CN114593451A - A kind of intelligent temperature control instant heating type floor heating heating system and installation method thereof - Google Patents

Abstract

The invention relates to the technical field of floor heating installation, in particular to an intelligent temperature control instant floor heating system and an installation method thereof, wherein the intelligent temperature control instant floor heating system comprises a floor heating module A, a floor heating module B, a floor heating module C and an intelligent temperature control module, wherein the floor heating module A is used for supporting and laying a floor heating pipeline, the floor heating module B is arranged at two opposite sides of the edge direction of the pipeline of the floor heating module A, the floor heating module C is arranged at the upper end of the floor heating module B and is provided with a curved groove for laying the floor heating pipeline in a bending way, and the intelligent temperature control module monitors the temperature in the floor heating pipeline in real time and can control the temperature within a set temperature range; the installation method adopts an assembled floor heating module combined structure, adopts a dry method for leveling, is convenient and efficient to install, is beneficial to maintaining or replacing ground decoration, realizes intelligent control of indoor heating temperature, and provides a solution for personalized, autonomous and comfortable heating of users.

Description

A kind of intelligent temperature control instant heating type floor heating system and installation method thereof

technical field

The present invention relates to the technical field of floor heating installation, in particular to an intelligent temperature-controlled instant floor heating heating system and an installation method thereof.

Background technique

The existing ceramic tile laying process has high requirements on the technical level of workers, and the labor cost is relatively high, and there are often difficulties in labor. Prefabricated decoration refers to the prefabrication of the parts and components required for decoration, and then assembling and construction on site, thereby reducing the measurement, cutting and other processes during on-site construction operations. Compared with traditional decoration and decoration operations, the construction operation of prefabricated decoration and decoration is more concise and convenient, which can improve work efficiency and reduce material waste, and keep the work site as clean as possible. It is a more green and environmentally friendly decoration and decoration method. .

In the related prefabricated floor heating installation technology, before installing the dry floor heating module, the installation ground needs to be leveled first. Currently, wet cement leveling is generally used to make the installation ground flat. However, the use of wet cement for leveling requires construction personnel to re-pour concrete on the installation ground, which is time-consuming and labor-intensive; the existing prefabricated floor heating system has poor thermal conductivity, uneven heat dissipation, complicated installation methods, and regular maintenance or replacement of the ground. It is convenient, and the maintenance or replacement cost is high; in addition, the existing floor heating heating system adopts the central heating method, and it is generally impossible to realize the user's independent temperature control and intelligent energy-saving temperature control. For each user with different indoor specific environments, the heating demand is greatly affected. or due to the sudden drop or rise in temperature and the difference in heating needs of users during the day and night, users cannot adjust the indoor heating temperature independently, resulting in substandard heating requirements, or serious waste of resources and increased heating costs.

SUMMARY OF THE INVENTION

In order to solve the above-mentioned technical problems, the present invention provides an intelligent temperature control instant heating type floor heating system and an installation method thereof. The assembled floor heating module combination structure is adopted, and the dry method is used for leveling. The installation is convenient and efficient, and is conducive to maintenance or replacement of floor decorations. , and realize the intelligent control of indoor heating temperature, which provides a solution for users' personalized, autonomous and comfortable heating.

To achieve the above object, the present invention adopts the following technical solutions to realize:

One aspect of the present invention provides an intelligent temperature-controlled instant heating system, comprising a floor heating module A, a floor heating module B, a floor heating module C and an intelligent temperature control module, wherein the floor heating module A is used to support and lay floor heating pipelines. The floor heating module B is arranged on the opposite sides of the pipeline of the floor heating module A along the direction, and the floor heating module C is arranged on the upper end of the floor heating module B, which is provided with a curved groove, which is used for the heating of the floor heating pipeline. For back-bend laying, the intelligent temperature control module monitors the temperature in the floor heating pipeline in real time and can control the temperature within the set temperature range.

In a possible technical solution, the floor heating module A includes a load-bearing heat-conducting plate, a supporting beam A and an adjusting bolt A. The load-bearing heat-conducting plate is prefabricated with a pipeline groove for inlaying and laying the floor heating pipeline, and the load-bearing heat-conducting plate is installed. At the upper end of the supporting beam A, the supporting beam A is connected to the floor panel through adjustment bolts A, which are used to adjust the height of the supporting beam A to level the floor heating module A.

In a possible technical solution, the pipeline groove and the supporting beam A are perpendicular to each other.

In a possible technical solution, a heat-conducting medium pipe or a heating cable or any combination of the two are inlaid and laid in the pipeline groove.

