JPH0387547A - Defrosting method for packaged air conditioner - Google Patents

Abstract

PURPOSE:To defrost during heating operation by a method wherein total heat exchangers are stopped, a damper is closed, and the returned gas heat exchanger is defrosted by a heat of the discharged gas. CONSTITUTION:Upon defrosting mode, a second damper 22 is closed and at the same time a first damper 20 is opened. Total heat exchangers 28 are stopped. Accordingly, returned air taken from a return port 24 into a return passage 16 is not heat exchanged at the total heat exchangers 28, but supplied to a return gas heat exchanger 32 under a relative high temperature condition. As a high temperature return gas is supplied to the returned gas heat exchanger 32, frost generated in the returned gas heat exchanger 32 is eliminated and removed. A surplus returned gas passes through the first damper 20 and is returned to an air supplying passage 18. It is mixed with the surrounding atmosphere taken from a surrounding air port 38, heated by a supplied air heat exchanger 48 and again it passes through a gas supplying port 42 and it is supplied to a room. Accordingly, even in case of a defrosting mode, a thermal recovery of the returned gas to be discharged is carried out while defrosting the returned gas heat exchanger 32.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a defrosting method for a package air conditioner, and in particular to a defrosting method for a package air conditioner that defrosts a return air heat exchanger in an outside air processing type package air conditioner. Regarding the method.

[Prior art]

During heating, frost in the return air heat exchanger of a package air conditioner has conventionally been removed by temporarily operating the heat pump in reverse cycle. That is, the dirty return air during heating is exhausted, but the heat of the return air is recovered by the total heat exchanger and the return air heat exchanger. The heat recovered by the return air heat exchanger is then used to warm the outside air taken in from outside for supply air through the supply air heat exchanger. However, if frost forms on the return air heat exchanger, the heat recovery rate of the return air will decrease, so the frost on the return air heat exchanger must be removed periodically. is removed by operating the heat pump in reverse cycle, ie, in cooling mode.

Another hot gas bypass method involves supplying a portion of the warmed supply air for space heating to a return air heat exchanger.
The frost is removed.

[Problem to be solved by the invention]

In the method of removing frost by reverse-cycle operation of a heat pump, there is a problem that cooling operation must be performed temporarily even during heating to remove frost, which reduces heating efficiency.

On the other hand, in the hot gas bypass method, a portion of the warmed supply air must be supplied to the return air heat exchanger for heating, so heating efficiency similarly decreased during defrosting due to heat loss.

Therefore, the main object of the present invention is to provide a defrosting method for a package air conditioner that can defrost during heating without reducing heating efficiency.

(Means for Solving the Problems) In the present invention, when in heating mode, return air is heat exchanged with a total heat exchanger, further heat exchanged with the return air heat exchanger, and the return air heat is exchanged with the total heat exchanger. In a package air conditioner that exhausts outside air together with the outside air taken in through a damper installed between the exchangers, when in defrost mode, the total heat exchanger is stopped, the damper is closed, and the heat of the exhaust air is used to exchange heat with the return air. This is a defrosting method for packaged air conditioners that defrosts the container.

[Effect]

During heating, when the defrosting mode is entered, the total heat exchanger is stopped and the damper is closed. therefore,
In the heating mode, the outside air that was supplied through the damper is no longer supplied to the return air heat exchanger. On the other hand, when the total heat exchanger is stopped, heat exchange of return air is no longer performed in the total heat exchanger. Therefore, the return air heat exchanger is supplied with relatively high temperature exhaust gas. Therefore, frost generated in the return air heat exchanger is removed by the high-temperature exhaust gas.

〔Effect of the invention〕

According to this invention, even in the defrosting mode during heating, there is no need to operate the heat pump in reverse cycle as in the past, and there is no need to supply part of the warmed supply air to the return air heat exchanger. Therefore, even if you enter defrost mode during heating,
The heating efficiency does not decrease.In other words, the total heat exchanger is stopped and relatively high temperature return air is supplied to the return air heat exchanger to remove frost. Heat can also be recovered, making it extremely efficient overall.

The main object, other objects, features, and advantages of the present invention will become more apparent from the following detailed description of embodiments with reference to the drawings.

〔Example〕

FIG. 2 is an illustrative view showing a package air conditioner according to an embodiment of the present invention. The package air conditioner IO includes a casing 12, and the casing 12 is formed with a partition wall 14 that divides the space into upper and lower halves. A return air passage 16 is formed on the upper side of the partition wall 14, and an air supply passage 18 is formed on the lower side.

In the middle of the bulkhead construction 4, a return air passage 16 and an air supply passage 18 are provided.
A first damper 20 and a second damper 22 are provided which communicate with each other in an openable and closable manner. In addition, in FIG. 2, the first damper 2
0 is shown closed, and the second damper 22 is shown opened.

A return air port 24 is provided at the left end of the return air passage 16. A return air fan 26 is arranged on the right side of the return air port 24.

Therefore, when the return air fan 26 is driven, the air in the room where the package air conditioner IO is installed flows into the return air path 16 as return air.

A total heat exchanger 28 is disposed between the first damper 20 and the second damper 22, penetrating the partition wall 14 and spanning the return air passage 16 and the supply air passage 18. Return air path 1 of the total heat exchanger 28
A filter 30 is provided on the left surface of the 6 side. Therefore, dust is removed from the return air sucked into the return air path 16 by the filter 30, and heat is exchanged by the total heat exchanger 28.

During heating, the heat of the return air is recovered by the total heat exchanger 28, and during cooling, the heat of the total heat exchanger 28 is carried away by the return air.

A return air heat exchanger 32 is arranged on the right side of the second damper 22 in the return air passage 16 . This return air heat exchanger 32 is provided to more effectively recover return air heat even after the first stage heat exchange is completed by driving the total heat exchanger 28.

