KR101005996B1 - Washing system of wastewater heat recovering device using a backwashing - Google Patents

Abstract

PURPOSE: A system for washing waste heat collecting device using back washing, for improving the performance of waste heat exchange device, is provided to back wash the pipes corresponding to a second filter, a heat exchanger and an evaporator of a heat pump and to simplify a cleaning process. CONSTITUTION: A system for washing waste heat collecting device using back washing comprises a first filter(1), a second filter(2), a heat exchanger(3), a heat pump(4) and a first pump(5). The first filter filters the waste water from waste water source. The second filter filters the waste water filtered by the first filter. The heat exchanger provides the waste water filtered by the second filter. The heat pump provides the waste water with heat-exchanged by the heat exchanger.

Description

WASHING SYSTEM OF WASTEWATER HEAT RECOVERING DEVICE USING A BACKWASHING}

The present invention relates to a washing system of a wastewater heat recovery apparatus, and more particularly, to a foreign material attached to a heat exchanger plate of a plate type wastewater heat exchanger in a wastewater heat recovery apparatus using wastewater discharged as a heat source. The present invention relates to a washing system of a wastewater heat recovery system using automatic backwashing to improve the performance of the wastewater heat exchanger.

In a place where hot water is used once and discharged into waste water, such as a public bath or a hotel, a waste water heat recovery device for recovering the heat of the waste water and heating the cold water is used. A general waste water heat recovery device includes a tube through which hot waste water flows. By installing the tubes in which the cold water flows to correspond to each other, the hot waste water and the cold water flow in opposite directions in the tube so that heat exchange takes place so that the hot waste water loses heat and the hot water gets heat, and the cold water obtains heat and turns it into hot water. do. That is, the wastewater heat recovery apparatus is mainly used a heat exchanger that transfers the heat of the wastewater to cold water to exchange heat between the two fluids.

In addition, recently, wastewater generated from a sewage treatment device is used as a heat source. The wastewater is introduced into the wastewater heat device after passing through several stages of filtration and the heat exchanged wastewater is discharged through a discharge pipe after undergoing a heat exchange process in a heat exchanger. The preheated water heat-exchanged with the waste water is supplied to necessary places such as a bath, a swimming pool, a factory, and the like. However, in order to use the wastewater of the sewage treatment plant as a heat source, the place of use should be located near the sewage treatment plant to be used as a heat source, and in order to use the wastewater as a heat source at a far distance, the length of the wastewater inflow pipe connected to the heat exchanger It is not suitable to use waste water as heat source because it needs to be long.

Recently, wastewater discharged from a bath, a hotel, a swimming pool, etc. is used as a heat source, but in general, wastewater discharged from the bath, a hotel, a pool, etc., contains foreign substances. The foreign matters generated at the above places are mainly wastes contained in the hair or water and the wastes discharged from the human body. When the foreign matters enter the tubes of the heat exchanger, the foreign substances are impaired in the heat exchanger, resulting in poor heat exchange. Since there is a problem that the flow path is blocked, the foreign matter is also required to be filtered by a separate filtration device, and the foreign matter is removed using a filtration device using a filtering net or sand.

However, even if the foreign matter is removed by installing a filtration device on the wastewater inlet conduit connected to the heat exchanger, the fine particles are not completely filtered, but are introduced into the tube in the heat exchanger through the inlet conduit and attached to the inner surface, thereby exchanging heat exchange performance. It is necessary to clean the tubes of the heat exchanger regularly because it significantly reduces the In order to clean the tube of the heat exchanger, the cleaning device is inserted into the tube and the cleaning device is cleaned by the cleaning device.The inflow of waste water is blocked, and the clean water is injected in the opposite direction to the flow of the waste water. Background Art A method using a backwash to remove a foreign substance and discharge it to a discharge tube to clean a heat exchanger tube and a conduit is used.

Backwashing is generally automatic backwashing that controls the flow direction of water as disclosed in Utility Model Registrations Nos. 260034 and 262473 by removing water from conduits, filters, etc. by flowing water in the reverse direction. Although the valve is mainly used, the backwashing device of this type has a disadvantage in that its structure is complicated and its manufacture is difficult.

