KR101146105B1 - Heat plate for heat exchanger - Google Patents

Abstract

PURPOSE: An electric heating plate for a plate type heat exchanger is provided to reduce a manufacturing process and uniformly maintains the flow velocity formed along a line by constituting the line without an additional process. CONSTITUTION: An electric heating plate for a plate type heat exchanger comprises a module consisting of three electric heating plates. The module comprises first and second gaps formed by the electric heating plates. The first gap accepts a heating medium and the second gap accepts a cooling medium. The heating medium is inserted and stored in a second area comprising a second pattern plane(121), a plurality of fifth through-holes, and a pair of sixth through-holes(123). The fifth and sixth through-holes are respectively arranged in the lower and upper parts of the second pattern plane so that a flow path for steam is formed.

Description

Heat transfer plate for plate heat exchanger {HEAT PLATE FOR HEAT EXCHANGER}

The present invention relates to a heat exchanger plate for a plate heat exchanger, and more particularly, it is possible to construct a line without a separate member and additional process for installation (easiness in manufacturing cost reduction, process shortening, defective rate, easy maintenance) And it relates to a heat transfer plate for a plate heat exchanger that can minimize the space occupied by the line configuration.

Generally, a heat exchanger is a device for transferring heat from a high temperature fluid to a low temperature fluid through a heat transfer wall.

Such a heat exchanger generally uses a metal tube as a heat transfer wall, and this type includes a main type, a double tube, a finned tube, and a tube type.

The double tube heat exchanger has an inner tube and an outer tube, and heat exchange is performed between the fluid inside the inner tube and the fluid in the annular portion between the tube and the tube. This format is simple in structure but requires less processing.

In addition, the large-capacity one uses a bushing type in which several small pipes are placed in a large external pipe. The flows of high fluid and low fluid flow in the same direction are referred to as cocurrent flows, and the flows in the opposite direction are referred to as counterflows and perpendicular flows are referred to as crossflows.

Unlike the tube type heat exchanger, there is also a method of using a plate type heat exchanger.

Plate-type heat exchangers take advantage of the small space compared to the tube-type method by heating, cooling, evaporating, and condensing from a space formed between a plurality of plates, and have an advantage of being more efficient than a small space.

Such plate heat exchangers have been manufactured for many years as seawater distillation apparatus in which one or a plurality of plate packages form the main part in the process, and in this regard, Swedish patent 464 938 relates to a desalination plant comprising a plate package provided in a cylinder vessel. Is disclosed.

The heat exchanger plate does not have a port for steam, but instead the space outside the heat exchanger plate is used as one or more flow paths for steam depending on the type of process.

However, the cost of the container is not only a big part of the overall cost of the plant (system), but also takes a long time to manufacture the container.

In addition, the maintenance of the plant is difficult because only the plate package and the heat exchanger plate are accessible.

Korean Patent Publication No. 10-2007-0118610 is disclosed as a technique for improving this problem.

According to the above-mentioned patent, the heat exchanger plates are arranged in parallel in such a manner that heating, cooling, evaporation, and condensation are performed through spaces formed between the plates after the plurality of heat exchanger plates are arranged in parallel, so that individual separation of the heat exchanger plates is possible. And the manufacturing cost is relatively low.

However, referring to FIG. 1, the patent discloses that the cooling line 2 and the heating line 3 are arranged in the center of the heat exchanger 1, and the discharge line 4 is aligned at the left and right ends of the heat exchanger plate 1a. Since the entire heat exchange line is formed in a state, when the cooling and heating lines are configured, a separate member 5 must be installed to form an unnecessary space for the separate member.

In the related art, since the heating medium and the cooling medium are formed in one gap, there is a problem in that the thermal conduction efficiency due to the thermal conductivity is reduced.

In addition, as the discharge line is disposed on both sides, as shown in FIG. 2, the space A for increasing the steam is relatively small, so that the smooth flow of the steam does not occur, thereby improving the yield. There is an unexpected problem.

An object of the present invention is proposed to improve the conventional characteristics as described above, and can be configured in the line without a separate and additional process for installation (easiness in manufacturing cost reduction, process shortening, defective rate, maintenance And to provide a heat transfer plate for a plate heat exchanger that can minimize the space occupied by the line configuration.

In addition, another object of the present invention is to provide a heat transfer plate for a plate heat exchanger that can maintain the flow rate formed along the line by making the line configuration uniform, thereby preventing corrosion of piping due to the high flow rate.

In addition, another object of the present invention is to make the passage on the evaporation side proportional to the amount of evaporation for the plate heat exchanger which can prevent the fluid accumulation phenomenon inside the heat transfer plate by uniformizing the flow of fluid from cooling to condensation and discharge In providing a heat transfer plate.

The present invention has the following structure in order to achieve the above object.

