KR200475832Y1 - Recycling system of wasted heat for shower room without electric power supply - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a waste heat recovery system for recycling waste heat of a waste water discharged from a shower of a small scale while being installed in various industrial sites or homes, And a drain pipe extending from the drain port of the shower room is connected to the main pipe of the waste heat recoverer so that the main pipe provides the discharge passage of the wastewater, The heat exchange chamber of the waste heat recovery unit is connected to the water supply pipe extending to the shower room of the shower so that the heat exchange chamber provides the supply passage of the tap water so that the waste heat of the waste water discharged during the shower is used without using a separate power source such as a pump mechanism When the tap water at room temperature supplied to the shower room of the shower is heated This makes it possible to reduce the amount of high temperature water supplied to the showerhead through the hot water piping and to greatly reduce the oil cost and electricity cost consumed in heating the hot water. In the near future, And to contribute to the advancement of national carbon emissions trading, and to a non-motorized waste heat recovery system for a shower room.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a non-powered waste heat recovery system for a shower room,

The present invention relates to a waste heat recovery system for recycling the waste heat of wastewater discharged during a shower from a small-sized shower room installed in various industrial sites or homes, and it is an object of the present invention to provide a waste heat recovery system that does not use a separate power source such as a pump mechanism, The present invention relates to a non-powered waste heat recovery system for a shower room, which can heat tap water at room temperature supplied to a shower room of a shower using waste heat of discharged waste water.

Generally, waste heat recovery system is widely used for heating low-temperature fluid such as cold water using waste heat contained in waste gas (exhaust gas or combustion gas) or waste water, or for securing evaporation heat source of refrigerant necessary for operation of heat pump A piping line through which a low-temperature fluid flows in or out of a flue from which waste gas is discharged or a refrigerant line constituting an evaporator is installed inside a storage tank in which waste water is stored.

As described above, the conventional method of applying the waste heat recovery system is suitable for a large-scale plant facility or a large-sized bathroom or sauna facility, and the waste water discharged from a small- Considering both the cost aspect of facility investment and operation of the system and the economical aspect due to the recovery of waste heat, it is somewhat unsuitable to apply the waste heat to the recycling purpose.

However, if it is assumed that three or two 1/2 inch (inch) diameter showerheads are used for an average of 4 hours a day in a small or medium sized shower room such as a shower room of workers working in various industrial fields, Since the flow rate of one unit is usually 30 liters / min, a total of 21,600 liters per day and 7,884,000 liters per year is used. In such total water, high temperature water at about 60 ° C is used at room temperature (around 20 ° C) Even if it is assumed to be mixed at a ratio of 1: 1, the usage amount of hot water per year becomes 3,942,000 L, which is 1/2 of that.

Considering the annual quantity of hot water used in small- and medium-sized showers, the cost of oil and electricity consumed in the composition of hot water is also a considerable economic burden, As a result of the existing waste heat recovery system applied to the bath or sauna facility, the waste heat recovery system, which can be used for small and medium sized showers, has not been available.

On the other hand, global warming due to the recent increase in carbon emissions and the resulting weather changes are becoming serious environmental problems all over the world. As a measure to prevent global warming, the upper limit of annual carbon emission And the carbon emission regulation that does not allow any further carbon emission is in effect. Therefore, Korea is also ahead of the legislation in 2015, and the carbon emission trading system that can deal with the carbon emissions allocated to each country is also implemented.

In line with this trend, it is expected that, in the near future, carbon emission regulations at the national level, ranging from large-scale business sites to small-scale businesses and households, will be strictly enforced. As a result, There is a need to prepare for carbon emission regulations ahead of time, and moreover, to find ways to contribute to the advancement of the national trading side of carbon credits from small businesses or households.