In a possible technical solution, the position of the supporting beam A corresponding to the adjusting bolt A is a hollow design, and the adjusting bolt A includes a hollow screw A, a first nut and a second nut, wherein the first nut is fixedly connected. At the lower end of the supporting beam A, the hollow screw A is arranged on the inner side of the first nut, the outer side of the hollow screw A is threadedly connected with the inner side of the first nut, and the upper part of the hollow screw A penetrates into the interior of the supporting beam A, and the second The nut is used to lock the hollow screw A from the upper part of the hollow screw A, and a process hole for adjusting the hollow screw A and the second nut is reserved at the position corresponding to the hollow screw A on the load-bearing heat-conducting plate.

In a possible technical solution, the floor heating module B includes a support plate, a supporting beam B and an adjusting bolt B, the supporting plate is used to support the floor heating module C, and the supporting plate is installed on the upper end of the supporting beam B, The supporting beam B is connected to the floor panel through adjusting bolts B, which are used to adjust the height of the supporting beam B to level the floor heating module B.

In a possible technical solution, the position of the supporting beam B corresponding to the adjusting bolt B is a hollow design, and the adjusting bolt B includes a hollow screw B, a third nut and a fourth nut, wherein the third nut is fixedly connected. At the lower end of the supporting beam B, the hollow screw B is arranged on the inner side of the third nut, the outer side of the hollow screw B is threadedly connected with the inner side of the third nut, and the upper part of the hollow screw B penetrates into the interior of the supporting beam B, and the fourth The nut is used to lock the hollow screw B from the upper part of the hollow screw B, and a process hole for adjusting the hollow screw B and the fourth nut is reserved at the position corresponding to the hollow screw B on the support plate.

In a possible technical solution, the intelligent temperature control module includes a temperature measurement device and an intelligent temperature controller, the temperature measurement device is arranged at an indoor temperature measurement point, and the temperature measurement device and the intelligent temperature controller are electrically connected.

In a possible technical solution, the intelligent temperature control module is connected to a mobile terminal through a cloud server, the cloud server is used to remotely manage the intelligent temperature control module, and the mobile terminal is used to remotely manage the intelligent temperature control module. interaction, the intelligent temperature control module and the mobile terminal are both electrically connected with the cloud server through radio.

Another aspect of the present invention provides an installation method for an intelligent temperature-controlled instant heating system, comprising the following steps:

S1. Place a number of floor heating modules A on the floor panel according to the design of the pipeline layout, level the floor heating modules A by adjusting the hollow screw A, and then lock and fix it with the second nut, and then inject glue into the hollow screw A;

S2. Arrange a number of floor heating modules B on opposite sides of the pipeline of the floor heating module A along the direction, and adjust the hollow screw B to level the floor heating modules B to be lower than the height of the floor heating module A, and then lock and fix with the fourth nut , and then inject glue into the hollow screw B;

S3. Arrange the floor heating module C on the upper end of the floor heating module B, and the height of the floor heating module C is flush with the height of the floor heating module A, so that the curved groove of the floor heating module C is in the same direction as the floor heating pipeline of the floor heating module A;

S4. Lay floor heating pipelines according to indoor heating demand;

S5, laying a first isolation film on the floor heating module A and the floor heating module C, laying an adhesive on the first isolation film, and then laying a second isolation film above the adhesive;

S6, open transverse shallow grooves on each of the four sides of the tile;

S7. Place the tiles directly on the second isolation film, adjust the gap between the beautiful seams, and then use a beautifying agent to beautify the seam.

Compared with the prior art, the beneficial effects of the present invention are: the floor heating module A, the floor heating module B, and the floor heating module C of the present invention are all prefabricated and processed components. For the layout of module B and floor heating module C, the overall laying and paving of floor heating devices are realized through the adjacency and docking of floor heating unit modules. Low cost, standardized construction, workers can be hired after simple training, the entire construction process can be significantly shortened, and the construction cost can be significantly reduced; all module components are from factory-like lean manufacturing, no secondary cutting is required on site, and all components are physically connected. , can achieve rapid assembly, rapid leveling, complete disassembly, dry operation in the whole process, no noise, no dust, no waste; simplifies the structure of the original multi-layer composite structure and the tedious construction and installation process, and the overall structure as The ground structure of the steel structure building reduces the weight of the ground structure to a large extent, conforms to the development direction of prefabricated buildings, and improves the safety performance of the building in response to emergencies such as earthquakes and fires. Floor heating module A, floor heating module B and floor heating module C are assembled and laid with floor heating pipelines to quickly transfer the heat of the floor heating pipelines to the indoor space, improve heat conduction efficiency, increase the effective utilization of heat, and save energy consumption; The control module monitors the indoor temperature in real time and can control the temperature within the set temperature range, realizing the user's independent temperature control, as well as various functions such as individual temperature control of each room, temperature control by time period, etc., and can be automatically adjusted according to the indoor temperature. Realize intelligent temperature control and low temperature heating function, which can solve the problem of energy saving and consumption reduction of electric heating to the greatest extent, and can achieve good heating effect.

