JP2014210223A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioner capable of suppressing adhesion of foreign matters to a desiccant block.SOLUTION: An air conditioner 1 comprises: a refrigerant circuit in which a compressor 3, a flow path switching device 4, a first heat exchanger 5, a decompressor, and a second heat exchanger 7 are mutually connected by a refrigerant pipe; a casing 2 including an air path in which the first heat exchanger 5 and the second heat exchanger 7 are arranged; a desiccant block 8 provided in the casing 2, for adsorbing/desorbing water, and including a plurality of cells 8a; and a mesh filter 14 provided upstream of the desiccant block 8 in the air path and inhibiting contamination of foreign matters 15. A width of a mesh in the filter 14 is smaller than a length of a shortest side of the cells 8a in the desiccant block 8.

Description

  The present invention relates to an air conditioner, and more particularly to an air conditioner having a dehumidifying function.

  A conventional air conditioner having a dehumidifying function includes a compressor, a condenser, an expansion valve, an evaporator, and a defrost heater, and a refrigerant is filled in a refrigeration cycle in the air conditioner. ing. In the refrigeration cycle, the refrigerant compressed by the compressor becomes a high-temperature and high-pressure gas refrigerant and is sent to the condenser. The refrigerant flowing into the condenser is liquefied by releasing heat to the air. The liquefied refrigerant is decompressed by an expansion valve to become a gas-liquid two-phase refrigerant, and then gasified by absorbing heat from ambient air in an evaporator and flows to the compressor. When this air conditioner is used in a refrigerated or refrigerated warehouse, the evaporation temperature in the evaporator is lower than 0 ° C. because it is necessary to control the air conditioner so as to maintain a temperature range lower than 10 ° C. For this reason, frost is generated in the evaporator, which reduces the refrigeration capacity (dehumidification capacity) of the air conditioner.

  Therefore, the defrosting operation is regularly performed by the defrost heater attached to the evaporator. As a result, extra energy is consumed as much as the defrosting operation is performed, causing a reduction in the efficiency of the air conditioner. Furthermore, after the dehumidifying operation, the temperature in the refrigerated or refrigerated warehouse increased, the load on the air conditioner increased, and the power consumption increased. Also, in the case of an air conditioner that can control the rotation speed of the compressor, the cooling load becomes small in the intermediate period of cooling (rainy season, autumn, etc.), so by reducing the rotation speed of the compressor, the load is reduced. I was following. As a result, the evaporation temperature in the evaporator rises and the sensible heat in the room can be removed, but the latent heat in the room cannot be removed. Increases the discomfort of people

  Therefore, conventionally, a defrosting operation is unnecessary by combining the refrigerant refrigerator and the moisture adsorbing means, and removing the moisture in the air flowing into the evaporator (heat absorber) in advance by the moisture adsorbing means. The technology is disclosed. Patent Document 1 discloses an air conditioner including a desiccant rotor. This Patent Document 1 supplies air dehumidified by a desiccant rotor, which is a moisture adsorbing means, to an evaporator (heat absorber). In addition, in order to desorb and regenerate the moisture absorbed by the moisture adsorbing means (desiccant rotor), air heated by a condenser (radiator) is supplied to the moisture adsorbing means (desiccant rotor).

  Patent Document 2 and Patent Document 3 also disclose an air conditioner or a dehumidifier that performs dehumidification with a desiccant roller, as in Patent Document 1.

  Furthermore, in Patent Document 4, the first heat exchanger, the deodorizing unit, and the second heat exchanger are arranged in this order from the upstream side of the air passage, and the deodorizing unit adsorbs the odor component to the deodorizing unit. There has been disclosed a deodorization apparatus that performs switching to a decomposition operation for decomposing an adsorbed odor component by switching heating and cooling of a first heat exchanger and a second heat exchanger.

