JP2504965Y2 - Plate type heat exchanger - Google Patents

Description

[Detailed description of the device]

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plate-type heat exchanger, and more particularly to a measure for preventing refrigerant drift.

[0002]

2. Description of the Related Art Conventionally , as a heat exchanger used as an outdoor unit of an air conditioner, for example , an actual Kaihei 2-1335.
A plate type is known as disclosed in Japanese Patent Publication No. 68 and “JIS Industrial Dictionary” , page 971 .

The structure will be described by taking the latter as an example.
In this plate heat exchanger, a plurality of heat transfer plates are arranged side by side with a gasket sandwiched therebetween, a plurality of small spaces are formed between these heat transfer plates, and the plurality of small spaces are alternated by the gasket. And two fluid passages that are alternately adjacent to each other are formed, and a fluid introduction pipe and a fluid discharge pipe that communicate with each fluid passage are arranged .

During operation of the air conditioner, high-temperature and low-temperature heat exchange fluids are circulated from the fluid introduction pipe to the respective fluid passages to cause heat exchange between the two fluids, and after this heat exchange is performed. The respective fluids are discharged from the fluid outlet pipe to the outside of the heat exchanger. In such a conventional plate-type heat exchanger, fluids that do not change phases together are used as fluids that flow through the fluid passages.

[0005]

By the way, in recent years, a plate type heat exchanger has been developed in which one of the fluid passages is made to pass a refrigerant having a gas-liquid phase change. However, in this case, since the liquid refrigerant and the gas refrigerant have different densities, the liquid refrigerant having a high density easily gathers in the inner part of the refrigerant passage,
There is a problem in that the gas refrigerant having a low density tends to gather near the inlet to cause a nonuniform flow, resulting in a decrease in heat exchange efficiency.

[0006] Therefore, it is conceivable to use a refrigerant introduction pipe having a large diameter and a long pipe length as the refrigerant introduction pipe communicating with the refrigerant passage to weaken the flow velocity of the refrigerant and prevent the uneven flow thereof. Since the introduction pipe is thick and long, it is uneconomical to secure a wide installation place.

The present invention has been made in view of the above points, and an object thereof is to make the refrigerant introduction pipe thin and short by changing the flow direction of the refrigerant at a stage before introducing it into the refrigerant passage. Even if there is, it is to try to improve the heat exchange efficiency by uniformly mixing the liquid refrigerant and the gas refrigerant to prevent uneven flow. Furthermore, it is intended to make the installation space small by making the refrigerant introduction pipe thin and short.

[0008]

In order to achieve the above-mentioned object, the solution means of the invention according to claim 1 is, as shown in FIG. 1, a plurality of heat transfer plates arranged in parallel at a predetermined interval. (6), (6), ... And the heat transfer plate (6),
A plurality of liquid branch passages (8), (8), ... Which are composed of heat transfer plates (6), (6) adjacent to each other (6), ... The heat transfer plates (6) adjacent to the heat plates (6), (6), ...
(6) Refrigerant branch passages (9), (9), ... Which are configured to be alternately arranged with the respective liquid branch passages (8) and through which the phase-change refrigerant (R) flows, and the respective liquid branch passages. A liquid collecting passage (10) and a refrigerant collecting passage (11) respectively connected to (8) and the refrigerant branch passage (9),
A plate type heat exchanger having a liquid introduction pipe (13) and a refrigerant introduction pipe (15) connected to the liquid collection passage (10) and the refrigerant collection passage (11), respectively.
I have.

[0009] Then, the refrigerant introducing pipe (15), the first introduction pipe portion connected to the coolant manifolds (11) (17)
And a second introduction pipe part (18) connected to the first introduction pipe part (17) and having an introduction hole center line intersecting with that of the first introduction pipe part (17) . Furthermore, on
The refrigerant introduction pipe (15) has a first introduction pipe portion (1
7) is connected to the upstream side of the first introduction pipe section (1
A bypass passage (30) is provided which is connected to 7) and in which the end portion is arranged so that the discharge direction of the refrigerant (R) at the end is directed to the refrigerant collecting passage (11) .