Description of drawings

1 is a schematic structural diagram of an intelligent temperature-controlled instant floor heating heating system according to the present invention;

Fig. 2 is the front sectional structure schematic diagram of floor heating module A;

Fig. 3 is the structural representation of adjusting bolt A;

Fig. 4 is the bottom view structure schematic diagram of floor heating module A;

5 is a schematic top view of the floor heating module B;

Fig. 6 is the front sectional structure schematic diagram of floor heating module B;

Fig. 7 is the bottom view structure schematic diagram of floor heating module B;

8 is a side view and a top view structural schematic diagram of the floor heating module C;

FIG. 9 is a top-view structural schematic diagram of a return-bending auxiliary member 1;

FIG. 10 is a schematic top view of the structure of the second return bending aid;

Figure 11 is a schematic cross-sectional view of the installation structure of the intelligent temperature control instant heating type floor heating heating system at the floor heating module A;

Fig. 12 is a schematic diagram of the interactive control logic of the intelligent temperature control module;

13 is a schematic diagram of a remote control connection of an intelligent temperature control module;

Reference numerals: 1-floor heating module A; 11-load-bearing heat-conducting plate; 12-joist A; 13-adjusting bolt A; 131-hollow screw A; 132-first nut; 133-second nut; 2-floor heating Module B; 21-support plate; 22-joist beam B; 23-adjusting bolt B; 231-hollow screw B; 232-third nut; 233-fourth nut; 3-floor heating module C; Piece 1; 32-return-bending auxiliary piece 2; 4-heat-conducting medium pipe; 5-heating cable; 6-floor panel; 7-first isolation film; 8-adhesive; 9-second isolation film; 10-tile ; 11-display device; 12-cloud server; 13-mobile terminal.

Detailed ways

In order to make the purposes, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments These are some embodiments of the present invention, but not all embodiments.

In the description of the present invention, it is to be understood that the terms "radial", "axial", "upper", "lower", "top", "bottom", "inner", "outer", etc. refer to orientations Or the positional relationship is based on the orientation or positional relationship shown in the drawings, which is only for the convenience of describing the present invention and simplifying the description, rather than indicating or implying that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation. , so it cannot be construed as a limitation of the present invention. In the description of the present invention, unless otherwise specified, "plurality" means two or more.

In the description of the present invention, it should be noted that, unless otherwise expressly specified and limited, the terms "installation", "arrangement" and "connection" should be understood in a broad sense, for example, it may be a fixed connection or a detachable connection connected, or integrally connected; either directly or indirectly through an intermediary. For those of ordinary skill in the art, the specific meanings of the above terms in the present invention can be understood according to specific situations.

The terms "first", "second", "third" and "fourth" in the description and claims of the present application and the drawings are used to distinguish different objects, rather than to describe a specific order . Furthermore, the terms "comprising" and "having", and any variations thereof, are intended to cover non-exclusive inclusion. For example, a process, method, system, product or device comprising a series of steps or units is not limited to the listed steps or units, but optionally also includes unlisted steps or units, or optionally also includes For other steps or units inherent to these processes, methods, products or devices.

As shown in FIG. 1 , an intelligent temperature control that is a thermal floor heating system of the present invention includes a floor heating module A1, a floor heating module B2, a floor heating module C3 and an intelligent temperature control module. The floor heating module A1 is used for supporting and laying floor heating The floor heating module B2 is arranged on the opposite sides of the pipeline along the direction of the floor heating module A1, the floor heating module C3 is arranged on the upper end of the floor heating module B2, and the floor heating module B2 supports the floor heating module C3. Function, it is provided with a curved groove, which is used for laying back bending of the floor heating pipeline. The intelligent temperature control module monitors the temperature in the floor heating pipeline in real time and can control the temperature within the set temperature range.

