WO2017059764A1 - Modular heating floor - Google Patents

Abstract

A modular heating floor, including a central portion and a peripheral portion, consists of module units (45) and lace units (46). A plurality of module units (45) are jointed, through a positioning mortise (21), a positioning strip (22), a connecting screw (36) and an embedded nut (38), to form the center portion of the modular heating floor, and a plurality of lace units (46) are jointed, through a lace tenon (27), a plug strip (26), a connecting screw (36), an embedded nut (38) and a fixing screw (49), to form the peripheral portion of the modular heating floor. A floor heating water pipe through groove (11) or a floor heating cable through groove (12) is provided inside the modular heating floor, wherein a floor heating water pipe (43) is placed in the floor heating water pipe through groove (11), or a floor heating cable (44) is placed in the floor heating cable through groove (12), a pipeline channel (52) is arranged all around, and the bottom is disposed with an elastic cushion block (40), which is fixed with a foot screw (41) or directly lays on the ground or floor. The modular heating floor tackles the issues of poor fit and prone-to-deformation, static visual effect, low comfort, noisy when walked upon, low heat utilization and difficulties maintenance, etc.

Description

Floor heating module floor Technical field

The invention belongs to the technical field of decoration engineering of buildings, and relates to components of solid wood flooring, solid parquet flooring and paving systems thereof. The invention relates in particular to floor heating floor and paving systems, and to components for the system.

Background technique

Traditional floor heating floor, fixed heating water pipe or floor heating cable on the thermal insulation layer, directly install the tile after paving the fine stone concrete, or after the concrete is dried, lay the floor, because the floor heating pipe or the floor heating cable is buried underground, and once it appears Failure, the entire floor heating system needs to be reinstalled, and the floor will be scrapped.

In the traditional floor heating system, solid wood or other geothermal floor is laid. Because the keel cannot be used, most of the geothermal floor can only be directly paved on the ground. The combination between the geothermal floor and the floor heating floor is not tight, easy to loose, and the foot is not comfortable. The noise is large when walking, and the heat utilization rate is low. If the floor glue is used for bonding, the thermal conductivity of the heat is lower.

Patent Application Publication No. CN 102852308 A discloses a self-heating geothermal floor, including an embedded geothermal floor and a penetrating geothermal floor, the embedded geothermal floor consisting of a floor, a pipe, a notch, a groove, and a card. The strip is composed of a groove on one side of the floor and a strip on the other side, and two notches are arranged in parallel on the bottom surface of the floor, the slot is elongated, and the slot is The bottom of the mouth is provided with a circular pipe, and the penetrating geothermal floor is composed of an upper floor block, a lower floor block and a pipe, and the upper floor block and the lower floor block are respectively provided with two semi-circular grooves. The upper floor block and the lower floor block are bonded by waterproof wood glue, and the upper and lower semi-circular grooves on the upper floor block and the lower floor block form two cylindrical pipes, one side of the lower floor block There is a strip on the other side and a groove on the other side. The invention realizes self-heating of the floor by placing a floor heating pipe inside the floor, which improves the energy utilization rate, but it is directly installed on the heat insulating layer through the strips and the grooves, and the same is also combined between the floor blocks. Not tight, easy to deform and loose, the foot feels uncomfortable, and the single shape of the floor can not be parquet, can not meet the individualized pursuit of modern people.

Summary of the invention

In view of the above problems, the present invention provides a floor heating type module floor. The utility model solves the problems of deformation, looseness, single visual effect, poor foot comfort, high noise during walking, low heat utilization rate and high maintenance difficulty of the existing floor heating floor.

The floor heating type module floor of the invention comprises a central part and a peripheral part, and is composed of a modular unit and a lace unit, and the plurality of modular units are connected by a positioning groove, a positioning stringer, a connecting screw and a pre-embedded nut to form a floor heating type module floor. In the central part, a plurality of lace units are connected by a lace hoe, a plug-in stringer, a connecting screw, a pre-embedded nut and a fixing screw to form a peripheral portion of the floor of the floor heating type module, and the floor heating type module floor is provided with a floor heating water pipe channel or Floor heating cable slot, A floor heating pipe is placed in the floor of the floor heating water pipe, or a floor heating cable is placed in the floor of the floor heating cable. The floor of the floor heating type module is provided with a pipeline passage, and the bottom is provided with an elastic block, which is fixed by a ground screw or directly paved on the ground or the floor. On the surface.