The present invention has been made to solve the above problems, an object of the present invention, the backwashing device of a simple structure to the foreign matter attached to the heat exchange plate of the plate-type wastewater heat exchanger using the discharged wastewater as a heat source Improves the performance of the wastewater heat exchanger by washing with water, and is easy to manufacture and install due to its simple structure, reduces the replacement cost and repair cost in case of failure, and makes it easy to construct a backwashing device by simply adding pipes and valves. To provide a cleaning system of the wastewater heat recovery device using.

In order to solve the above problems, a washing system of a wastewater heat recovery apparatus using backwashing according to the present invention includes: a primary filter for filtering wastewater introduced from a wastewater source; A secondary filter for filtering the wastewater passed through the primary filter; A heat exchanger receiving wastewater filtered from the secondary filter; A heat pump receiving wastewater heat exchanged in the heat exchanger; A first waste water supply pipe installed at a rear of the heat pump and operating to discharge waste water, the first waste water supply pipe connecting the waste water source and the primary filter, and connecting the primary filter and the secondary filter. 2 a wastewater supply pipe, a third wastewater supply pipe connecting the secondary filter and the heat exchanger, and the heat exchanger and the heat pump are connected to a fourth wastewater supply pipe, a wastewater supply pump is installed on the first wastewater supply pipe, and the second wastewater A check valve is installed on the supply pipe, the first pump is installed on the wastewater discharge pipe, washing water is injected into the second, third and fourth wastewater supply pipes, and the level filter and the perforated plate are installed on the first filter. In order to prevent foreign matter from adhering to the perforated plate, the wastewater upper limit position of the level switch is set at 2 to 5 cm above the perforated plate, and the wastewater lower limit position of the level switch is perforated plate. Set to the lower 2 ~ 5cm, the wastewater supply pump is stopped at the upper limit position set in the level switch, the wastewater supply pump is operated at the lower limit position, the heat exchanger and the heat pump is characterized in that connected in series.

Preferably, a washing water supply pipe is connected to a predetermined position of the wastewater discharge pipe, and a second automatic valve is installed on the washing water supply pipe, and the washing water discharge is disposed between the predetermined position of the second wastewater supply pipe and the predetermined position of the wastewater discharge pipe. A pipe is connected and a first automatic valve is installed on the wash water discharge pipe.

Washing system of the waste water heat recovery apparatus using the backwash according to the present invention having the features as described above, the structure is simple, can reduce the production cost and installation cost, in case of failure can easily replace and repair the device operating The cost can be reduced, the backwashing of the secondary filter, the heat exchanger and the heat pump evaporator and the corresponding conduit can be backwashed, simplifying the washing process and improving the performance of the wastewater heat recovery system.

1 is a schematic diagram illustrating a washing system of a wastewater heat recovery apparatus using backwashing according to the present invention.

The present invention is the performance of the wastewater heat recovery apparatus by washing the foreign matter adhering to the heat exchange plate of the plate-type wastewater heat exchanger using the automatic backwashing by the automatic valve in the wastewater heat recovery apparatus using wastewater discharged from the molten metal as a heat source It relates to a cleaning system of the wastewater heat recovery device to improve the.

Referring to Figure 1 will be described an embodiment of the washing system of the waste water heat recovery apparatus using backwashing according to the present invention.

The washing system of the wastewater heat recovery apparatus according to the present invention, By washing the foreign matter adhering to the heat exchange plate of the plate-type wastewater heat exchanger (3) by using backwashing, the washing system comprises: a primary filter (1) for filtering wastewater flowing from the wastewater source; A secondary filter (2) for filtering the wastewater passed through the primary filter (1); A heat exchanger (3) receiving wastewater filtered by the secondary filter (2); A heat pump 4 receiving wastewater heat exchanged in the heat exchanger 3; It is characterized in that it comprises a first pump (5) installed at the rear of the heat pump (4) and operative to discharge wastewater.

The wastewater source and the primary filter 1 are connected to the first wastewater supply pipe 10, and the primary filter 1 and the secondary filter 2 are connected to the second wastewater supply pipe 20. The tea strainer 2 and the heat exchanger 3 are connected to the third wastewater supply pipe 30. The heat exchanger 3 and the heat pump 4 are connected to a fourth wastewater supply pipe 40, a check valve 21 is installed on the second wastewater supply pipe 20, and the first pump 5 is The wastewater discharge pipe 50 is installed on the wastewater discharge pipe 50, and the wastewater deprived of heat while passing through the heat exchanger 3 and the heat pump 4 is smoothly pumped by the first pump 5. Is released.