An exhaust fan 34 is arranged on the right side of the return air heat exchanger 32. An exhaust port 36 is provided at the front of the exhaust fan 34, that is, at the right end of the return air passage 16. Therefore, when the exhaust fan 34 is driven, the return air that has flowed into the return air path 16 by the return air fan 26 is also sucked by the exhaust fan 34. That is, the movement of the return air from the left side to the right side is promoted, and the return air that has undergone heat exchange in the return air heat exchanger 32 is discharged to the outside from the exhaust port 36.

An outside air port 38 is provided below the exhaust port 36, that is, at the right end of the air supply path 18. A filter 40 is fitted into the outside air port 3.

On the other hand, an air supply port 42 is provided at the left end of the air supply path 18. An air supply fan 44 is located on the right side of the air supply port 42.
is placed. Therefore, when the air supply fan 44 is driven, the air supply is discharged into the room from the air supply port 42. Accordingly, a negative pressure is generated in the air supply path 18, and the negative pressure causes outside air to flow in from the outside air port 38.

The outside air taken into the air supply path 18 first undergoes heat exchange in the total heat exchanger 28. This heat exchange involves heating the outside air by the total heat exchanger 28 during heating, and cooling the outside air during cooling.

Note that a part of the outside air taken into the supply air passage 18 is passed through the second damper 22, which is opened as necessary, to the return air passage 16.
Also supplied.

The outside air that has undergone heat exchange in the total heat exchanger 28 has already had large dust particles removed by a filter 40, and fine dust particles are also removed by a filter 46. Then, the outside air is made high or low temperature by the supply air heat exchanger 48.

The supply air heat exchanger 48 and the return air heat exchanger 32 are connected by a pipe and constitute a heat pump. The flow direction of the heat exchange fluid circulating through the supply air heat exchanger 48 and return air heat exchanger 32 depends on heating or cooling.
This is changed by the gate valve 50. Therefore, this packaged air conditioner 10 can perform both heating and cooling. The heat exchange fluid is compressed by compressor 52.

The outside air warmed or cooled by the supply air heat exchanger 48 is supplied into the room from the air supply port 42 as supply air.

In the heating mode, airflow flows in the direction of the arrow indicated by the two-dot chain line in FIG. The return air taken into the return air path 16 from the return air port 24 is first heat exchanged in the total heat exchanger 28, and the heat is recovered. This recovered heat is transferred to the outside air port 3.
It is used to warm the outside air taken into the air supply path 18 from the air supply path 8.

The return air that has passed through the total heat exchanger and exchanger 28 is also heat exchanged in the return air heat exchanger 32, and further heat is recovered. Then, the dirty indoor air, that is, the return air, is diluted with the outside air taken in from the second damper 22, and is discharged to the outside from the exhaust port 36.

The heat recovered in the return air heat exchanger 32 is used to warm the outside air supplied as supply air in the supply air heat exchanger 4. The warmed outside air is then supplied into the room from the air supply port 42 as air supply.

When the defrosting mode is entered during heating, as shown in FIG. 1, the second damper 22 is closed and the first damper 20 is opened. Then, the total heat exchanger 28 is stopped. Therefore, the return air taken into the return air passage 16 from the return air port 24 flows in the direction of the arrow shown by the two-dot chain line, and is kept at a relatively high temperature without undergoing heat exchange in the total heat exchanger 28. It is supplied to the heat exchanger 32. When the high-temperature return air is supplied to the return air heat exchanger 32, the frost forming on the return air heat exchanger 32 disappears and is removed. At the same time, the high-temperature return air undergoes heat exchange in the return air heat exchanger 32, recovers the heat, and then is discharged to the outside through the exhaust port 36.

Note that in the defrosting mode, not all of the return air taken into the return air path 16 is supplied to the return air heat exchanger 32.
A portion of the return air is sufficient to defrost the return air heat exchanger 32. Therefore, excess return air is returned to the air supply path 18 through the opened first damper 20. Therefore, outside air vent 3
After the air is mixed with the outside air taken in from 8, and dust is removed by a filter 46, it is warmed by a supply air heat exchanger 48, and then supplied into the room through the air supply port 42 again. Therefore, even in the defrosting mode, heat is recovered from the exhausted return air while removing the frost from the return air heat exchanger 32. The recovered heat is then used to warm the air supplied indoors.

Therefore, even when in defrost mode, cooled air is not supplied into the room from the air supply port, unlike when the heat pump is in reverse cycle operation, and efficiency decreases, unlike in the hot gas bypass method. Nor.

The operation in the cooling mode is no different from the conventional one, so it will be omitted.

[Brief explanation of drawings]

FIG. 1 is an illustrative diagram for explaining the operation of a defrosting mode of a package air conditioner according to an embodiment of the present invention. FIG. 2 is an illustrative diagram for explaining the operation of a heating mode of a package air conditioner according to an embodiment of the present invention. . In the figure, 12 is a casing, 14 is a partition, 16 is a return air path, 18 is a supply air path, 20 is a first damper, 22 is a second damper, 24 is a return air port, 28 is a total heat exchanger, and 34 is a 38 is an outside air port, and 42 is an air supply port.

Claims (1)

[Claims] When in heating mode, return air is heat exchanged with a total heat exchanger, further heat exchanged with a return air heat exchanger, and between the total heat exchanger and the return air heat exchanger. In a package air conditioner configured to exhaust outside air together with the outside air taken in through a provided damper, when in the defrosting mode, the total heat exchanger is stopped and the total heat exchanger is stopped.
A defrosting method for a package air conditioner, in which the damper is closed and the return air heat exchanger is defrosted using exhaust heat.