The present invention is conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a waste heat recovery apparatus having a cylindrical heat exchange chamber on the outside of a central portion of a main pipe having a predetermined length, A drain pipe extending from a drain port of a shower room is connected to allow the main pipe to provide a discharge passage for waste water while a water pipe extending to a shower port of a shower room is connected to the heat exchange chamber of the waste heat recoverer, The present invention provides an economical and rational method of non-operation for the shower room, which uses the waste heat of the waste water discharged during the shower to heat the tap water supplied to the shower part of the shower room without using a separate power source such as a pump mechanism. Providing a waste heat recovery system is one of the main technologies It is the challenge.

According to an aspect of the present invention, there is provided a non-powered waste heat recovery system for a shower, comprising: a hot water pipe for supplying hot water to a shower room of a shower; a water supply pipe for supplying tap water at room temperature to a shower room of the shower; A drain pipe extending from a drain port of the shower room and a waste heat recovering device for exchanging wastewater discharged through the drain pipe with tap water at room temperature, And a heat exchange chamber provided in a cylindrical shape on the outer surface of a central portion of the main pipe to provide a supply passage for tap water. On both side ends of the main pipe, an inlet port and a discharge port for connecting the drain pipe Respectively, and at both ends of the heat exchange chamber, oil for connection of the water pipe is provided An inlet port and an exhaust port are provided, respectively, and a pipe cap is detachably installed at both side ends of the main pipe.

In another embodiment of the present invention, the waste heat collecting device is horizontally inserted into a drain space at the bottom of a shower room, and the inlet port of the main pipe is disposed at a lower side of the main pipe And a drain pipe is connected to the discharge port. The main pipe and the drain pipe are connected to each other through a drain pipe, And a pipe connector for disassembling and assembling the pipe is applied to the connection portion and the connection portion between the heat exchange chamber and the water supply pipe, wherein a spiral partition for forming a swirl flow of tap water is installed in the heat exchange chamber .

According to the present invention as described above, tap water at room temperature (about 20 ° C) supplied to shower parts of a shower room using waste heat (around 40 ° C) of waste water discharged during a shower without using a separate power source such as a pump mechanism (60 ° C or less) supplied through the hot water piping to the showerhead, and the oil cost and electricity cost consumed for heating the hot water can be greatly reduced. For example, assuming that three boilers are connected to a boiler hot water system using light oil, the annual heat recovery rate is 17,374,000 kcal, and the annual oil saving cost is 1,690 per liter (liter) It is the level of 3,827,850.

Particularly, when the waste heat collecting device is inserted horizontally into the drain hole space at the bottom of the shower, the tap water at room temperature supplied through the heat exchange chamber is completely surrounded by the waste water passing through the inside of the main pipe and the waste water space It is possible to further improve the heating performance of the tap water due to the waste heat of the wastewater and further contribute to the reduction of the oil cost and the electric cost, and at the same time, The present invention provides a waste heat recovery system that simplifies the piping structure according to the installation of the waste heat recovery system and can be easily and easily applied to various shower rooms by allowing the stored waste water to flow naturally through the open type inlet port on one side of the main pipe It is effective.

As a further matter, when the detachable pipe stopper is provided at both end portions of the main pipe, it is possible to perform scaling and foreign matter removal work inside the main pipe through which the waste water flows without disconnecting the waste heat recoverer from the pipe, And a pipe connector is applied to a portion where the inlet port and the discharge port of the heat exchange chamber are connected to the drain pipe and the water pipe, it is necessary to separate the waste heat recoverer from each pipe to perform maintenance work on the piping line, Or a replacement operation can be easily performed. When a spiral partition is provided inside the heat exchange chamber, the swirling flow of the tap water is induced to maximize the heat exchange performance with the wastewater Effect.

Ultimately, there is an effect of providing an economical and rational method of waste heat recovery system which can not be provided by existing waste heat recovery system but can be used only for a small-sized shower room. In addition, It is possible to respond more actively to carbon emission regulations that are expected to be strictly applied to business or general households, and to contribute to the preemptive advantage of carbon trading among countries.

