CN216664829U - Ground heating floor with double bent pipe grooves - Google Patents

Abstract

The utility model discloses a floor heating floor with double bent pipe grooves, which comprises a floor body and pipe grooves formed in the top surface of the floor body, wherein the end parts of the pipe grooves on the two sides of the floor body respectively take four end parts as a group; a first semicircular groove for connecting the two end parts is formed between the two end parts of the inner side of each group; a second semicircular groove for connecting the two end parts is formed between the two end parts of the outer side of each group; two sets of tube seat tip that correspond on floor body both sides dislocation two tube seat tip settings each other. The water inlet and the water return opening of the floor heating floor are close to each other, the temperature rise is uniform, the body feeling comfort is good, the floor heating floor is convenient to connect with a water collecting and distributing device, the required water pressure is low, the heat source selection range is wide, the laying area is large, and the heat exchange with the indoor space is fast.

Description

Ground heating floor with double bent pipe grooves

Technical Field

The utility model relates to the technical field of floor heating floors, in particular to a floor heating floor with double bent pipe grooves.

Background

Traditional ground heating floor uses single bent pipe groove as the owner, its structure is as shown in figure 1, set up the pipe chase that a plurality of equidistance set up on the floor body, then the both sides that are equipped with the pipe chase tip at the floor body use per two pipe chase tips as a set of, set up the semicircle channel of connecting these two pipe chase tips between two pipe chase tips of every group, and the pipe chase tip that misplaces each other of two sets of pipe chase tips that the floor body both sides correspond sets up, its structure after laying the water pipe is as shown in figure 2, traditional ground heating floor has following shortcoming:

1. the distance between the water inlet and the water return port is far, so that the temperature of the floor at the water inlet is high, the temperature of the floor at the water return port is low, the temperature rise is uneven, and the body feeling comfort is poor;

2. the water inlet and the water return port are far away from each other and are inconvenient to be connected with the water collecting and distributing device, and a single pipe groove is needed to be paved with a water pipe to be connected with the water collecting device;

3. too many water pipe bends, obvious pressure reduction, high required water pressure and narrow heat source selection range;

4. the water pipe is bent too much, the pressure reduction is obvious, and the laying area is small;

5. too many bent water pipes have obvious pressure reduction, slow water flow velocity and slow heat exchange with the indoor space.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems in the prior art, the utility model provides the floor heating floor with the double bent pipe grooves, the water inlet and the water return port of the floor heating floor are close, the temperature rise is uniform, the body feeling comfort is good, the floor heating floor is convenient to connect with a water dividing and collecting device, the required water pressure is low, the heat source selection range is wide, the laying area is large, and the heat exchange with the indoor is fast.

The technical scheme adopted by the utility model is as follows:

a floor heating floor with double bent pipe grooves comprises a floor body and pipe grooves formed in the top surface of the floor body, wherein four end parts of the pipe grooves on two sides of the floor body are respectively arranged in a group; a first semicircular groove for connecting the two end parts is formed between the two end parts of the inner side of each group; a second semicircular groove for connecting the two end parts is formed between the two end parts of the outer side of each group; two sets of tube seat tip that correspond on floor body both sides dislocation two tube seat tip settings each other.

Preferably, the floor body comprises a plurality of floor boards which are spliced to form the floor body.

Preferably, the floor blocks comprise a first floor block and a second floor block, and the top surfaces of the first floor block and the second floor block are provided with 4n pipe grooves; the end parts of the pipe grooves on one side of the first floor block are grouped into one group from every four pipe groove end parts on one side to the other side of the side; the pipe groove end parts of one side of the second floor block extend to the two sides of the side in sequence by taking every four pipe groove end parts from the middle part of the pipe groove end parts of the second floor block as a group until two pipe groove end parts are left on two sides respectively, a first semicircular groove of 1/2 is formed between the pipe groove end part positioned on the outer side in the two pipe grooves left on the two sides of the side of the second floor block and the side of the adjacent and parallel second floor block, and a second semicircular groove of 1/2 is formed between the pipe groove end part positioned on the inner side in the two pipe grooves left on the two sides of the side of the second floor block and the side of the adjacent and parallel second floor block.

