KR100664511B1 - Heating recycling system - Google Patents

Abstract

A heating recycling system is provided to uniformize the entire supply flow rate and the entire recollecting flow rate of a heat transfer medium to remove vibrations and noises, thereby providing comfortable living environment. A heating recycling system includes a supply header(100), a return header(200), bypass passages(B1,B2,B3,.....BN), and a flow rate regulation part(500). The supply header supplies a heat transfer medium into a plurality of heating spaces through pipes. The return header collects the heat transfer medium passed through the plurality of heating spaces via a main passage. The bypass passages are connected to each other through pipes and valves disposed at inlet ports of the plurality of heating spaces, and in communication with the main passage by bypassing the plurality of heating spaces. The flow rate regulation part controls a progress passage of the heat transfer medium by operating the valve.

Description

Heating Recycling System

1 is a conceptual diagram of a heating circulation system according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: supply header 200: return header

300: boiler 400: main path

500: flow control unit 600: pump

R1, R2, R3 ... RN: Evacuation space

B1, B2, B3 ... BN: Bypass

V1, V2, V3 ... VN: Valve

The present invention relates to a heating circulation system, and in particular, by installing a bypass passage bypassing the evacuation space at the inlet end of the evacuation space of the piping through which the heat transfer medium, such as hot water flows, it is possible to adjust the flow rate, thereby The present invention relates to a heating circulation system in which noise, vibration, etc., do not occur due to changes.

In general, in the case of the heating system of the multi-family house, the centralized supply method of the heating system has been the mainstream in the early stage, but it is becoming more diversified with the advent of district heating and the development of the technology of the individual boilers.

In district heating system, buildings, shopping malls, schools, hospitals, factories, etc. in one city or a certain area are not equipped with heating facilities, but one or several concentrated heat source plants are constructed to increase heating and hot water supply. It is a system for producing hot water (about 80 ~ 120 ℃) and supplying it to each customer through a heat transport pipe.

On the other hand, in houses and apartments, the water is heated by heat generated when a boiler burns a predetermined fuel such as oil or gas to supply heating water, which is a heat transfer medium, and the supplied heating water is provided in a plurality of rooms, respectively. It circulates by heating tube and is heating. When all of the heating water is supplied to the heating tubes provided in the plurality of rooms, the unused rooms are also heated together, thus consuming much fuel. Therefore, a distributor having a plurality of valves is installed between a discharge port from which the heating water is discharged from the boiler and a plurality of heating tubes respectively installed in the plurality of rooms, and the user individually controls the opening and closing amount of the plurality of valves of the distributor. The amount of heating water supplied to the room is controlled and the heating temperature is controlled. The individual heating method as described above is a method of controlling the temperature by installing a distributor having a plurality of valves when the temperature control is required for each room or living room.

In other words, as the concept of indoor temperature control and refined flow became important, it was developed from the control of each generation to the control of each room by generation.

However, in the conventional district heating method or the individual heating method as described above, when the flow rate of the heat transfer medium such as hot water is differently distributed because the set temperature is different for each household or each room, each evacuation space of each household or each room is different. Since the flow rate of the heat transfer medium flows differently, the water pressure difference due to the difference between the total supply flow rate and the total return flow rate is excessively generated, which causes vibration or noise in the heating pipe. And there was also a problem that the damage and failure of the device appears due to the pressure difference as described above. Thus, there was a problem that harmful elements are generated in a comfortable living environment.

Accordingly, the present invention has been proposed to solve the conventional problems as described above, and an object of the present invention is to bypass the evacuation space at the inlet end of the evacuation space of the pipe flowing heat transfer media such as hot water By providing the total flow rate and total return flow rate of the heat transfer medium such as hot water, the harmful elements in the creation of a pleasant living environment such as vibration and noise are removed to provide a heating circulation system that can create a more comfortable living environment.

In the heating circulation system according to the present invention, a heating circulation system, comprising: a supply header for supplying a heat transfer medium to a plurality of evacuation spaces through a pipe; A return header through which the heat transfer medium passing through the plurality of evacuation spaces is recovered via the main path; A bypass passage connected to pipes and valves respectively located at the inlet end of the plurality of evacuation spaces, wherein the heat transfer medium bypasses the plurality of evacuation spaces and communicates with a main pass passage; It is configured to include a flow rate control unit for controlling the progress path of the heat transfer medium by operating the valve.

The flow rate controller may control the heat transfer medium to flow only through the valve through the valve when the evacuation space reaches a temperature set by the demand.

In addition, the flow rate control unit may proportionally control the flow amount to the evacuation space or the flow to the bypass path by adjusting the opening and closing degree of the valve according to the set temperature of the evacuation space to the heat transfer medium discharged from the supply header It may be.

In addition, the flow rate control unit may be configured such that a plurality of each of the plurality of valves installed in the pipes respectively located at the inlet end of the plurality of evacuation space. When the flow rate control unit is connected as described above, the user manually controls the degree of opening and closing of the valve, thereby controlling the flow direction or amount of flow of hot water.