1 is a schematic piping diagram of a non-powered waste heat recovery system for a shower according to an embodiment of the present invention;
Fig. 2 is an exemplary installation state diagram of Fig. 1. Fig.
Fig. 3 is an exploded perspective view of Fig. 2; Fig.
4 is a schematic piping diagram of a non-powered waste heat recovery system for a shower according to another embodiment of the present invention;
Fig. 5 is an exemplary installation state diagram of Fig. 4; Fig.
FIG. 6 is a plan view of the main part of FIG. 5; FIG.
7 is a schematic piping diagram of a non-powered waste heat recovery system for a shower according to another embodiment of the present invention;

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

As shown in Figs. 1 to 3, each embodiment of a non-powered waste heat recovery system for a shower according to the present invention includes a hot water pipe 5 for supplying hot water to a shower room of a shower room 1, A drain pipe 7 extending from the drain port 2 of the shower room floor 1a and a drain pipe 7 extending through the drain pipe 7, (10) for heat exchange with tap water at room temperature.

The hot water supply pipe 5 extends from the boiler hot water supply equipment to the shower room of the shower room 1 and the water supply pipe 6 supplies tap water using a water pressure from a roof water tank The shower mechanism is installed on the shower wall body 1b and includes a shower main body 3a to which the hot water pipe 5 and the water pipe 6 are connected, A shower water supply pipe 4 extending upward and a shower 3 installed at an end of the shower water supply pipe 4. The shower main body 3a is provided with an adjustment for adjusting the mixing degree of hot water and tap water A valve V is installed.

The drainage port 2 provided in the shower floor 1a serves as an indoor-side wastewater inlet for discharging the wastewater generated during the showering through the drain pipe 7 to a sewer or the like, The bottom of the shower room 1a is formed as a rectangular groove and is formed as an inclined bottom surface inclined toward the drain port 2 for smooth drainage of the wastewater. The upper part of the drain port 2 is provided with a mesh plate for filtering various foreign substances. And a screen 2a in the form of a stencil.

3, the waste heat recoverer 10 of the present invention includes a main pipe 11 having a predetermined length to provide a discharge passage for the wastewater, And a heat exchange chamber (12) provided in the form of a supply passage for supplying tap water, while being disposed in a vertical direction on a space provided in a lower portion of the shower room floor (1a).

As described above, in the waste heat recovery system according to one embodiment of the present invention, it is necessary to secure a space for installing the waste heat recovery device 10 in the lower part of the shower room floor 1a, 2 is a schematic view showing the shower room floor 1a (see FIG. 1) by a supporting stand 9 supporting the shower floor 1a, And the concrete floor 8 is provided with a space for installing the waste heat recoverer 10. [

However, the installation mode of the waste heat recovery system shown in FIG. 2 is only one representative example, which does not mean that the installation method of the waste heat recovery system according to the present invention is limited to the system shown in FIG. 2, 2 may be arranged in the horizontal direction on the lower side of the shower floor 1a and the water supply pipe 5 and the water supply pipe 6 extend in the shower room 1 side 1 corresponds to the waste heat recoverer 10 and the pipe protection cover 10a for protecting the respective pipes.

3, an inlet port 11a and an outlet port for connecting the drain pipe 7 are formed on the upper and lower side surfaces of the main pipe 11 of the waste heat collector 10, A discharge port 12b and an inlet port 12a for connecting the water pipe 6 are formed on the upper and lower sides of the heat exchange chamber 12 of the waste heat collector 10, .

Accordingly, the discharge direction of the wastewater through the main pipe 11 and the supply direction of the tap water through the heat exchange chamber 12 cross each other in the upward and downward directions, so that efficient heat exchange is performed between the wastewater and tap water, A spiral partition 12c for providing a swirling flow of tap water is provided in the heat exchange chamber 12 from the inlet port 12a to the outlet port 12b.

