPS) -PVC panel (polyvinyl chloride - extruded polystyrene foam - polyvinyl chloride), or from a laminated PVC film chipboard (chipboard), or from a combined panel galvanized metal sheet - PU foam (polyurethane foam) (PIR / PUR) - PVC sheet, or from plastic panels, or from painted metal strips, or from PVC tension membrane with fittings for easy installation on it, in particular, ventilation and lighting devices. When installing a ceiling made of gypsum plasterboard, tension or rack, a supporting frame is made that is identical to the frame of the module walls. Making the ceiling from these materials, and not from a concrete slab, as is known from the prior art, can significantly reduce the weight of the module and achieve minimal linear deviations from the specified shapes, since the assembly and sheathing of the frame are made in the factory.

To realize the purpose, the built-in sanitary-technical module contains engineering communications in the form of a ventilation duct and sewage pipes, cold and hot water supply, made with the possibility of connecting sanitary equipment, located partially inside the walls and floor, between the frame elements. The specified channels and pipes can be made of steel, including galvanized and stainless steel, metal-plastic, HDPE, PVC, polypropylene, cross-linked polyethylene. Utilities can also include drainage of the air conditioning system to be able to connect to air conditioning systems.

To be able to lift the sanitary-technical module and install it on the floor, lifting or lifting devices are attached to the gripping elements rigidly fixed to the floor frame. They allow you to raise the module, transferring the entire load to the floor frame, which means that excessive rigidity of the entire structure is not required and it can be made from lighter and more technologically advanced materials. Due to the gripping elements for lifting and moving the built-in module, ease of transportation and installation of the module in the building is achieved. There is no need to use additional straps, connectors or shipping containers. This design makes it possible to deliver the module to the place of its installation using a minimum of human effort and additional technological operations, both during the transportation of the module and during its installation.

In the sanitary-technical module for connection and maintenance of utilities, openings equipped with inspection hatches or removable panels can be provided, which greatly simplifies the maintenance and repair of equipment, which makes it possible to talk about the high manufacturability of the module.

The frame of the walls and floor can be filled with heat and sound insulation material. Such filling is the most technologically advanced way of obtaining walls with the required heat and sound insulation, since filling occurs with engineering communications already fixed in the frame, which are not damaged when the wall is filled with heat and sound insulation material, in addition, in the factory, such materials are simply consumed and the quality of each is monitored. module. The use of this material allows not only to reduce heat losses, to increase fire resistance and the level of sound insulation of the sanitary-technical module, but also to reduce the weight of the module, since the indicated properties of the module are achieved with a much smaller thickness of the walls and ceiling, and, therefore, with significantly less weight than in known concrete solutions. The ceiling outside can be covered with a protective self-adhesive foil heat and sound insulation material based on polyethylene foam or foam rubber or covered with sheet metal to protect the built-in sanitary module from precipitation rain, snow and welding splashes at the construction site.

Due to the fact that utilities include drainage of the air conditioning system, the need to install additional moisture removal systems after the installation of the built-in module is eliminated, which makes the process of bringing the module to full readiness more laborious and less technologically advanced. In addition, drainage ensures the maintainability of the module: such systems are easy to maintain, and their absence can lead to damage to the decoration of the room, equipment failure.

When connecting plumbing fixtures to utilities, the process of preparing the built-in module for direct operation is reduced to its transportation and installation.

The frame of the frame structure of the floor can be made welded along the perimeter from a metal profile made with a lower protrusion facing inward of the perimeter. This design makes it possible to quickly and conveniently place the floor sheet material, and, in general, simplifies the transportation and installation of the module due to the formation of the integrity of its lower contour.

To two parallel sides of the frame perimeter of the floor frame structure, girder strings can be attached, dividing the contour of the welded metal frame into cells, with the formation of shelves at the bottom for securing the sheet material, which further simplifies the installation and fixation of the sheets.

The claimed technical solution is illustrated further with the help of the figures, which conditionally represent embodiments of the built-in sanitary-technical module.

Figure 1 shows a general sectional view of a built-in sanitary module with installed plumbing fixtures with an inspection hatch, figure 2 is a general sectional view of a built-in sanitary module with removable panels, figure 3 is a general view of a built-in sanitary module, with slinging option.

Figures 1-3 show: frame walls 1, frame floor 2, ceiling 3, doorway 4, plumbing box 5, frame 6 of the frame structure of the floor, sheathed with cement-bonded particle boards 7, waterproofing 8 of which is made with an institution on frame walls, engineering communications 9, made in the form of sewage pipes, cold and hot water supply, a ventilation channel and containing elements for connecting plumbing fixtures 10, in the plumbing box 5 there are openings equipped with inspection hatches 11 or removable panels 12 for connecting and maintaining utility lines 9.

The built-in sanitary-technical module is designed to be located inside the building and connected to the utilities of the building.

The preferred embodiment of the claimed built-in sanitary module is presented below.