JP 2001-241893 A (Claim 1, Claim 6, Pages 6 to 8, FIG. 2) JP 2006-308236 A (Claim 1, paragraph 0015, FIG. 2) JP 2006-150305 A (Claim 1, Claim 7, FIG. 1) JP 2008-148832 A (Claim 1, FIG. 1)

  However, in Patent Document 4, there is a problem that the deodorizing unit is clogged while using the deodorizing device, and the adsorption / desorption performance is deteriorated. The same applies to the desiccant rotors of Patent Documents 1 to 3 described above.

  The present invention has been made against the background of the above-described problems, and provides an air conditioner that can prevent foreign matter from adhering to a desiccant block.

  An air conditioner according to the present invention includes a refrigerant circuit in which a compressor, a flow path switching device, a first heat exchanger, a decompression device, and a second heat exchanger are connected by a refrigerant pipe, a first heat exchanger, and a second heat exchanger. A housing having an air passage in which a heat exchanger is arranged, a desiccant block having a plurality of cells, which is provided in the housing, performs moisture adsorption and desorption, and is provided upstream of the air passage from the desiccant block. And a mesh-like filter that suppresses the mixing of foreign matter, and the mesh width in the filter is smaller than the length of the shortest side of the cell of the desiccant block.

  According to the present invention, the filter is installed in the air conditioner, and the width of the mesh of the filter is smaller than the length of the shortest side of the cell of the desiccant block, so that foreign matter adheres to the desiccant block. Can be suppressed.

1 is a schematic diagram showing an air conditioner 1 according to Embodiment 1. FIG. 5 is a moisture adsorption characteristic diagram of a solid adsorbent used for a desiccant block 8. FIG. FIG. 3 is a schematic diagram showing a desiccant block 8 in the first embodiment. It is an air wetness diagram which shows the state change of the air at the time of a 1st operation mode. It is an air wetness diagram which shows the state change of the air at the time of a 2nd operation mode. FIG. 6 is a schematic diagram showing a desiccant block 8 in a second embodiment. FIG. 6 is a schematic diagram showing a cell 8a of a desiccant block 8 in a third embodiment. FIG. 10 is a schematic diagram showing a cell 8a of a desiccant block 8 in a fourth embodiment. It is the schematic which shows the air conditioning apparatus 1 which concerns on the modification of this invention.

  Hereinafter, embodiments of an air-conditioning apparatus according to the present invention will be described with reference to the drawings. The present invention is not limited to the embodiments described below. Moreover, in the following drawings including FIG. 1, the relationship of the size of each component may be different from the actual one. Further, in the following description, terms for indicating directions (for example, “up”, “down”, “right”, “left”, “front”, “back”, etc.) are used as appropriate for easy understanding. This is for explanation and these terms do not limit the present invention.

Embodiment 1 FIG.
FIGS. 1A and 1B are schematic diagrams showing an air conditioner 1 according to Embodiment 1. FIG. The air conditioner 1 will be described based on FIGS. 1 (a) and 1 (b). As shown in FIGS. 1A and 1B, the air conditioner 1 includes a compressor 3 and a flow path switching device 4 in a machine room 2a, and a first heat exchange in the housing 2. 5, an expansion valve 6 that is a decompression device, and a second heat exchanger 7 that is arranged in parallel with the first heat exchanger 5, and these are connected in a ring shape with refrigerant piping to constitute a refrigerant circuit A. ing.

  The compressor 3 compresses the sucked refrigerant to a high pressure. Further, the flow path switching device 4 can switch the flow path so that the refrigerant flows in the direction of FIG. 1A or the direction of FIG. 1B, and is switched to the flow path of FIG. In this case, the refrigerant discharged from the compressor 3 flows in the order of the flow path switching device 4, the first heat exchanger 5, the expansion valve 6, the second heat exchanger 7, and the flow path switching device 4 and returns to the compressor 3. Configure the refrigeration cycle. In this configuration, the first heat exchanger 5 operates as a condenser (heat radiator), and the second heat exchanger 7 operates as an evaporator.