Preferably, washing water is injected into each of the wastewater supply pipes 20, 30 and 40 to wash the wastewater supply pipes 20, 30 and 40.

The washing water supply pipe 60 is connected to a predetermined position of the wastewater discharge pipe 50, and the washing water for backwashing is supplied through the washing water supply pipe 60. The washing water discharge pipe 70 is connected between the predetermined position of the second wastewater supply pipe 20 and the predetermined position of the wastewater discharge pipe 50, and the washing water supplied through the washing water supply pipe 60 is a heat pump. (4), each wastewater supply pipe (20, 30, 40) flows in a reverse direction in which wastewater flows through each wastewater supply pipe (20, 30, 40) connecting the heat exchanger (3) and the secondary filter (2) And remove the foreign matter attached to the secondary filter (2), the removed foreign matter is discharged to the wastewater discharge pipe 50 through the wash water discharge pipe (70).

A check valve 21 is installed on the second wastewater supply pipe 20, a first automatic valve 71 on the washing water discharge pipe 70, a second automatic valve 61 and a wastewater discharge on the washing water supply pipe 60. On the pipe 50, the third automatic valve 51 is installed, respectively. Preferably, the third automatic valve 51 is installed between the heat pump 4 and the first pump 5. The automatic valves 51, 61, 71 are controlled by a control panel (not shown) to open and close in conjunction with each other.

After the wastewater filtered by the primary filter 1 is supplied to the secondary filter 2 through the second wastewater supply pipe 20 to remove fine foreign matter, the third wastewater supply pipe 30 and the fourth wastewater supply pipe ( 40 is discharged to the wastewater discharge pipe 50 after the heat is desorbed from the heat exchanger 3 and the heat pump 4 while flowing to 40, and the first automatic valve 71 installed in the washing water discharge pipe 50 during the above operation. ) Is closed so that the waste water does not flow to the wash water discharge pipe 70 and is not discharged to the outside through the waste water discharge pipe 50, and the second automatic valve 61 of the wash water supply pipe 60 is also closed to backwash. Prevents the washing water from being supplied to the waste water supply pipes 20, 30, and 40. Only the third automatic valve 51 installed in the wastewater discharge pipe 50 is opened so that the waste water is smoothly discharged through the wastewater discharge pipe 50.

During backwashing operation, the second automatic valve 61 of the washing water supply pipe 60 is opened so that the clean washing water is supplied to the wastewater supply pipes 20, 30, 40, and flows in the reverse direction in which the waste water flows. The foreign matter is removed while passing through the air filter (3) and the secondary filter (2) is discharged to the wastewater discharge pipe 50 through the wash water discharge pipe 70, wherein the first automatic valve 71 is the waste water smoothly Open to be discharged to the discharge pipe 50, the third automatic valve 51 is closed to prevent the washing water is discharged directly to the outside through the waste water discharge pipe 50, installed in the second waste water supply pipe (20) The check valve 21 is closed to prevent the washing water including the foreign matter flowing in the direction of the primary filter 1. In the heat exchange operation and backwash operation using the waste water, the respective automatic valves 51, 61, and 71 are interlocked by a control panel (not shown) to adjust the opening and closing thereof. As the automatic valve, it is preferable to use a solenoid valve whose opening and closing is controlled by an electric signal.

In the washing system of the wastewater heat recovery apparatus according to the present invention, the heat exchanger 3 and the heat pump 4 are arranged in series, and the heat exchanger 3 uses a plate type and a coil type. It is preferable to use. The heat exchanger 3 is connected to a cold water supply pipe 31 through which cold water is supplied from a cold water source (water supply, etc.), wherein the cold water flows in response to the wastewater of the third wastewater supply pipe 30 while flowing through the cold water supply pipe 31. Heat exchanged with the waste heat of the waste water in the machine (3) is converted into medium and low temperature water is supplied to the place of use through the first hot water pipe (32).