Preferably, the floor body comprises a plurality of floor blocks, the floor body is formed by splicing the floor blocks, and the top surfaces of the floor blocks are provided with 4n pipe grooves; the end parts of the pipe grooves on one side of the floor block are divided into a group from one side edge vertical to the side edge to the other side edge vertical to the side edge, and n groups are formed; the two outermost pipe groove end parts on the two sides of the pipe groove end part on the other side of the floor block are respectively a half group, and every four pipe groove end parts between the two half groups are taken as a group from one side to the other side; a first semicircular groove for connecting the two end parts is formed between the two end parts of the inner side of the end part of each group of pipe grooves; a second semicircular groove for connecting the two end parts is formed between the two end parts of the outer side of the end part of each group of pipe grooves; the openings of the first semicircular groove and the second semicircular groove are oppositely arranged; the end part of the pipe groove, which is close to the outer side of the floor block, in the end part of the half group of pipe grooves is connected with a first semicircular groove of 1/2, and the end part of the pipe groove, which is close to the inner side of the floor block, in the end part of the half group of pipe grooves is connected with a second semicircular groove of 1/2; a first semicircular groove is formed between the two pipe groove ends of one half group of pipe groove ends.

The utility model has the beneficial effects that:

1. the double-bent pipe groove design has the advantages that the water inlet is adjacent to the water return port, compared with the traditional single-bent pipe groove design, the temperature rise is more uniform, the problems of hot indoor water inlet end and cold indoor water return end are avoided, and the body feeling is more comfortable;

2. the water inlet pipeline and the water return pipeline are adjacent and are conveniently connected with the water collecting and distributing device, and a water pipe laid in a single pipe groove is not needed to be connected with the water collecting device;

3. the design of the double-bent pipe groove enables 180-degree bending of the pipeline to be reduced by half in theory compared with the traditional single-bent pipe groove design, the pressure reduction of the whole pipeline is smaller, the requirement on water pressure is lower, and the heat source selection range is wide;

4. under the same condition, compared with the traditional single-bent pipe groove system, the pressure reduction of the double-bent pipe groove system pipeline is smaller, and the laying area is larger;

5. under the same condition, compare with traditional single return bend groove system, two return bend groove system pipelines step-down is littleer, and the velocity of water flow is fast, and is fast with indoor heat exchange, and indoor reaching the same temperature can save time 15%, and then the energy consumption reduces 15%.

Drawings

Fig. 1 is a schematic structural view of a floor heating floor with a conventional single bent pipe groove;

fig. 2 is a schematic view of a water pipe laying structure of a floor heating floor of a conventional single bent pipe groove;

fig. 3 is a schematic structural view of a floor heating floor according to embodiment 1 of the present invention;

FIG. 4 is a schematic structural view of one of the additional splicing parts used in the installation of the floor heating floor according to the embodiment of the utility model;

FIG. 5 is a schematic structural view of another additional splicing part used in the installation of the floor heating floor according to the embodiment of the utility model;

fig. 6 is a structural schematic view of the floor heating floor in embodiment 1 of the utility model after being installed;

fig. 7 is a schematic diagram of a laying structure of one of the water pipes after the floor heating floor in fig. 6 is installed;

fig. 8 is a schematic view of another water pipe laying structure after the floor heating floor in fig. 6 is installed;

fig. 9 is a schematic structural view of a first floor board in embodiment 2 of the present invention;

fig. 10 is a schematic structural view of a second floor panel according to embodiment 2 of the present invention;

fig. 11 is a schematic structural view of a floor heating floor formed by splicing a first floor block and a second floor block according to embodiment 2 of the present invention;

fig. 12 is a schematic view of a laying structure of one of the water pipes after the floor heating floor in fig. 11 is installed;

fig. 13 is a schematic view of the structure of the floor panel in embodiment 3 of the present invention;

fig. 14 is a schematic structural view of a floor heating floor spliced by floor boards in embodiment 3 of the utility model;

fig. 15 is a schematic view of a water pipe laying structure after the floor heating floor in fig. 14 is installed;

reference numerals: 10. floor body, 11, chase, 12, semicircular groove, 13, water pipe, 14, water inlet, 15, return water mouth, 20, floor body, 21, chase, 22, first semicircular groove, 23, second semicircular groove, 24, first floor block, 25, second floor block, 30, first extra concatenation portion, 31, the extra concatenation portion of second, 40, water pipe, 41, water inlet, 42, return water mouth, 50, floor block.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

