KR101051467B1 - Heat exchanger for distilled water cooling - Google Patents

Abstract

The present invention relates to a heat exchanger for cooling distilled water, by forming a triple pipe structure in which distilled water is flowed through an intermediate pipe, but cooling water is flowed through inner and outer pipes to allow room temperature cooling of distilled water. The goal is to simplify the structure and significantly reduce the failure rate of the equipment, making it easier to manage. The present invention is configured for this purpose in the heat exchanger for distilled water cooling to cool the high temperature distilled water distilled in the process of distilling the raw water into distilled water through a predetermined process at room temperature, the distilled water is installed at regular intervals A plurality of first cooling water flow pipes for cooling the distilled water; A plurality of first cooling water connection pipes connecting the first cooling water flow pipes in an up-and-down rotation to make a series connection; A distilled water flow pipe configured on the outer circumferential surface of each of the first cooling water flow pipes, wherein the distilled water flows through the distilled water to the outer circumferential surface of the first cooling water flow pipe to perform cooling; A plurality of distilled water connecting pipes connected to the distilled water flow pipes in an up and down alternating manner to make a series connection; A plurality of second cooling water flow pipes formed on the outer circumferential surface of each of the distilled water flow pipes to allow the cooling water to flow to the outer circumferential surface of the distilled water flow pipe to cool the distilled water; And a plurality of second coolant connection pipes connecting the second coolant flow pipes alternately in a vertical direction to form a series connection.

Distillation Unit, Chiller, Distilled Water, Cooling Water

Description

Heat exchanger apparatus for cooling distilled water

The present invention relates to a heat exchanger for cooling distilled water, and more particularly, to cool the distilled hot distilled water to room temperature in the process of distilling raw water such as tap water into distilled water through a predetermined process so that the water can be immediately utilized for collection. It relates to a heat exchanger for distilled water cooling.

In general, the distillation apparatus refers to a device for obtaining high-purity distilled water required by a laboratory of a laboratory, a hospital, a pharmaceutical company, etc., and the distillation apparatus obtains high-purity distilled water through a predetermined process from raw water such as tap water. do.

On the other hand, distilled water distilled through the distillation apparatus as described above is prepared by condensing water vapor evaporated through the heating of water. At this time, the distilled water condensed into the liquid condensed water in the steam is very hot at the time of condensation.

Therefore, the distilled water at the time of condensation as described above has a problem that it cannot be used immediately because it is a high temperature, so it must be cooled to a usable temperature through a cooling heat exchanger for cooling the hot distilled water.

However, the heat exchanger for cooling the distilled water according to the related art has a very complicated structure for cooling the high temperature distilled water at the time of condensation of steam. there is a problem.

Therefore, while simplifying the heat exchanger for cooling the distilled water for cooling the distilled hot distilled water to room temperature ready for immediate use, there is a need for a structure that has excellent cooling effect and ease of installation and facility cost.

The present invention has been made in order to solve the problems of the prior art as described above, while allowing the distilled water to flow through the middle pipe, the cooling water flows through the inner and outer pipes so that the cooling of the distilled water at room temperature It is an object of the present invention to provide a heat exchanger for distilled water cooling that simplifies the structure by constituting a triple pipe structure, thereby significantly reducing the failure rate of the device, thereby facilitating management.

Another object of the technology according to the present invention is to facilitate the facility by simplifying the heat exchanger for cooling the distilled water in which the distilled water flows through the inner and outer pipes through the middle pipe and the cooling water flow through the middle pipe. Of course, there is a reduction in costs according to the facility.

In addition, the technology according to the present invention simplifies the heat exchange device for distilled water cooling into a triple pipe structure, but distilled water by allowing a room temperature cooling of the distilled water by flowing the flow direction of the distilled distilled water and the flow direction of the cooling water in opposite directions. The purpose is to improve the cooling effect of the.

Furthermore, the technique according to the present invention enables the detachment of the heating rod inside the pipe through which the distilled water flows, so that the temperature of the distilled water is too low compared to the normal temperature due to the stop of operation at a low temperature such as winter. The purpose is to raise the temperature to a ready-to-use room temperature.