In addition, a pipe cap 13 is detachably installed at the upper end opening and the lower end opening of the main pipe 11, and the inlet port 11a and the discharge port 11b of the main pipe 11, Is disposed between the heat exchange chamber 12 and the assembled portion of the pipe cap 13 and is connected to the end portion of the drain pipe 7 connected to the inlet port 11a and the discharge port 11b of the main pipe 11 Pipe connectors 6a and 7a are applied on the end sides of the water supply pipe 6 connected to the inlet port 12a and the discharge port 12b of the heat exchange chamber 12 so that the pipe can be disassembled and assembled have.

The pipe stopper 13 is provided with a packing bolt 13a for sealing both opened end portions of the main pipe 11 in a watertight manner so that the pipe stopper 13 can be assembled A nut portion 14a for fastening the packing bolt 13a is formed on the inner circumferential surface of the assembled end portion 14 of the main pipe 11 to reduce the thickness of the pipe caused by the machining of the nut portion 14a, Each of the assembly end portions 14 is formed to protrude to the outside of the main pipe 11 by a predetermined thickness so as to compensate for the decrease in strength.

When the detachable pipe stopper 13 is installed at the upper and lower openings of the main pipe 11 as described above, the waste heat recoverer 10 is separated from the drain pipe 7 and the water pipe 6, The scaling and foreign matter removal inside the main pipe 11 through which the wastewater flows can be easily performed by removing only the side pipe plug 13 and pushing the cleaning mechanism into the main pipe 11, As a representative example of the mechanism, there is a radial attachment of a cleaning brush of a dimension matching the inner diameter of the main pipe 11 along a wire bendable in any direction.

Since the clean water is supplied to the heat exchange chamber 12 so that no separate internal cleaning operation is required, the heat exchange chamber 12 is formed into a cylindrical shape through which the main pipe 11 passes, and then welded together with the main pipe 11 The heat exchange chamber 12 may be installed on the main pipe 11 in such a manner that the respective divided bodies are assembled by being brought into contact with each other in a state in which the heat exchange chamber 12 is divided into two semi- In this case, it is needless to say that water-tightness treatment must be performed on the assembled parts of the respective divided bodies constituting the heat exchange chamber 12.

On the other hand, the pipe connectors 6a and 7a are rotatably supported by a known rotation (not shown) provided so as to be rotatable with a sealing ring or the like not shown on the connection end side of the water supply pipe 6 and the drain pipe 7 interposed therebetween, When the respective pipe connectors 6a and 7a are fastened along the fastening portions provided at the ends of the inlet ports 11a and 12a and the discharge ports 11b and 12b as the nut type components, And the discharge ports 11b and 12b are firmly brought into close contact with the drain pipe 7 and the end side of the water pipe 6 and the water pipe is tightly sealed.

As described above, the main pipe 11 is connected to the drain pipe 7 and the water pipe 6 at the portions where the inlet ports 11a and 12a and the discharge ports 11b and 12b of the heat exchange chamber 12 are connected to the drain pipe 7 and the water pipe 6, When the connectors 6a and 7a are applied, the maintenance work of the piping line and the repair and maintenance or replacement work of the waste heat recovery machine 10 can be easily performed by separating the waste heat recovery machine 10 from each piping And it is also possible to apply the pipe connectors 6a and 7a to the respective inlet ports 11a and 12a and the outlet ports 11b and 12b.

According to the non-powered waste heat recovery system for a shower of the present invention having the above-described configuration, waste heat (around 40 캜) of wastewater discharged during a shower is used without using a separate power source such as a pump mechanism, (About 20 DEG C) supplied to the shower unit can be heated, thereby reducing the amount of high temperature water (about 60 DEG C) supplied to the shower through the hot water pipe 5, Costs and electricity costs can also be greatly reduced.

