CN213514046U - A lay structure for building indoor geothermol power pipeline - Google Patents

Abstract

The utility model belongs to the technical field of the building, especially, be a laying structure for building indoor geothermol power pipeline, comprising a base plate, the top of bottom plate is connected with the insulating layer, the top of insulating layer is connected with the radiation reflection layer, the top of radiation reflection layer is connected with the layer that generates heat, the inner wall on the layer that generates heat is provided with the cooling tube, one side of cooling tube is connected with the connecting pipe, the top of connecting pipe is connected with the inlet tube, the top of inlet tube is connected with always controls the center, the bottom of always controlling the center is connected with the outlet pipe. Lay with the tradition and compare, uncertainty when not only having avoided laying makes warm up and lays simpler and more understandable, and the distance homogeneous phase of every cooling tube makes warm up the heating more even, and the temperature in every region can be measured to the thermoscope of setting to distinguish fast and adjust, the heat that the wire netting transmission cooling tube of setting distributed out, thereby it is more even to make warm up the heating.

Description

A lay structure for building indoor geothermol power pipeline

Technical Field

The utility model belongs to the technical field of the building, concretely relates to a laying structure for building indoor geothermal pipeline.

Background

The floor heating is short for floor radiation heating, the whole floor is used as a radiator, the whole floor is uniformly heated through a heating medium in a floor radiation layer, and heat is supplied to the indoor through the floor in a radiation and convection heat transfer mode, so that the purpose of comfortable heating is achieved. The heat transfer medium is divided into a water ground heating type and an electric ground heating type according to different heat transfer media, and the heat transfer medium is mainly divided into a dry ground heating type and a wet ground heating type according to different paving structures.

When installing, the traditional floor heating needs to be arranged in a flat line, so that the floor heating can be uniformly cooled, however, in actual operation, a fixed coil pipe is difficult to achieve, if a problem occurs in the floor heating test, the root cause of the problem cannot be found quickly, and almost all concrete filling layers need to be damaged in the maintenance process.

SUMMERY OF THE UTILITY MODEL

To solve the problems set forth in the background art described above. The utility model provides a laying structure for building indoor geothermal pipeline has solved the inconvenient problem of installation.

In order to achieve the above object, the utility model provides a following technical scheme: a laying structure for building indoor geothermal pipelines comprises a bottom plate, wherein the top of the bottom plate is connected with a heat insulation layer, the top of the heat insulation layer is connected with a radiation reflection layer, the top of the radiation reflection layer is connected with a heating layer, the inner wall of the heating layer is provided with a heat radiation pipe, one side of the heat radiation pipe is connected with a connection pipe, the top of the connection pipe is connected with a water inlet pipe, the top of the water inlet pipe is connected with a general control center, the bottom of the general control center is connected with a water outlet pipe, the other end of the heat radiation pipe is connected with a hydraulic cylinder, one end of the hydraulic cylinder is connected with a movable plate, the side of the movable plate is connected with a connection rod, one end of the connection rod is connected with a connection port, the top of the heating layer is connected with a heat, the top of the heat transfer layer is connected with a floor layer, and the side of the heat dissipation layer is connected with a grounding wire.

Preferably, one or more radiating pipes may be provided, and the distance between each radiating pipe is the same.

Preferably, the bottom of the water outlet pipe and the bottom of the water inlet pipe are connected with the connecting pipe through bolts and the like, and only one device is required to be connected with the water outlet pipe and the water inlet pipe in actual use.

Preferably, the ground wire penetrates through the bottom plate, the heat insulation layer, the radiation reflection layer and the heating layer, and a heat insulation sleeve is arranged on the surface of the ground wire.

Preferably, the wire netting is divided into horizontal rows and rows, and the wire netting is crossed to form a square.

Preferably, the temperature measuring instrument measures data near the heat transfer layer and transmits the data to the master control center, and one temperature measuring instrument is arranged between every two radiating pipes.

