KR101457466B1 - heating tube - Google Patents

Abstract

The present invention relates to a heating piping device. In the heating piping device according to the present invention, a partition plate (52) is disposed in a transverse direction of heating piping, water that is generated by cooling of steam which flows along an upper portion of the partition plate (52) flows out downward from the partition plate (52) through a through-hole (54) formed in the partition plate (52), and an inclined water receiving plate (60) is formed below the partition plate (52) so that the water flowing out of the through-hole (54) is received and collected in a central portion of the heating piping (50). According to the present invention, the water that is generated in the heating piping can be recovered within a shortest distance through a suction hose disposed in an air layer and boiler efficiency can be maximized.

Description

{Heating tube}

The present invention relates to a floor structure and a piping device for minimizing the interlayer noise and to improve the heating efficiency, and a steam boiler used together with the floor structure.

Recently, the interlayer noise problem of apartment is serious. Inter-floor noise can harm the mental health and deteriorate the residential environment, leading to a disagreement between the neighbors, leading to social crime. In order to solve this problem, there is a movement to regulate the floor structure of apartments such as apartments and to minimize the interlayer noise, but the regulation to secure the thickness of the buffer has not achieved much effect.

In a conventional apartment floor structure, a heating pipe is buried, and hot steam or water generated from a boiler flows through a heating pipe and warms the floor. However, there is a problem that the floor becomes hot only in the vicinity of the heating pipe, and the part where the piping does not pass is still cold, and the entire floor is not heated evenly.

On the other hand, the steam boiler circulates water vapor through the pipe to warm the interior of the building. The high-temperature water vapor generated inside the boiler changes into water as it enters the room through the pipe and releases heat to warm the surroundings. The heating efficiency is not deteriorated until the generated water is recovered well.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a bottom structure that minimizes the interlayer noise and uniformizes the floor heating.

Another object of the present invention is to provide a bottom structure and a steam boiler which can quickly and surely recover the water generated in the heating pipe.

According to an aspect of the present invention for achieving the above object, the present invention provides an interlayer noise preventing bottom structure, comprising: a foamed concrete layer formed on a slab and having a plurality of grooves recessed at a predetermined depth; And a top layer formed on the buffer layer and composed of 30% foamed concrete, 30% cotton, 40% styrofoam, 30% foamed concrete, 30% cotton, and 40% styrofoam.

Wherein an air layer is formed at the center of the pipe layer in a transverse direction and a longitudinal direction is formed at an upper portion of the pipe layer and a piping groove for installing a heating pipe is formed in the upper portion of the pipe layer, And the heat of the heating pipe is transmitted to the entire floor along the air layer.

Wherein the heating pipe is provided with a partition plate partitioning the heating pipe up and down and formed with a plurality of water holes, a water receiving plate for collecting water that has escaped from the water holes is formed at an underside of the partition plate, A suction hose is connected to a lower portion of the heating pipe corresponding to a lower portion of the heating pipe to extract water collected at a lower portion of the inclination of the water receiving plate and to install the suction hose in the air layer so as to recover the water at the shortest distance .

The present invention relates to a heating pipe connected to a steam boiler and installed inside a floor, wherein a partition plate is installed in the heating pipe in the lateral direction of the heating pipe, and a partition wall is formed through the water hole formed in the partition plate, The water generated due to the cooling of the steam flowing along the partition plate escapes to the lower portion of the partition plate and the water receiving plate for collecting the water escaping from the water holes and collecting the water in the center portion of the heat pipe is formed obliquely below the partition plate.

A central portion of the heating pipe corresponding to a lower portion of the inclined portion of the water receiving plate is connected to a suction hose, and the suction hose is connected to a recovery motor for recovering water in the suction hose to the steam boiler.

The steam boiler of the present invention comprises a steam generator for generating steam, a high-temperature wind generator for supplying high-temperature wind to the steam generated in the steam generator, a heating pipe for heating the steam generated from the steam generator, The water recovered by the recovery motor is transferred to the hot water tank and reused as hot water.

According to the bottom structure of the present invention, since grooves are formed in the foamed concrete and the buffer plate is provided, the interlayer noise is minimized. Further, the floor heating can be made uniform by the air layer formed in the piping layer.

According to the bottom structure and the piping apparatus of the present invention, the water generated in the heating pipe is recovered at the shortest distance through the suction hose provided in the air layer, the recovered hot water is reused as hot water, and the efficiency of the boiler is maximized. Waste can be minimized.

1 is a conceptual view showing a steam boiler and a heating pipe according to the present invention;
2 is a sectional view taken along line AA 'of FIG. 1 showing the heating floor structure of the present invention.
3 is a partial perspective view showing a heating floor structure according to the present invention.
4 is a perspective view showing a part of a piping apparatus according to the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1, the construction of the steam boiler 10 of the present invention will be described. The steam boiler 10 includes a steam generator 11 for producing steam, a high-temperature wind generator 12 for supplying high-temperature steam to the steam generated in the steam generator 11, A heating pipe 50 for performing heating through steam, and a recovery motor 80 for recovering water generated in the heating pipe 50.