In addition, a valve means (33) for opening and closing the bypass passage (30), a temperature detecting means (40) for detecting the outside air temperature, and a temperature detection signal from the temperature detecting means (40), Control means (4) for opening the valve means (33) when the outside air temperature falls below a predetermined set value.
1) and are provided .

Further , the solution means of the invention according to claim 2 is
As shown in FIG. 6 , in the refrigerant introducing pipe (15), the starting end is connected to the upstream side of the first introducing pipe portion (17) and the terminating end is the first end.
Refrigerant (R) at the end connected to the introduction pipe part (17)
Is provided with a bypass passage (30) in which the end portion is arranged so that the discharge direction of the refrigerant is directed to the refrigerant collecting passage (11).
I have.

Further , a valve means (33) for opening and closing the bypass passage (30), a pressure detecting means (42) for detecting the pressure of the refrigerant (R), and a pressure detection signal from the pressure detecting means (42). In response to this, there is provided a control means (41) for opening the valve means (33) when the pressure of the refrigerant (R) becomes less than a predetermined set value.

[0013]

With the above construction, in the device according to claim 1,
When the refrigerant (R) moves from the second introduction pipe part (18) whose introduction hole center line intersects with that of the first introduction pipe part (17) to the first introduction pipe part (17), 1 introduction pipe part (1
7) It collides with the inner wall of the connection part with it, and is then introduced into the refrigerant collecting passageway (11) through the first introduction pipe part (17),
It is distributed to each refrigerant branch passage (9).

Therefore, before the liquid refrigerant and the gas refrigerant are introduced into the respective refrigerant collecting passages (11), the first introduction pipe portion (17) and the second introduction pipe portion (18) are connected to each other. uniformly mixed by the collision at the junction, is prevented drift of the refrigerant (R) is the improvement in heat exchange efficiency is achieved.

Since the shape of the refrigerant introduction pipe (15) is specified by the first and second introduction pipe portions (17) and (18) as described above, in order to prevent the uneven flow of the refrigerant (R). It is not necessary to use a long refrigerant introduction pipe (15), and the installation space can be reduced.

Further, the refrigerant circulation amount may decrease when the outside air temperature decreases. When the refrigerant circulation amount decreases, the flow velocity toward the refrigerant collecting passageway (11) decreases,
Refrigerant (R) only up to the inlet of the refrigerant collecting passageway (11)
Does not reach and the refrigerant (R) does not flow to the inner part.

[0017] Therefore, when the outside air temperature detected by the temperature detection means (40) is less than the predetermined set value, the control means (41) is a valve means for opening and closing the bypass passage (30) and (33) The opening operation is performed, and the refrigerant (R) is discharged from the bypass passage (30) into the refrigerant collecting passage (11) in addition to the second introduction pipe portion (18). That is, the refrigerant circulation amount in the refrigerant circuit decreases due to the decrease in the outside air temperature, and as a result, the refrigerant (R) in the first introduction pipe portion (17) or the refrigerant collecting passageway (11).
Only when the flow velocity of is decreased, the flow velocity component toward the inside of the refrigerant collecting passageway (11) is increased .

Therefore, since the flow velocity of the refrigerant (R) is corrected to an appropriate value, the refrigerant (R) flows into the inner part of the refrigerant collecting passage (11), and the refrigerant branch passage ( The refrigerant (R) always flows through 9).

[0019] In the invention according to claim 2, when the pressure of the cooling medium detected (R) is less than a predetermined set value by the refrigerant circulation amount of the refrigerant circuit is reduced by the pressure detecting means (42) The control means (43) opens the valve means (33) for opening and closing the bypass passage (30) to open the bypass passage (30) in addition to the second introduction pipe section (18).
The refrigerant (R) is discharged from the inside into the refrigerant collecting passageway (11) .

Therefore, due to the reduction of the circulation amount of the refrigerant (R), the first introducing pipe portion (17) or the refrigerant collecting passage (1)
The speed is increased only when the flow rate of the refrigerant (R) of 1) decreases,
Correct the flow velocity to a proper value. As a result, the refrigerant (R) flows into the inside of the refrigerant collecting passage (11), and the refrigerant (R) always flows through the refrigerant branch passage (9) located in the inside.