The modular unit of the present invention consists of a mosaic panel, a substrate, a keel grid and a bottom surface, and is joined together under certain conditions by an adhesive, a nail or other fixing member to form an irreversible and firm whole. The outer shape is a rectangular parallelepiped, and the rectangular parallelepiped further comprises a rectangular parallelepiped having a square bottom surface, a moisture barrier layer on the lower bottom surface and a floor paint on the upper bottom surface.

The module unit is provided with a positioning groove with a rectangular cross section on the same plane, which is located in the lower part or the middle part of the substrate. The module unit is positioned by positioning the rafter, and the size of the positioning rafter is matched with the positioning groove. Mounting, positioning the purlins and positioning the troughs of the troughs into rounded corners.

The parquet panel of the present invention is composed of a plurality of rectangular blocks of equal thickness and different shapes, the height is the thickness of the block, and the inner angle of the adjacent adjacent blocks is equal to 180° or 360°, if the block The sides of the objects are arcs, and the sides of the adjacent blocks have the same curvature, and the blocks are seamlessly joined together, and the blocks are fixed together by a connecting nail or an adhesive.

The parquet panel is a rectangular parallelepiped, and a plurality of floor heating water pipe troughs or floor heating cable troughs parallel to the side of the parquet panel are evenly arranged on the lower part, and the top of the floor heating trough or the floor heating cable trough is on the same plane, the plane is parallel to the parquet The bottom surface of the panel has a semicircular or rectangular cross section of the floor heating channel or the floor heating cable channel.

The same plane in the middle of the mosaic panel is evenly provided with a plurality of transverse heat conduction metal through grooves parallel to the upper surface of the mosaic panel and perpendicular to the ground heating water pipe channel or the floor heating cable channel, the top surface of the lateral heat conduction metal channel is higher than the ground water pipe channel or The top of the floor of the floor heating cable is a diameter unit of a heat conducting wire, and the center line of the two adjacent warm water pipe channels is respectively provided with a longitudinal heat conducting metal channel, and the top of the longitudinal heat conducting metal channel is in the ground heating water pipe On the top plane, the top of all transversely conductive wire passages or longitudinal thermally conductive metal channels are provided with a thermally conductive wire having a width equal to the diameter of the thermally conductive wire.

The substrate of the present invention is a single-layer solid wood panel or a multi-layer solid wood composite board or a bamboo rubber board. The upper part of the substrate of the water-heating module floor is provided with a plurality of ground heating water pipes, and the number, shape and distribution of the water heating water pipes. The position is matched with the floor heating water pipe through groove in the lower part of the parquet panel; the upper part of the substrate of the electric heating type module floor has no floor heating cable through groove, and if the thickness of the parquet panel is thin enough to open the heating cable channel, at this time, the electric heating type The upper part of the substrate of the module floor is provided with a plurality of the same floor heating cable troughs parallel to the side of the substrate, and the cross section is semicircular or rectangular.

When the bottom surface of the mosaic panel and the bottom surface of the substrate are combined and bonded into the module unit, the same plane in the module unit constitutes a plurality of complete ground heating water pipe troughs or floor heating cable troughs parallel to the upper bottom surface and the left and right side surfaces of the module unit. The upper part of the floor heating trough or the floor heating trough of the modular unit forms a network of heat transfer system located in the middle of the mosaic panel.

The keel square of the present invention is surrounded by a plurality of square materials having a rectangular cross section, and is a closed square, which is a "mouth" shape, a "day" shape, a "field" shape, a "囲" shape or other status, keel. The square is embedded with a heat insulation board, and the heat insulation board is provided with a tool through groove, and the square material is wood or organic material and has the same thickness.

The keel square adjacent to the A and B sides of the keel of the present invention is provided with a pre-embedded nut, a connecting screw through hole, a tool through hole and a ground screw oblique hole, and the connecting screw through hole and the tool through hole are in the same The pre-embedded nuts are disposed on the connecting screw through holes and the two center lines are coincident; and the adjacent C and D square materials are provided with connecting screw through holes, and the connecting screw is connected Place the connecting screw inside the hole. Correspondingly, the connecting screw through holes on both sides of C and D, the tool through holes on the inner square material, and the center lines of the tool through holes on both sides of A and B are on the same straight line, and are parallel to the upper bottom surface and the left and right sides of the keel square. .

The keel square of the invention is divided into two types: A and B. The tool through hole of the A side of the A keel square, the connecting screw through hole and the connecting screw through hole of the corresponding B side keel A side, tools The through hole is at the same position, and the tool through hole of the A-shaped keel square B and the connecting screw through hole are respectively at the same position as the connecting screw through hole and the tool through hole of the corresponding B-shaped keel square B side; The connecting screws on the sides of the keel squares C and D are respectively fixed on the pre-embedded nuts on the sides of the B-shaped keel squares. The connecting screws on the sides of the B-shaped keel squares are fixed on the A-shaped keel square A. , on the B side of the pre-embedded nut.