Compared with the prior art, the beneficial effects of the utility model are that:

the connecting port is connected with the connecting pipe of another device, the device can be fixed on the ground, the connection and smoothness of the radiating pipe can be realized, compared with the traditional laying, the utility model not only avoids the uncertainty of laying, makes the laying of the floor heating simpler and easier to understand, the distance of each radiating pipe is the same, the heating of the floor heating is more uniform, the temperature is adjusted by the master control center after charging, the temperature measurer can measure the temperature of each area, thereby rapidly distinguishing and adjusting, the arranged wire netting transmits the heat emitted by the radiating pipe, thereby the floor heating heat supply is more uniform, the device can be quickly disassembled by withdrawing the connecting port through the hydraulic cylinder, therefore, the defect that the whole floor heating system needs to be damaged when the traditional floor heating system is debugged is avoided, and the defect that the ground surface decoration layer needs to be damaged when the floor heating system is maintained can be overcome to a certain extent by the floor layer of the device.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a complete structural schematic diagram of the present invention;

fig. 2 is a sectional view of a front view of the present invention;

fig. 3 is a cross-sectional view of a side view of the present invention.

In the figure: 1, a bottom plate; 2, a heat insulation layer; 3 a radiation reflecting layer; 4 a heating layer; 5, radiating pipes; 6, connecting pipes; 7, a water inlet pipe; 8, a master control center; 9, discharging a water pipe; 10 hydraulic cylinders; 11 moving the board; 12 connecting rods; 13, a connecting port; 14 a heat dissipation layer; 15, a wire mesh; 16 ground lines; 17 a heat transfer layer; 18 a floor layer; 19 thermometer.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides the following technical solutions: a laying structure for building indoor geothermal pipelines comprises a bottom plate 1, wherein the top of the bottom plate 1 is connected with a heat insulation layer 2, the top of the heat insulation layer 2 is connected with a radiation reflection layer 3, the top of the radiation reflection layer 3 is connected with a heating layer 4, the inner wall of the heating layer 4 is provided with a heat dissipation pipe 5, one side of the heat dissipation pipe 5 is connected with a connecting pipe 6, the top of the connecting pipe 6 is connected with a water inlet pipe 7, the top of the water inlet pipe 7 is connected with a general control center 8, the bottom of the general control center 8 is connected with a water outlet pipe 9, the other end of the heat dissipation pipe 5 is connected with a hydraulic cylinder 10, one end of the hydraulic cylinder 10 is connected with a movable plate 11, the side of the movable plate 11 is connected with a connecting rod 12, one end of the connecting rod 12 is connected with a connecting port 13, the top of, the heat transfer layer 17 is connected to a floor layer 18 at the top, and the heat dissipation layer 14 is connected to a ground line 16 at the side.

In the embodiment, when the floor heating device is used, the two devices are placed on the ground to be aligned, the movable plate 11 is pushed through the hydraulic cylinder 10 to enable the connecting ports 13 to extend out of the devices, the connecting ports 13 are connected with the connecting pipes 6 of the other device, the devices can be fixed on the ground, and the connection and the smoothness of the radiating pipes 5 can be realized, then the adjacent connecting ports 13 or the connecting pipes 6 are connected through the external pipelines, and the two connecting pipes 6 are reserved to be connected with the water inlet pipe 7 and the water outlet pipe 9, so that the laying of the floor heating pipeline is realized, compared with the traditional laying, the uncertainty in laying is avoided, the floor heating laying is simpler and easier to understand, the distance of each radiating pipe 5 is the same, the floor heating is more uniform, the temperature is adjusted through the master control center 8 after charging, the temperature detector 19 can measure the, the heat that 15 transmission cooling tubes 5 of wire netting of setting gave out to the heat supply warms up more evenly to make, withdraw connector 13 through pneumatic cylinder 10 and can quick dismounting device, thereby need destroying the shortcoming of whole underfloor heating system when having avoided the debugging of traditional underfloor heating, the device is from the floor layer 18 of taking also can overcome to a certain extent and warm up the shortcoming that need destroy the earth's surface decorative layer when maintaining.

Specifically, the radiating pipes 5 may be provided with one or more, and the distance between each radiating pipe 5 is the same, the overall length and width of the device can be controlled by assembling a plurality of radiating pipes 5, thereby coping with different decoration spaces.

Specifically, the bottoms of the water outlet pipe 9 and the water inlet pipe 7 are connected with the connecting pipe 6 through bolts and the like, only one device needs to be connected with the water outlet pipe 9 and the water inlet pipe 7 in actual use, and heat circulation in floor heating is achieved through the water inlet pipe 7 and the water outlet pipe 9.

Specifically, the grounding wire 16 penetrates through the bottom plate 1, the heat insulation layer 2, the radiation reflection layer 3 and the heating layer 4, a heat insulation sleeve is arranged on the surface of the grounding wire 16, energy is provided for the device through the grounding wire 16, and the device can be more attractive in appearance.