In addition, it is preferable to use a three-way valve in order to change the flow direction of the heat transfer medium and to control the flow rate in proportion as described above.

In addition, the evacuation space may be each room in individual heating, a living room kitchen, or the like, or may be each generation or complex in an apartment or a residential complex in district heating. In other words, the evacuation space is not limited to any specific space but can be applied in various ways.

That is, the heating circulation system as described above is characterized in that it is provided with a flow rate control unit and a bypass path for the constant flow rate and pressure in the pipe at all times.

Hereinafter, an embodiment according to the present invention as described above, the technical spirit of the heating circulation system will be described with reference to the drawings.

1 is a conceptual diagram of a heating circulation system according to an embodiment of the present invention.

As shown in the drawing, the boiler 300 heats water while burning a predetermined fuel to generate hot water. Then, the hot water is supplied to the supply header 100 to supply hot water to each of the evacuation spaces R1, R2, R3... RN. The hot water acts as a heat transfer medium. The hot water passing through each of the evacuation spaces R1, R2, R3... RN is recovered to the return header 200 via the main path 400. The hot water recovered by the return header 200 flows back into the boiler 300 through the pump 600 and is heated again. Hot water is circulated through the path as described above.

However, the set temperatures of the plurality of evacuation spaces (R1, R2, R3 ... RN) can be set differently, and when the temperature is above the set temperature, the hot water is the plurality of evacuation spaces (R1, R2, R3 ...) It flows through the bypass paths B1, B2 and B3 without passing through RN. In this way, the flow rate control unit 500 to flow the hot water to the bypass (B1, B2, B3 ... BN) without passing through a plurality of evacuation space (R1, R2, R3 ... RN) The valves of the plurality of valves (V1, V2, V3 ... VN) are adjusted. The plurality of bypass paths B1, B2, B3... BN communicate with the main path 400.

For example, when R1, which is one of the evacuation spaces, exceeds the set temperature, a flow rate as much as an amount to flow into the evacuation space R1 flows through the bypass passage B1. This is done by controlling the opening and closing degree of the valve (V1) in the flow control unit 500. And the hot water is recovered to the return header 200 through the main path (400). The recovered hot water flows into the boiler 300 and is heated again. The cycle is thus repeated.

In addition, the flow rate control unit 500 controls the opening and closing degree of the valve (V1, V2, V3 ... VN) in proportion to the set temperature of the heating space (R1, R2, R3 ... RN). You may. That is, a part of the hot water flow rate may be controlled to flow into the bypass paths B1, B2, B3 ... BN and the remaining part flows into the evacuation spaces R1, R2, R3 ... RN.

On the other hand, the above-mentioned valves (V1, V2, V3 ... VN) uses a three-way valve that can flow in three directions to achieve the desired purpose.

In addition, the heating circulation system as described above may use the evacuation spaces R1, R2, R3 ... RN as individual rooms, living rooms, kitchens, etc. in individual heating, or in households such as apartments and residential buildings in district heating. Or just as such.

And such a heating circulation system may be operated as follows.

When all of the evacuation spaces R1, R2, R3 ... RN become above a set temperature, the hot water, which is the heat transfer medium, does not need to flow into the evacuation spaces R1, R2, R3 ... RN. Therefore, the hot water supplied from the supply header 100 flows only through the bypass passages B1, B2, B3... BN without passing through the evacuation spaces R1, R2, R3... RN. The hot water is recovered to the return header 200 via the main path 400. As a result, hot water equal to the amount of hot water from the supply header 100 is recovered to the return header 200. The hot water recovered by the return header 200 is circulated again by being heated in the boiler 300.

In the heating circulation system according to the present invention described above, the amount of hot water flowing out of the supply header 100 and the amount of hot water recovered to the return header 200 are the same. Therefore, the hydraulic pressure difference according to the flow rate hardly occurs because the total oil supply flow rate and the total ash flow rate are the same. Therefore, even if the amount of hot water flowing into any evacuation space (RN; Nth evacuation space) changes, the flow rate on the supply header 100 side and the return header 200 side hardly changes, so that the flow rate suddenly changes. There is no noise or vibration caused by the change.

In addition, in the heating circulation system according to the present invention described above, even when hot water, which is a heat transfer medium, flows through the bypass paths B1, B2, B3, BN, heat loss hardly occurs. This can be confirmed through the following relationship.

Comparing the heat loss of the heating circulation system according to the existing model and the heating circulation system according to the present invention under the following conditions as follows.

External (indoor) temperature: 20 ℃ Internal (fluid) temperature: 60 ℃

Piping: L type 100A (thickness 2.79mm outer diameter is 104.78mm)

Calculation of heat dissipation during 40T insulation construction of grease wool insulation container is as follows.