The lace unit of the present invention is composed of an upper part of the lace unit and a lower part of the lace unit, wherein the upper part of the lace unit is composed of a lace panel, an upper substrate and a lace head, and the lower part of the lace unit is composed of a lower base plate and a lace keel. The whole body is provided with a clearance hole, a screw opening and a pipeline passage. The lace keel is a part of the keel square, the lace keel is embedded with a heat insulation board, and the lower surface of the lace unit is provided with a moisture proof layer and an upper bottom surface. Painted with floor coating.

The upper part of the lace unit of the present invention is provided with a lace head, the size of the lace head is matched with the size of the positioning groove of the module unit, the diamond angle of the lace head is rounded, and the floor of the lace head is provided with a ground pipe through the floor. Or a heating cable trough is arranged above the lace head, and a U-shaped floor heating water pipe is provided in the upper part of the plumbing type lace unit.

The graphic of the lace panel of the present invention is a part of the mosaic panel, or a plurality of blocks of equal thickness and different shapes are seamlessly formed into a pattern with lace characteristics.

The block of the present invention is a wooden block or a jade or a stone block or a glass block or an organic block. According to the design pattern, the block is cut into straight columns of various shapes, and the mosaic panel or the lace panel is made of one type or It consists of a variety of different wooden blocks, or a mixture of wooden blocks and other one or two materials. The jade or stone or glass block or organic block is embedded in the wooden block, and the starting point is decorated with decoration.

The elastic block of the invention is made of elastic material such as rubber or plastic, and the thickness of the elastic block is determined according to the needs of the ground. Degree, from the height adjustment and mute effect, set at the bottom of the keel square.

The floor heating water pipe of the present invention is connected with the hot water source heating water pipe, and the hot water is circulated inside the floor of the floor heating module through the hot water circulation pump, and the floor heating cable is connected with the power source to achieve the heating purpose.

Floor heating type modular flooring generally does not use anchor bolts. If the floor area is large or the ground is uneven or the ground is relatively wet, use anchor bolts.

The floor heating modular floor realizes the modularization of the floor. The modular floor heating is beneficial to the scale production of the factory and simplifies the on-site installation procedure. The manufacturer provides the finished floor according to the size of the user, without the need for on-site cutting, the floor is no longer a semi-finished product.

Due to the shape, color, wood texture and surface coating (or wood oil) of the blocks constituting the mosaic panel and the lace panel, various patterns and visual effects can be presented to satisfy the individual needs of the user.

The modular panel and the lace unit's parquet panel, base plate and keel square are tightly connected to form a solid whole. The wood fiber of the mosaic panel is damaged and the stability is strong; all the modular units and the lace unit are passed through the positioning stringer or the lace head. It is fixed in the positioning groove and is firmly connected by the connecting screw, the pre-embedded nut and the fixing screw to form a seamless whole, which has long service life and is not easy to be deformed and cracked.

Since there is no relative movement between the module units, between the lace units, the module unit and the lace unit, and the floor heating type module floor has sufficient thickness and the elastic block below, the module floor has a good mute effect and a comfortable foot. .

The connecting piece between the units inside the floor heating type module is a screw nut, which can transfer or partially replace the damaged parts, which is convenient for maintenance. The upper part of the lace panel can be removed, which is convenient for replacing the aging heating water pipe or the floor heating cable.

The heating water pipe or the floor heating cable is directly installed inside the floor of the floor heating type module, and the heating body transfers the heat directly to the parquet panel and the lace panel through the heat conductive wire, and the thickness thereof is half of the ordinary geothermal floor, and the substrate and the insulation compartment are arranged below. Hot plate, high heat utilization rate.