In the heat exchange plate for plate heat exchanger of the present invention, three heat transfer plates constitute one module, the module having a first gap and a second gap formed by the respective heat transfer plates, wherein the first gap is heated. The space where the medium is accommodated and steam is introduced to generate condensate, and the second gap is a space where the cooling medium is accommodated and the steam is generated so that the first gap and the second gap are alternately formed. In the heat transfer plate for a plate heat exchanger, the heating medium is introduced and stored in the first gap and the first region formed so that the raw water is introduced and stored in the second gap, and the steam generated by evaporation of the raw water A second region formed to move, and the first gap collects condensed water condensed by the steam, and the cold gap in the second gap. It is separated by a third region formed to ensure that the stored medium flows.

The first region, the second region, and the third region may be sequentially formed from the lower portion of the heat transfer plate in an upward direction.

In addition, the first region may include a first pattern surface formed in the center portion in a state separated by a groove, a pair of first through holes located on both sides of the upper portion of the first pattern surface, and a lower center portion of the first pattern surface. It is preferable that the formed third through hole and the seventh through hole formed at a position adjacent to the third through hole.

The second region may include a second pattern surface symmetrically formed with respect to the virtual vertical center line, a plurality of second through holes formed at equal intervals below the second pattern surface, and a virtual vertical center line above the second pattern surface. It is preferable that the pair is made of a sixth through-hole formed to be symmetrical with respect to.

In addition, the third region may include a third pattern surface formed at regular intervals in the horizontal direction, a fourth pattern surface extending from both ends of the third pattern surface, a second through hole formed on the side of the fourth pattern surface, and the third pattern surface. It is preferably made of a fourth through-hole formed on the lower side of the three pattern surface, each of the second and fourth through-hole is formed in a state separated by a groove with respect to the third and fourth pattern surface.

The first through hole may further include a first surface extending vertically downward from one side of the outer circumferential surface and a second surface inclined toward the first surface direction from one side of the outer circumferential surface.

In addition, it is preferable that the directions of the patterns formed on the first pattern surface and the third pattern surface are opposite to each other.

In addition, the first pattern surface may be formed by repeatedly repeating the first and first grooves and the second and second grooves.

In addition, the first yaw is preferably formed of a relatively shorter length than the second yaw.

In addition, the second pattern surface may be formed of a first groove and a second groove formed on the top of the first groove in a cross section of the heat transfer plate.

In addition, the third and seventh through holes are preferably formed in the inner region of the triangular pyramid-shaped groove formed in the first region.

In addition, each of the sixth through holes is preferably in the form of narrowing toward the top.

In addition, the fourth through hole is formed in the inner region of the groove formed in the third region is preferably in the form of an inverted triangular pyramid.

In addition, the first pattern surface and the third pattern surface is preferably formed with fine corrugation (corrugation) to increase the surface area.

According to the present invention, it is possible to configure the line without a separate and additional process for installation, the ease of manufacturing (reduced cost, process shortening, defective rate reduction, easy maintenance) and the effect that can minimize the space occupied by the line configuration have.

In addition, according to the present invention, by uniformizing the line configuration it is possible to maintain a uniform flow rate along the line to prevent corrosion of the pipe due to the high flow rate, and the passage on the evaporation side proportional to the amount of evaporation As a result, the flow of the fluid from cooling to condensation and discharge can be made uniform, thereby preventing fluid accumulation in the heat transfer plate.

In addition, according to the heat transfer plate of the present invention, it is possible to remove moisture from the steam by using a demister and to remove salts contained in the moisture, thereby obtaining condensed water of higher purity, and having a pattern surface having a different volume. And by forming a fine pattern on the pattern surface can improve the heat transfer efficiency of the cooling medium side than the heating medium side, and by forming the heating medium and the cooling medium in different gaps by reducing the effect of thermal conductivity to heat transfer efficiency There is an effect that can be improved.

1 and 2 are schematic diagrams showing a conventional plate heat exchanger.
3 is a perspective view showing a plate heat exchanger of the present invention.
4 is a front view showing a heat transfer plate of the plate heat exchanger according to the present invention.
FIG. 5 is a partial cross-sectional view showing a cross section taken along the line AA of FIG. 4. FIG.
6 is a partial cross-sectional view showing a bonding state of the first pattern surface according to the present invention.
FIG. 7 is a partial cross-sectional view showing a cross section taken along line BB shown in FIG. 4. FIG.
8 is a partial cross-sectional view showing a bonding state of a second pattern surface according to the present invention.
9 is an exploded perspective view showing a plate heat exchanger according to the present invention.
10 to 13 is an operation diagram showing an operating state of the plate heat exchanger according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described below. These embodiments are provided to explain in detail the present invention to those skilled in the art. Accordingly, the shape of each element shown in the drawings may be exaggerated to emphasize a more clear description.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are only used to distinguish one component from another.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

3 and 10, in the plate heat exchanger 10 in which the heat transfer plate of the present invention is used, the heat transfer plate 100 is continuously disposed so that the first gap 200 and the second gap 300 are repeated. Are alternately formed.