A heat storage tank 80 is installed between the heat exchanger 3 and the heat pump 4, and the first hot water pipe 32 connects the heat exchanger 3 and the heat storage tank 80, and the heat storage tank ( 80 and the heat pump 4 are connected to the second hot water pipe 43. A second pump 45 is installed on the second hot water pipe 43. The second pump 45 is a medium and low temperature water stored in the heat storage tank 80 to the heat pump 4 for heat exchange. The pumping operation to be supplied smoothly, the automatic valve 46 is installed at the rear of the second pump 45 to open and close the flow of the low and medium temperature water flowing into the heat pump (4). In detail, the heat exchanger (3) is connected to the heat storage tank (80) by the second branch pipe (32b) branched from the first hot water pipe (32), and the hot water tank (90) by the first branch pipe (32a). Connected with Mid- and low-temperature water is supplied to the heat storage tank 80 and the hot water tank 90 through the branch pipes 32a and 32b.

The heavy and low temperature water absorbed by the heat exchanger (3) is supplied to the place of use through the first hot water pipe (32), and a part thereof is stored in the heat storage tank (80) through the second branch pipe (32b). Some of the medium and low temperature water stored in the heat storage tank 80 flows into the second hot water pipe 43 and is changed into a high temperature water in the heat pump 4 to the hot water tank 90 through the hot water recovery pipe 44. Part of the medium and low temperature water flows into the hot water tank 90 from the heat storage tank 80 to the first branch pipe 32a. The hot water of the hot water tank 90 is supplied to the place of use. On the hot water recovery pipe 44, it is preferable to further install an automatic valve and a check valve for preventing the flow of hot water and backflow.

The heat pump 4 has a closed circuit structure in which the refrigerant flows in the order of the evaporator 4a-> compressor 4b-> condenser 4c-> expansion valve 4d. Wastewater that is primarily heat-exchanged (heat deprived) in the heat exchanger (3) flows into the heat pump (4) through the third wastewater supply pipe (40) and is deprived of heat to the evaporator (4a), and then the wastewater discharge pipe. The medium and low temperature water discharged to 50 and introduced into the heat pump 4 through the second hot water pipe 43 are converted into high temperature water by obtaining heat from the condenser 4c, and the high temperature water recovers the hot water. It is introduced into the hot water tank 90 through the pipe (44).

Conventionally, the medium for transferring heat to the refrigerant in the evaporator 4a of the heat pump 4 is raw water such as tap water. Since tap water changes its temperature according to the season, it is about 5 ° C. in winter. In other words, the heat pump does not operate properly because heat is not properly transferred to the refrigerant. In the present invention, by using the waste water can ensure a smooth operation of the heat pump (4) regardless of the season at all times, and if it is difficult to ensure the hot water of the degree desired by the user only by the heat exchanger (3) heat pump (4) By using as a secondary heat exchanger, the wastewater discharged by heat exchanged first by the heat exchanger 3 can be reused. By using the heat exchanger 3 and the heat pump 4 as described above, it is possible to maximize the heat of waste water.

In the present invention, the wastewater is used as a heat exchange medium to install a filter so that foreign matter does not flow into each conduit, which is a primary filter (1) and a primary filter for filtering (filtering) a relatively large foreign material. Install and configure the secondary filter (2) for filtering the fine foreign matter that may remain in the filtered wastewater in (1). Wastewater from which foreign substances are filtered through the primary filter 1 and the secondary filter 2 is introduced into the heat exchanger 3. Preferably, the secondary filter 2 uses a sand filter.

The primary filter 1, which is configured in the shape of a collecting tank, is provided with a perforated plate or a mesh net to remove foreign matter (hair, soap residue, etc.) in the wastewater. However, when the wastewater is filtered, foreign matter gets stuck in the perforated plate or the mesh net, and thus often causes holes to be clogged.

Therefore, in order to prevent the hole of the perforated plate or the mesh net by the foreign matter, a level switch (not shown) is additionally installed in the primary filter 1 so that an upper limit of the wastewater supplied to the primary filter 1 is provided. Adjust the water level and low water level. That is, the wastewater supply pump 10b is stopped or operated at a predetermined up and down level position set in the level switch so that foreign matter does not adhere to the perforated plate.