DRAWINGS

Figure 1 is a three-dimensional view of the plumbing module unit;

Figure 2 is a three-dimensional view of the floor heating cable module unit;

Figure 3 is a three-dimensional bottom view of the plumbing type modular unit mosaic panel;

Figure 4 is a three-dimensional bottom view of the heating cable type modular unit mosaic panel;

Figure 5 is a three-dimensional view of the A-type keel square;

Figure 6 three-dimensional view of the B-type keel square (with insulation board);

Figure 7 is a three-dimensional schematic diagram of the keel splicing method;

Figure 8 is a three-dimensional schematic diagram of the structural decomposition of the plumbing module unit and its components;

Figure 9 is a three-dimensional schematic diagram of structural decomposition and components of the floor heating cable module unit;

Figure 10 is a three-dimensional view of the plumbing type lace unit;

Figure 11 is a three-dimensional view of the upper and lower structures of the plumbing type lace unit;

Figure 12 is a three-dimensional bottom view of the upper right end structure of the plumbing type lace unit;

Figure 13 is a three-dimensional bottom view of the upper left end structure of the plumbing type lace unit;

Figure 14 is a three-dimensional bottom view of the upper left end inlet and outlet structure of the plumbing type lace unit;

Figure 15 is a three-dimensional bottom view of the upper left end of the plumbing type lace unit;

Figure 16 is a three-dimensional view of the floor heating cable type lace unit;

Figure 17 is a three-dimensional view of the upper and lower structures of the heating cable type lace unit;

Figure 18 is a module unit and lace unit splicing method front view I;

Figure 19 is a front view II of the module unit and the lace unit splicing method;

Figure 20 is a three-dimensional schematic diagram of a water heating module floor assembly method;

Figure 21 is a three-dimensional schematic diagram of a floor heating cable type module assembly method;

Figure 22 is an overall three-dimensional view of the floor heating module floor.

detailed description

Example 1: Plumbing type module floor.

As shown in FIG. 1, FIG. 7, FIG. 8, FIG. 10, FIG. 11, FIG. 18, FIG. 20 and FIG. 22, the plumbing type module floor includes a central portion and a peripheral portion, and is composed of a module unit 45 and a lace unit 46. The module unit 45 is embedded in the positioning groove 21 by positioning the stringer 22, and the connecting screw 36 is fixed to the pre-embedded nut 38 of the adjacent module unit 45 by the screw tool 42 to form a central portion of the floor of the plumbing module; the lace unit 46 is composed of a lace unit upper portion 47 and a lace unit lower portion 48. The plurality of lace unit lower portions 48 are fixed to the embedded nut 38 of the adjacent lace unit lower portion 48 by a connecting screw 36, and the plurality of lace unit upper portions 47 are passed through the lace head 27 Embedding into the positioning groove 21 of the adjacent module unit 45, the insertion type stringer 26 is inserted, and the peripheral portion of the floor of the floor heating module is fixed by the fixing screws 49.

The floor of the plumbing type module is provided with a heating water pipe through slot 11, the floor heating water pipe through slot 11 is provided with a heating water pipe 43, the water heating type module floor is provided with a pipeline passage 52, the bottom is provided with an elastic pad 40, and the water heating type module floor is used for the grounding foot. The screws 41 are fixed or directly laid on the floor or floor.

As shown in FIG. 2, the module unit 45 is sequentially and vertically joined by the mosaic panel 10, the substrate 20, and the keel square 30, and is connected together under specific conditions by an adhesive or an iron nail to form a solid irreversible whole. The overall shape is a rectangular parallelepiped having a square bottom surface, a moisture barrier layer on the lower bottom surface, and a floor paint on the upper bottom surface.

The module unit of this embodiment is provided with a positioning groove having the same rectangular cross section on the same plane. 21, the groove depth is 10mm, the slot width is 8mm, and there are four ground heating water pipes through slots 11. The upper plane of the positioning groove 21 is slightly lower than the lower top plane of the ground heating water pipe groove 11, and the lower plane of the positioning groove 21 is located. It is the upper plane of the keel square 30.

The size of the positioning beam 22 coincides with the positioning groove 21, and the corners of the positioning beam 22 and the positioning groove 21 are rounded for ease of installation.

As shown in FIG. 1 and FIG. 3, the parquet panel 10 of the present embodiment is assembled from nine high-quality hardwood blocks having a thickness of 20 mm and formed into a rectangular parallelepiped having a bottom surface, and the height is 20 mm, and the contact faces between the wooden blocks are coated. The wood glue is kept under a certain pressure, and is fixed by the connecting code nail 19, and the wooden blocks are seamlessly spliced into one whole, that is, the parquet panel 10.

On the same plane of the lower portion of the parquet panel 10, four floor heating water pipe passages 11 parallel to the side surface and the upper bottom surface of the parquet panel 10 are uniformly formed, and the cross section is semicircular; and six vertical water heating pipe channels are provided on the other plane. The transverse heat conduction metal through groove 14 of the eleven horizontal heat conduction metal through groove 14 is higher than the diameter unit of the heat conduction wire 13 on the top plane of the ground heating water pipe groove 11; the middle lines of the two adjacent warm water pipe passages 11 are respectively provided There is a longitudinal heat conducting metal through groove 15, and the top of the longitudinal heat conducting metal through groove 15 is on the top plane of the ground heating water pipe through groove 11.