The floor heating module A1, the floor heating module B2 and the floor heating module C3 of the present invention are all prefabricated and formed components. When laying the floor heating pipeline, the layout of the floor heating module A1, the floor heating module B2 and the floor heating module C3 is designed according to the pipeline layout. The overall laying and paving of the floor heating device can be realized by splicing methods such as adjacency and docking. The standard modular assembly construction is adopted, which is convenient for construction, convenient and flexible in floor heating arrangement, low skill requirements for workers, construction specifications, and construction costs are significantly reduced; all modular components All come from factory-like lean manufacturing, no secondary cutting is required on site, and the physical connection between each part can realize rapid assembly, rapid leveling, complete disassembly, dry operation in the whole process, no noise, no dust, and no garbage; The structure of the original multi-layer composite structure and the cumbersome construction and installation process are simplified. The intelligent temperature control module is used to monitor the temperature in the floor heating pipeline in real time and can control the temperature within the set temperature range, realizing the user's independent temperature control, as well as various functions such as individual temperature control of each room, temperature control by time periods, etc. Automatic adjustment according to indoor temperature; it can solve the problem of energy saving and consumption reduction of electric heating to the greatest extent, and can achieve good heating effect.

In some embodiments of the present invention, as shown in FIG. 2 , the floor heating module A1 includes a load-bearing heat-conducting plate 11 , a joist beam A12 and an adjusting bolt A13 . The load-bearing heat-conducting plate 11 is a square prefabricated standard plate, which can be integrally formed and can bear and conduct heat. The plate needs to be made of heat-conducting material, preferably, the load-bearing heat-conducting plate is made of metal, such as but not limited to iron, copper, aluminum, stainless steel, etc.; the thickness and toughness of the load-bearing heat-conducting plate can be selected according to specific construction needs. There are prefabricated pipeline grooves for inlaying and laying floor heating pipelines. The floor heating pipelines can be matched and installed in the pipeline grooves. The shape of the pipeline grooves can be any suitable shape, such as but not limited to square grooves, circular grooves and Curved grooves, etc., can also be a combination of two or more of the above-mentioned arbitrary shapes; when laying the floor heating pipeline, it is only necessary to place the floor heating pipeline directly on the floor heating module A1 without fixing, which can protect the floor heating The pipeline can save labor and material; the load-bearing heat-conducting plate 11 is installed on the upper end of the support beam A12, and the installation method can be fixed or detachable. For example, the load-bearing heat-conducting plate 11 can be welded on the support beam A12. The upper end of the joist A12; optionally, the load-bearing heat-conducting plate 11 can be riveted on the upper end of the joist A12 without rivets, and the rivetless riveting method can realize the stable connection of the two without damaging the metal surface anti-corrosion layer, and Effectively save costs; the supporting beam A12 is connected to the floor panel by adjusting bolts A13. The adjusting bolts A13 are used to adjust the height of the supporting beams A12 to level the floor heating module A1. It can effectively adjust the height of the supporting beam A, realize the leveling adjustment of the load-bearing heat-conducting plate, replace the setting of the original leveling layer, reduce the dependence on the levelness of the original floor plate, and make the leveling of the floor heating module A easier. Convenience; the shape and specification of the supporting beam A can be arbitrarily selected according to the specific load requirements, and its structural design can be solid or hollow, as long as it can meet the load bearing and the adjustment connection with the adjusting bolt A; The material of the joist A needs to be a thermally conductive material, preferably, the joist A is made of a metal material, such as but not limited to iron, copper, aluminum, stainless steel, etc.; the bottom end of the load-bearing thermal conductive plate is connected to one or more supporting The number of beam A and supporting beam A can be determined according to the actual load requirements. The load-bearing heat-conducting plate is directly in contact with the floor heating pipeline. Both the load-bearing heat-conducting plate and the supporting beam A are made of heat-conducting material. Adjusting bolt A is convenient for leveling at the same time. The overall structure design of the floor heating module A can realize the rapid conduction of the heat of the floor heating pipeline to the indoor space, improve the heat conduction efficiency, increase the effective utilization of heat, and save energy consumption.

In a preferred embodiment of the present invention, as shown in FIG. 4 , the direction of the pipeline groove and the support beam A12 are perpendicular to each other, which can maximize the maximum extent under the condition that the support beam A supports the load-bearing heat-conducting plate stably. It saves the number of supporting beams A used, simplifies the structure of the floor heating module A, reduces the weight of standardized module components, and saves consumables, transportation and labor costs.

In the present invention, the heat-conducting medium pipe 4 or the heating cable 5 or any combination of the two are inlaid and laid in the pipe groove. The heat-conducting medium in the heat-conducting medium pipe 4 is water or heat-conducting oil. The individualization of the floor heating module requires specific planning and prefabrication to enhance the applicability of the floor heating module and expand the user group.