For example, the upper limit position of the level switch is set at 2-5 cm of the upper perforated plate provided in the primary filter 1, and the lower limit position is set at 2-5 cm at the lower perforated plate. In the lower limit position, the wastewater supply pump 10b installed in the first wastewater supply pipe 10 is operated to supply wastewater to the primary filter 1, and in the upper limit position, the wastewater supply pump 10b is stopped to supply the wastewater. If the repetitive operation is repeated frequently, the level of the wastewater changes frequently up and down, thereby preventing foreign matter from sticking to the punched plate. The level switch and the wastewater supply pump 10b are connected to a control device (not shown). The control device receives the detection signals (upper and lower position signals) sent from the level switch to operate the wastewater supply pump 10b. And the stop state.

Hereinafter, the operation method and backwashing method of the wastewater heat recovery apparatus will be described.

In the wastewater source, the wastewater is filtered through the first wastewater supply pipe 10 by the operation of the wastewater supply pump 10b to filter the large foreign matter from the first filter 1, and then flows to the second wastewater supply pipe 20 to the second filter. The fine foreign matter is filtered again while passing through (2). Waste water from which foreign substances have been removed passes through the heat exchanger 3 through the third wastewater supply pipe 30, wherein the wastewater is supplied to the cold water supply pipe 31 and passes through the heat exchanger 3. Heat exchange (with heat deprived) and the temperature is lowered and flows to the fourth wastewater supply pipe 40 flows into the heat pump (4).

Cold water passing through the heat exchanger (3) endotherm heat of the waste water is converted into medium and low temperature water is supplied to the place of use through the first hot water pipe (32), or supplied to the heat storage tank (80) and hot water tank (90) do. The medium and low temperature water flows into the hot water tank 90 and the heat storage tank 80 through the first branch pipe 32a and the second branch pipe 32b branched from the first hot water pipe 32, and the heat storage Some of the heavy and low temperature water introduced into the tank 80 may flow into the hot water tank 90 through the first branch pipe 32a. The hot water collected in the hot water tank 90 is supplied to the end use through the pipe.

The wastewater flowing into the fourth wastewater supply pipe 40 and introduced into the heat pump 4 is discharged to the outside through the wastewater discharge pipe 50 in a state where the remaining heat is desorbed from the evaporator 4a and the temperature is lowered. A portion of the heavy and low temperature water stored in the heat storage tank 80 through the heat exchanger 3 is introduced into the heat pump 4 through the second hot water pipe 43 to obtain heat from the condenser 4c to be converted into high temperature water. Flow into the hot water recovery pipe 44 flows into the hot water tank (90).

A second pump 45 is installed on the second hot water pipe 43 connecting the heat storage tank 80 and the heat pump 4, and the second pump 45 is the second hot water pipe 43. The pumping operation is performed so that the medium and low temperature water flowing smoothly flows into the heat pump (4). In addition, an automatic valve 46 is installed behind the second pump 45, and the automatic valve 46 controls the flow of medium and low temperature water flowing into the heat pump 4 from the heat storage tank 80. Since the demand for high temperature water varies depending on the season, the medium and low temperature water stored in the heat storage tank 80 can be sufficiently used at the place of use in summer. Do not allow to enter. Since the heat exchange is not possible in the state in which the medium and low temperature water do not flow into the heat pump 4, the operation of the heat pump 4 is temporarily suspended, and only the heat exchanger 3 produces and supplies hot water required for use.

When the wastewater passing through the heat exchanger 3 is passed again to the heat pump 4 as described above, the remaining heat of the wastewater is completely absorbed by the cold water (raw water), so that the remaining heat of the wastewater can be efficiently absorbed.

When the endothermic (heat exchange) process of cold water (raw water) and medium and low temperature water is repeatedly performed using the heat exchanger 3 and the heat pump 4, the respective wastewater supply pipes 20, 30, 40 and 2 Fine foreign matter may enter and adhere to the tea strainer (2). In this case, backwashing is used. In the present invention, the second, third and fourth wastewater supply pipes 20, 30 and 40 connect the secondary filter 2, the heat exchanger 3 and the heat pump 4 to each other. Backwash by injecting the wash water in the reverse direction of the waste water flow. Closing the automatic valve 10a installed on the wastewater supply pipe 10 stops the wastewater from flowing into the primary filter 1, stops the heat exchange process, and then wash water connected to a predetermined position of the wastewater discharge pipe 50. Injecting the washing water in the reverse direction of the flow of the wastewater into the supply pipe 60, to remove the fine foreign matter attached to each of the wastewater supply pipe (20, 30, 40) and the secondary filter (2) to wash water discharge pipe (70) Through the discharge to the wastewater discharge pipe (50). During the backwashing, the third automatic valve 51 is closed to prevent the washing water from being discharged directly to the wastewater discharge pipe 50, and the washing water is prevented due to the check valve 21 installed on the second wastewater supply pipe 20. It does not flow in the direction of the first filter 1, but flows into the wash water discharge pipe 70, so that a smooth backwash is achieved.