The steam boiler 10 is provided with a cold water tank 21 and a hot water tank 23. A shield plate 25 is disposed between the cold water tank 21 and the hot water tank 23, Water is transferred from the cold water tank 21 to the hot water tank 23 through the water passage 26 formed in the hot water tank 23.

The cold water tank 21 is connected to a water pipe 27 for supplying water and a hot water pipe 28 for supplying hot water generated in the hot water tank 23 to the user is connected to the hot water tank 23. The hot water pipe (28) may be provided with a hot water motor (29) for supplying hot water smoothly.

The steam device 11 receives water from the cold water tank 21 through a water supply pipe 32 connecting the cold water tank 21 and the steam device 11. The water supplied from the cold water tank 21 is changed into steam from the steam generator 11.

The high-temperature wind generated in the high-temperature wind apparatus 12 and the steam generated in the steam apparatus 11 are separated and separated into the heating supply line 35 and the recovery line 36 through the hot water heating automatic switch 34 . The hot water and heating automatic switch 34 selectively opens and closes the heating supply line 35 and the collecting line 36 in accordance with the heating mode and the heating mode in the form of a valve.

The heating supply line 35 is closed and the collection line 36 is opened by the operation of the hot water and the automatic heating switch 34 so that the steam of the steam apparatus 11 is totally returned to the collection line 36 To provide heat to the hot water generation of the hot water tank 23.

On the contrary, in the case of heating only, the heating supply line 35 is opened by the operation of the hot water and the automatic heating switch 34, and the recovery line 36 is closed, and the steam of the steam apparatus 11 is all supplied to the heating supply line 35).

In the case of the heating and hot water mixing mode, both the heating supply line 35 and the recovery line 36 are opened by the operation of the hot water and the automatic heating switch 34, and the steam of the steam device 11 is supplied to the heating supply line (35) and the recovery line (36).

The steam delivered to the heating supply line 35 moves along the heating pipe 50 and is then returned to the hot water tank 23 through the recovery line 36.

The steam boiler 10 of the present invention is provided with a recovery motor 80 for recovering water generated in accordance with a change in steam in the heating pipe 50. In this embodiment, The recovery motor (80) is installed at the point where the recovery line (36) meets.

FIG. 2 is a cross-sectional view of the present invention's interlayer noise-preventing floor structure, and FIG. 3 is a perspective view of the interlayer noise-preventing floor structure.

2 and 3, the present invention provides a floor structure for preventing noise between beds, which comprises a foamed concrete layer 120 formed on a slab and having a plurality of grooves 123, a buffer plate 140 formed on the foamed concrete layer 120, ), A piping layer 160 formed on the buffer plate 140 and composed of 30% foamed concrete, 30% cotton and 40% styrofoam, 30% foamed concrete, 30% cotton, and styrofoam 40 formed on the piping layer 160 % ≪ / RTI >

The foamed concrete layer 120 is a layer formed by curing foamed concrete. Here, the term "foam concrete" refers to a porous concrete containing a large amount of air bubbles in a cement paste mixed with a foaming agent or mixed with a stable foam and a cement paste. The foamed concrete layer 120 may have a thickness of 15 cm to 25 cm.

A plurality of grooves 123 are formed on the foamed concrete layer 120. The grooves 123 are formed by being recessed to a predetermined depth in the upper part of the foamed concrete layer 120 in the shape of a quadrangle, and a plurality of grooves 123 are arranged at regular intervals. Since the grooves 123 contain air, the foamed concrete layer 120 can efficiently cushion the interlayer noise. In addition, direct contact between the foamed concrete layer 120 and the buffer plates 140 can be prevented in the groove 123, and transmission of vibration and impact through the medium can be blocked to some extent.

And a buffer plate 140 formed of a raw material is provided on the foamed concrete layer 120. Since the buffer plate 140 is made of raw material, the shock absorbing plate 140 can reliably absorb the shock, and the interlayer noise can be prevented. The buffer plate 140 may have a thickness of 15 cm or more and 25 cm or less.

The pipe layer 160 formed on the buffer plate 140 is formed by compression molding of 30% foamed concrete, 30% cotton and 40% styrofoam. The pipe layer 160 is formed to a total thickness of 80 cm, and an air layer 165 having a rectangular cross section is formed at a central portion thereof as a grid of a horizontal line and a vertical line.

A piping groove 170 is formed in the upper portion of the pipe layer 160 so that a heating pipe 50 can be installed. 3, the lower part of the pipe groove 170 and the upper part of the air layer 165 communicate with each other at intersections.

The air layer 165 serves to transmit heat generated from the heating pipe 50 in the pipe layer 160 to the entire floor. That is, the heat of the pipe layer 160 is transferred to the air layer 165 at the intersection of the pipe layer 160 and the air layer 165, and the air layer 165, The heat can be transferred to the portion where the pipe layer 160 is not present.

