JP2887406B2 - Plate heat exchanger - Google Patents

Description

Description: BACKGROUND OF THE INVENTION The present invention relates to an improvement of a plate heat exchanger used for heating and cooling a fluid, and more particularly, to a fluid exchanger having six or more fluid flow ports. The present invention relates to a plate heat exchanger knitted with heat exchange plates having the following.

[Conventional technology]

FIG. 5 is a front view showing a conventional example of a heat exchange plate disposed in a laminated structure between a fixed frame and a moving frame of a plate heat exchanger. In the figure, (1) is a first heat exchange plate of a laminated type manufactured by molding a metal plate or a synthetic resin plate, and (2) and (3) are at the upper edge of the heat exchange plate (1). The first provided as a through hole,
Further, the second fluid flow ports, (4) and (5) are third and fourth fluid flow ports provided as through holes in the lower edge of the heat exchange plate (1), and (6) is a vertical 2 opposed to
An annular gasket mounted around a plurality of fluid flow ports, for example, a first fluid flow port (2), and a third fluid flow port (4) as a leakage prevention member for a first fluid, for example, steam; (7) is mounted on the heat transfer surface (8) including the second fluid circulation port (3) and the fourth fluid circulation port (5) as a leakage preventing member for the second fluid, for example, the liquid to be heated. 3 shows a looped gasket. Before and after the first heat exchange plate (1), a second heat exchange plate (not shown) having an opposite flow path structure is arranged. That is, the second heat exchange plate is the same as the heat exchange plate (1) in FIG.
Place it upside down.

[Problems to be solved by the invention]

Generally, the first heat exchange plate (1) having a total of four fluid flow openings between the fixed frame and the movable frame, and the second heat exchange plate having a liquid flow path structure opposite thereto. Are stacked and arranged with an annular gasket (6) and a loop-shaped gasket (7) interposed therebetween to form a plate heat exchanger. However, this plate type heat exchanger is used as a heat exchange means for three types of fluids, for preheating the liquid to be heated, and
In the case of performing heating, as shown in FIG. 6, a third fluid, for example, an inlet (13) for hot water for preheating, is provided between the fixed frame (9) and the moving frame (10). Partition plate (12) provided with a through-hole (13a) for a fluid, for example, a liquid to be heated
And the hot water outlet (17) on the fixed frame (9) side
And an inlet for liquid to be heated (18)
On the 0) side, an inlet (14) and an outlet (15) for a first fluid, for example, steam for heating, and an outlet (16) for a second fluid, for example, a liquid to be heated, are disposed. It constitutes a heat exchanger (11), which complicates the piping structure.

When the partition plate is not used, two plate heat exchangers are provided side by side, so that the equipment becomes large, the installation space becomes large, and the piping structure becomes complicated.

Further, when two types of fluids are heat-exchanged by a multi-pass, for example, two-pass, plate-type heat exchanger (11), as shown in FIG. A fluid, for example, a hot water inflow nozzle (13) and a second fluid, for example, an outflow nozzle (16) for a liquid to be heated are provided, and correspondingly, a hot water outflow nozzle (17) is provided on the moving frame (10) side. It is necessary to install an inflow nozzle (18) for the liquid to be heated. In this way, if the nozzles for inflow and outflow of the fluid are installed on the moving frame (10) side of the plate heat exchanger (11), these nozzles are connected when disassembling and cleaning the plate heat exchanger (11). It must be removed from each moving frame (10), and the complicated piping structure greatly increases the number of disassembly and assembly steps.

When a large amount of fluid having a large specific volume such as steam is supplied to the plate heat exchanger (11), as shown in FIG. 8, the first inflow nozzle (14A) is provided on the fixed frame (9) side. ) And an outflow nozzle (15), and a second inflow nozzle (14B) in a branched connection state to the moving frame (10) as auxiliary inflow means for the steam having a large specific volume.
It has to be installed, and the disadvantage that the piping structure is complicated has been found. In the plate heat exchanger (11) shown in FIG. 8, the flow path configuration of the other fluid that exchanges heat with steam is omitted.

For the above reasons, the plate heat exchanger (11) shown in FIGS. 6 to 8 has a problem that the disassembly / assembly work becomes difficult and the production cost rises.