In addition, the first gap 200 is a space in which the heating medium (H) is accommodated and the steam (V) is introduced to generate condensed water (W), and the second gap (300) is the cooling medium (C). It is composed of a space where steam (V) is generated.

In addition, the first gap 200 includes a heating part 210 in which a heating medium H is accommodated, a raw water supply part 220 which is absent in the heating part 210 and in which raw water SW is introduced, and the second gap. The evaporator 230 in which the steam V generated in the gap 300 is collected and the collected steam is cooled to form condensed water W.

In addition, the second gap 300 is formed by the raw water reservoir 310 which receives and stores the raw water SW supplied from the raw water supply unit 220 and the heating medium H in the first gap 200. An evaporator 330 in which the raw water W is heated and evaporated, a cooling unit 240 in which the cooling medium C is accommodated and condensing the vapor V collected in the first gap 200; The condensate collecting unit 350 collects the condensed water W condensed in the first gap 200.

In addition, the lines of the fluids C, H, W, and SW flowing through the first gap 200 and the second gap 300 formed by continuously arranging the heat transfer plates 100 respectively have one line 410, 420, 430, 440, and 450. Is formed.

In addition, the fluid flowing through each of the lines 410, 420, 430, 440, and 450 is blocked from each other by the separation walls 212, 221, 241, 251, 311, 322, and 342 so as to flow only the first gap 200 or only the second gap 300.

In addition, the partition walls 212, 221, 241, 251, 311, 322 and 342 are preferably gaskets having a predetermined pattern.

In addition, the evaporator 230 of the first gap 200 and the evaporator 330 of the second gap 300 further includes droplet separators 231 and 331 for separating the droplets contained in the vapor (V). do.

In addition, the raw water supply unit 220 is in communication with the second gap 300 in order to replenish the raw water (SW) due to the evaporation in the second gap 300, the first gap 200 is blocked. Raw water supply unit 223 is further formed.

In addition, it is preferable that separate discharge ports 213 and 314 are further formed in each of the first gap 200 and the second gap 300 to discharge the concentrated water T after the raw water SW is evaporated.

Here, the first gap 200 includes a heating unit 210 in which the heating medium H supplied by the heating line 410 is accommodated, and raw water into which raw water flows in an isolated state in the heating unit 210. Supply unit 220, the evaporator 230 to induce the steam (V) formed by evaporation of the raw water (SW) heated by the heating unit 210 in a state arranged on the heating unit 210, and the evaporation The condensate collector 250 is disposed on the unit 230 and moves the vapor V collected by the evaporator 230 to the evaporator to collect condensate W formed by cooling the steam. That is, the first gap 200 serves as a space for storing the supplied heating medium, heating and evaporating the raw water supplied to the second gap through the heating medium, and collecting the vaporized vapor.

In addition, the second gap 300 is a raw water reservoir 310 for receiving and storing the raw water (SW) supplied from the raw water supply unit 220, 320, and the steam formed on the raw water reservoir 310 and heated by heating Evaporation unit 330 to collect (V) to the first gap 200 to guide, and a cooling medium (C) disposed on the evaporation unit 330 to cool the vaporized vapor (V) The cooling unit 340 and the condensate collecting unit 350 for collecting and discharging the condensed water (W) that is cooled and collected in a separate state in the cooling unit 340. That is, the second gap 300 serves to allow the raw water heated and evaporated in the first gap 200 to be cooled by the cooling medium and collected again via the second gap and discharged again. .

A shielding plate 400 is formed on the front surface of the first gap 200, and the shielding plate 400 passes through the first gap 200 and the first gap 200, respectively. Lines 410, 420, 430, 440, and 450 are configured to be connected to 300, and each of the lines includes a cooling line, a heating line, a condensate discharge line, a raw water supply line, and a concentrated water discharge line.

The cooling line 410 is configured to allow the cooling medium C supplied from the outside to be supplied to the second gap 200 through the first gap 200, and the heating line 420 is supplied from the outside. The heating medium (H) is supplied to the first gap 200 and passes through the second gap 300 is supplied to the first gap alternated, the condensate discharge line 430 is the first gap 200 And a second gap 300, and configured to discharge the condensed water formed in the first gap to the outside, and the raw water supply line 440 receives the raw water SW supplied from the outside into the first gap. It is configured to pass through the 200 to supply to the second gap 300, the concentrated water discharge line 450 is formed after the steam (V) from the raw water (SW) to the remaining concentrated water (T) to the outside It is a structure for discharging.

For example, as illustrated in FIGS. 3 and 9, a heating part 210, a raw water supply part 220, and an evaporation part 230 are provided in the first gap 200 formed by the shielding plate 400 and the first heat transfer plate 100. And a condensate collecting unit 250, and a raw water reservoir 310 and a raw water supply unit 320 in the second gap 300, which is a space formed between the first heat transfer plate 100 and the second heat transfer plate 100 ′. The evaporator 330, the cooling unit 340, and the condensate collector 350 are configured.