  On the other hand, when the flow path of the flow path switching device 4 is switched to the flow path of FIG. 1B, the refrigerant discharged from the compressor 3 is replaced with the compressor 3, the flow path switching device 4, and the second heat exchanger. 7, the expansion valve 6, the 1st heat exchanger 5, and the flow-path switching apparatus 4 flow in order, and the refrigeration cycle which returns to the compressor 3 is comprised. In this configuration, the second heat exchanger 7 operates as a condenser (heat radiator), and the first heat exchanger 5 operates as an evaporator.

For example, R410A is used as the refrigerant of the air conditioner 1. Note that the refrigerant is not limited to R410A, and other than that, an HFC refrigerant, an HC refrigerant, an HFO refrigerant, or the like can be applied, and a natural refrigerant such as CO ₂ or NH ₃ can be applied. In the case of applying a CO ₂ refrigerant, when the high pressure is an operation at a critical pressure or higher, the condenser operates as a radiator.

  Moreover, the 1st heat exchanger 5 and the 2nd heat exchanger 7 consist of plate fin tube heat exchangers, for example, and are the structure which heat-exchanges the refrigerant | coolant which flows through the inside of a heat exchanger tube, and the air which flows around a fin. . The expansion valve 6 is a valve whose opening degree is fixed, and decompresses and expands the refrigerant passing therethrough. The expansion valve 6 may be an electronic expansion valve whose opening degree is variable.

  In the housing 2, a suction port 10 a for introducing air to be dehumidified is formed on one side surface of the housing 2, and a blower for discharging the dehumidified air to the outside is formed on the other side surface of the housing 2. An outlet 10b is formed. And the air conveyed by the air blower 9 flows from the suction inlet 10a to the blower outlet 10b in the direction of arrow (alpha) of Fig.1 (a), (b). In the air channel chamber 10, a mesh-like filter 14 that suppresses the introduction of foreign substances, a first heat exchanger 5, a desiccant block 8 that is a desiccant material arranged in parallel with the first heat exchanger 5, and first heat An air passage B is formed in which the second heat exchanger 7 and the blower 9 arranged in parallel with the exchanger 5 are arranged in series. Therefore, the air sucked into the air passage B from the suction port 10a is straight in the air passage B in the order of the filter 14, the first heat exchanger 5, the desiccant block 8, the second heat exchanger 7, and the air blower 9. After the flow, the air is exhausted from the air outlet 10b to the outside of the air conditioner 1.

  Next, the desiccant block 8 will be described. The desiccant block 8 is obtained by molding a desiccant material into a solid and rectangular shape, and is made of a material that absorbs and desorbs moisture. As this material, for example, zeolite, silica gel, mesoporous silica, or a polymeric adsorbent is applied. FIG. 2 is a moisture adsorption characteristic diagram of the solid adsorbent used for the desiccant block 8. In FIG. 2, the horizontal axis represents relative humidity, and the vertical axis represents the equilibrium adsorption rate. C in FIG. 2 is silica gel or zeolite. Further, D in FIG. 2 is a porous silicon material, and the rate of change (inclination) of the equilibrium adsorption rate of moisture relative to the relative humidity when the relative humidity is in the range of about 30% to 40% is less than 30% and 40%. It is larger than the rate of change of the equilibrium adsorption rate of moisture with respect to relative humidity in the range exceeding%. This porous silicon material is, for example, a material (mesoporous silica) having a large number of pores of about 1.5 nm. Furthermore, E in FIG. 2 is a polymer-based adsorbent, and the equilibrium adsorption rate in the range where the relative humidity is high is extremely high.

  As the desiccant material of the desiccant block 8, any of C, D, and E in FIG. 2 may be selected, but D and E in FIG. 2 need to have a lower relative humidity when moisture is desorbed. There is no. For this reason, when the 1st heat exchanger 5 operate | moves as a condenser (at the time of the 1st operation mode mentioned later), the desorption of the moisture contained in the desiccant block 8 is possible with the blowing air. In addition, when C in FIG. 2 is selected as the desiccant material, moisture desorption may be incomplete with only the air blown from the first heat exchanger 5, and a separate auxiliary heater (not shown) is required. It may become.