[Means for solving the problem]

As a means for solving the above-mentioned problems, the present invention provides: (1) a plate-type heat exchanger in which a number of heat exchange plates are stacked and arranged via a gasket between a fixed frame and a moving frame; Three or more fluid flow ports are provided on the upper and lower edges, respectively, and one or more of the fluid flow ports on the upper edge and the lower edge of the heat exchange plate are selectively surrounded, and three or more types of heat transfer ports are provided. Using three or more types of loop-shaped gaskets for forming the surfaces, a large number of heat exchange plates having the three or more types of heat transfer surfaces are stacked and arranged so that heat is exchanged with two types of heat exchange media by multi-pass knitting. ,
A plate-type heat exchanger, wherein all the fluid inlets and outlets of the two types of heat exchange media to be heat-exchanged are provided on the fixed frame side.

(2) In a plate-type heat exchanger in which a large number of heat exchange plates are stacked and disposed between a fixed frame and a moving frame via a gasket, three heat exchange plates are provided at the upper edge and the lower edge, respectively. And at least two fluid flow ports at the upper edge of the heat exchange plate and one of the fluid flow ports at the lower edge surrounding the heat exchange plate. And a heat exchange medium having a small volume change before and after a heat exchange operation by surrounding one of the fluid flow ports at the upper edge and the lower edge of the heat exchange plate. A loop-shaped gasket that forms the heat transfer surface of the medium is used, and a large number of heat exchange plates that form the above two heat transfer surfaces are stacked and arranged to form a group of heat exchange plate assemblies. Secure all fluid ports in the exchange medium. To provide a plate heat exchanger, characterized in that provided on the frame side.

[Action]

An annular gasket that is formed by drilling three or more independent fluid flow ports on the upper edge and lower edge of the heat exchange plate so as to face each other vertically, and mounted around these fluid flow ports;
In addition, by selectively changing the type of the loop gasket between the adjacent heat exchange plates, heat exchange of three types of fluids is performed by a partition plate or the like, and further, multi-pass knitting is performed by two types of fluids. When heat exchange is performed, a plate-type heat exchanger is formed in which all of the inflow nozzles and outflow nozzles of each fluid are concentrated on the fixed frame side.

〔Example〕

FIG. 1 is a front view of a heat exchange plate according to the present invention, FIG. 2 is a front view showing a specific example of a heat exchange plate, and FIG. It is a schematic flow path diagram of an exchanger.

The heat exchange plate (20) is, as exemplified in FIG.
At its upper edge, three independent fluid flow ports (21)
(22) and (23) are formed, and three independent fluid flow ports (24) (24) ( 25) and (26) are drilled. In the heat exchange plate (20) shown in FIG. 1, the second fluid circulation port (22) at the upper edge portion and the third fluid circulation port (2
3) And, by attaching annular gaskets (27) around the fifth fluid passage (25) and the sixth fluid passage (26) at the lower edge, respectively, the second and third gaskets (27) are attached.
Of the fluid is formed. On the other hand, by attaching a loop gasket (28) around the first fluid passage (21) at the upper edge and the sixth fluid passage (26) at the lower edge, the heat exchange plate (20) A heat transfer surface (29) through which the first fluid flows is formed. Position the annular gasket (27) and loop gasket (28)
As shown in FIGS. I, II, and III, heat exchange plates (20A) (20B) (20
C), an alternate flow path in which the type of fluid flowing through the heat transfer surface (29) changes in a certain order is formed in the group of heat exchange structures. More specifically, the annular gasket (27) and the loop gasket (2
By selecting the mounting position 8), in the heat exchange plate (20A) shown in FIG. 2, the first fluid communication port (21) moves from the first fluid communication port (21) toward the sixth fluid communication port (26). Of the fluid, for example, the steam A flows down to form a heat transfer surface (29A). Similarly, the heat exchange plate (20
In B), by selecting the mounting positions of the annular gasket (27) and the loop-shaped gasket (28), from the second fluid flow port (22) to the fifth fluid flow port (25), Alternatively, a heat transfer surface (29B) through which a second liquid, for example, the liquid to be heated B flows, is formed from the fifth fluid communication port (25) toward the second fluid communication port (22). Figure III
In the heat exchange plate (20C) shown in (3), the third fluid flowing port (24) moves toward the third fluid flowing port (23) in the third direction.
Heat transfer surface (29)
Form C). These three types of heat exchange plates (20
A) The plate heat exchanger (30) shown in FIG. 2 (IV) is formed by laminating (20B) and (20C) in a predetermined order with the gaskets (27) and (28) interposed. In the front part (30F) of this heat exchange structure, the second heat exchange plate (2
0B) and the third heat exchange plate (20C) are alternately stacked to form a low-temperature preheating zone by the hot water C. In the latter part (30R) of the heat exchange structure, the first heat exchange plate (20A) and the second heat exchange plate (20B) are alternately laminated, so that the high-temperature heating area by the steam A is increased. Is formed. Corresponding to this laminated structure, the fixed frame (9) has a steam A
Inflow nozzle (31 _IN ), steam A outflow nozzle (31 _IN )
_OUT ), hot water C inflow nozzle (33 _IN ), hot water C outflow nozzle (33 _OUT ), and hot liquid B outlet (3
2 _OUT ), and only the inlet (32 _IN ) for the liquid B to be heated is provided on the moving frame (10) side.