[0021]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 2 shows a plate heat exchanger according to the first embodiment of the present invention. (1) is an outer frame composed of a fixed frame (2) and a moving frame (3), and a plurality of outer frames are provided between the fixed frame (2) and the moving frame (3) of the outer frame (1). The heat transfer plates (6), (6), ... Are arranged side by side at a predetermined interval .

As shown in FIG. 3, each heat transfer plate (6) is formed of a substantially rectangular metal thin plate having corrosion resistance, and a heat exchange area is enlarged in a portion excluding upper and lower end portions. Herringbone protrusions (6a) are formed by pressing.

Further, four flow holes (6b), (6b), (6c), (6c) through which fluid flows are provided at the left and right corners of the upper end and the lower end of each heat transfer plate (6). Formed, the flow holes (6b) at the lower left corner and the upper right corner,
(6b) is for the liquid (W) such as water to flow, and the flow holes (6c) at the lower right corner and the upper left corner,
(6c) is for flowing the refrigerant (R) in which the liquid refrigerant and the gas refrigerant are mixed .

As shown in FIG. 1, the heat transfer plates (6) are arranged in parallel at a predetermined interval, and the heat transfer plates (6), (6), ... Adjacent to each other. A plurality of liquid branch passages (8), (8), ... Through which the liquid (W) that does not change phase due to (6) and (6) flows are arranged alternately. In addition, the heat transfer plate (6),
Refrigerant branch passages (9) through which the refrigerant (R) whose phase changes by the heat transfer plates (6), (6) adjacent to each other (6), ...
.. are alternately arranged so as to be alternately arranged with the respective liquid branch passages (8).

Further, in the liquid branch passages (8) and the refrigerant branch passages (9), the flow holes (6b), (6) are provided.
The liquid collecting passage (10) and the refrigerant collecting passage (11) configured in (c) are connected to each other.

[0027] left and right corners of the upper and lower ends of the fixed frame (2), the communicating hole (12), (12), ...
Are the above-mentioned flow holes (6b), (6b), (6c), (6c)
The liquid introduction pipe (13) is connected to the flow hole (6b) at the upper right corner, and the liquid outlet pipe (14) is connected to the flow hole (6b) at the lower left corner. The liquid inlet pipe (13) and the liquid outlet pipe (14) are connected to the liquid collecting passages (10) by the flow holes (6b) .

A refrigerant introduction pipe (15) is provided in the flow hole (6c) at the lower right corner of the fixed frame (2), and a refrigerant outlet pipe (16) is provided in the flow hole (6c) at the upper left corner. The refrigerant inlet pipe (15) and the refrigerant outlet pipe (16) are connected to each other, and are connected to the respective refrigerant collecting passages (11) through the flow holes (6c).

Further, as one of the features of the invention according to claim 1, the refrigerant introducing pipe (15) is provided with a refrigerant collecting passage (1).
1) is provided with a large-diameter first introduction pipe part (17) ,
The first introduction pipe part (17) is connected to a small diameter second introduction pipe part (18) whose introduction hole center line changes its angle at right angles to that of the first introduction pipe part (17) and intersects from above. Has been done. Further, a refrigerant supply pipe (not shown) for supplying the refrigerant (R) is provided to the second introduction pipe part (18), and a space between the heat transfer plates (6) and (6) is provided to the refrigerant discharge pipe (16). Discharge pipes (not shown) for discharging the refrigerant (R) that has circulated through the upper side refrigerant collecting passageway (11) are respectively connected .

In FIG. 1, (19) is a liquid introducing pipe (1
3) is a liquid supply pipe connected to
0), (20), ... Are meters for measuring the inflow pressure and the outflow pressure and the temperature of the liquid (W) and the refrigerant (R).

On the other hand , when the outside air temperature drops, the refrigerant circulation amount may decrease. When the refrigerant circulation amount decreases, the flow velocity toward the refrigerant collecting passageway (11) decreases,
Refrigerant (R) only up to the inlet of the refrigerant collecting passageway (11)
Does not reach, and the refrigerant (R) does not flow to the inner part. Therefore, the circulation of the refrigerant (R) is concentrated in the refrigerant branch passage (9) located near the inlet of the refrigerant collecting passage (11), and the refrigerant (R) is contained in the refrigerant branch passage (9) located in the inner part. distribution to
Instead, drift will occur .