FIGS. 3A and 3B are schematic views showing the desiccant block 8 in the first embodiment. 3A is an overall view of the desiccant block 8, and FIG. 3B is a diagram showing the cell 8 a of the desiccant block 8. As shown in FIG. 3A, the desiccant block 8 has a plurality of cells 8a. The shape of the cell 8a, as shown in FIG. 3 (b), for example, a flat has been isosceles triangle, the length of the base and D _1, the length of the hypotenuse When D _2, D _1> and it has a D _2. That is, in this cell 8a, the shortest side (shortest side) is the hypotenuse, its length is D _2. In addition, the size of the cell 8a in the desiccant block 8 can be about 0.9 mm to 5 mm, and can be appropriately selected in consideration of the balance between the pressure loss and the device size in the air conditioner 1.

Next, the filter 14 provided on the upstream side of the air passage B from the desiccant block 8 and the first heat exchanger 5 will be described. In the desiccant block 8, the size of the surface area inside the cell 8a in the desiccant block 8 corresponds to the dehumidifying / humidifying ability. For this reason, the filter 14 is arrange | positioned in the upstream of the desiccant block 8 and the 1st heat exchanger 5 in the air path B as mentioned above. Thereby, foreign matters such as dust are collected by the filter 14, and the foreign matter adheres to the surface of the cell 8 a in the desiccant block 8 and is clogged. In addition, the filter 14 has a mesh shape, thereby suppressing foreign matters from being mixed into the air passage B. The mesh width in the filter 14 is smaller than the length D ₂ of the shortest side of the desiccant block 8.

  The filter 14 can be made of, for example, water or exhaust gas. The filter 14 may be impregnated with an alkaline substance that neutralizes the acidic substance, or may be impregnated with an acidic substance that neutralizes the alkaline substance. When the substance contained in the air around the air conditioner 1 is acidic or alkaline, if the substance adheres to the desiccant block 8, the desiccant block 8 may be deteriorated. When the substance contained in the surrounding air is acidic, the acidic substance can be neutralized if the filter 14 is impregnated with an alkaline substance. Further, when the substance contained in the surrounding air is alkaline, the alkaline substance can be neutralized if the filter 14 is impregnated with an acidic substance. Thereby, deterioration of the desiccant block 8 can be suppressed. Examples of the alkaline substance include ammonia. Since this filter 14 is provided on the most upstream side of the air passage B, it can be easily taken out from the housing 2 and can be easily replaced. For this reason, it is easy to change the material of the filter 14 as appropriate.

Next, the effect | action of the air conditioning apparatus 1 of this Embodiment 1 is demonstrated. The air sucked into the air passage B from the suction port 10a first passes through the filter 14 in the air passage B. When foreign matter is mixed in the air sucked from the suction port 10a, the filter 14 prevents the foreign matter from reaching the downstream side of the filter 14 in the air passage B. The mesh width in the filter 14 is shorter than the length D ₂ of the shortest side of the desiccant block 8. Thus, the filter 14 can be wide to collect D ₂ or more foreign objects.

On the other hand, a foreign object having a width smaller than D ₂ may pass through the filter 14. However, since the length of the shortest side of the cell 8a in the desiccant block 8 is D _2, this desiccant block 8, be deposited is smaller foreign matter than the width D _2, cell 8a of the desiccant block 8 closed It ’s difficult. For this reason, since clogging of the desiccant block 8 is suppressed, the replacement cycle of the desiccant block 8 can be extended. In the present embodiment, the mesh width of the filter 14 is smaller than the length of the shortest side of the cell 8a. However, the mesh width of the filter 14 is set to 1 of the length of the shortest side of the cell 8a. It may be smaller than / 2. Thereby, since the clogging of the desiccant block 8 can be further suppressed, the replacement cycle of the desiccant block 8 can be further extended.