Example 1

As shown in fig. 3, the floor heating floor with double bent pipe slots comprises a floor body 20 and pipe slots 21 arranged on the top surface of the floor body 20, wherein four end portions are respectively arranged at the end portions of the pipe slots 21 on two sides of the floor body 20; a first semicircular groove 22 for connecting the two end parts is arranged between the two end parts of the inner side of each group; a second semicircular groove 23 for connecting the two end parts is arranged between the two end parts of the outer side of each group; the two groups of pipe grooves 21 corresponding to the two sides of the floor body 20 are arranged at the ends of the two pipe grooves 21 which are staggered with each other.

The number of the pipe grooves 21 on the floor body 20 is an integral multiple of 4, as shown in fig. 3, when every four ends of the pipe grooves 21 are set as a group, and after the two corresponding groups of pipe grooves 21 on the upper and lower sides are staggered with respect to each other by two pipe grooves 21, if the upper side is grouped with the leftmost side, the lower side is grouped after being deviated from the two pipe grooves 21, and after the lower side is grouped, both sides will respectively have both ends, so that a first semicircular groove 22 of 1/2 is formed between the end of the pipe groove 21 positioned on the outer side in the two remaining pipe grooves 21 on both sides and the edge of the adjacent and parallel second floor panel 25, and a second semicircular groove 23 of 1/2 is formed between the end of the pipe groove 21 positioned on the inner side in the two remaining pipe grooves 21 on both sides and the edge of the adjacent and parallel second floor panel 25.

When the floor body 20 is installed, it is required to be installed in cooperation with the first additional splicing portion 30 shown in fig. 4 and the second additional splicing portion 31 shown in fig. 5. It can be seen that both the first additional splicing part 30 and the second additional splicing part 31 can be cut out directly from the floor body 20, but can also be separately manufactured. During installation, the first additional splicing part 30 is installed at the lower left corner of the floor body 20 shown in fig. 3, and the second additional splicing part 31 is installed at the upper left corner of the floor body 20 shown in fig. 3. The floor heating floor after final installation is as shown in fig. 6, the floor heating floor shown in fig. 6 is as shown in fig. 7 after the water pipe 40 is installed, the water inlet 41 and the water return 42 of the water pipe 40 can be respectively led out through the first semicircular groove 22 of 1/2 at the lower right corner of fig. 6 and the second semicircular groove 23 of 1/2 and then connected with the water collecting and distributing device, or can be directly led out in a straight line as shown in fig. 8 and then connected with the water collecting and distributing device.

The floor heating floor adopting the double-elbow-pipe groove design has the following advantages:

1. the water inlet is adjacent to the water return port, and compared with the traditional single-bent pipe groove design, the temperature rise is more uniform, the problems of hot indoor water inlet end and cold indoor water return end do not exist, and the body feeling is more comfortable;

2. the water inlet pipeline and the water return pipeline are adjacent and are conveniently connected with the water collecting and distributing device, and a water pipe laid in a single pipe groove is not needed to be connected with the water collecting device;

3. the design of the double-bent pipe groove enables 180-degree bending of the pipeline to be reduced by half in theory compared with the traditional single-bent pipe groove design, the pressure reduction of the whole pipeline is smaller, the requirement on water pressure is lower, and the heat source selection range is wide;

4. under the same condition, compared with the traditional single-bent pipe groove system, the pressure reduction of the double-bent pipe groove system pipeline is smaller, and the laying area is larger;

5. under the same condition, compare with traditional single return bend groove system, two return bend groove system pipelines step-down is littleer, and the velocity of flow is fast, and is fast with indoor heat exchange, and indoor reaching the same temperature can save time 15%, and then the energy consumption reduces 15%.