The air layer 165 is further provided with a suction hose 90 for moving the water generated in the heating pipe 50 to the steam boiler 10. The suction hose 90 will be described later.

Hereinafter, the structure of the heating pipe 50 of the present invention will be described with reference to FIG. As shown in FIG. 4, the heating pipe 50 is a pipe through which the steam generated in the steam boiler 10 passes, and the whole bottom of the heating pipe 50 is heated while the steam moves along the heating pipe 50.

Fig. 4 shows a pipe corresponding to a unit length of 20 m of the heating pipe 50. However, these unit lengths may be set to various dimensions depending on floor area or pipe length.

Inside the heating pipe 50, a partition plate 52 transversely crossing the center of the heating pipe 50 is installed. Steam passes through the partition plate (52). A plurality of through holes 54 are formed in the partition plate 52 to allow the water generated as the steam flowing to the upper portion of the partition plate 52 is cooled down. That is, the water generated in the upper part of the partition plate 52 through the through hole 54 falls down to the lower part of the partition plate 52. As shown in FIG. 4, the partition plate 52 is curved in the center, and the through-holes 54 are formed at a predetermined interval in the center of the partition plate 52.

A water receiving plate 60 for collecting water at the center of the heating pipe 50 is formed below the partition plate 52. The water receiving plate 60 is connected to the suction hose connecting hole 62 at both ends of the heating pipe 50 so as to collect water by a suction hose connecting hole 62 formed at the center of the heating pipe 50 As shown in FIG.

The suction hose 90 is connected to the suction hose connecting hole 62, and the suction hose 90 is installed in the air layer 165. Since the suction hose 90 is installed in the air layer 165, the length of the suction hose 90 can be shortest, and water generated in the heating pipe 50 can be quickly discharged to the steam boiler 10 ).

That is, in the present invention, due to the internal structure of the heating pipe 50, water generated as the state changes in the steam is collected toward each suction hose joint hole 62 formed in the heating pipe 50, The water can be moved to the shortest distance along the suction hose 90 connected to the suction hose connecting hole 62 and recovered to the steam boiler 10. The water passing through the suction hose (90) can be sucked well toward the steam boiler (10) by the recovery motor (80).

The heating pipe 50 shown in FIG. 4 is cut in a unit length, and a plurality of heating pipes 50 having the same structure are connected to each other and installed on the entire floor.

A suction hose 90 is connected to each of the suction hose connecting holes 62 and the suction hose 90 is connected to the pipe hose 90. The suction hose 90 is connected to each suction hose connecting hole 62, And may be connected to the recovery motor 80 through the shortest length of the air layer 165. That is, the moving distance of water can be minimized, and the water recovery rate can be increased.

The water recovered by the recovery motor 80 may be introduced into the hot water tank 23 along the recovery line 36 of the steam boiler 10 and reused as hot water. Because the hot water recovered from steam is recovered, it is possible to reduce the number of times the boiler is operated separately in order to raise the temperature of the hot water. As a result, it is possible to reduce waste of energy such as electricity, gas, and oil to maintain the hot water temperature.

The steam flowing in the upper part of the partition plate 52 of the heating pipe 50 flows through the heating pipe 50 in the steam boiler 10 after the entire heating pipe 50 installed on the floor is circulated, ).

Thus, according to the present invention, the floor structure is improved to minimize interlayer noise. Further, the floor heating can be made uniform by the air layer 165 formed in the piping layer.

According to the present invention, water generated in the heating pipe is recovered through the suction hose 90 provided in the air layer 165 at the shortest distance, and the recovered hot water is reused as hot water, thereby maximizing the efficiency of the boiler .

The scope of the present invention is not limited to the embodiments described above, but may be defined by the scope of the claims, and those skilled in the art may make various modifications and alterations within the scope of the claims It is self-evident.

10: Steam boiler 11: Steam device
12: high-temperature wind device 21: cold water tank
23: hot water tank 35: heating supply line
36: collection line 52: partition plate
54: Through hole 60: Drain plate
62: suction hose connecting hole 90: suction hose
120: foamed concrete layer 123: groove
140: buffer plate 160: piping layer
165: air layer 180: upper layer

Claims (6)

1. A heating piping device connected to a steam boiler and installed inside a floor,
A partition plate (52) is provided in the heating pipe in the lateral direction of the heating pipe,
The water generated by the cooling of the steam flowing along the upper part of the partition plate 52 through the through holes 54 formed in the partition plate 52 escapes to the lower portion of the partition plate 52,
Wherein a water receiving plate (60) for collecting the water escaping from the through hole (54) and collecting the water in the central part of the heating pipe (50) is formed obliquely below the partition plate (52). The hose according to claim 1, wherein a center portion of the heating pipe (50) corresponding to a lower portion of the inclined portion of the water receiving plate (60) is connected to a suction hose (90), and the suction hose Is connected to a recovery motor (80) for recovering the water of the steam boiler to the steam boiler. delete delete delete delete

Images