Therefore, one of the features of the invention according to claim 1
As a result, in the present embodiment, when the refrigerant circulation amount is small, the refrigerant (R) is shunted from the refrigerant circuit and discharged into the first introduction pipe portion (17), and the inside of the first introduction pipe portion (17) is discharged. It is to try to give the velocity components directed toward the refrigerant collection path (11) to the flow of the refrigerant (R).

Specifically, the refrigerant introduction pipe (15) is
Bypass passage (30) is provided. This bypass ((3
0), the inflow port (31) at the start end is the second introduction pipe part (18)
And a terminal discharge port (32) is provided in the first introduction pipe part (17). Furthermore , the bypass path (3
In 0), a horizontally formed branching portion (30a), a vertical pipe portion (30b), and a horizontally formed merging portion (30c) as a terminal portion are sequentially connected, and have a substantially U-shape. It is configured. The discharge direction of the discharge port (32) of the merging portion (30c) is directed to the refrigerant collecting passageway (11). The bypass passage (30) is provided with an opening / closing valve as valve means.
(33) is provided.

The discharge direction of the discharge port (32) is as follows.
It suffices that the refrigerant (R) is directed to at least the refrigerant collecting passageway (11), and in order to make it easier for the refrigerant (R) to flow into the inner part of the refrigerant collecting passageway (11), the communication port of the refrigerant collecting passageway (11) ( It is preferable that it is directed to the inside of 12), and more preferably it is coincident with the center line of the communication port (12).

Further, a temperature sensor (40) as a temperature detecting means for detecting the outside air temperature Th is provided . That
Te, the detection signal from the temperature sensor (40) is input to the control means in the controller (43) (41), the bypass passage by the control means (41) off valve (30) (3
The operation of 3) is controlled.

Next, a description will be based on the opening and closing control of the bypass passage (30) in the flow chart of FIG.

First, in step S1, the outside air temperature Th input from the temperature sensor (40) is a predetermined lower limit value α1.
It is determined whether the temperature is lower than (for example, 0 ° C.). Then, when the outside air temperature Th is equal to or higher than the predetermined lower limit value α1, the determination is repeated by waiting in step S1 .

On the other hand, the outside air temperature Th is a predetermined set value α.
Less than 1 when the process proceeds to step S2, reduces the amount of circulating refrigerant, the on-off valve determines the drift such as Figure 1 has occurred
(33) is opened to flow the refrigerant (R) through the bypass passage (30), and the process proceeds to step S3. Then, the refrigerant flow through the bus <br/> bypass passage (30) (R) is discharged toward the refrigerant collection path (11), as shown in FIG. 4, the back flow of the refrigerant (R) from the entrance Make even the parts.

Further , in step S3, after the outside air temperature Th has recovered to a predetermined lower limit value α1, it further rises, and it is determined whether the outside air temperature Th is above a predetermined upper limit value α2 (for example, 2 ° C.). When the outside air temperature Th becomes less than the predetermined upper limit value α2, the process stands by in step S3 and the determination is repeated. Outside temperature T
When h becomes equal to or greater than the predetermined upper limit value α2, the process proceeds to step S4, it is determined that the refrigerant circulation amount is recovered, the on-off valve (33) is closed, the bypass passage (30) is closed, and the step S4 is performed.
Return to 1.

In step S2 of the above flow chart, when the refrigerant (R) flows through the bypass passage (30), the refrigerant (R) flows from the discharge port (32) at the end of the bypass passage (30) into the refrigerant collecting passage (11). It is discharged toward. Due to the jet flow from the discharge port (32), the first introduction pipe portion (1
7) Of the flow of the refrigerant (R) in the refrigerant collecting passage (1
The flow velocity component toward 1) increases. Therefore, as shown in FIG. 4 , the refrigerant (R) flows into the inside of the refrigerant collecting passage (11), and the refrigerant branch passage (9) located in the inside thereof.
The refrigerant (R) circulates through.