In a preferred embodiment of the present invention, the groove wall of the pipeline groove is preferably completely attached to the outer surface of the heat-conducting medium pipe 4 or the heating cable 5, so as to facilitate rapid heat transfer; further preferably, the Reinforcing grooves are arranged between them to improve the toughness of the load-bearing heat-conducting plate 11 and enhance the supporting function of the load-bearing heat-conducting plate 11 .

In a preferred embodiment of the present invention, the position of the supporting beam A12 corresponding to the adjusting bolt A13 is a hollow design, and the hollow structure is more conducive to adjusting the adjusting bolt A13 while effectively reducing the weight of the supporting beam A. As shown in FIG. 3 , the adjusting bolt A13 includes a hollow screw A131, a first nut 132 and a second nut 133, wherein the first nut 132 is fixedly connected to the lower end of the supporting beam A12, and the hollow screw A131 is arranged on the first nut 132 The inner side of the hollow screw A131 is threadedly connected to the inner side of the first nut 132, the upper part of the hollow screw A131 penetrates into the interior of the joist A12, and the second nut 133 is used to lock the hollow screw A131 from the upper part of the hollow screw A131. The position corresponding to the hollow screw A131 on the load-bearing heat-conducting plate 11 is reserved for the adjustment of the hollow screw A131 and the second nut 133. The process hole can be any shape. The height is leveled, and colloid is injected into the interior of the hollow screw A during installation, so that the contact surface between the hollow screw A and the floor panel is increased, and the overall structural support of the floor heating module A is more firm and reliable.

In a preferred embodiment of the present invention, as shown in FIGS. 5 and 6 , the floor heating module B2 includes a support plate 21, a supporting beam B22 and an adjustment bolt B23, and the support plate 21 is used to support the floor heating module C3, The supporting plate 21 is installed on the upper end of the supporting beam B22, and the supporting beam B22 is connected with the floor panel by adjusting bolts B23. The adjusting bolt B23 is used to adjust the height of the supporting beam B22 to level the floor heating module B2; the supporting plate 21 It is a square prefabricated standard plate, which can be integrally formed. The support plate 21 needs to be made of thermally conductive material. Preferably, the support plate 21 is made of metal material, such as but not limited to iron, copper, aluminum and stainless steel. The thickness of the support plate 21 and The toughness can be selected according to the specific construction needs. Preferably, there are prefabricated reinforcing rib grooves for strengthening the supporting effect. The supporting plate 21 is installed on the upper end of the supporting beam B22. The installation method can be a fixed form or a In a detachable form, for example, the support plate 21 can be welded on the upper end of the joist beam B22; alternatively, the support plate 21 can be riveted on the upper end of the joist beam B22 without rivets. The supporting beam B22 is connected to the floor panel through adjusting bolts B23, and the adjusting bolts B23 are used to adjust the height of the supporting beam B22 to level the floor heating module B2. Adjust the bolts B makes it easier to realize the leveling adjustment in the construction operation, can effectively adjust the height of the supporting beam B, realize the leveling adjustment of the supporting plate, replace the setting of the original leveling layer, and reduce the leveling of the original floor plate. The degree of dependence of the floor heating module B makes the leveling of the floor heating module B more convenient; the shape and specification of the supporting beam B can be arbitrarily selected according to the specific load requirements, and its structural design can be solid or hollow, as long as it can meet the load-bearing and The adjustment connection with the adjustment bolt B can be applied; the material of the supporting beam B needs to be a thermally conductive material, preferably, the supporting beam B is a metal material, such as but not limited to iron, copper, aluminum, stainless steel, etc.; support The bottom end of the plate is connected to one or more supporting beams B. The number of supporting beams B can be determined according to the actual load requirements. The supporting plate supports the floor heating module C. The supporting plate and the supporting beam B are both thermally conductive materials. Adjust the bolts. B is convenient for leveling, while the support plate and the supporting beam B are overhead. The overall structure design of the floor heating module B can effectively support the floor heating module C, and at the same time, it can quickly transfer the heat of the floor heating pipeline to the indoor space, improve the heat conduction efficiency, and increase the heat transfer efficiency. Effective utilization of large heat, saving energy consumption.

In a preferred embodiment of the present invention, as shown in FIG. 7 , the direction of the reinforcing rib groove and the supporting beam B22 are perpendicular to each other, which can save the maximum cost when the supporting beam B22 supports the supporting plate stably. The number of supporting beams B used simplifies the structure of the floor heating module B, reduces the weight of the standardized module components, and saves consumables, transportation and labor costs.