Embodiment 2 FIGS. 3 I, II, and III are front views of a heat exchange plate showing a specific example in which the present invention is applied to a multi-pass knitted heat exchange structure. FIG. 3 IV is a plate after assembly. FIG. 3 is a schematic flow chart of the heat exchanger of the first embodiment. In the following description, the same constituent members as those in FIGS. 1 and 2 are denoted by the same reference numerals, and the description of the same items will be omitted in principle.

In the plate heat exchanger (30) of FIG. 3 IV, a first heat exchange plate (2) having a heat transfer surface (29C) for hot water C is provided.
0C) and a third heat exchange plate (20B) having a heat transfer surface (29B) for the liquid B to be heated are alternately stacked with the gaskets (27) and (28) interposed therebetween to form a two-pass knitting machine. Constitutes the front part (30F) of the plate-type heat exchange structure of
A second heat exchange plate (20C) provided with a heat transfer surface (29a) for hot water C in the second pass, and a third heat exchange plate (20B) provided with a heat transfer surface (29B) for liquid B to be heated. The gasket (2
7) By alternately laminating with the intervention of (28), 2
It constitutes the rear part (30R) of the plate-type heat exchange structure with pass formation. Corresponding to this laminated structure, all the liquid outlets, ie, the hot water C inflow nozzle (33 _IN ), the hot water C outflow nozzle (33 _OUT ), and the flow of the liquid B to be heated, are provided on the fixed frame (9) side. An inlet (32 _IN ) and an outlet (32 _OUT ) for the liquid to be heated B are provided. As a result, a simple multi-pass knitted plate heat exchanger (30) having a piping structure in which the inflow and outflow nozzles and outflow ports of the heat exchange medium are not disposed on the moving frame (10) side is formed. .

Third Embodiment FIGS. 4I and II are front views of a heat exchange plate showing a specific example in which the present invention is applied to a plate heat exchanger using a high-temperature steam having a large specific volume as a heat exchange medium. Fig. 4
III is a schematic flow chart of the plate heat exchanger after assembly.

In the plate heat exchanger (30) in FIG.
The first heat exchange plate (20A) having the heat transfer surface (29A) of the steam A and the second heat exchange plate (20B) having the heat transfer surface (29B) of the liquid to be heated B are formed into an annular shape. Gasket (2
7) and a heat exchange structure is formed by alternately laminating between the fixed frame (9) and the moving frame (10) with the interposition of the loop gasket (28). In the first heat exchange plate (20A), in order to reduce the pressure loss of the steam A having a large specific volume, a second fluid communication port (22) provided at the upper edge of the heat exchange plate (20A). And the third fluid communication port (23) are surrounded by a common loop gasket (28), and these fluid communication ports (22) (2)
Each of 3) is provided on the first frame provided on the fixed frame (9).
Is connected to the second steam inflow nozzle (31 _IN ) and the second steam inflow nozzle ( _31'IN ) so that the cross-sectional area of the inlet-side flow path of the steam A is smaller than the cross-sectional area of the outflow-side flow path. It is set large. Further, a fourth fluid communication port (24) provided at the lower edge of the first heat exchange plate (20A) is used as an outflow path of the steam A whose specific volume has been reduced by condensation. That is, the fourth fluid communication port (24)
Is surrounded by the loop gasket (28), and the fourth fluid communication port (24) is condensed by being connected to a steam outlet nozzle (31 _OUT ) provided in the fixed frame (9). Form a drain outflow channel. As shown in FIGS. 4I and II, when two steam inflow nozzles (31 _IN ) and (31 ′ _IN ) are used in combination, the first heat exchange plate (20A) has The second fluid flow port (22), the third fluid flow port (23), and the fourth fluid flow port (24) at the lower edge are surrounded by a loop-shaped gasket (28), and the heat transfer surface (29A ) Is formed, and this heat transfer surface functions as a flow path of the steam A. Correspondingly, in the second heat exchange plate (20B), the first fluid communication port (21) on the upper edge and the sixth fluid communication port (26) on the lower edge are connected to the loop gasket. The heat transfer surface (29B) is surrounded by (28), and this heat transfer surface (29B) functions as a flow path for the liquid B to be heated. The flow path of the liquid B to be heated is, as shown in FIG. 4 (III), an inlet (32 _IN ) and an outlet (32 _OUT ) provided in the fixed frame (9) of the plate heat exchanger (30).
Are connected in a communication state.