The tops of all of the transverse heat conducting wire passages 14 and the longitudinal heat conducting metal through grooves 15 are provided with heat conducting wires 13, and the width of the transverse heat conducting wire passage grooves 14 or the longitudinal heat conducting metal through grooves 15 is equal to the diameter of the heat conducting wires 13.

As shown in FIG. 1 and FIG. 8 , the substrate 20 of the embodiment is a single-layer solid wood panel, and four heating water pipe passages 11 perpendicular to the direction of the wood fiber are disposed on the upper portion thereof, and the ground heating water pipe groove 11 in the lower portion of the parquet panel 10 is provided. In agreement, when the lower bottom surface of the mosaic panel 10 and the bottom surface of the substrate 20 are coincident, the complete ground heating water pipe through groove 11 is formed in a circular cross section.

As shown in FIG. 5, FIG. 6, FIG. 7 and FIG. 8, the keel square 30 is connected by a wooden square with six cross-sections of the same rectangular shape through a taro and a gutter to form a square square of "Tian" shape, and the keel square 30 The bottom surface and the bottom surface of the mosaic panel 10 are identical; the keel square 30 has four heat insulation panels 33 embedded therein, and the upper portion of the heat insulation panel 33 is provided with a tool through groove 34 for facilitating the passage of the screw tool 42 and the heat insulation panel 33. It has the same thickness as the keel square 30.

Two pre-embedded nuts 38, two pre-embedded nut slots 37, two tool through holes 31 and two connecting screw through holes 32 are respectively disposed on two adjacent sides of A and B on the periphery of the keel square 30. One or three anchor screw slanting holes 35, connecting screw through holes 32 and tool through holes 31 at different positions on the same plane, the pre-embedded nut 38 is disposed on the connecting screw through hole 32 and the two center lines are coincident; Two connecting screw through holes 32 are respectively disposed on the two sides of the adjacent C and D, and the two connecting screws 36 are placed in the two connecting screw through holes 32. The connecting screw through hole 32 is in line with the center line of the tool through hole 31 on the opposite side A or B side and the tool through hole 31 on the inner wooden side; all connecting screw through holes 32 and tools in the keel square 30 The center lines of the through holes 31 are on the same plane and are parallel to the upper and left and right sides of the keel square 30.

As shown in FIG. 5, FIG. 6 and FIG. 7, the keel square 30 is divided into two types: A and B. The two tool through holes 31 on the side of the A-shaped keel square A of the present embodiment are connected to the screw through holes 32. Within the distance between the two tool through holes 31 to two adjacent sides L1, the distance between the two connecting screw through holes 32 to two adjacent sides is L2, L1>L2; the two tool through holes 31 on the B side are outside the two connecting screw through holes 32, and the two tool through holes 31 are The distance between the two adjacent sides is L2, and the distance between the two connecting screw through holes 32 to the two adjacent sides is L1. The B-shaped keel square is opposite to the A-type keel square, that is, the two tool through holes 31 on the A side are outside the two connecting screw through holes 32, and the two tool through holes 31 on the B side are in the two connecting screw through holes 32. Within.

As shown in FIG. 7, the distance between the two connecting screw through holes 32 on the side of the A-type keel square C of the present embodiment to the two adjacent side faces is L1, and the two connecting screw through holes 32 on the D side are adjacent to the two adjacent sides. The distance is L2; the B-shaped keel square is opposite to the A-type keel square, the distance between the two connecting screw through holes 32 on the C side to the two adjacent sides is L2, and the two connecting screw through holes 32 on the D side are two to two The distance between adjacent sides is L1.

The connecting screws 36 on the sides of the A and keel squares C and D are respectively fixed on the pre-embedded nuts 38 on the sides of the B-shaped keel squares. The connecting screws 36 on the sides of the B-shaped keels of the B-shaped keel are respectively It is fixed on the pre-embedded nut 38 on the sides of the A-shaped keel squares A and B. The modular unit containing the A-shaped keel square and the modular unit containing the B-shaped keel square are arranged and fixed together.