In a preferred embodiment of the present invention, the position of the support beam B22 corresponding to the adjusting bolt B23 is hollow design, and the adjusting bolt B23 includes a hollow screw B231, a third nut 232 and a fourth nut 233, wherein the third The three nuts 232 are fixedly connected to the lower end of the supporting beam B23, the hollow screw B231 is arranged on the inner side of the third nut 232, the outer side of the hollow screw B231 is threadedly connected with the inner side of the third nut 232, and the upper part of the hollow screw B231 penetrates into the support Inside the beam B23, the fourth nut 233 is used to lock the hollow screw B231 from the upper part of the hollow screw B231, and the position corresponding to the hollow screw B231 on the support plate 21 is reserved for adjusting the hollow screw B231 and the fourth nut 233. Process hole, the process hole can be any shape, and the height of the supporting beam B can be adjusted by adjusting the hollow screw B to achieve leveling. The interior of the hollow screw B is injected with colloid during installation, so that the contact surface between the hollow screw B and the floor plate increases, and the floor heating module B The overall structural support is firmer and more reliable.

In a preferred embodiment of the present invention, the floor heating module C3 includes two or more separate parts of the return-bending auxiliary parts, and the separate parts of the return-bending auxiliary parts are combined to form a curved groove, which assists the return-bending laying of the floor heating pipeline, The material of the return bend auxiliary can be any solid material that meets the requirements of load and environmental protection, and the thickness can be close to the height of the floor heating pipeline. As shown in Figures 8-10, the floor heating module C3 includes a return-bending auxiliary part 1 31 and a return-bending auxiliary part 2 32. The overall outline of the return-bending auxiliary part 1 31 is a square flat plate, and one of the sides of the square flat plate is opened inward with a C-shaped orifice, the overall contour of the second return bending aid 32 is a racket-shaped flat plate that matches the inner side of the C-shaped orifice, and the size of the outer contour of the second return bending aid 32 is smaller than the size of the C-shaped orifice inside the first return bending aid 31 A curved groove is formed by the combination of the return-bending auxiliary part 1 31 and the return-bending auxiliary part 2 32, and the floor heating pipe passes through the curved groove.

In a preferred embodiment of the present invention, as shown in FIG. 12 , the intelligent temperature control module includes a temperature measurement device and an intelligent temperature controller, the temperature measurement device is arranged at an indoor temperature measurement point, and the temperature measurement device and the intelligent temperature controller are electrically connected ; It should be noted that when the heat-conducting medium pipe 4 is inlaid in the pipeline groove, the interior of the heat-conducting medium pipe 4 should be provided with an electric heater, and the temperature measuring device is one or more, and the temperature measuring device and the electric heater are respectively Connect the intelligent thermostat, and the electric heater includes resistance wire, electric heating film, electric heating tape, electric heating cable, electric heating tube or electric heating sheet, etc. When the heating cable 5 is embedded in the pipeline groove, the heating cable 5 is connected with the controller. The temperature measurement device and the controller are respectively connected to the intelligent thermostat; the intelligent thermostat controls the electric heater or the controller to continue heating or stop heating according to the temperature of the indoor temperature measurement point measured by the temperature measurement device in real time, which can be based on the specific indoor conditions. Adjust the heating conditions to realize the control of the heat dissipation of the floor heating heating system, so as to achieve the effect of saving energy and keeping warm; specifically, the intelligent thermostat can be set to different gears. Then continue heating, when the signal of the temperature measuring device is T2°C (adjustable), that is, the temperature control setting limit stops heating, and the heat-conducting medium or heating cable cools down naturally; the temperature measuring device can be a temperature sensor or a thermometer; The control module realizes the user's independent temperature control, as well as various functions such as individual temperature control of each room, temperature control by time period, etc., and can be automatically adjusted according to the indoor temperature; it can maximize the energy saving and consumption reduction of floor heating, and can achieve good results. heating effect.

In a preferred embodiment of the present invention, the intelligent temperature controller further includes a display device 11, preferably, the display device 11 is a touch display screen; the intelligent temperature control module is connected to the mobile terminal 13 through the cloud server 12, and the cloud server 12 is used for remote management of the intelligent temperature control module, and the mobile terminal 13 is used for remote interaction with the intelligent temperature control module. The terminal 13 includes a smart phone, a personal mobile pc, and a smart tablet. The operator can directly access the cloud server 12 through the mobile terminal 13 and then can control the smart thermostat through the cloud server 12; for example, as shown in FIG. 13, when remote control , take the PC terminal as an example, open the computer software to access the cloud server 12 through the network, read the indoor temperature measured by the temperature measuring device in real time, and set the temperature through the computer software; The indoor temperature is adjusted by accessing the cloud server 12 through the mobile phone according to the above operation.