〔The invention's effect〕

The upper and lower edges of the heat exchange plate are independent of each other.
At least one fluid flow port is bored in a pair of upper and lower parts, an annular gasket, and, with the interposition of a loop-shaped gasket, by laminating this heat exchange plate in a predetermined order, the fluid outflow and inlet ports can be formed even in multi-pass knitting. A plate-type heat exchanger is formed in which everything is concentrated on the fixed frame side. Since the plate heat exchanger can eliminate the fluid inlet / outlet nozzle provided on the moving frame side, it has a remarkable effect on simplification of the piping structure and reduction in the number of steps of disassembly and assembly work. Further, since a plate heat exchanger capable of exchanging thermal energy among three or more types of fluids is formed without using a fluid introduction unit such as a partition plate or dividing a number of units, the field of application is A great effect is exhibited also for the expansion of.

[Brief description of the drawings]

FIG. 1 is a front view of a heat exchange plate according to the present invention,
FIG. 2 is a front view showing a specific example of a heat exchange plate, and FIG. 2 is a schematic flow chart of a plate heat exchanger after assembly. FIG. 3 is a front view of a heat exchange plate showing a specific example in which the present invention is applied to a multi-pass knitted heat exchange structure. FIG. 3 is a front view of a plate heat exchanger after assembly. It is a schematic flow path diagram. FIGS. 4I and II are front views of a heat exchange plate showing a specific example in which the present invention is applied to a plate heat exchanger using steam having a large specific volume as a heat exchange medium, and FIGS. It is a schematic flow path diagram of a plate type heat exchange. FIG. 5 is a front view showing a conventional example of a heat exchange plate disposed in a laminated structure between a fixed frame and a moving frame of a plate heat exchanger. 6 to 8 are schematic side views showing a conventional example of a plate heat exchanger. (9) ... fixed frame, (10) ... moving frame,
(20) ... heat exchange plate, (21) (22) (23) (24)
(25) (26): Fluid flow port, (27): Annular gasket, (28): Loop gasket, (30): Plate heat exchanger.

Claims (2)

(57) [Claims] 1. A plate type heat exchanger comprising a plurality of heat exchange plates laminated via a gasket between a fixed frame and a movable frame, wherein the upper and lower edges of the heat exchange plate are respectively provided. Three or more fluid passages are provided, and three or more heat transfer surfaces are formed by selectively surrounding one of the fluid passages at the upper edge and the lower edge of the heat exchange plate. Using a loop-shaped gasket, heat exchange plate with three or more heat transfer surfaces
A plate wherein a number of heat exchange media are heat-exchanged by multi-pass knitting in a multi-layered arrangement, and all fluid inlets and outlets of the two heat exchange media to be heat-exchanged are provided on a fixed frame side. Type heat exchanger. 2. A plate heat exchanger comprising a plurality of heat exchange plates stacked and arranged between a fixed frame and a moving frame via a gasket, wherein an upper edge portion and a lower edge portion of the heat exchange plate are respectively provided. Three or more fluid communication ports are provided, and the two or more fluid communication ports at the upper edge of the heat exchange plate and one of the fluid communication ports at the lower edge are surrounded by a steam having a large volume change before and after the heat exchange action. And a heat exchanger having a small volume change before and after the heat exchanging operation by surrounding one of the fluid flow ports at the upper edge and the lower edge of the heat exchange plate. A loop-shaped gasket forming a heat transfer surface of the exchange medium is used, and a large number of heat exchange plates having the two heat transfer surfaces are stacked and arranged to form a group of heat exchange plate assemblies. All fluids in and out of the heat exchange medium A plate type heat exchanger characterized in that the mouth is provided on the fixed frame side.