As shown in FIGS. 10, 11, 18 and 19, the lace unit 46 of the present embodiment is composed of a lace unit upper portion 47 and a lace unit lower portion 48. The upper portion 47 of the lace unit is fixed by the lace panel 16, the upper substrate 23 and the lace head 27 in a specific manner to form a solid unit; the lower portion 48 of the lace unit is fixed by the lower substrate 24 and the lace keel 39 in a specific manner. Forming a solid whole, the lace keel 39 is part of the keel square 30. The lower bottom surface of the lace unit 46 is provided with a moisture barrier layer, and the upper bottom surface is coated with a floor paint.

As shown in FIG. 11, the lace panel 16 of the present embodiment is composed of four long wooden squares, 24 triangular wooden blocks and five rectangular wooden blocks having a thickness of 20 mm, and is composed of five different kinds of high-quality hardwoods of wood. The pattern of the lace feature (the color difference of the black and white pattern is not obvious); the thickness of the upper substrate 23 is the thickness of the module unit substrate 20 minus the thickness of the positioning groove 21; the thickness of the lace head 27 is 8 mm. Both the lace panel 16 and the lace tassel 27 are fixed to the upper substrate 23, and the horn of the lace tassel 27 is rounded for ease of installation.

As shown in Fig. 12, Fig. 13, Fig. 14, and Fig. 15, a U-shaped floor heating water pipe passage 11 is formed in the bottom surface of the formed lace unit upper portion 47, and the groove depth is slightly larger than the diameter of the floor heating water pipe 43, in consideration of the floor heating water pipe 43 The expansion and contraction is appropriately widened in parallel with the direction of the lace head 27 and the width of the U-shaped floor heating water passage groove 11 of the tortuous portion.

As shown in FIG. 20, in the present embodiment, we refer to one side of the floor heating water inlet and outlet 17 as the left end, the opposite side as the right end, and the two sides without the floor heating water pipe are called the two sides, and the lower part of the upper part of the lace unit 47 on both sides is not used. U-shaped floor heating water pipe trough 11 is opened, one type of U-shaped floor heating water pipe channel 11 is opened at the right end (as shown in FIG. 14), and three types of U-shaped floor heating water pipe channel 11 are opened at the right end (see FIGS. 15 and 16). 17)).

The two lace units 46 of the four corners of the module floor are sawed at the corresponding positions by the 45° angle. The triangle part is composed, and the area is relatively small. In actual production, the four corner parts are respectively incorporated into the lace units on the adjacent sides.

As shown in FIG. 10, FIG. 11, FIG. 18 and FIG. 19, in the present embodiment, the thickness of the lower substrate 24 of the lace unit 46 is the thickness of the module unit positioning groove 21 (= 8 mm in this embodiment), and the width is the upper substrate. The width of 23 is subtracted from the width of the lace head 27, and when the lace head 27 is embedded in the positioning groove 21 of the module unit 45, the lace head 27, the upper substrate 23, the lower substrate 24, and the lace keel 39 enclose the mounting clearance hole 25, and the insertion The size of the stringer 26 is matched with the size of the mounting clearance hole 25; the lower substrate 24 is provided with a screw opening 28 for fastening the connecting screw 36, and if the edge of the lace keel 39 is left with a pre-embedded nut 38, the lower substrate 24 may not be provided with screw opening 28; if the floor heating screw 41 of the plumbing type module is used, after installing the lower part 48 of the lace unit, the anchor screw 41 is required to be tightened; the floor 50, the wall 51, the lace keel 39 and the lower substrate 24 are enclosed. It becomes a pipeline channel 52.

As shown in Fig. 20, when installing the plumbing type module floor, according to the pre-designed position, a row of side lace unit lower portions 48 with corner portions is installed on one side of the room, and the end edge lace units are installed on the other side adjacent to the room. In the lower part 48, attention is paid to the interlocking arrangement of the type A and the type B of the lace keel 39.

When the module unit 45 is installed, the connecting screws 36 on the sides C and D are respectively fixed to the pre-embedded nuts 38 of the lace keels 39 on the adjacent sides by using the screw tool 42, and the elastic pads 40 of appropriate thickness are padded to tighten the feet. Screw 41; and so on, ...; the last piece is installed as module unit 45. According to the pre-designed position, note that the A-type keel square and the B-shaped keel square are staggered.

After the module unit 45 is installed, similarly, the lower part 48 of the remaining lace unit is mounted.

According to the method shown in FIG. 20, the floor heating water pipe 43 is inserted into the floor heating water pipe passage 11 of the plumbing type module unit 45, and the ground heating water pipe inlet and outlet 17 is connected to the hot water source heating water pipe, and the hot water circulation pump is used to make the hot water. Circulate inside the floor heating module floor to check if it is normal.

