KR200309587Y1 - Heat exchanging device for waste water - Google Patents

Abstract

The present invention is designed to exchange heat with waste hot water by passing low temperature water at low temperature through the inflow side and the outflow side water flow unit and the heat exchange tube, thereby minimizing the components, thereby reducing the temperature of the low temperature water without regard to the installation place. It is to provide a heat exchanger for the waste heat recovery to efficiently increase.

The heat exchanger device for waste heat recovery according to the present invention has a predetermined shape to guide and supply and discharge low-temperature water introduced from the outside, and the inflow and outflow side water flow units 10 and 20 and the inflow and outflow water passages. It is configured as heat exchange tubes 30 connected to at least one or more pipes to pass the low temperature water between the units (10) (20).

Description

Heat exchanging device for waste water

The present invention allows low temperature low temperature water to exchange heat with waste water, and in particular, it relates to a heat exchange device for waste heat recovery that efficiently raises the temperature of low temperature water with a simple structure with minimal components.

In the past, heat exchangers for waste heat recovery have been developed to obtain hot water by using thermal energy containing waste hot water discharged from dyeing plants, food and chemical plants, and groundwater flowing underground.

Proposed in connection with such a waste heat recovery heat exchanger, Korean Registered Utility Model Publication No. 256619 (registered on November 26, 2001) states that "in the construction of a wastewater heat recovery system using a heat exchange method of wastewater heat, A stack of fresh water induction pipes having drop holes formed in multiple stages are disposed so that the waste water passages are zigzag between them, and a plate is provided on both sides of the fresh water induction pipes so that the waste water paths are connected to each other, and a fresh water guide plate is formed on the outside of the plates. The fresh water flowing into the fresh water induction pipe is selectively moved, and the upper and lower parts of the waste water passage constitute a waste water inflow pipe and a waste water discharge pipe, and cold water inflow pipes and hot water discharge pipes are formed above and below one side of the fresh water guide pipe. Containing wastewater is introduced into the wastewater passage through the wastewater inlet pipe and then circulated downward through the wastewater discharge pipe. At the same time, the fresh water introduced through the cold water inlet pipe is heated while circulating zigzag up through the fresh water induction pipe and the fresh water guide guide plate, and then discharged to the outside through the hot water discharge pipe. Wastewater heat recovery system "has been registered.

This pre-registration registration proposal is that waste water is supplied to the top of the wastewater heat recovery machine and circulated in a zigzag through the wastewater passage, and fresh water flows from the bottom of the wastewater heat recovery machine to the zigzag through the fresh water induction pipe, and heat exchanges with the wastewater to increase the temperature. It worked.

However, such a pre-registration registration proposal is accompanied by the following problems because the water discharge guide pipe is installed in multiple stages at intervals in the main body, and the waste water passage is secured between the fresh water guide pipes. First, since the fresh water to be exchanged with the waste water in the main body having the set size of the contents is converted to hot water, the heat exchange capacity is limited, it is difficult to obtain the required amount of hot water, secured between the fresh water induction pipes in the second body There was a problem that the heat exchange function is reduced by the accumulation of foreign matters on the path through which the waste water passes through the wastewater passages, and the overall structure is complicated and the installation cost is excessively increased due to the increase in the number of unnecessary components. There was a problem.

The present invention is designed to heat the low temperature water through the inlet and outlet side water flow units and the heat exchanger tube to exchange heat with the waste hot water, and is a simple structure that minimizes the components for waste heat recovery. It is an object to provide a heat exchanger.

1 is a perspective view showing a heat exchanger device for waste heat recovery of the present invention

Figure 2 is a partially cutaway plan view showing a heat exchanger device for waste heat recovery of the present invention

Figure 3 is a partially cutaway plan view showing a heat exchanger device for waste heat recovery according to a modification of the present invention

Figure 4 is an enlarged cross-sectional view extracting the main part of the heat exchanger device for waste heat recovery

5 and 6 shows an embodiment of the heat exchanger device for waste heat recovery

7 is a perspective view showing a heat exchange device for waste heat recovery according to another embodiment of the present invention

<Description of the symbols for the main parts of the drawings>

1: heat exchanger for waste heat recovery 10: inlet side water supply unit 10a: water passage hole

11: Inlet 12: Outlet 20: Outflow side water supply unit

20a: water passage 21: outlet 22: inlet

30: heat exchange tube 31: connection member A: stainless corrugated tube

40: pillars on all sides 50: front and rear fixed

1 and 2, the heat exchanger 1 for waste heat recovery according to the present invention has an inlet and outlet side water flow unit 10 formed to guide and supply and discharge low-temperature water introduced from the outside in a predetermined shape. 20) and at least one heat exchange tube 30 connected to each other so as to pass the low temperature water between the inflow side and the outflow side water flow unit 10, 20 is characterized in the technical configuration.