As described above, according to this embodiment, the refrigerant
(R) is the second introduction pipe portion (18) of the refrigerant introduction pipe (15)
The first introduction pipe part (17) when flowing from the first introduction pipe part (17)
After colliding with the inner wall of the connection part with (17), the first introduction
After flowing into the refrigerant collecting passageway (11) through the pipe section (17),
It is distributed to the refrigerant branch passage (9). Therefore, liquid refrigerant
And the gas refrigerant are introduced into the refrigerant collecting passage (11).
In the stage, the first introduction pipe part (17) and the second introduction pipe part
Collide with the inner wall of the joint with (18) and mix evenly.
It is possible to prevent uneven flow of the refrigerant (R).
The heat exchange efficiency can be improved.

In the refrigerant introduction pipe (15), liquid refrigerant
Mixing with gas refrigerant prevents refrigerant (R) from drifting
To use a long refrigerant introduction pipe (15),
The installation space can be reduced.

[0043] Moreover, start end connected to the second inlet pipe portion (18), terminating the said first inlet pipe portion and the bypass passage provided in the (17) (30) is provided, the controller (43) is a temperature sensor When the outside air temperature Th detected by (40) becomes less than the predetermined lower limit value α1, the control means (41) opens the on-off valve (33) to open the second introduction pipe section (18). The refrigerant (R) is discharged from the bypass passage (30) toward the refrigerant collecting passage (11) .

Therefore, the refrigerant circulation amount in the refrigerant circuit decreases due to the decrease of the outside air temperature Th, and as a result, the refrigerant collecting passage ((R) does not reach the inner part of the refrigerant collecting passage (11). 11) The flow velocity component of the refrigerant (R) flowing inward can be increased, and the flow velocity can always be corrected and maintained at an appropriate value. As a result, as shown in FIG. 4 , the refrigerant (R) is caused to flow into the inner part of the refrigerant collecting passage (11), and the refrigerant (R) is always distributed and distributed in the refrigerant branch passage (9) located in the inner part. It is possible to prevent the heat exchange efficiency from decreasing.

In this embodiment, the heat transfer plate
(6) with herringbone protrusions (6a) formed
However, the shape is not limited to this, and a corrugated protrusion or the like
It may be made.

Further , the second introduction pipe portion (18) is connected to the first guide pipe.
I tried to cross the inlet (17) at a right angle,
Not limited to this, the refrigerant (R) may be collided with the inner wall of the connection part between the two.
If the angle is such that the liquid refrigerant and the gas refrigerant can be mixed uniformly
Good.

Second Embodiment FIGS. 6 and 7 show a second embodiment of opening / closing control of the bypass path (30) . In this embodiment, the pressure of the low-pressure refrigerant is used to detect the decrease in the refrigerant circulation amount. That is, step S in FIG. 5 of the first embodiment.
Instead of 1 and S3, steps S5 and S6 are provided. In FIG. 7 , the other steps are the same as those in FIG. 5 , so the same step numbers are used.

As shown in FIG. 6 , the first introducing pipe portion (17)
A pressure sensor (42) as a pressure detecting means is attached to the. Then, the inflow pressure signal from the pressure sensor (42) is input to the controller (43) of the control means (41), operation of the on-off valve of the bypass passage (30) by the control means (41) (33) Is controlled.

Next, description will be based on the opening and closing control of the bypass passage (30) in the flow chart of FIG.

First, at step S5, the inflow pressure PL input from the pressure sensor (42) is a predetermined lower limit value β.
Determine if it is less than 1 (eg 2.5 kg / cm ² G). Then, when the inflow pressure PL becomes equal to or higher than the predetermined lower limit value β1, the process stands by in step S5 and the determination is repeated. When the inflow pressure PL becomes less than the predetermined set value β1, the process proceeds to step S2,
When it is determined that the refrigerant circulation amount has decreased, the on-off valve (33) is opened, the refrigerant (R) is circulated through the bypass passage (30), and the process proceeds to step S6.

In step S6, the inflow pressure PL is the lower limit value β.
After recovering to 1, when it further increases, it is determined whether or not the inflow pressure PL is equal to or higher than a predetermined upper limit value β 2 (for example, 3.5 kg / cm ² G). When the inflow pressure PL becomes less than the predetermined upper limit value β2, the process waits at step S6 to repeat the determination. Inflow pressure
When PL becomes equal to or higher than the predetermined upper limit value β2, the process proceeds to step S4, it is determined that the refrigerant circulation amount is recovered, the on-off valve (33) is closed, the bypass passage (30) is closed, and step S4 is performed.
Return to 5.