Specifically, wire netting 15 divide into horizontal row and the criss-cross distribution of number row, and a plurality of wire netting 15 are alternately formed the square, can transmit the heat through wire netting 15 to the heat that warms up and gives out is more even.

Specifically, the temperature measuring instrument 19 measures data near the heat transfer layer 17 and transmits the data to the master control center 8, one temperature measuring instrument 19 is arranged between every two radiating pipes 5, and whether the floor heating is uneven or not can be quickly judged through detection of the temperature measuring instruments 19.

The utility model discloses a theory of operation and use flow: after the utility model is installed, when in use, two devices are placed on the ground to be aligned, the movable plate 11 is pushed by the hydraulic cylinder 10 to extend the connecting port 13 out of the device, the connecting port 13 is connected with the connecting pipe 6 of another device, not only the device can be fixed on the ground, but also the connection and smoothness of the radiating pipes 5 can be realized, then the adjacent connecting port 13 or the connecting pipe 6 is connected by an external pipeline, two connecting pipes 6 are reserved to connect the water inlet pipe 7 and the water outlet pipe 9, thereby realizing the laying of floor heating pipelines, the distance of each radiating pipe 5 is the same, the floor heating is more uniform, the temperature is adjusted by the general control center 8 after charging, the temperature of each area can be measured by the arranged thermodetector 19, the arranged wire netting 15 transmits the heat emitted by the radiating pipes 5, the floor heating is more uniform, the device can be quickly disassembled by withdrawing the connecting port 13 by the hydraulic, thereby the shortcoming that needs destroy whole underfloor heating system when having avoided traditional warm up the debugging, the floor layer 18 of device from the area also can overcome to a certain extent and warm up the shortcoming that needs destroy the earth's surface decorative layer when maintaining, the input of the consumer in this equipment all with external power source electric connection.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. A laying structure for building indoor geothermal pipeline, includes bottom plate (1), the top of bottom plate (1) is connected with insulating layer (2), its characterized in that: the top of insulating layer (2) is connected with radiation reflecting layer (3), the top of radiation reflecting layer (3) is connected with layer (4) that generates heat, the inner wall of layer (4) that generates heat is provided with cooling tube (5), one side of cooling tube (5) is connected with connecting tube (6), the top of connecting tube (6) is connected with inlet tube (7), the top of inlet tube (7) is connected with total accuse center (8), the bottom of total accuse center (8) is connected with outlet pipe (9), the other end of cooling tube (5) is connected with pneumatic cylinder (10), one end of pneumatic cylinder (10) is connected with movable plate (11), the side of movable plate (11) is connected with connecting rod (12), one end of connecting rod (12) is connected with connector (13), the top of layer (4) that generates heat is connected with heat layer (14), the heat dissipation layer is characterized in that an iron wire mesh (15) is arranged on the inner wall of the heat dissipation layer (14), the top of the heat dissipation layer (14) is connected with a temperature measuring instrument (19), the top of the heat dissipation layer (14) is connected with a heat transfer layer (17), the top of the heat transfer layer (17) is connected with a floor layer (18), and the side face of the heat dissipation layer (14) is connected with a grounding wire (16).

2. A laying structure for building indoor geothermal piping according to claim 1, wherein: one or more radiating pipes (5) can be arranged, and the distance between every two radiating pipes (5) is the same.

3. A laying structure for building indoor geothermal piping according to claim 1, wherein: the bottom of outlet pipe (9) and inlet tube (7) is passed through the bolt etc. and is connected with connecting pipe (6), only has a device to need connect outlet pipe (9) and inlet tube (7) when the in-service use.

4. A laying structure for building indoor geothermal piping according to claim 1, wherein: the ground wire (16) penetrates through the bottom plate (1), the heat insulation layer (2), the radiation reflection layer (3) and the heating layer (4), and a heat insulation sleeve is arranged on the surface of the ground wire (16).

5. A laying structure for building indoor geothermal piping according to claim 1, wherein: the wire netting (15) divide into horizontal row and the crisscross distribution of several rows, and a plurality of wire netting (15) are crisscross and are formed the square.

6. A laying structure for building indoor geothermal piping according to claim 1, wherein: the temperature measuring instrument (19) measures data near the heat transfer layer (17) and transmits the data to the master control center (8), and one temperature measuring instrument (19) is arranged between every two radiating pipes (5).

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