An installation method of an intelligent temperature-controlled instant heating system of the present invention, as shown in FIG. 11 , includes the following steps:

S1. Place a number of floor heating modules A1 on the floor panel 6 according to the piping layout design, level the floor heating modules A1 by adjusting the hollow screw A131, and then lock and fix them with the second nut 133, and then inject glue into the hollow screw A131 ;

S2. Arrange a number of floor heating modules B2 on the opposite sides of the pipeline of the floor heating module A1 along the direction, adjust the hollow screw B231 to level the floor heating modules B2 and lower the height of the floor heating module A1, and then lock them with the fourth nut 233 Fix, and then inject glue into the hollow screw B231;

S3. Arrange the floor heating module C3 on the upper end of the floor heating module B2, and the height of the floor heating module C3 is flush with the height of the floor heating module A1, so that the curved groove of the floor heating module C3 is in the same direction as the floor heating pipeline of the floor heating module A1;

S4. Lay floor heating pipelines according to indoor heating demand;

S5, lay the first isolation film 7 on the floor heating module A1 and the floor heating module C3, lay the adhesive 8 on the first isolation film 7, and then lay the second isolation film 9 above the adhesive 8;

S6, open transverse shallow grooves on each of the four sides of the ceramic tile 10;

S7. Place the tile 10 directly on the second isolation film 9, adjust the gap between the beautiful seams, and then use a beautifying agent to beautify the seam.

Wherein, in step S5, the adhesive 8 is laid, and the fluidity of the adhesive is used to make the laying surface self-leveling. When leveling, a leveler can be used for leveling, or a vibrator can be used to vibrate slightly to make the adhesive level and solidify. , preferably, the thickness of the adhesive is below 5mm.

In step S7, a beautifying agent is used to beautify the seam. After the beautifying agent fills the shallow grooves of the tiles, the beautifying agent solidifies and forms a small cross shape, so that the tiles are firmly connected. Since the first isolation film is laid on the floor heating module A1 and the floor heating module C3, and the second isolation film is also laid above the adhesive, when the tiles are damaged and repaired or the tiles need to be replaced, the beautifying agent can be cleaned with a slitter. , the tiles can be removed, and the solidified adhesive can be removed. This installation method is convenient for repairing or replacing the tiles, the operation is simple, and the maintenance cost is saved; in addition, a thin second isolation film is set between the adhesive and the tiles. , which can ensure that when the tiles and the adhesive are completely adhered, there will be no air between the adhering surfaces, which is more conducive to heat conduction.

The installation method of the intelligent temperature-controlled instant-heated floor heating system of the present invention does not generate solid waste even when the floor heating system reaches its service life and needs to be removed, and the removed tiles and floor heating modules can be reused, which is environmentally friendly. policy requirements.

The above are only the preferred embodiments of the present invention. It should be pointed out that for those skilled in the art, without departing from the technical principles of the present invention, several improvements and modifications can also be made. These improvements and modifications It should also be regarded as the protection scope of the present invention.

Claims (10)

1. The utility model provides an intelligence control by temperature change instant heating type ground heating system, its characterized in that, including ground heating module A (1), ground heating module B (2), ground heating module C (3) and intelligent temperature control module, ground heating module A (1) is used for the bearing to lay the ground heating pipeline, ground heating module B (2) is laid the pipeline of ground heating module A (1) is along to relative both sides, ground heating module C (3) sets up the upper end of ground heating module B (2), it is provided with bent shape slot for ground heating pipeline's inflection is laid, temperature in the intelligent temperature control module real-time supervision ground heating pipeline can be with temperature control in setting for the temperature range.

2. The intelligent temperature-control instant heating type floor heating system as claimed in claim 1, wherein the floor heating module A (1) comprises a bearing heat-conducting plate (11), a bearing beam A (12) and an adjusting bolt A (13), a pipeline groove for embedding and laying a floor heating pipeline is prefabricated on the bearing heat-conducting plate (11), the bearing heat-conducting plate (11) is installed at the upper end of the bearing beam A (12), the bearing beam A (12) is connected with a floor panel through the adjusting bolt A (13), and the adjusting bolt A (13) is used for adjusting the height of the bearing beam A (12) to enable the floor heating module A (1) to be leveled.

3. The intelligent temperature-controlled instant floor heating system as claimed in claim 2, wherein the pipeline slot is perpendicular to the supporting beam A (12).