The heating unit 210 is insulated to store a predetermined amount of the heating medium (V) supplied through the heating medium supply port 211 formed on both sides of the heat transfer plate 100 in the width direction so as to be connected to the heating line (420). It is comprised by the partition wall 212. That is, the heating unit 210 is configured to always maintain a heating medium having a constant temperature on the side of the first gap 200 so that the raw water described later can be heated.

The raw water supply unit 220 is a raw water supply unit 222 and the raw water supply unit 223 opened in the lower portion of the heat transfer plate 100 are located in the heating unit 210 by the raw water separating wall 221 of the triangular pyramid shape, respectively. It is a configuration that supplies raw water through the raw water supply line with an isolated space.

The evaporator 230 is formed on the vapor collecting port 232 and the steam collecting port 232 opened in a plurality on the heating unit 210, the yaw and iron formed in the horizontal direction are arranged at equal intervals in the vertical direction A droplet separator 231 is disposed.

That is, the evaporator 230 collects raw water accommodated in the second gap 300 through a heating medium accommodated in the heating unit 210 of the first gap 200. The droplets contained in the steam are separated to raise the steam and drop the droplets back to the raw water reservoir.

The condensate collecting unit 250 is separated from the evaporation unit by the condensate collecting guide wall 251, and a connection hole 252 having an inverted triangular pyramid shape is opened and collected in the central portion of the condensate collecting guide wall 251. The condensate is collected and discharged.

In addition, a blocking wall 201 is formed in the first gap 200 to block the outside along the circumferential surface of the heat transfer plate 100, and a cooling medium supplied through the cooling line 410 is formed in the first gap 200. Cooling medium separation wall 241 that isolates the cooling medium supply port 242 formed on both sides of the heat transfer plate 100 in the upper width direction so as to be supplied to the second gap 300 while being isolated from the first gap 200. ) Is configured.

In this case, each of the separation walls is a gasket is used as a configuration for isolating each part formed in the heat transfer plate from each other, the gasket is preferably used for airtightness, corrosion resistance, heat resistance, excellent material.

In addition, the condensate collecting unit 250 has steam distribution ports 253 and 333 for guiding the vapor collected and guided by the vapor collecting unit 230 and the evaporation unit 330 of the second gap 300 to the condensate collecting unit side. Is formed.

The concentrated water outlet 213 for condensing raw water and discharging the remaining concentrated water to the outside is formed at both sides of the heat plate 100 in the width direction.

Looking at the configuration formed in the second gap 300,

The raw water reservoir 310 is formed in a state in which a heating medium separating wall 313 is formed to surround the heating medium supply port 312 formed at both sides of the lower side of the heat transfer plate 100 ′ and to be isolated from the second gap 300. In the heating medium separating wall 313 is extended downward from each of the "U" shaped raw water reservoir wall 311 is formed. That is, the raw water storage unit 310 receives and stores raw water stored in the raw water supply unit 210 formed in the first gap 200 through the raw water supply unit 223, and is evaporated by the operation of the present invention. As much as the amount of raw water is supplied, it is possible to keep the water supply constant at all times.

The raw water supply unit 320 is separated from the raw water storage wall 311 and separated from the raw water storage wall 311 so as to surround and separate the raw water transport hole 321 formed on the heat transfer plate 100 'and the raw water transport hole 321. It is comprised by the raw water supply port 323 formed in the position adjacent to ().

That is, in the raw water supply unit 220 formed in the first gap 200, the raw water supply port and the raw water supply port are enclosed in the raw water separation wall in the form of a triangular pyramid, and the storage and transport of the raw water may be performed in parallel. The raw water supply unit 320 formed at 300 is configured to transfer the raw water to the next gap in a state in which the raw water feeder is isolated and to supply the raw water through the raw water feeder.

This is to enable the raw water to be supplied only to the raw water storage part of the second gap by allowing the raw water supplied through the raw water supply part to be transferred to the plurality of gaps through the raw water feed hole, and isolated from the first gap and supplied from the second gap.

The evaporator 330 is formed on the steam collecting port 332 and the steam collecting hole 332 which is opened on the raw water reservoir 310, the yaw and iron formed in the horizontal direction are equally spaced in the vertical direction The droplet separator 331 and the vapor separator 331 is disposed on the heat distribution plate 100 is composed of a vapor distribution port 333 disposed on both sides in the width direction.

The cooling unit 340 surrounds the cooling medium supply port 341 formed on both sides of the heat transfer plate 100 ′ in the upper width direction, and surrounds the circumferential surface of the heat transfer plate 100 ′ to isolate the second gap 300 from the outside. The cooling medium separating wall 342 extending from the blocking wall 301 has a predetermined space above the heat transfer plate 100 ′ and includes the cooling medium supply port 341 in the space.

That is, the cooling medium supplied through the cooling line 410 is supplied to the cooling unit 340 by the cooling medium supply port of the second gap 300 through the first gap 200 to be evaporated as described above. The collected steam is cooled by.