In other words, the waste heat recovery heat exchange device 1 of the present invention is a simple structure for passing the low temperature water supplied from the outside by connecting the inlet and outlet side water supply units 10 and 20 to the heat exchange tubes 30. , So that the low temperature water passing through the internal heat exchange with the external waste water through the heat exchange tube 30 to increase the temperature.

The present invention configured as described above gives the flexibility to arbitrarily select the heat exchange capacity as the thickness and length of the first heat exchange tubes 30, thereby enabling to obtain the required amount of hot water without being limited in content, and in the second interior By passing the low-temperature water through the heat exchange tube 30 to the external waste water naturally, the foreign matter contained in the waste hot water is accumulated on the water passage to prevent the phenomenon that the heat exchange function is degraded, and the third overall structure By simplifying and reducing the number of unnecessary components, the installation cost is reduced.

Hereinafter, the technical details of the present invention through the specific embodiments shown in the accompanying drawings in detail as follows.

The inlet and outlet side water supply units 10 and 20 are configured to supply and discharge the low temperature water introduced from the outside.

In the present embodiment, the inflow side water supply unit 10 has a shape of a cylindrical body having a water passage hole 10a formed therein as a required diameter size and at one side of the inlet port 11 at equal intervals in the circumferential direction on the other side thereof. Outlets 12 are formed, and the outlet side water supply unit 20 has a shape of a cylindrical body having a water passage hole 20a formed therein as a required diameter size, and has an outlet port 21 on one side thereof in a circumferential direction. It is illustrated that the inlets 22 are formed at equal intervals. The inflow side water supply unit 10 distributes the low temperature water flowing in from the outside to pass through the heat exchange pipes 30, the outflow side water supply unit 20 passes through the heat exchange pipes 30 to the temperature Will collect the high temperature water and discharge it to the outside.

As in the modified example of the present invention shown in Figure 3, the inflow side water supply unit 10 has a shape of a pipe in which a water supply hole 10a is formed therein as a required length and one side of the inlet at a predetermined position in the longitudinal direction (11) the outlets 12 are formed at equal intervals in the longitudinal direction of the other side, and the outlet side water supply unit 20 has a shape of a pipe having a water passage hole 20a formed therein as a required length and a length at one side thereof. It turns out that the inlet port 21 may be formed at the predetermined position of a direction by the inlet port 22 in every longitudinal equal interval of the other side.

In addition, the inlet port 11 of the inlet side water supply unit 10 is connected to the low temperature water supply pipe 2 through a connection socket 2a screwed to the outside, and the outlet port of the outlet side water supply unit 20 ( 21) is connected to the hot water discharge pipe (3) through a connecting socket (3a) screwed to the outside.

The heat exchange tubes 30 are connected to the inlet and outlet side water supply units 10 and 20, respectively, so that the low temperature water passed into the heat exchange tube may exchange heat with the external waste water. .

In this embodiment, each of the heat exchange tubes 30 is connected to the outlet 12 of the inflow side water supply unit 10 through a connecting member 31 whose front end is fitted to the outside, and the terminal end thereof is fitted to the outside. The paper is connected to the inlet port 22 of the outlet side water supply unit 20 through the connection member 31, and is passed through the low-temperature water supplied to guide the heat exchange with the waste hot water. At this time, the connecting member 31 is an internal connection port 31a which is formed to be screwed into the inlet port 12 of the inlet side water supply unit 10 or the outlet 22 of the outlet side water supply unit 20 as shown in FIG. ), An outer connector 31b formed to be screwed to the outside of the inner connector 31a, and an airtight packing 31c fitted into the outer connector 31b, so that the heat exchange tubes 30 are The inlet and outlet side water supply unit 10, 20 to be connected closely.

And, it is important that the heat exchange tubes 30 are each made of stainless corrugated pipe (A). The reason is that the corrosion resistance of the heat exchange tubes 30 which are in contact with the waste hot water mixed with the chemical for a long time can be prevented from being easily corroded, and the heat exchange tubes 30 are in contact with the waste hot water to increase the area for heat exchange efficiency. This is to help improve. Furthermore, the heat exchange tubes 30 made of stainless corrugated pipe A are flexed freely, so that the low temperature water passing through the inside is immersed in the waste hot water container 4 where waste hot water is stored as shown in FIG. As shown in FIG. 6, the underground water is buried in the stored ground layer part 5 to have a side effect of allowing the cold water passing through the inside to exchange heat with the ground water.