Example 2

In this embodiment, on the basis of embodiment 1, the floor body 20 includes a plurality of floor boards, and the floor boards are spliced to form the floor body 20.

As shown in fig. 9 and 10, the floor boards include a first floor board 24 and a second floor board 25, wherein the top surfaces of the first floor board 24 and the second floor board 25 are respectively provided with 4n pipe grooves 21, and in this embodiment, the first floor board 24 and the second floor board 25 are respectively provided with 8 pipe grooves 21 as an example; the end parts of the pipe grooves 21 on one side of the first floor block 24 are grouped from one side to the other side by four pipe grooves 21; the end portions of the pipe grooves 21 of one side of the second floor board 25, starting from the middle portion of every four pipe grooves 21, sequentially extend to the two sides of the side until two pipe grooves 21 are left on the two sides, a first semicircular groove 22 of 1/2 is formed between the end portion of the pipe groove 21 positioned on the outer side in the two pipe grooves 21 left on the two sides of the side of the second floor board 25 and the side of the adjacent and parallel second floor board 25, and a second semicircular groove 23 of 1/2 is formed between the end portion of the pipe groove 21 positioned on the inner side in the two pipe grooves 21 left on the two sides of the side of the second floor board 25 and the side of the adjacent and parallel second floor board 25.

Through the design, the modular assembled floor heating floor is characterized in that as shown in fig. 11, the first floor blocks 24 are correspondingly spliced on the upper sides of the second floor blocks 25 to form floor blocks, then the floor blocks are spliced left and right to form the floor body 20, and the principle of the spliced floor body 20 is the same as that of embodiment 1.

In this embodiment, the first floor board 24 or the second floor board 25 may be further joined between the first floor board 24 and the second floor board 25 joined to each other to enlarge the installation area, and only the pipe grooves 21 corresponding to each other need to be aligned, and the first floor board 24 or the second floor board 25 located in the middle may only use the pipe grooves 21 of the straight line portion, instead of the first semicircular groove 22 and the second semicircular groove 23, that is, the first floor board 24 or the second floor board 25 located in the middle mainly functions to extend the straight line portion of the water pipe 40.

Example 3

In this embodiment, on the basis of embodiment 1, as shown in fig. 13 to 14, the floor body 20 includes a plurality of floor boards 50, the floor boards 50 are spliced to form the floor body 20, and the top surfaces of the floor boards 50 are provided with 4n pipe grooves 21; the end parts of the pipe grooves 21 on one side of the floor block 50 are divided into n groups from one side edge perpendicular to the side edge to the other side edge perpendicular to the side edge, wherein every four end parts of the pipe grooves 21 are divided into one group; the two outermost pipe groove 21 end parts on two sides of the pipe groove 21 end part on the other side of the floor block 50 are respectively half-group, and every four pipe groove 21 end parts are a group from one side to the other side of the pipe groove 21 part between the two half-group; a first semicircular groove 22 for connecting the two end parts is arranged between the two end parts on the inner side of the end part of each group of pipe grooves 21; a second semicircular groove 23 for connecting the two end parts is arranged between the two end parts of the outer side of the end part of each group of pipe grooves 21; the openings of the first semicircular groove 22 and the second semicircular groove 23 are oppositely arranged; a first semicircular groove 22 of 1/2 is connected to the end of the pipe groove 21 close to the outer side of the floor board 50 in the end part of the half group of pipe grooves 21, and a second semicircular groove 23 of 1/2 is connected to the end of the pipe groove 21 close to the inner side of the floor board 50 in the end part of the half group of pipe grooves 21; a first semicircular groove 22 is formed between the end parts of the two pipe grooves 21 at the end part of one half group of pipe grooves 21.