The condensate collector 350 is composed of a connection hole 352 separated by a raw water separation wall 351 of an inverted triangular pyramid form under the cooling medium separation wall 342 of the cooling unit 340. That is, when the condensate generated by cooling the steam by the cooling unit is collected in the condensate collecting unit 250 having the open shape in the first gap, the condensate collecting unit 350 is collected in the isolated condensate collecting unit 350 of the second gap 300. It is discharged to the outside through the condensate discharge line.

Here, the same concentrated water outlet 314 as the concentrated water outlet 213 formed in the lower portion of the first gap 200 is formed to communicate with each other.

The first gap 200 and the second gap 300 are configured such that a plurality of heat transfer plates 100 and 100 'are arranged in alignment with each other, and heating is performed in the first gap 220. Cooling is performed in the gap 300, and the evaporation and collection are performed in the first gap and the second gap, and thus different roles may be performed in the space, thereby allowing a natural flow of heating, evaporation, cooling, and condensation. . In addition, the amount of raw water supplied by heating, the amount of steam generated by heating, and the amount of condensed water can be maintained uniformly so that the uniformity of supply (raw water) and demand (condensed water) is maintained at all times.

In addition, although not shown in the drawings, the steam collecting ports 232 and 332 and the steam distribution ports 253 and 333 formed in the condensate collecting unit 250 and the evaporating unit 230 and 330, respectively, include a demister for removing moisture contained in the steam ( Demister); is further provided.

That is, as described above, if the droplet is separated from the steam using the droplet separator, but the droplet is not completely separated from the droplet separator, the secondary water is used to remove water from the steam using a demister so that it is included in the steam from the raw water and evaporated. The salt can be completely removed. To this end, the demister is preferably in the form of a fine mesh, but may include any of the means for removing moisture from the steam.

Meanwhile, the heat transfer plate 100 according to the present invention has a plate-shaped heat exchanger having a region divided into a first region 110, a second region 120, and a third region 130 by grooves 101 formed in a predetermined pattern, respectively. The first region 110 is a conventional heat transfer plate, the first through hole 111 formed on both sides of the virtual vertical center line, the third through hole 112 formed below the virtual vertical center line, and the third And a seventh through hole 112a formed to be adjacent to the through hole 112, and a first pattern surface 113 formed therein separated by a groove, wherein the second area 120 is disposed on the first area. The second pattern surface 121 is disposed and bisected on the basis of the virtual vertical center line, the fifth through hole 122 formed under the second pattern surface 121, and the second pattern surface 121. And a pair of sixth through holes 123 formed thereon, wherein the third region 130 is disposed on the second region 120, but the virtual three A second through hole 131 formed at both sides of the furnace center line, a fourth through hole 132 formed at the lower center portion, a third pattern surface 134 formed in a region separated by the groove, and the second through hole. The fourth pattern surface 133 formed between the 131 and the third pattern surface 134 is included.

In addition, the first pattern surface 113 and the third pattern surface 134 are formed such that the pattern directions face opposite directions.

In addition, the first pattern surface 113 is formed by alternating first and second grooves 113a, first grooves 113c, and second grooves 113b and second grooves 113d.

The first yaw 113a is formed to have a relatively shorter length than the second yaw 113b.

In addition, in the cross-section of the heat transfer plate, the second pattern surface 121 is provided with a second groove 132b stepped on the first groove 132a and the first groove 132a.

The third through hole 112 and the seventh through hole 112a are formed in the inner region of the triangular pyramid-shaped groove formed in the first region 110.

In addition, the sixth through hole 123 is narrowed toward the top, the fourth through hole 132 is formed in the inner region of the groove formed in the third region 130, but has an inverted triangle shape.

That is, as shown in FIG. 4, the first region 110, the second region 120, and the third region 130 are formed in one plate shape, and the partition wall (gasket) is formed in the first region 110. The heating unit of the first gap and the raw water reservoir of the second gap may be selectively formed by using the second gap, and the evaporation unit in which the droplet separation unit is formed in common in the first gap and the second gap may be formed in the second area 120. The condensate collecting unit of the first gap 200 and the cooling unit and the condensate collecting unit of the second gap 300 may be selectively formed in the third region 130.

To this end, grooves 101 formed by a predetermined pattern are formed in the heat transfer plate 100, and the grooves 101 are formed in the first region 110, the second region 120, and the third region 130, respectively. The gasket is inserted into each of the grooves of the region to be separated, according to the purpose of use of the pattern surface and the holes formed therein, and is used to form a space between the first gap and the second gap of the plate heat exchanger.

That is, after forming the grooves 101 having a predetermined pattern, a gasket is inserted to form a separate zone and formed to fit the first gap or formed to fit the second gap to form the first gap and the second gap. To let you choose. These separate zones allow each fluid supplied by the line to form a separate conduit as described above.