As a specific example, it is assumed that three boilers having a diameter of 1/2 inch (inch) having a flow rate of 30 L (liters) / min are installed in a boiler hot water system using light oil for an average of 4 hours per day , The recovered heat per hour of the shower obtained by applying the waste heat recovery system of the present invention was 11,900 kcal, and the annual recovered heat calculated based on this was 17,374,000 kcal, and the annual recovered heat (10,300kcal / kg), the savings in annual diesel will be 1,880kg, or 2,265L, which is calculated as $ 1,690 per 1L of diesel, resulting in annual fuel cost savings of $ 3,827,850.

As a further matter, when the detachable pipe stopper 13 is provided at both end portions of the main pipe 11, the scale inside the main pipe 11 through which the wastewater flows, without separating the waste heat recoverer 10 from the pipe, When the pipe connectors 6a and 7a are applied to the portions where the main pipe 11 and the heat exchange chamber 12 are connected to the drain pipe 7 and the water pipe 6, It is possible to separate the waste heat recovering machine 10 from each piping to easily perform the maintenance work of the piping line and the repair and maintenance or replacement work of the waste heat recovering machine 10 and the spiral partition 12c), it is possible to maximize the heat exchange performance with the wastewater by inducing the circulation flow of the tap water.

4 to 6 show a non-powered waste heat recovering system for a shower according to another embodiment of the present invention, wherein the waste heat recovering device 10 is horizontally disposed inside the space of the drain hole 2 of the shower floor 1a. The inlet port 11a of the main pipe 11 is installed on one side (left side in the figure) of the main pipe 11 so as to be positioned below the water surface of the wastewater stored in the drain port 2, And the drain port 11b of the main pipe 11 is provided at a lower portion of the main pipe 11 (right side in the figure) so as to provide a drain port directly to the drain port 11b. And the piping 7 are connected to each other, and other detailed technical configurations are the same as those of the preceding embodiment.

In the waste heat recovery system according to another embodiment of the present invention, the inlet chamber 11a of the main pipe 11 has a simple funnel shape rather than a simple pipe shape, so that the inlet side has a wide funnel shape, The discharge port 11b of the main pipe 11 is connected to the drain pipe 7 so that the waste water stored in the main pipe 11 can be easily guided into the main pipe 11 through the inlet port 11a. The pipe connector 7a described above can be used. However, as shown in the figure, the discharge port 11b of the main pipe 11 is connected to the inside of the drain pipe 7 passing through the bottom side of the drain port 2 ) Is inserted most preferably in a manner that minimizes piping connection work.

According to another embodiment of the present invention in which the waste heat recoverer 10 is inserted into the space of the drain hole 2 of the shower floor 1 a as described above, the waste heat collector 10 itself is connected to the drain hole 2 The tap water at room temperature supplied through the heat exchange chamber 12 is discharged into the wastewater passing through the inside of the main pipe 11 and the wastewater stored in the space of the drain port 2, It is possible to create an atmosphere capable of performing heat exchange with the exhaust gas.

This makes it possible to further improve the heating performance of the tap water caused by the waste heat of the wastewater as compared with the case of the previous embodiment, thereby further contributing to the reduction of the oil cost and the electric cost, Of the drain pipe 7 connected to the inlet port 11a of the main pipe 11 by naturally flowing the wastewater stored in the main pipe 11 through the opening type inlet port 11a of the main pipe 11. [ It is possible to simplify the piping structure of the waste heat recovery system and utilize the space of the drain hole 2 of the shower room floor 1a as a space for installing the waste heat collecting machine 10, The present invention can provide a waste heat recovery system that can be applied easily and easily.

7 shows a non-powered waste heat recovery system for a shower according to another embodiment of the present invention. In this system, a plurality of (three in the figure) shower mechanisms are connected to a waste heat collector 10, The water supply pipe 6 extending from the discharge port 12b of the heat exchange chamber 12 is branched into a plurality of pipes and then each pipe is connected to a shower device inside the shower 1 Is installed.