The present invention is configured to achieve the object as described above is as follows. That is, the heat exchanger for cooling distilled water according to the present invention is a heat exchanger for distilled water cooling to cool the distilled water of distilled water to room temperature in the process of distilling raw water into distilled water through a predetermined process, the cooling water is installed at regular intervals A plurality of first cooling water flow pipes configured to cool the distilled distilled water by the flow of water; A plurality of first cooling water connection pipes connecting the first cooling water flow pipes in an up-and-down rotation to make a series connection; A distilled water flow pipe configured on the outer circumferential surface of each of the first cooling water flow pipes, wherein the distilled water flows through the distilled water to the outer circumferential surface of the first cooling water flow pipe to perform cooling; A plurality of distilled water connecting pipes connected to the distilled water flow pipes in an up and down alternating manner to make a series connection; A plurality of second cooling water flow pipes formed on the outer circumferential surface of each of the distilled water flow pipes to allow the cooling water to flow to the outer circumferential surface of the distilled water flow pipe to cool the distilled water; And a plurality of second coolant connection pipes connecting the second coolant flow pipes alternately in a vertical direction to form a series connection.

In the configuration according to the present invention as described above, the cooling water flowing through the first cooling water flow pipe and the second cooling water flow pipe is flowed in the same direction, but the distilled water flowing through the distilled water flow pipe is the first cooling water flow pipe and the second It may be designed to flow in the reverse direction to the cooling water flowing through the cooling water flow pipe.

Meanwhile, in the configuration according to the present invention, the cooling water flowing through the first cooling water flow pipe and the second cooling water flow pipe is heat-exchanged through a heat exchanger after the room temperature cooling of the distilled water flowing through the distilled water flow pipe and the first cooling water flow pipe. It is better designed to circulate with the second cooling water flow pipe.

In addition, in the configuration according to the present invention, the inside of each of the first cooling water flow pipes is installed in a size that does not block the flow of the cooling water, but by applying the power source to heat the cooling water flowing through the first cooling water flow pipe to lower the temperature as in winter The heating rod may be further configured to heat the low-temperature distilled water to room temperature when the distillation apparatus is stopped in operation.

According to the technology of the present invention, by distilled water flows through the intermediate pipe, but through the inner and outer pipes to form a triple pipe structure to allow the room temperature cooling of the distilled water by flowing the cooling water through the pipe to simplify the structure of the device Along with the effect of significantly reducing the failure rate, it is easy to manage.

In addition, the technique according to the present invention can facilitate the facility by simplifying the heat exchanger for cooling the distilled water in which the distilled water flows through the middle pipe and the cooling water flows through the pipe on the inner side and the triple pipe structure. Of course, it can be seen that the effect can be reduced to reduce the cost of the facility.

In addition, the technology according to the present invention simplifies the heat exchange device for distilled water cooling into a triple pipe structure, but by flowing the flow direction of the distilled distilled water and the flow direction of the cooling water in the opposite direction to allow room temperature cooling of the distilled water. Cooling effect can be improved.

Furthermore, the technique according to the present invention enables the detachment of the heating rod inside the pipe through which the distilled water flows, so that the temperature of the distilled water is too low compared to the normal temperature due to the stop of operation at a low temperature such as winter. It can be raised to the temperature of the room temperature immediately available.

Hereinafter, a heat exchanger for cooling distilled water according to an embodiment of the present invention will be described in detail.

1 is a front configuration diagram showing a heat exchanger for distilled water cooling according to the present invention, Figure 2 is a plan view showing a heat exchanger for distilled water cooling according to the present invention, Figure 3 shows a heat exchanger for distilled water cooling according to the present invention It is a cross-sectional block diagram.

As shown in FIGS. 1 to 3, the heat exchanger 100 for distilled water cooling according to the present invention is a high temperature distilled water distilled in a process of distilling distilled water through a predetermined process through a distillation apparatus (not shown). By cooling to room temperature, the distilled water cooling heat exchanger 100 according to the present invention is installed at a predetermined interval a plurality of first cooling water flow pipe 110, the first cooling water flow pipe 110 is made of the flow of the cooling water The first cooling water connecting pipe 120 to connect the in series, the distilled water flowing pipe 130, the distilled water flow pipe 130 is made of the flow of distilled water, the distilled water connecting pipe 140 to connect the distilled water flow pipe 130 in series, the made of the flow of cooling water The second cooling water flow pipe 150 and the second cooling water flow pipe 150 is configured in a configuration of the second cooling water connection pipe 160 in series.