Reference numeral 1a, which is not described above, indicates a drain, and when the level switch installed in the primary filter malfunctions and fails to recognize the upper limit position of the waste water, the waste water is excessively supplied to the primary filter. It is a waterproof path to discharge.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

1.1 Primary Filter 2.2 Primary Filter
3.heat exchanger 4.heat pump
4a.Evaporator 4b.Compressor
4c.Condenser 4d.Expansion valve
5.First pump 10.First wastewater supply pipe
10a.Automatic valve 10b.Waste water supply pump
20.Second wastewater supply pipe 21.Check valve
30.Third waste water supply pipe 31.Cold water supply pipe
32.First hot water pipe 40.4 Waste water supply pipe
43. Second hot water pipe 44. High temperature water recovery pipe
45.2nd pump 46.Automatic valve
50. Wastewater discharge pipe 51. Third automatic valve
60.Wash water supply pipe 61.2nd automatic valve
70.Wash water discharge pipe 71.1st automatic valve
80. Heat storage tank 90. Hot water tank

Claims (8)

In the washing system of the wastewater heat recovery apparatus for cleaning the foreign matter adhering to the heat exchanger plate of the plate-type wastewater heat exchanger by using backwashing,
The cleaning system,
A primary filter for filtering wastewater flowing from the wastewater source;
A secondary filter for filtering the wastewater passed through the primary filter;
A heat exchanger receiving wastewater filtered from the secondary filter;
A heat pump receiving wastewater heat exchanged in the heat exchanger;
A first pump installed at the rear of the heat pump and operative to discharge wastewater;
Including;
A first wastewater supply pipe connecting the wastewater source and the primary filter, a second wastewater supply pipe connecting the primary filter and the secondary filter, a third wastewater supply pipe connecting the secondary filter and the heat exchanger, and the heat exchanger and the heat A pump is connected to a fourth wastewater supply pipe, a wastewater supply pump is installed on the first wastewater supply pipe, a check valve is installed on the second wastewater supply pipe, and the first pump is installed on a wastewater discharge pipe. The washing water is injected into the second, third and fourth wastewater supply pipes, and a washing water supply pipe is connected to a predetermined position of the wastewater discharge pipe, a second automatic valve is installed on the washing water supply pipe, and between the heat pump and the first pump. A third automatic valve is further installed, the level filter and the perforated plate are installed in the first filter, and the waste water of the level switch so that no foreign matter is stuck to the perforated plate. One position is set on the upper 2-5cm of the perforated plate, and the lower limit of the wastewater of the level switch is set on the lower 2-5cm of the perforated plate, and the wastewater supply pump is stopped at the upper limit set by the level switch, and the wastewater is supplied at the lower limit position. A pump is operated, the heat exchanger and the heat pump is a washing system of the wastewater heat recovery apparatus, characterized in that connected in series.
delete delete The method of claim 1,
The washing water discharge pipe is connected between the predetermined position of the second waste water supply pipe and the predetermined position of the waste water discharge pipe, and the first automatic valve is installed on the washing water discharge pipe.
The method of claim 1,
The heat exchanger washing system of the wastewater heat recovery device, characterized in that the cold water supply pipe for supplying cold water from the cold water source is installed.
The method of claim 1,
A heat storage tank is installed between the heat exchanger and the heat pump, a first hot water pipe is connected between the heat exchanger and the heat storage tank, and a second hot water pipe is connected between the heat storage tank and the heat pump and the second hot water pipe. The washing system of the wastewater heat recovery apparatus, characterized in that the second pump is installed on the bed.
delete delete

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