As shown in Figs. 11, 19, and 20, the upper portion 47 of the lace unit is attached, the insertion type stringer 26 is inserted into the attachment clearance hole 25, and the fixing screw 49 is tightened. All modular units and lace units are integrated into a single unit to form a plumbing module floor.

Embodiment 2, an electric heating type module floor.

The structure of the electric heating type module floor and the plumbing type module floor has many identical parts, except that the diameter of the floor heating cable is smaller than that of the floor heating water pipe, and its structure is optimized. This embodiment only describes different parts.

As shown in FIG. 2, FIG. 16, and FIG. 21, the electric heating type module floor includes a central portion and a peripheral portion, and is composed of a module unit 45 and a lace unit 46. The electric heating type module floor is provided with a heating cable passage slot 12 and a floor heating cable. The through slot 12 places the ground heating cable 44.

As shown in FIG. 2 and FIG. 4, the parquet panel 10 of this embodiment is assembled from 33 pieces of wood blocks of equal thickness and a piece of jade 29 into a rectangular parallelepiped whose bottom surface is square, and the height is the thickness of the wooden block (= 20 mm). The wooden blocks are seamlessly joined together into a fixed irreversible whole, that is, the mosaic panel 10.

On the same plane of the lower portion of the mosaic panel 10, six floor heating cable passages 12 parallel to the side surface and the upper bottom surface of the mosaic panel 10 are uniformly opened, and the cross section is square; and six transverse lines perpendicular to the heating cable passage 12 are disposed on the other plane. The heat conducting metal through groove 14 has a top plane of the six heat conducting metal through grooves 14 which is higher than a diameter unit of a heat conducting wire 13 on the top plane of the ground heating cable through groove 12.

As shown in FIG. 2 and FIG. 9, the substrate 20 of this embodiment is a three-layer solid wood panel, and the upper portion thereof has no floor heating cable through slots.

As shown in FIG. 16 and FIG. 17, a horizontal U-shaped floor heating cable channel 12 is formed above the lace head 27 of the present embodiment, and is located at a lower portion of the lace panel 16, parallel to the lace head 27, and has a groove depth larger than the diameter of the floor heating cable 44. The groove width is equal to the height of the floor heating cable channel 12 on the parquet panel 10.

As shown in FIG. 1, FIG. 9, FIG. 17, and FIG. 21, the keel structure, the connection method, the assembly, and the mounting manner of the electric heating type module floor are the same as those of the water heating type module floor in the first embodiment.

As shown in Fig. 21, the positive and negative poles 18 of the floor heating cable are connected to the power source for heating purposes, and all the modular units and the lace unit are integrated into one body to form an electric heating type module floor.

The specific embodiments described herein are merely illustrative of the spirit of the invention. A person skilled in the art can make various modifications or additions to the described technical solutions or replace them in a similar manner, such as changing the screw nut connection between the module unit and the lace unit into a snap connection. Or other means of connection, the modular unit is changed to a positive 6 prism or a regular triangular prism, but does not deviate from the scope defined by the first or second claim of the appended claims.

Claims (10)