7 shows another embodiment of the present invention, the inflow side water supply unit 10 has a shape of a pipe in which a water supply hole 10a is formed therein as a required length, and has an inlet 11 at one side thereof. Outlets 12 are formed at equal intervals in the longitudinal direction, and the outlet side water supply unit 20 has a shape of a pipe having a water supply hole 20a formed therein as a required length, and has a outlet 21 at one side thereof. The inlets 22 are formed at equal intervals in the longitudinal direction, and the inflow side and the outflow side water supply units 10 and 20 are fixed as four pillars 40 which are erected perpendicularly to the lower portion thereof. The heat exchanger pipes 30 connected to the water supply unit 10 and 20 to allow water flow between the side and the outflow side water flow units 30 are installed horizontally up and down by setting one to two front and rear sides of the four pillars 40. Winding around the rear holder 50 is arranged neatly It is a lock. At this time, the heat exchanger tube 30 wound around the front and rear fixing table 50 is preferably fixed to each of the fixing iron 51 firmly.

Here, the individual heat exchange tubes 30 connect the front end portion to the outlet 12 of the inflow side water supply unit 10 through the same connecting member 31 as used in the present embodiment, and the end portion thereof. It is connected to the inlet 22 of the outlet side water supply unit 20.

As discussed above, the waste heat recovery heat exchange device of the present invention is a simple structure for passing the low temperature water supplied from the outside by connecting the inflow side and the outflow side water supply units with heat exchange tubes, and installed in contact with the waste hot water. It is configured to raise the temperature by allowing the cold water passed through the heat exchange tubes to exchange heat with the waste hot water so that the required amount of hot water can be obtained without limiting the contents, and foreign substances contained in the waste hot water Not only prevents the phenomenon that the heat exchange function is reduced by stacking, but also has a useful advantage such as reducing the installation cost.

Claims (5)

Between the inlet and outlet side water supply units 10 and 20 and the inlet and outlet side water supply units 10 and 20 formed to guide and supply and discharge cold water introduced from the outside in a predetermined shape. Heat exchanger for waste heat recovery, characterized in that configured as a heat exchange pipe 30 is connected to at least one or more pipes to pass the low temperature water. According to claim 1, wherein the inlet side water flow unit 10 has a shape of a cylindrical body having a water passage hole (10a) formed therein as the required diameter size, the inlet port 11 on one side and equal intervals in the circumferential direction on the other side. Outlets 12 are formed each time, and the outlet side water supply unit 20 has a cylindrical shape having a water passage hole 20a formed therein as a required diameter size, and has an outlet 21 on one side thereof in a circumferential direction thereof. Heat exchanger for waste heat recovery, characterized in that by forming inlets 22 at equal intervals of the. According to claim 1, wherein the inlet side water supply unit 10 has a shape of a pipe in which the water supply hole (10a) is formed inside as a required length and one side the inlet 11 at a predetermined position in the longitudinal direction of the other side Outlets 12 are formed at equal intervals in the direction, and the outlet side water supply unit 20 has a shape of a pipe having a water passage hole 20a formed therein as a required length, and one side of the outlet water outlet 21 at a predetermined position in the longitudinal direction. Heat exchanger for waste heat recovery, characterized in that the inlet (22) is formed at equal intervals in the longitudinal direction of the other side. The inflow-side water supply unit 10 has a shape of a pipe in which a water supply hole 10a is formed as a required length, and the inlet port 11 is drawn out at an equal interval in the longitudinal direction. (12) are formed, the outlet side water supply unit 20 has a shape of a pipe in which a water supply hole 20a is formed as a required length, and the outlet 21 at each of the corners at equal intervals in the longitudinal direction thereof. Inlets 22 are formed, and the inlet and outlet side water supply units 10 and 20 are fixed as four pillars 40 that are vertically erected at their lower sides, and the inlet and outlet side water supply units ( 10) The heat exchanger pipes 30 connected to each other so as to be able to pass through the water pipes 30 on the front and rear sides of the pillars 40 of the four to the front and rear stator 50 is installed horizontally vertically Waste heat, characterized in that it is wound and arranged neatly Receiving the heat exchanger. The heat exchanger for waste heat recovery according to claim 1, wherein each of the heat exchange tubes (30) is made of a stainless corrugated pipe (A).