The first region 110 is configured to open the first through holes 111 on both sides of the virtual vertical center line P so that the heating medium flows from the outside, and the third through the bottom of the virtual vertical center line. And forming a 112 to introduce raw water from the outside, and forming a seventh through hole 112a at a position adjacent to the third through hole 112 to feed the raw water introduced through the third through hole 112. It is a structure for supplying to the raw water storage part of the 2nd clearance gap formed as a module, Comprising: The 4th through hole 115 is formed in the lower both sides with respect to the said virtual longitudinal center line, and it is comprised so that the processed raw water may be discharged to the outside.

In addition, a first pattern surface 113 is formed at the center of the first region 110 to facilitate diffusion and circulation of the heating medium supplied through the first through hole.

As illustrated in FIG. 5, the first pattern surface 113 is formed such that the first yaw 113a, the first groove 113c, the second yaw 113b, and the second groove 113d alternate with each other.

The length L1 of the first groove 113c formed by the first yaw 113a may be shorter than the length L2 of the second groove 113d formed by the first yaw 113b. Do.

Further, fine wrinkles 114d and 134d are further formed on the first pattern surface 113 and the third pattern surface 134 to increase the surface area for boiling promotion of the evaporator and the condenser.

That is, the surface of both the first and second grooves and the second groove and the second groove are formed with a fine pattern to increase the surface area so that it is advantageous for the generation of bubbles. You can increase it.

For example, as shown in FIG. 8, the volume of the cross section formed in the first gap and the second gap formed by arranging the heat transfer plates 100 and 100 ′ is supplied so that the lengths of the first and second grooves are alternately different from each other. It is possible to increase the heat transfer efficiency by accelerating the flow of the heating medium to increase the heating efficiency to form a larger volume on the side of the cooling medium in which the phase change from raw water to steam than the heating medium side.

In addition, as described above, the first through hole 111 is a hole by supply of a heating medium, the third through hole 112 is a hole for transporting raw water, and the seven through hole 112a is the third hole. The raw water supplied by the through hole is a hole for supplying raw water only to the second gap in a state separated from each other between the first gap and the second gap, and the fourth through hole 115 discharges the remaining concentrated water after condensation is finished. It is a hole for.

Here, although the first through hole 111 is represented by a hole opened in a cylindrical shape, as shown in FIG. 4, the first surface 111 a extending vertically downward from one side of the outer circumferential surface, and the first surface from one side of the outer circumferential surface. It is also possible to have a form in which the second surface 111b extending inclined in the (111a) direction is further formed. That is, it is also possible to form the hole opened by the combination of the arc and the V shape.

This is because the second surface 111b has an inclined shape with respect to the first hole 111 when the raw water reservoir in the second gap 300 is formed with the first hole 111 separated by a gasket. This is to allow the vapor evaporated in the raw water stored in the second gap 300 to be naturally guided upward along the second surface 111a inclined upward.

As described above, a second pattern surface 121 bisected based on the virtual center line P is formed as an area in which the evaporators 230 and 330 are formed, and the second pattern is formed in the second region 120. A plurality of fifth through holes 122 are formed under the surface 121, and sixth through holes 123 having a trapezoidal shape are formed on both sides of the second pattern surface 121.

Here, the area of the fifth through 122 and the sixth through 123 are expanded to be equal to each other, thereby facilitating the movement of the generated steam, thereby causing the heat transfer plate erosion (erosion corrosion). Damage can be prevented.

In addition, as shown in FIGS. 4 and 7, the second pattern surface 121 is formed by protruding the first grooves 132a formed in the horizontal direction of the heat transfer plate at equal intervals, and the length of the first grooves 132a. The pair of second grooves 132b are configured to face each other along the direction.

That is, the second pattern surface 121 is formed by the recesses and grooves, and as described above, the droplets can be separated from the vapor, and the second grooves are configured to more effectively separate the droplets. to be.

For example, as shown in FIG. 6, steam V rises through a space in which the first gap 200 and the second gap 300 are formed, and the steam flow VF is included in the steam by the grooves and grooves when the vapor flow VF is generated. The droplets can be separated.

In the third region 130, second through holes 131 are formed at both upper sides of the virtual vertical center line P, and a third pattern surface 134 is formed at the center portion of the virtual vertical center line P. FIG. The fourth pattern surface 133 is formed to be adjacent to the second through hole 131 based on the virtual vertical center line P, and a fourth inverted triangular pyramid shape is formed on the virtual vertical center line P side. A through hole 132 is formed.

The third pattern surface 134 is formed with the same pattern surface as the pattern surface shown in FIGS. 5 and 6, and the fourth pattern surface 133 is formed in a lattice form with the grooves and the grooves.

For example, as described above, the third pattern surface naturally guides the vapors collected on the first gap side to be supplied to the fourth pattern plane, and improves the fluidity of the cooling medium on the second gap side. Is a configuration in which the cooling medium supplied through the second through hole easily moves to the cooling unit formed in the third region, and the expanded or generated steam is naturally induced to the condensate collecting unit side.