In the configuration of the heat exchanger 100 for distilled water cooling according to the present invention as described above, the configuration of the first cooling water flow pipe 110, the distilled water flow pipe 130, and the second cooling water flow pipe 150 is illustrated in FIGS. 1 and FIG. As shown in FIG. 3, the distilled water flow pipe 130 is inserted into the second cooling water flow pipe 150 in the longitudinal direction, and the first cooling water flow pipe 110 is disposed inside the distilled water flow pipe 130. It is composed of a three-pipe structure is inserted so that the cooling of the distilled water flowing through the distilled water flow pipe 130 between the first cooling water flow pipe 110 and the second cooling water flow pipe 150 can be made.

On the other hand, the heat exchanger 100 for cooling the distilled water according to the present invention as described above, the first cooling water flow pipe 110 as shown in Figures 1 to 3 so that the flow of distilled water and cooling water can be flowed in series The first cooling water connection pipe 120 is connected, the distilled water flow pipe 130 is connected through the distilled water connection pipe 140, the second cooling water flow pipe 150 through the second cooling water connection pipe 160 Connected.

In other words, the heat exchange apparatus 100 for cooling distilled water according to the present invention is installed at a predetermined interval, but the plurality of first cooling water flow pipe 110, the first cooling water flow pipe (110) for cooling the distilled distilled water is made of the flow of cooling water ( The first and second cooling water connection pipes 120 and the first cooling water flow pipe 110 are configured on the outer circumferential surface of each of the first cooling water flow pipes 100 so as to connect 110 in an up and down alternating manner to make a series connection. Distilled water flow pipe 130, the distilled water flow pipe 130 to make the cooling is made by the flow of distilled water to the outer circumferential surface, a plurality of distilled water connecting pipes 140 to connect in series up and down, distilled water flow It is composed of the outer circumferential surface of each of the pipe 130, the cooling water flows to the outer circumferential surface of the distilled water flow pipe 130 is made to cool the distilled water But a plurality of second coolant flow pipe 150 and the second water flow pipe 150 for connection to a down shift is made in a number of configurations of the second coolant connection pipe 160 so that the serial connection is made.

The heat exchanger 100 for distilled water cooling according to the present invention will be described in detail as follows. First, the first cooling water flow pipe 110 is for cooling the high temperature distilled water flowing to the outer circumferential surface through the cooling water flowing into the room temperature to room temperature, the first cooling water flow pipe 110 is shown in FIGS. As described above, a plurality of uprights at a predetermined interval are installed to cool the high temperature distilled water flowing to the outer circumferential surface thereof. At this time, the first cooling water flow pipe 110 is formed in the form of a hollow pipe is connected in series by the first cooling water connection pipe 120 to be described later.

Meanwhile, as described above, the first coolant flow pipe 110 configured at the outermost side of the plurality of first coolant flow pipes 110 is configured with a coolant inlet 112 through which coolant is introduced, The other side of the first cooling water flow pipe 110 is configured to have a configuration in which a cooling water outlet 114 for flowing out the cooling water flowing out after cooling the distilled water is formed.

The first cooling water flow pipe 110 configured as described above is cooled by the cooling water flowing therein. Therefore, the hot distilled water flowing from the top to the bottom or from the bottom to the top of the outer circumferential surface of the first cooling water flow pipe 110 is cooled by the first cooling water flow pipe 110. At this time, the flow direction of the cooling water and the flow direction of distilled water flowing through the first cooling water flow pipe 110 is flowed in the reverse direction.

The first cooling water connection pipe 120 constituting the present invention has a plurality of first cooling water flow pipes 110 connected in series so that the flow of the cooling water flowing inside the first cooling water flow pipe 110 is the outermost side. In order to be able to flow from the first outer coolant flow pipe 110 of the outermost via a plurality of first coolant flow pipe 110 from, the first coolant connection pipe 120 is shown in FIGS. As shown in FIG. 1, the first cooling water flow pipe 110 is alternately connected up and down, but is configured to have a series connection.