1. A floor heating type module floor comprising a central part and a peripheral part, characterized in that: the floor heating type module floor is composed of a module unit (45) and a lace unit (46), and the plurality of module units (45) are positioned by a stringer ( 22), the connecting screw (36) and the pre-embedded nut (38) are connected to form a central portion of the floor of the floor heating module; the plurality of lace units (46) pass the lace head (27), the connecting screw (36), the pre-embedded nut (38) and the fixing screw (49) are connected to form a peripheral portion of the floor of the floor heating type module; the floor of the floor heating type module is provided with a floor heating water pipe channel (11) or a floor heating cable channel (12), and a floor heating water pipe channel (11) Place the floor heating pipe (43), or the floor heating cable (44) in the floor heating cable channel (12), with the pipeline passage (52) around, the elastic block (40) at the bottom, and the ground screw (41) Fixed or directly paved on the ground or on the floor.
2. The floor heating type module floor according to claim 1, wherein the module unit (45) is sequentially composed of a mosaic panel (10), a substrate (20), and a keel square (30), and the bottom surface is overlapped. Mixtures, nails or other fasteners are joined together under certain conditions to form a solid rectangular body with a rectangular truncated positioning groove (21) on the substrate (20). The lower part or the middle part of the surrounding area is provided with a moisture-proof layer on the lower bottom surface and a floor paint on the upper bottom surface.
3. The floor heating type module floor according to claim 1 or 2, characterized in that: a plurality of floor heatings parallel to the upper bottom surface and the left and right sides of the module unit (45) are uniformly disposed on the same plane in the module unit (45). a water pipe channel (11) or a floor heating cable channel (12), the ground heating water pipe channel (11) or the floor heating cable channel (12) has a circular or rectangular cross section, and is located on the mosaic panel (10) and the substrate ( 20) The intersection.
4. The floor heating type module floor according to claim 3, characterized in that: a plurality of parallel grooves on the same plane in the module unit (45) are parallel to the upper surface of the module unit (45) and perpendicular to the ground heating water pipe slot. (11) or the transverse heat-conducting metal through-groove (14) of the floor heating cable channel (12), the top plane of which is higher than the top surface of the ground heating water pipe channel (11) or the floor heating cable channel (12), a heat-conducting wire (13) The diameter unit, the center line of the two adjacent warm water pipe passages (11) is respectively provided with a longitudinal heat conductive metal through groove (15), the top of which is located on the top plane of the ground heating water pipe through groove (11), the lateral heat conduction A wire of a wire (14) or a longitudinally thermally conductive metal channel (15) is provided with a heat conducting wire (13) located in the middle of the panel (10).
5. The floor heating type module floor according to claim 2, wherein the keel square (30) is surrounded by a plurality of square materials having a rectangular cross section, and has a closed square shape. The "day" shape, the "field" shape, the "囲" shape or other status quo, the keel square (30) is embedded with a heat insulation board (33), and the upper part of the heat insulation board (33) is provided with a tool through groove (34) The square material is a wood or organic material and has the same thickness.
6. The floor heating type module floor according to claim 2 or 5, characterized in that: the keel square (30) is provided with a pre-embedded nut (38) and a connecting screw through the square materials on both sides A and B. Hole (32), tool through hole (31) and the anchor screw slanting hole (35), the connecting screw through hole (32) and the tool through hole (31) are at different positions on the same plane and parallel to each other, and the pre-embedded nut (38) is disposed Connected to the screw through hole (32) and the two center lines are coincident; in addition, the adjacent C and D sides of the square material are provided with connecting screw through holes (32), and the connecting screw through holes (32) are placed by the connecting screw ( 36); correspondingly, the connecting screw through holes (32) on both sides of C and D, the tool through holes (31) on the inner square material, and the center line of the tool through holes (31) on both sides of A and B are on the same line. And parallel to the upper bottom and left and right sides of the keel square (30).
7. The floor heating type module floor according to claim 6, wherein the keel square (30) is divided into two types: A and B, and a tool through hole of the A side keel (30) A side ( 31) The connecting screw through holes (32) are respectively at the same position as the connecting screw through holes (32) and the tool through holes (31) of the corresponding B-shaped keel square (30) A side, and the type A keel square ( 30) The tool through hole (31) and the connecting screw through hole (32) on the B side are respectively in the same shape as the connecting screw through hole (32) and the tool through hole (31) of the corresponding B-shaped keel square (30) B side. Position: The connecting screws (36) on the sides of the A and keel squares are fixed on the pre-embedded nuts (38) on the sides A and B of the keel, and the B-shaped keels are on the C and D sides. The connecting screws (36) are respectively fixed to the pre-embedded nuts (38) on the sides A and B of the A-shaped keel.
8. A floor heating type modular floor according to claim 2, wherein said lace unit (46) is composed of a lace unit upper portion (47) and a lace unit lower portion (48), and said lace unit upper portion (47) is composed of The lace panel (16), the upper substrate (23) and the lace head (27) form a solid whole, and the lower portion (48) of the lace unit is composed of a lower substrate (24) and a lace keel (39). There is a clearance hole (25), a screw opening (28) and a pipeline passage (52), the lace keel (39) is a part of the keel square (30), and the lower surface of the lace unit (46) is provided with moisture proof The upper and lower surfaces are coated with a floor coating.
9. A floor heating type module floor according to claim 8, wherein the upper portion (47) of the lace unit is provided with a lace head (27), and the size of the lace head (27) and the module unit (45) The positioning groove (21) is matched in size, and a heating cable channel (11) is provided inside and above the lace head (27), and a floor heating cable channel (12) is arranged above the floor heating pipe (11). The upper part of the lace unit (47) is provided with a U-shaped floor heating water pipe (11).
10. A floor heating type module floor according to claim 8, wherein the parquet panel (10) and the lace panel (16) are formed by a plurality of blocks of equal thickness and different shapes, and the inside thereof. The adjacent blocks are seamlessly joined together, and the blocks are wood blocks or jade or stones or glass blocks or organic blocks.

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