4. The intelligent temperature-control instant-heating floor heating system as claimed in claim 2, wherein the heat-conducting medium pipe (4) or the heating cable (5) or any arrangement combination of the two is embedded and laid in the pipeline groove.

5. The intelligent temperature-controlled instant-heating floor heating system as claimed in claim 2, the position of the supporting beam A (12) corresponding to the adjusting bolt A (13) is designed to be hollow, the adjusting bolt A (13) comprises a hollow screw A (131), a first nut (132) and a second nut (133), wherein the first nut (132) is fixedly connected with the lower end of the bearing beam A (12), the hollow screw A (131) is arranged at the inner side of the first nut (132), the outer side of the hollow screw A (131) is in threaded connection with the inner side of the first nut (132), the upper part of the hollow screw A (131) extends into the bearing beam A (12), the second nut (133) is used for locking the hollow screw A (131) from the upper part of the hollow screw A (131), and process holes for adjusting the hollow screw A (131) and the second nut (133) are reserved in the position, corresponding to the hollow screw A (131), of the bearing heat-conducting plate (11).

6. The intelligent temperature-control instant heating type floor heating system as claimed in claim 2, wherein the floor heating module B (2) comprises a support plate (21), a support beam B (22) and an adjusting bolt B (23), the support plate (21) is used for supporting the floor heating module C (3), the support plate (21) is installed at the upper end of the support beam B (22), the support beam B (22) is connected with a floor panel through the adjusting bolt B (23), and the adjusting bolt B (23) is used for adjusting the height of the support beam B (22) to level the floor heating module B (2).

7. The intelligent temperature-controlled instant-heating floor heating system as claimed in claim 6, the position of the supporting beam B (22) corresponding to the adjusting bolt B (23) is designed to be hollow, the adjusting bolt B (23) comprises a hollow screw B (231), a third nut (232) and a fourth nut (233), wherein the third nut (232) is fixedly connected with the lower end of the supporting beam B (22), the hollow screw B (231) is arranged at the inner side of the third nut (232), the outer side of the hollow screw B (231) is in threaded connection with the inner side of the third nut (232), the upper part of the hollow screw B (231) extends into the supporting beam B (22), the fourth nut (233) is used for locking the hollow screw B (231) from the upper part of the hollow screw B (231), and process holes for adjusting the hollow screw B (231) and the fourth nut (233) are reserved in the position, corresponding to the hollow screw B (231), of the support plate (21).

8. The intelligent temperature-controlled instant floor heating system according to claim 7, wherein the intelligent temperature-controlled module comprises a temperature measuring device and an intelligent temperature controller, the temperature measuring device is arranged at an indoor temperature measuring point, and the temperature measuring device is electrically connected with the intelligent temperature controller.

9. The intelligent temperature-control instant-heating floor heating system as claimed in claim 8, wherein the intelligent temperature control module is connected with the mobile terminal through a cloud server, the cloud server is used for remotely managing the intelligent temperature control module, the mobile terminal is used for remotely interacting with the intelligent temperature control module, and the intelligent temperature control module and the mobile terminal are both in radio electrical connection with the cloud server.

10. An installation method of the intelligent temperature-control instant floor heating system as claimed in any one of claims 1 to 9, characterized by comprising the following steps:

s1, placing a plurality of floor heating modules A (1) on a floor panel (6) according to pipeline arrangement design, leveling the floor heating modules A (1) by adjusting hollow screws A (131), locking and fixing the floor heating modules A (1) through second nuts (133), and injecting glue into the hollow screws A (131);

s2, arranging a plurality of floor heating modules B (2) on opposite sides of a pipeline of the floor heating module A (1) along the direction, leveling the floor heating modules B (2) by adjusting the hollow screw B (231) to be lower than the floor heating module A (1), locking and fixing the floor heating modules B (2) through a fourth nut (233), and injecting glue into the hollow screw B (231);

s3, arranging a floor heating module C (3) at the upper end of the floor heating module B (2), wherein the height of the floor heating module C (3) is flush with that of the floor heating module A (1), and the curved groove of the floor heating module C (3) is consistent with the direction of a floor heating pipeline of the floor heating module A (1);

s4, laying a floor heating pipeline according to indoor heat supply requirements;

s5, paving a first isolation film (7) on the floor heating module A (1) and the floor heating module C (3), paving a bonding agent (8) on the first isolation film (7), and paving a second isolation film (9) above the bonding agent (8);

s6, arranging transverse shallow grooves on four side edges of the ceramic tile (10) respectively;

s7, directly placing the ceramic tile (10) on the second isolation film (9), adjusting the seam beautifying gap, and then adopting seam beautifying agent to beautify the seam.

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