In other words, the first coolant connection pipe 120 has the first configuration of the first coolant connection pipe 120 connecting the first and second first coolant flow pipes 110 as shown in FIGS. 1 to 3. When the first and second cooling water flow pipes 110 are configured to connect the lower end of the first and second cooling water flow pipes 110 to connect the first cooling water flow pipe 110 is a second and The first cooling water connection pipe 120 is connected up and down alternately such that a plurality of first cooling water flow pipes 110 are connected in series, such as a method of connecting the upper end of the third first cooling water flow pipe 110. do.

Accordingly, as described above, the plurality of first cooling water flow pipes 110 connected in series by the first cooling water connection pipe 120 may include the cooling water inlet 112 formed in the first cooling water flow pipe 110 on the outermost side. The coolant flows out through the coolant outlet 114 formed in the first coolant flow pipe 110 on the outermost side via the plurality of first coolant flow pipes 110 while the coolant is introduced therethrough.

The distilled water flow pipe 130 constituting the present invention is for flowing hot distilled water at the time of distillation by a distillation apparatus (not shown) between the first cooling water flow pipe 110 and the second cooling water flow pipe 150. The distilled water flow pipe 130 is configured on the outer circumferential surface of each of the first cooling water flow pipes 110, as shown in FIGS. 1 to 3, but the flow of hot distilled water to the outer circumferential surface of the first coolant flow pipe 110. This configuration is made to cool. At this time, a distilled water inlet 132 through which distilled water is introduced is formed on the distilled water flowing pipe 130 formed in the first cooling water flow pipe 110 on the outermost side, and the first cooling water flow pipe 110 on the outermost side. The distilled water outlet 134 through which the distilled water flows out is formed on the distilled water flow pipe 130.

The distilled water flow pipe 130 configured as described above allows the flow of hot distilled water between the first cooling water flow pipe 110 and the second cooling water flow pipe 150 to allow the inside and outside of the distilled water flow pipe 130. Cooling of the high-temperature distilled water by the cooling water flowing through the first cooling water flow pipe 110 and the second cooling water flow pipe 150 is composed of.

On the other hand, the flow direction of the high-temperature distilled water flowing through the distilled water flow pipe 130 configured as described above is the first cooling water flow pipe 110 and the second as described in the configuration of the first cooling water flow pipe 110 It flows in the opposite direction to the flow direction of the cooling water flowing through the cooling water flow pipe 150.

Distilled water connecting pipe 140 constituting the present invention is for connecting the distilled water flowing pipe 130 in series, such distilled water connecting pipe 140 is distilled water flowing pipe 130 as shown in Figs. ) Is configured to connect serially by up and down alternately.

In other words, the distilled water connecting pipe 140 has a configuration of the distilled water connecting pipe 140 connecting the first and second distilled water flowing pipes 130 as shown in FIGS. 1 to 3. The distilled water connecting pipe 140 connecting the second and third distilled water flowing pipe 130, if the configuration consists of connecting the upper portion of the pipe 130, the lower portion of the second and third distilled water flowing pipe 130 The distilled water connection pipe 140 is connected up and down alternately such that the plurality of distilled water flow pipes 130 are connected in series.

Therefore, as described above, the plurality of distilled water flowing pipes 130 connected in series by the distilled water connecting pipe 140 has the inflow of distilled water through the distilled water inlet 132 configured in the outermost distilled water flowing pipe 130. The distilled water is discharged through the distilled water outlet 134 formed in the distilled water flowing pipe 130 on the outermost side through the plurality of distilled water flowing pipes 130. As such, the flow direction of distilled water flows in the opposite direction to the cooling water.

The second cooling water flow pipe 150 constituting the present invention allows the cooling water to flow through the outer circumferential surface of the distilled water flow pipe 130 to allow cooling of the distilled water outside the distilled water flow pipe 130. The second cooling water flow pipe 150 is configured on the outer circumferential surface of each of the distilled water flow pipes 130 as shown in FIGS. 1 to 3, but the cooling water flows to the outer circumferential surface of the distilled water flow pipe 130. Allow cooling of

The second coolant flow pipe 150 of the second coolant flow pipe 150 configured at the outermost side of the second coolant flow pipe 150 configured as described above is introduced with the coolant in the same way as the coolant inlet 112 of the first coolant flow pipe 110. The cooling water inlet 152 is configured, and the second cooling water flow pipe 150 configured at the outermost side, like the cooling water outlet 114 of the first cooling water flow pipe 110, cools the distilled water and then flows out of the cooling water flowing out. It is made of a configuration in which the cooling water outlet 154 is formed.