(Here, New Model refers to the heating circulation system according to the present invention, Old Model means the existing model.)

The following shows the changes in the discharge temperature of the pipes of the new and old models. Assume that the calculation is made under the following conditions.

When Bypass Operation is 50:50

New model (NM) Discharge Temperature-Inlet Temperature: 60 ℃ Discharge Capacity: 300lpm (l / m)

Old model (OM) Feeding temperature-Inlet temperature: 60 ℃ Feeding rate: 150lpm (l / m)

The temperature change equation in the pipe is shown in Equation 4 below.

Looking at the temperature in the pipe by the above equation in the calculation is as follows.

As a result of the above analysis, it can be seen that the change in the temperature in the pipe with respect to the length of the pipe (100 m) is smaller in NM.

Therefore, the transmission loss calories can be seen through the equation (5).

Therefore, the calorie loss ratio is as follows.

And the loss calories at the return is shown in Equation 6.

 In addition, loss calorie ratio is as follows.

Therefore, the return loss calories ratio of the two models is 1.33 times larger than that of the transmission. Thus, the total heat loss ratio is 1.1735. The results are shown in the table as follows.

Model Total Dissipation Calorie Transmission Return Total Temperature drop Loss calories Temperature drop Loss calories Loss calorie ratio % Increase in heat loss New 13.8860 0.07 1465.45 0.0534 1117.929 1.1735 0.243 Old 13.8824 0.13 1360.77 0.0803 840.54

As described above, if the amount of loss is extremely small, it can be seen more clearly than the insignificant amount of money exchange.

(In terms of amount)

*. Converts lost heat into gas volume

  -. Heat loss: convert w to kcal (1w is 0.86kcal)

  -. LNG calorific value: 1N / M3: 12,000KCAL

  Gas unit price: 477.29 won per M3

Therefore NEW-OLD

      1565.45W-1360.77W = 104.68W

      104.68W = 0.10468KW = 90.0247KCAL / H

      90.0247KCAL X 24H = 2160.59KCAL

Converted to Gas Cost: 447.29KRWX2190.59KCAL / 12,000KAL

               = $ 81.65 / day increase

When the amount of calorie loss is converted into the amount of money by the above calculation formula, the amount is about 81.65 won per day, which is very small amount if it is input to create a living environment without vibration or noise.

Meanwhile, although not shown in the drawings, the heating circulation system according to the present invention, as described above, connects a plurality of flow control units to each of a plurality of valves installed in pipes respectively located at inlets of the plurality of evacuation spaces. The user can also control the flow direction or amount of hot water by manually adjusting the opening and closing degree of each valve.

Meanwhile, the heating circulation system according to the present invention has been mainly described using hot water as a heat transfer medium, but may be used in a cooling circulation system by using a cooling medium (such as cooling water) instead of the heat transfer medium.

Although the preferred embodiment of the present invention has been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

As described above, the heating circulation system according to the present invention provides a total supply of heat transfer media such as hot water by installing a bypass passage bypassing the evacuation space at the inlet end of the evacuation space of the pipe through which the heat transfer medium such as hot water flows. The flow rate and the total return flow rate are constant to remove harmful elements such as vibration and noise to create a pleasant living environment, thereby creating a more comfortable living environment.

In addition, there is an effect that can solve the unbalance of the flow rate distribution caused by the unbalance of the pipeline resistance value due to the difference in the length of the heating coil for each evacuation space.

Claims (6)

In the heating circulation system, A supply header for supplying a heat transfer medium to a plurality of evacuation spaces through piping; A return header through which the heat transfer medium passing through the plurality of evacuation spaces is recovered via the main path; A bypass passage connected to pipes and valves respectively located at the inlet end of the plurality of evacuation spaces, wherein the heat transfer medium bypasses the plurality of evacuation spaces and communicates with a main pass passage; And a flow rate control unit configured to operate the valve to control a progress path of the heat transfer medium. The method of claim 1, The flow rate control unit is a heating circulation system, characterized in that the heat transfer medium flows only through the valve via the valve when the evacuation space is more than the temperature set by the demand. The method of claim 1, The flow rate control unit may proportionally control the flow rate to the evacuation space or the flow rate to the bypass passage by adjusting the opening and closing degree of the valve according to the set temperature of the evacuation space to the heat transfer medium discharged from the supply header Heating circulation system, characterized in that. The method of claim 1, The flow rate control unit is a heating circulation system, characterized in that a plurality of valves are installed in each of the plurality of valves installed in the pipes respectively located at the inlet end of the plurality of evacuation space to manually control the flow of the heat transfer medium. The method according to any one of claims 1 to 4, The evacuation space is a heating circulation system, characterized in that each room in the individual heating, living room kitchen and the like. The method according to any one of claims 1 to 4, The evacuation space is a heating circulation system, characterized in that each complex in an apartment or residential complex in district heating, or each building in a school, a hospital, or the like.

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