As shown in fig. 14, the floor heating floor 20 can be spliced by a plurality of floor boards 50, the number of the floor boards 50 is determined according to the area of the floor heating floor 20 actually required, as shown in fig. 15, the schematic diagram of the installed water pipe 40 of the embodiment is shown, in the embodiment, the structures of the floor boards 50 are completely the same, and the first semicircular groove 22 is formed in the middle point of the water pipe between the end parts of the two pipe grooves 21 at the end part of one of the half pipe grooves 21, and there is no need to additionally install the first additional splicing part 30 and the second additional splicing part 31, so that the modular production and the building block installation of uniform specification are really realized.

The above-mentioned embodiments only express the specific embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention.

Claims (4)

1. A floor heating floor with double bent pipe grooves comprises a floor body (20) and pipe grooves (21) formed in the top surface of the floor body (20), and is characterized in that the end parts of the pipe grooves (21) on the two sides of the floor body (20) are respectively in groups of four end parts; a first semicircular groove (22) for connecting the two end parts is arranged between the two end parts of the inner side of each group; a second semicircular groove (23) for connecting the two end parts is arranged between the two end parts of the outer side of each group; the floor is characterized in that the end parts of two groups of corresponding pipe grooves (21) on two sides of the floor body (20) are staggered with the end parts of the two pipe grooves (21).

2. The ground heating floor with double bending pipe groove as claimed in claim 1, characterized in that the floor body (20) comprises a plurality of floor boards which are spliced to compose the floor body (20).

3. The ground heating floor with double bending pipe grooves as claimed in claim 2, wherein the floor boards comprise a first floor board (24) and a second floor board (25), the top surfaces of the first floor board (24) and the second floor board (25) are provided with 4n pipe grooves (21); the end parts of the pipe grooves (21) on one side of the first floor block (24) start from one side to the other side of the side, and the end parts of every four pipe grooves (21) form a group; the pipe groove (21) end of one side of the second floor board (25) starts every four pipe groove (21) ends from the middle part to be a group and extends to the two sides of the side in sequence until two pipe groove (21) ends are remained on the two sides respectively, a first semicircular groove (22) of 1/2 is formed between the pipe groove (21) end positioned on the outer side in the two pipe grooves (21) remained on the two sides of the side of the second floor board (25) and the side of the adjacent and parallel second floor board (25), and a second semicircular groove (23) of 1/2 is formed between the pipe groove (21) end positioned on the inner side in the two pipe grooves (21) remained on the two sides of the side of the second floor board (25) and the side of the adjacent and parallel second floor board (25).

4. The ground heating floor with double bending pipe grooves as claimed in claim 1, wherein the floor body (20) comprises a plurality of floor boards (50), the floor boards (50) are spliced to form the floor body (20), and the top surfaces of the floor boards (50) are provided with 4n pipe grooves (21); the end parts of the pipe grooves (21) on one side of the floor block (50) start from one side edge vertical to the side, and the end parts of every four pipe grooves (21) form one group till the other side edge vertical to the side edge, wherein n groups are provided; the end parts of two outermost pipe grooves (21) on two sides of the end part of the pipe groove (21) on the other side of the floor block (50) are respectively half groups, and the end parts of every four pipe grooves (21) between the two half groups are arranged in one group from one side to the other side; a first semicircular groove (22) for connecting the two end parts is arranged between the two end parts on the inner side of the end part of each group of pipe grooves (21); a second semicircular groove (23) for connecting the two end parts is arranged between the two end parts on the outer side of the end part of each group of pipe grooves (21); the openings of the first semicircular groove (22) and the second semicircular groove (23) are oppositely arranged; a first semicircular groove (22) of 1/2 is connected to the end part of the pipe groove (21) close to the outer side of the floor block (50) in the end part of the half group of pipe grooves (21), and a second semicircular groove (23) of 1/2 is connected to the end part of the pipe groove (21) close to the inner side of the floor block (50) in the end part of the half group of pipe grooves (21); a first semicircular groove (22) is formed between the end parts of the two pipe grooves (21) at the end part of one half group of pipe grooves (21).

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