In step S2 of the above flow chart, when the refrigerant (R) flows through the bypass passage (30), the refrigerant (R) flows from the discharge port (32) into the refrigerant collecting passage (11).
Is discharged toward. Therefore, the refrigerant collecting passage (11)
(R) flows into the inner part of the refrigerant, and the refrigerant (R) flows through the refrigerant branch passage (9) located in the inner part.

[0053] Thus, the refrigerant the inflow pressure PL (R)
As described above, the condition for detecting the decrease in the flow velocity is that the flow pressure of the refrigerant (R) in the refrigerant collecting passage (11) decreases as the refrigerant circulation amount decreases. This is because the flow velocity becomes small.

According to this embodiment, the control means (41)
Is the inflow pressure PL detected by the pressure sensor (42)
Is less than the predetermined lower limit value β1, the control means (4
1) causes the on-off valve (33) to open, and the refrigerant collecting passage (1
1) The refrigerant (R) is discharged into the inside. Therefore, the refrigerant (R) can be reached only when the refrigerant (R) does not reach the inner part of the refrigerant collecting passage (11) because the amount of refrigerant circulation in the refrigerant circuit has decreased.
Can be increased, and the flow rate of the refrigerant (R) can always be corrected and maintained at an appropriate value. As a result ,
The same effect as that of the first embodiment can be exhibited. That
Other configurations, operations, and effects are similar to those of the first embodiment.

In each of the above embodiments, the bypass path (3
The starting end of (0) was connected to the second introducing pipe part (18), but the starting end is not limited to this position, and the first introducing pipe part (1)
7) It may be connected to any position as long as it is on the upstream side of the refrigerant circuit.

[0056]

As described above, according to the first aspect of the invention, in the plate heat exchanger using the refrigerant (R), the refrigerant introduction pipe (15) is connected to the adjacent heat transfer plates (6). ), (6), a first introduction pipe portion (17) connected to the refrigerant collecting passageway (11) communicating with each refrigerant branch passageway (9),
The first introduction pipe part (17) is connected to the first introduction pipe part (17) and the center line of the introduction hole is constituted by the second introduction pipe part (18) intersecting with that of the first introduction pipe part (17). Pipe (1
7) Collision of the refrigerant (R) with the inner wall of the connecting portion between the second introduction pipe part (18) and the second introduction pipe part (18) to uniformly mix the liquid refrigerant and the gas refrigerant to prevent uneven flow and improve heat exchange efficiency. In addition, since it is not necessary to use the long refrigerant introduction pipe (15), it is possible to reduce the installation space.

[0057] Moreover, start end connected first inlet pipe portion from (17) on the upstream side, end is connected to said first inlet pipe portion (17), the discharge direction coolant manifolds of the refrigerant (R) at the end A bypass passage (30) having a terminal portion arranged so as to be directed to (11) is provided. Then, the control means (41) causes the valve means (33) to open when the outside air temperature detected by the temperature detection means (40) becomes less than a predetermined set value, and the refrigerant is cooled. Since the refrigerant (R) is discharged toward the collecting passage (11), the flow velocity of the refrigerant (R) can always be corrected to an appropriate value. Therefore, the refrigerant (R) can be made to flow into the inside of the refrigerant collecting passage (11), and the refrigerant (R) can be always distributed and distributed in the refrigerant branch passage (9) located in the inside.
It is possible to prevent a decrease in heat exchange efficiency.

In the invention according to claim 2 , the control means (41) includes the temperature detecting means (4) according to the invention according to claim 1.
0) instead of the control means (4) when the pressure detected by the pressure detection means (42) becomes less than a predetermined set value.
1) is opening operation of the valve means (33), since the discharged refrigerant (R) toward the refrigerant collection path (11), according to claim 1
It is possible to exert the same effect as the invention according to.

[Brief description of drawings]

FIG. 1 is a side view showing a first embodiment of the plate heat exchanger with a part thereof cut away.

FIG. 2 is a perspective view of a plate heat exchanger according to the first embodiment.

FIG. 3 is a front view of the heat transfer plate according to the first embodiment.

FIG. 4 is a side view of the plate heat exchanger showing the flow of the refrigerant when the bypass passage is in the open state according to the first embodiment.