The metal frame of the walls 1 is filled with heat and sound insulating material and sheathed with gypsum plasterboard sheets (GKLV). The frame 6 of the floor frame structure can, in particular, be welded around the perimeter from a metal profile with a lower projection facing inwardly of the perimeter. To two parallel sides of the perimeter of the frame 6, girder strings are fixed, dividing the contour of the welded metal frame into cells, with the formation of shelves from below for fixing the sheet material. The frame 6 is made with a rigidity sufficient to hold the static and dynamic load during transportation and installation of the sanitary-technical module, and cement-bonded particle boards 7 (DSP) are used as sheet material, which are laid on the shelves (protrusions) of the frame and strings. Then the frame 6 is connected to the frame walls 1, a threshold is installed in the doorway 4, waterproofing 8 is performed with the establishment on the frame walls 1 and the threshold. The floor may contain finishes such as ceramic tiles. The sheet material of the walls 1 is waterproofed and finished from the inside, for example, with ceramic tiles and / or cladding panels. Ceiling 3 covers the entire perimeter of the plumbing module, it is fixed to walls 1 and finished. Engineering communications 9, in particular, in the form of sewer pipes, cold and hot water supply, ventilation, electrical wiring, are placed in the plumbing box 5 and / or partially in the frame of the walls 1 and partially on the profiles of the walls 1 outside, while on the frame walls 1, on the floor 2 and on the ceiling 3 there are elements for connecting plumbing fixtures 10, lighting fixtures, sockets and other equipment. In the preferred embodiment, the module already contains the plumbing fixtures 10 themselves, installed and connected to utilities 9. The plumbing box 5 provides openings for connecting and maintaining utilities 9, equipped with inspection hatches 11 or removable panels 12.

The height of the built-in sanitary-technical module varies depending on the height of the floor of a particular object.

The packaging of the built-in sanitary-technical module is carried out in polyethylene.

The combination of materials and their arrangement provide the requirements for sound insulation and waterproofing of the structure, the requirements for fire resistance, as well as the low weight of the structure. The weight of the structure is 700-1500 kg, depending on the configuration and the specified thickness and height of the walls. The properties of the structure can be changed during its manufacture in accordance with the nature of the use of the built-in sanitary-technical module and the conditions of its operation. This is achieved by adjusting the thickness of the outer walls, the thickness of the heat and sound insulation material, sheets of gypsum plasterboard, and finishing material.

Frame walls 1, floor 2 and ceiling 3 together provide sufficient structural strength to prevent structural damage during transportation and installation of the built-in sanitary module.

The built-in sanitary module, after being manufactured at the factory, is transported to the installation site using a truck and installed on site according to the layout and type of the sanitary module.

Lifting is carried out using removable slings or lifting devices fixed to the floor frame of the built-in sanitary module.

The roll-in of the built-in sanitary-technical module is carried out on wheels mounted in the holes of the floor frame for lifting devices.

Installation includes lifting a built-in sanitary module, for example, with a tower crane and installation (gluing) inside the building frame, which has a base and internal walls with technological gaps relative to them. The size of the technological gap from the inner walls is 20-50 mm.

Such a constructive implementation of the declared built-in sanitary-technical module makes it possible to produce standard sanitary-technical modules of various modifications with subsequent installation on one or another object. It should be noted that the figures presented, the description of the design and implementation do not exhaust the possible options for execution and do not in any way limit the scope of the proposed technical solution. Other variants of execution and use are possible within the scope of the claimed formula. Depending on the purpose, the sanitary-technical module can be made of different sizes, modifications, with full or partial complete set of sanitary ware and other devices, with varying degrees of heat and sound insulation.

Claims (12)

1. A built-in sanitary-technical module, which is a volumetric-spatial unit, made with the possibility of being located inside the building and connecting to the utilities of the building, including walls, floor, ceiling and doorway, made in one of the walls, containing a sanitary box, utilities in the form of a ventilation duct and sewer pipes, cold and hot water supply, made with the possibility of connecting plumbing equipment, while the walls are made in the form of a frame structure sheathed with sheet material, in which engineering communications are installed, the floor contains gripping elements for lifting and moving the module, which is different the fact that the floor is made in the form of a frame structure, sheathed with sheet material, along which waterproofing is made with an installation on the walls, and the gripping elements are rigidly fixed to the floor frame. 2. The built-in sanitary-technical module according to claim 1, characterized in that gypsum plasterboard sheets are used as the sheet material with which the frame structure of the walls is sheathed. 3. The built-in sanitary-technical module according to claim 1, characterized in that cement-particle boards are used as the sheet material with which the frame structure of the floor is sheathed. 4. The built-in sanitary-technical module according to claim 1, characterized in that waterproofing and finishing are made according to the sheet material with which the frame structure of the walls is sheathed. 5. The built-in sanitary-technical module according to claim 1, characterized in that the finish is made according to the sheet material with which the frame structure of the floor is sheathed. 6. The built-in sanitary-technical module according to claim 1, characterized in that the utilities include drainage of the air conditioning system. 7. The built-in sanitary-technical module according to claim 1, characterized in that the sanitary box is made with inspection hatches. 8. The built-in sanitary-technical module according to claim 1, characterized in that the sanitary box is made with removable panels. 9. The built-in sanitary-technical module according to claim 1, characterized in that the frame structure is filled with heat and sound insulation material. 10. The built-in sanitary-technical module according to claim 1, characterized in that plumbing fixtures are connected to the utilities. 11. The built-in sanitary-technical module according to claim 1, characterized in that the frame of the frame structure of the floor is welded along the perimeter of a metal profile made with a protrusion facing the inside of the perimeter for fixing sheet material thereon. 12. The built-in sanitary-technical module according to claim 11, characterized in that girder strings are fixed to two parallel sides of the frame perimeter of the floor frame structure, dividing the contour of the welded metal frame into cells, with the formation of shelves from below for fixing the sheet material.

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