On the other hand, the first pattern surface and the third pattern surface is configured to repeat the curved form in the opposite direction to each other.

This is because when the curves are formed to have a pattern formed in the lower heating part and a pattern formed in the upper cooling part in different directions, the flow paths formed in the heating part and the cooling part have flows facing each other, and thus, between the cooling part and the heating part. This is because the steam generation in the evaporation unit located at can be efficiently made.

Looking at the coupling relationship according to the present invention, first, the heat transfer plate 100 on which the first gap 200 is formed is brought into close contact with the shielding plate 400 side. In this case, as described above, the heat plate 100 is provided with a heating part 210, a raw water supply part 220, an evaporation part 230, and a condensate collecting part 250, and the heating part 210 is separated from the heating part. It is constructed in a state of being shielded from each other with the wall.

Next, the heat transfer plate 100 ′ on which the second gap 300 is formed is brought into close contact with the side surface of the heat transfer plate 100. Likewise, the cooling portion is shielded while the second gap 300 is separated from each other by the separating walls.

In addition, the first heat transfer plate 100 is configured to be shielded by the shielding plate 400. The shielding plate 400 forms a line through which raw water, a cooling medium, a heating medium, and the like are supplied to the first gap and the second gap, and discharge condensed water and concentrated water.

That is, an alternating first gap 200 forms a conduit through which a heating medium flows by a gasket, and a conduit through which a cooling medium flows is formed, and steam is formed in the first gap and the second gap, respectively. A flowing conduit is formed to form condensate between the first gap and the second gap.

In addition, the formed condensate is discharged to the outside for use in the next process. At this time, the condensed water is water obtained through the vapor (V) evaporated from the raw water (SW). Therefore, the heat transfer plate and the plate heat exchanger using the same of the present invention can be used in various fields such as a concentrating device as well as desalination apparatus of seawater.

Hereinafter, with reference to the accompanying drawings will be described the operating state of the plate heat exchanger using the heat transfer plate of the present invention.

As shown in FIG. 10 and FIG. 11, the present invention coupled as described above exists in a space divided into a first gap and a second gap by a plurality of heat transfer plates 100 and 100 ′, and in the first gap 200. The heating medium H supplied through the heating line 420 is accommodated and circulated to heat the raw water, and the cooling medium C supplied through the cooling line 410 to the second gap 300. Is accommodated and circulated to cool the steam to generate condensate.

That is, the heating medium H supplied from the heating line 420 is connected to the heating medium supply port 211 in a state in which the heating medium H is isolated by the heating part separating wall 212 of the first gap 200. ) Is supplied to the heating medium.

The fresh water heating medium is diffused, circulated and flows by the first pattern surface formed in the heating unit 210.

In addition, the cooling medium C supplied from the cooling line 410 passes through the second medium 300 after being separated from the first gap by the cooling medium separation wall 241 formed in the first gap 200. Using the third pattern surface and the third pattern surface in a state in which the cooling medium is supplied to the cooling unit 340 insulated by the cooling medium separation wall 342 and communicated with the cooling medium supply port 341. Allow the cooling medium to diffuse, flow and circulate.

That is, the received cooling medium is diffused into the cooling unit by the fourth pattern surface formed in the cooling unit 340, circulated by the third pattern surface, and flows.

The raw water supplied from the raw water supply line 440 is stored in the raw water reservoir 220 formed in the first gap 200 through the raw water supply port 223 formed in the raw water reservoir 220. Raw water is stored in the raw water storage part 310 formed by the raw water separating wall 311 at the side of the second gap 300.

Next, the steam collecting port 232 is not completely submerged by the raw water, and a certain amount of raw water is always discharged together with the concentrated water through the concentrated water outlet formed in the lower portion, thereby maintaining a certain portion of the open state.

That is, the stored raw water is no longer submerged at the boundary between the vapor collecting port and the evaporator while both the first gap and the second gap are injected. This is because the raw water is evaporated and the concentrated water remaining after the evaporation of the raw water is discharged by the concentrated water outlet 213 formed at the bottom thereof, thereby maintaining the level of the raw water at all times.

In this way, the raw water supplied through the raw water supply unit formed in the first gap and the second gap is heated and evaporated by the heating medium accommodated in the first gap, and the vaporized vapor is positioned in the evaporator via the evaporator. do.

The steam located in this way is located at the condensate collecting part side and is cooled by the cooling unit 340 formed in the second gap 300 to become condensed water having a higher specific gravity than steam.

The condensate is naturally induced by the condensate guide wall of the condensate collecting unit formed in the first gap 200 to be collected and discharged through the condensate discharge line 430 connected to the condensate collecting unit.

12 and 13 illustrate the flows of raw water, cooling medium, heating medium, steam, condensate, and concentrated water, and the respective flows are separated from each other in the first gap and the second gap. It can be seen that it has.