On the other hand, the second cooling water flow pipe 150 configured as described above is cooled by the cooling water flowing therein. Therefore, the hot distilled water flowing from the top to the bottom or from the bottom to the top of the main surface of the second cooling water flow pipe 150 is cooled by the second cooling water flow pipe 150. At this time, the flow direction of the cooling water and the flow direction of distilled water flowing through the second cooling water flow pipe 150 is flowed in the reverse direction. Therefore, it can be seen that the flow direction of the coolant by the second coolant flow pipe 150 and the flow direction of the coolant by the first coolant flow pipe 110 are the same direction.

In the second cooling water connection pipe 160 constituting the present invention, the second cooling water flow pipe 150 is connected in series so that the flow of the cooling water flowing therein is plural from the second cooling water flow pipe 150 at the outermost side. In order to be able to flow to the second outer coolant flow pipe 150 of the outermost via the second coolant flow pipe 150, this second coolant connecting pipe 160 is shown in Figs. As described above, the second cooling water flow pipe 150 is connected up and down alternately so as to be connected in series.

In other words, the second coolant connection pipe 160 has the first configuration of the second coolant connection pipe 160 connecting the first and second second coolant flow pipes 150 as shown in FIGS. 1 to 3. The second and second cooling water connection pipes 160 connecting the second and third second cooling water flow pipes 150 may be configured to connect the lower portions of the second and second cooling water flow pipes 160. The second cooling water connection pipe 160 is connected up and down alternately such that a plurality of second cooling water flow pipes 150 are connected in series, such as a method of connecting the upper portion of the third second cooling water flow pipe 150. Be sure to

Therefore, as described above, the plurality of second coolant flow pipes 150 connected in series by the second coolant connection pipes 160 are the coolant inlets 152 formed in the second coolant flow pipes 150 on the outermost side. The coolant flows out through the coolant outlet 154 formed in the second coolant flow pipe 150 on the outermost side via the plurality of second coolant flow pipes 150 while the coolant is introduced therethrough.

As described above, the distilled water cooling heat exchanger 100 according to the present invention includes a first pipe consisting of a triple pipe structure of the first cooling water flow pipe 110, the distilled water flow pipe 130, and the second cooling water flow pipe 150. It is understood that the cooling efficiency is improved by cooling the distilled water flowing through the distilled water flowing pipe 130 installed between the cooling water flow pipe 110 and the second cooling water flow pipe 150 inside and outside the distilled water flow pipe 130. Can be.

On the other hand, in the configuration of the heat exchanger 100 for cooling the distilled water according to the present invention, each of the first cooling water flow pipe 110, the distilled water flow pipe 130, and the second cooling water flow pipe 150 is the first cooling water connection pipe 120. ) Is connected in series by the distilled water connecting pipe 140 and the second cooling water connecting pipe 160, and the flow direction of the distilled water and the flow direction of the cooling water flow in the reverse direction to further improve the cooling efficiency. In this case, as shown in FIG. 2, a plurality of rows of the first cooling water flow pipes 110 connected in series may be connected in parallel.

In addition, the cooling water flowing through the first cooling water flow pipe 110 and the second cooling water flow pipe 150 in the configuration of the heat exchange device 100 for cooling the distilled water according to the present invention flows through the distilled water flow pipe 130. After cooling to room temperature of the distilled water flowing, it is designed to be heat-exchanged through the heat exchanger 170 to circulate the first cooling water flow pipe 110 and the second cooling water flow pipe 150.

Figure 4 is a cross-sectional view showing another embodiment of a heat exchange device for distilled water cooling according to the present invention.