FIG. 5 is a flowchart showing the first embodiment and showing the opening / closing control of the bypass path.

FIG. 6 is a side view of the plate heat exchanger according to the second embodiment.

FIG. 7 is a flowchart showing the second embodiment and showing the opening / closing control of the bypass path.

[Explanation of symbols]

6 Heat Transfer Plate 8 Liquid Branch Passage 9 Refrigerant Branch Passage 10 Liquid Collecting Passage 11 Refrigerant Collecting Passage 13 Liquid Introducing Pipe 15 Refrigerant Introducing Pipe 17 First Introducing Pipe Section 18 Second Introducing Pipe Section 30 Bypass Path 33 Open / Close Valve (Valve Means) 40 temperature sensor (temperature detection means) 42 pressure sensor (pressure detection means) 43 control means R refrigerant W liquid

Claims (2)

(57) [Scope of utility model registration request] 1. A plurality of heat transfer plates (6), (6), ... Arranged side by side at a predetermined interval, and heat transfer plates adjacent to each other (6), (6) ,. A plurality of liquid branch passages (8), (8), ... Comprised of plates (6), (6), through which a liquid (W) that does not change phase flows.
And the respective liquid branch passages (8) by the heat transfer plates (6), (6) adjacent to the heat transfer plates (6), (6) ,.
, And the refrigerant branch passages (9), (9), ... In which the phase-change refrigerant (R) flows, and the liquid branch passages (8) and the refrigerant branch passages (9), respectively. A liquid collecting passage (10) and a refrigerant collecting passage (11) connected to each other, and a liquid introducing pipe (13) and a refrigerant introducing pipe (15) connected to the liquid collecting passage (10) and the refrigerant collecting passage (11), respectively. A plate type heat exchanger comprising: a first introduction pipe part (17) connected to the refrigerant collecting passageway (11); and a first introduction pipe part (15). 17) and a second introduction pipe part (18) whose introduction hole center line intersects with that of the first introduction pipe part (17) and a start end of which is connected to the upstream side of the first introduction pipe part (17). And the end is connected to the first introduction pipe section (17), and the refrigerant at the end is Valve means discharging direction R) to open and close the bypass passage terminal end, which are arranged to direct the coolant manifolds (11) and (30), the bypass passage (30) (33)
And a temperature detection means (40) for detecting the outside air temperature, and a temperature detection signal from the temperature detection means (40). When the outside air temperature falls below a predetermined set value, the valve means (33) is opened. A plate heat exchanger comprising: a control means (41) for operating the plate heat exchanger. 2. A plurality of heat transfer plates (6), (6), ... Arranged in parallel at a predetermined interval, and the heat transfer plates (6), (6) ,. A plurality of liquid branch passages (8), (8), ... Comprised of plates (6), (6), through which a liquid (W) that does not change phase flows.
And the respective liquid branch passages (8) by the heat transfer plates (6), (6) adjacent to the heat transfer plates (6), (6) ,.
, And the refrigerant branch passages (9), (9), ... In which the phase-change refrigerant (R) flows, and the liquid branch passages (8) and the refrigerant branch passages (9), respectively. A liquid collecting passage (10) and a refrigerant collecting passage (11) connected to each other, and a liquid introducing pipe (13) and a refrigerant introducing pipe (15) connected to the liquid collecting passage (10) and the refrigerant collecting passage (11), respectively. A plate type heat exchanger comprising: a first introduction pipe part (17) connected to the refrigerant collecting passageway (11); and a first introduction pipe part (15). 17) and a second introduction pipe part (18) whose introduction hole center line intersects with that of the first introduction pipe part (17) and a start end of which is connected to the upstream side of the first introduction pipe part (17). And the end is connected to the first introduction pipe section (17), and the refrigerant at the end is Valve means discharging direction R) to open and close the bypass passage terminal end, which are arranged to direct the coolant manifolds (11) and (30), the bypass passage (30) (33)
And a pressure detection means (42) for detecting the pressure of the refrigerant (R) and a pressure detection signal from the pressure detection means (42), when the pressure of the refrigerant (R) becomes less than a predetermined set value. Control means (41) for opening the valve means (33)
And a plate heat exchanger.