According to each of the above embodiments, it is possible to provide an economical and rational method of using a waste heat recovery system that can be used for a small- or medium-sized shower room 1 that can not be provided by the existing waste heat recovery system, Furthermore, it will be able to cope more actively with the carbon emission regulations that are expected to be strictly applied to small-scale businesses and households in the not too distant future, .

The main pipe 11 and the heat exchange chamber 12 of the waste heat recoverer 10 are preferably made of copper or copper alloy or stainless steel having excellent thermal conductivity and corrosion resistance. It is preferable that the drain pipe 7 is made of the same material and that the pipe plug 13 is made of the same material as the main pipe 11 but only the pipe plug 13 is made of a plastic material .

The outer diameter of the main pipe 11 is about 80 mm and the inner diameter dimension of the heat exchange chamber 12 is about 90 mm and the width of about 5 mm between the main pipe 11 and the heat exchange chamber 12 The length of the main pipe 11 is about 400 mm and the length of the heat exchange chamber 12 is about 200 mm and the length of the main pipe 11 is about 200 mm. And the heat exchanging chamber 12 are preferably about 1 mm or less, and it is to be noted that the dimension range of each of these parts can also be arbitrarily adjusted in accordance with the amount of wastewater discharged from the shower chamber 1. [

1: Shower room 1a: Shower room floor 1b: Shower room wall
2: Drain 2a: Pickle 3: Shower
3a: Shower body 4: Shower water supply pipe 5: Hot water pipe
6: Waterworks piping 6a, 7a: Pipe connector 7: Drain piping
8: Concrete floor 9: Strut 10: Waste heat recovery
10a: pipe protection cover 11: main pipe 11a, 12a: inlet port
11b, 12b: exhaust port 12: heat exchange chamber 12c: spiral partition
13: pipe cap 13a: packing bolt 14: assembly end
14a: nut part V: adjusting valve

Claims (5)

A waste heat recovery system for recycling waste heat contained in wastewater as a heating source,
The waste heat recovery system includes a hot water pipe 5 for supplying hot water to a shower room of a shower room 1, a water supply pipe 6 for supplying tap water at room temperature to a shower room of the shower room 1, A drain pipe 7 extending from a drain port 2 of the drain pipe 1a and a waste heat collector 10 for exchanging wastewater discharged through the drain pipe 7 with tap water at room temperature,
The waste heat recoverer 10 includes a main pipe 11 having a predetermined length to provide a discharge passage for wastewater, a heat exchange chamber (not shown) provided on the outer surface of the central portion of the main pipe 11 to provide a supply passage for tap water 12)
An inlet port 11a and an outlet port 11b for connecting the drain pipe 7 are provided on both sides of the main pipe 11. A water pipe 6 is provided at both ends of the heat exchange chamber 12, An inlet port 12a and an outlet port 12b are provided, respectively,
Wherein a pipe stopper (13) is detachably installed at both side ends of the main pipe (11). The apparatus according to claim 1, wherein the waste heat recovering device (10) is horizontally inserted into a space of a drain port (2) of a shower floor (1a) and an inlet port (11a) of the main pipe (11) The main pipe 11 is provided at an upper portion of one side of the main pipe 11 so as to be positioned below the water surface of the wastewater stored in the main pipe 11,
Characterized in that the discharge port (11b) of the main pipe (11) is installed at the lower part of the other side of the main pipe (11) and the drain pipe (7) is connected to the discharge port (11b) system. delete The pipe connector according to claim 1 or 2, wherein a connection portion between the main pipe (11) and the drain pipe (7) and a connection portion between the heat exchange chamber (12) (6a) and (7a) are applied to the non-powered waste heat recovery system for a shower. 3. The system as claimed in claim 1 or 2, wherein a spiral partition (12c) for forming a swirl flow of tap water is installed in the heat exchange chamber (12).

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