4 shows another embodiment of the heat exchanger 100 for cooling the distilled water according to the present invention. As shown in FIG. 4, the present invention includes a first cooling water flow pipe 110 in addition to the configuration of FIGS. 1 to 3. The inside of each of the distillation apparatus is installed in such a size that the flow of the cooling water is not blocked, but the cooling water flowing through the first cooling water flow pipe 110 by the application of power to stop the operation in a low temperature state, such as winter The heating rod 180 is further configured to heat the low-temperature distilled water to room temperature when it is restarted.

In other words, when the operation of the distillation apparatus is stopped in a low temperature state, such as winter, distilled water and cooling water stopped in the inside of the heat exchanger 100 for cooling distilled water are in a low temperature state, and thus there is a problem in utilizing the same. . Therefore, it is necessary to raise the temperature to room temperature immediately to utilize the distilled water, the heating rod 180 of the present invention to increase the cooling water temperature of the first cooling water flow pipe 110 through the application of power to heat the low-temperature distilled water It will increase the temperature to room temperature.

As described above, according to the present invention, the distilled water flows through the distilled water flowing pipe 130 formed between the first cooling water flow pipe 110 and the second cooling water flow pipe 150, which is made of a triple pipe structure. By allowing the inside and outside of the pipe 130 to be cooled, it can be seen that the facility has an effect of significantly reducing the failure rate through a simple structure and improving cooling efficiency.

The present invention is not limited to the above embodiments, and various modifications can be made within the scope of the technical idea of the present invention.

1 is a front configuration diagram showing a heat exchanger for distilled water cooling according to the present invention.

Figure 2 is a plan view showing a heat exchange device for distilled water cooling according to the present invention.

Figure 3 is a cross-sectional view showing a heat exchanger for distilled water cooling according to the present invention.

Figure 4 is a cross-sectional view showing another embodiment of a heat exchanger for cooling distilled water according to the present invention.

[Description of Symbols for Main Parts of Drawing]

100. Heat exchanger 110. First cooling water flow pipe

112, 152. Coolant inlet 114, 154. Coolant outlet

120. First cooling water connecting pipe 130. Distilled water flowing pipe

132. Distilled water inlet 134. Distilled water outlet

140. Distilled water connecting pipe 150. Second cooling water flowing pipe

160. Second cooling water connection pipe 170. Heat exchanger

180. Heating rod

Claims (4)

In the heat exchanger for distilled water cooling to cool the hot distilled water distilled in the process of distilling raw water into distilled water through a predetermined process to room temperature, A plurality of first cooling water flow pipes installed at regular intervals, the cooling water flowing to cool the distilled distilled water; A plurality of first cooling water connection pipes connecting the first cooling water flow pipes in an up and down alternating manner to make a series connection; A distilled water flow pipe configured on the outer circumferential surface of each of the first cooling water flow pipes, wherein the distilled distilled water flows to the outer circumferential surface of the first coolant flow pipe to allow cooling; A plurality of distilled water connecting pipes connecting the distilled water flowing pipes in an up and down alternating manner to make a series connection; A plurality of second cooling water flow pipes configured on the outer circumferential surface of each of the distilled water flow pipes to allow the cooling water to flow to the outer circumferential surface of the distilled water flow pipe to cool the distilled water; And Distilled water cooling heat exchanger comprising a plurality of second cooling water connecting pipes for connecting the second cooling water flow pipe up and down alternately to make a series connection. The cooling water flowing through the first cooling water flow pipe and the second cooling water flow pipe is flowed in the same direction, the distilled water flowing through the distilled water flow pipe is the first cooling water flow pipe and the second cooling water. Heat exchanger for cooling distilled water, characterized in that designed to flow in the reverse direction with the cooling water flowing through the flow pipe. The cooling water flowing through the first cooling water flow pipe and the second cooling water flow pipe is heat-exchanged through a heat exchanger after room temperature cooling of distilled water flowing through the distilled water flow pipe. 1. A heat exchanger for cooling distilled water, wherein the cooling water flow pipe and the second cooling water flow pipe are designed to be circulated. According to claim 3, wherein the inside of each of the first cooling water flow pipe is installed in such a size that the flow of the cooling water is not blocked, but by applying the power to the cooling water flowing through the first cooling water flow pipe to heat the low temperature, such as winter Distilled water cooling heat exchanger further comprises a heating rod for heating the low-temperature distilled water to room temperature when the operation of the distillation apparatus is stopped in operation.

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