For example, as illustrated in FIGS. 12 and 13, the first gap 200 and the second gap 300 are respectively divided into a heating part and a cooling part, and are commonly shared on the first gap and the second gap. By collecting the steam through the evaporator to move to the condensate collecting unit to be cooled, the flow of raw water is not only natural, but also configured to balance each other, so that bottlenecks occur at any one position. It can be prevented to maximize the production efficiency of condensate (fresh water).

In the above, the heat transfer plate of the present invention has been described by the preferred embodiment and the accompanying drawings, which are not intended to limit the technical scope of the present invention, but are intended to help understanding of the invention.

That is, those skilled in the art without departing from the technical gist of the present invention can be variously modified or modified, as well as such changes or modifications, the technical scope of the present invention in the interpretation of the claims. It is hard to say that I am within.

10: plate heat exchanger 100: heat transfer plate
110: first region 120: second region
130: third region 200: first gap
210: heating unit 220: raw water supply unit
230: evaporation unit 250: condensate collection unit
300: second gap 310: raw water reservoir
320: raw water supply unit 330: evaporation unit
340: Cooling unit 350: Condensate collection unit

Claims (14)

Three heat transfer plates form a module, the module having a first gap and a second gap formed by each heat transfer plate, wherein the first gap 200 accommodates a heating medium and inflows steam. And the second gap 300 is a space in which a cooling medium is accommodated and vapor is generated, and the first gap and the second gap are repeatedly formed to alternately form a heat exchanger. In the plate,
In the first gap, the heating medium flows in and is stored therein, and in the second gap, the first area 110 is formed to allow the raw water to flow in and is stored therein, and the second is formed to move the steam generated by evaporation of the raw water. The region 120 is divided into a third region 130 formed to collect condensed water condensed by the steam in the first gap and to allow the cooling medium to flow in and be stored in the second gap.
The second region 120 includes a first groove 132a formed at regular intervals in a longitudinal direction of the heat transfer plate, and a second groove 132b stepped from an upper portion of the first groove 132a. The second pattern surface 121 and a plurality of fifth through holes 122 and a pair of six through holes 123 respectively disposed below and above the second pattern surface 121 to form a flow path of steam are virtual. Heat transfer plate for a plate heat exchanger, characterized in that formed on the longitudinal center line symmetrically. The method of claim 1,
The first region (110), the second region 120 and the third region (130) is a heat transfer plate for a plate heat exchanger, characterized in that formed sequentially from the bottom to the heat transfer plate. The method according to claim 1 or 2,
The first region 110 is a first pattern surface 113 formed in the center portion in a state separated by a groove, and a pair of first through holes 111 located on both sides of the upper portion of the first pattern surface 113. And a third through hole 112 formed at a lower center portion of the first pattern surface 113 and a seventh through hole 112 a formed at a position adjacent to the third through hole 112. Heat transfer plate for machine. delete The method of claim 3,
The third region 130 may include a third pattern surface 134 formed at regular intervals in the horizontal direction, a fourth pattern surface 133 extending from both ends of the third pattern surface 134, and the fourth pattern surface. The second through hole 131 formed on the side of the surface 133 and the fourth through hole 132 formed under the third pattern surface 134, respectively, the second through hole 131 and the fourth through hole ( 132 is a heat-transfer plate for a plate heat exchanger, characterized in that formed in a state separated by a groove with respect to the third pattern surface 134 and the fourth pattern surface (133). The method of claim 3,
The first through-hole 111 has a form in which a first surface 111a extending vertically downward from one side of the outer circumferential surface and a second surface 111b extending inclined toward the first surface 111a from one side of the outer circumferential surface are further formed. Heat transfer plate for a plate heat exchanger, characterized in that. The method of claim 5,
Heat transfer plate for a plate heat exchanger, characterized in that the direction of the pattern formed on the first pattern surface 113 and the third pattern surface 134 are opposite to each other. The method of claim 3,
The first pattern surface 113 is a heat transfer for a plate heat exchanger, characterized in that the first yaw (113a) and the first groove (113c) and the second yaw (113b) and the second groove (113d) are formed alternately with each other. plate. The method of claim 8,
The first yaw (113a) is a heat transfer plate for a plate heat exchanger, characterized in that the length is formed relatively shorter than the second yaw (113b). delete The method of claim 3,
The third through hole (112) and the seven through hole (112a) is a heat transfer plate for a plate heat exchanger, characterized in that formed in the inner region of the triangular pyramid-shaped groove formed in the first region (110). The method according to claim 1 or 2,
Each of the sixth through holes 123 is a plate heat exchanger, characterized in that the width becomes narrower toward the top. The method of claim 5,
The fourth through hole 132 is formed in the inner region of the groove formed in the third region 130, plate heat bridge for heat exchanger, characterized in that the shape of the inverted triangular pyramid. The method of claim 5,
The first plate surface 113 and the third pattern surface (134), the plate heat exchanger, characterized in that the fine wrinkles (corrugation) to further increase the surface area is formed.

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