  The air passage chamber 10 is provided with a temperature / humidity sensor 11 that measures the temperature and humidity of the intake air of the air conditioner 1 (the temperature and humidity around the air conditioner 1). The machine room 2 a in the air conditioner 1 is provided with a control device 12 that controls the operation of the air conditioner 1. The control device 12 includes a dehumidifying operation control described later (switching of the flow path switching device 4 according to the detection signal of the temperature / humidity sensor 11), the rotational speed control of the blower 9, the rotational speed control of the compressor 3, and the expansion valve. Various controls such as opening degree control 6 are performed.

  Next, the dehumidifying operation operation of the air conditioner 1 will be described. In the air conditioning apparatus 1, two operation modes can be realized by switching the flow path of the flow path switching device 4. Hereinafter, it demonstrates in order.

(First operation mode: operation of the refrigeration cycle)
First, the operation in the first operation mode, which is a case where the flow path of the flow path switching device 4 is switched in the direction of FIG. The operation of the refrigeration cycle in the first operation mode is as follows. After the low-pressure gas is sucked by the compressor 3, it is compressed and becomes a high-temperature and high-pressure gas. The refrigerant discharged from the compressor 3 flows into the first heat exchanger 5 through the flow path switching device 4. The refrigerant flowing into the first heat exchanger 5 dissipates heat to the air flowing through the air passage B, and while the air is heated, the refrigerant itself is cooled and condensed to become a high-pressure liquid refrigerant. Spill from. The liquid refrigerant flowing out of the first heat exchanger 5 is decompressed by the expansion valve 6 and becomes a low-pressure two-phase refrigerant. Thereafter, the refrigerant flows into the second heat exchanger 7, absorbs heat from the air flowing through the air passage B, and while cooling the air, the refrigerant itself is heated and evaporated to become low-pressure gas. Thereafter, the refrigerant is sucked into the compressor 3 through the flow path switching device 4.

(First operation mode: Air operation)
Next, the operation of air in the first operation mode will be described based on FIG. FIG. 4 is an air wetting diagram showing air state changes in the first operation mode, where the vertical axis represents the absolute humidity of the air and the horizontal axis represents the dry bulb temperature of the air. Moreover, the curve of FIG. 4 shows saturated air, and the relative humidity in saturated air is 100%.

  The air around the air conditioner 1 (point a in FIG. 4) flows into the air conditioner 1 and is heated by the first heat exchanger 5, and the temperature increases and the relative humidity decreases. (FIG. 4, point b). Thereafter, air flows into the desiccant block 8, but since the relative humidity of the air is low, the moisture retained in the desiccant block 8 is desorbed (released), and the amount of moisture contained in the air increases. On the other hand, desorption heat accompanying desorption is removed from the air that has flowed into the desiccant block 8, the temperature of the air is lowered, and the humidity is high (point c in FIG. 4). Thereafter, the air flows into the second heat exchanger 7 and is cooled. The refrigerant circuit A is operated such that the refrigerant temperature in the second heat exchanger 7 is lower than the dew point temperature of air, and the air is cooled and dehumidified by the second heat exchanger 7. The temperature becomes low and the absolute humidity is low (point d in FIG. 4). Thereafter, the air flows into the blower 9 and is discharged from the air outlet 10b to the outside of the air conditioner 1.

(Second operation mode: operation of the refrigeration cycle)
Next, the operation in the second operation mode in which the flow path of the flow path switching device 4 is switched in the direction of FIG. 1B will be described. The operation of the refrigeration cycle in the second operation mode is as follows. After the low-pressure gas is sucked by the compressor 3, it is compressed and becomes a high-temperature and high-pressure gas. The refrigerant discharged from the compressor 3 flows into the second heat exchanger 7 through the flow path switching device 4. The refrigerant flowing into the second heat exchanger 7 dissipates heat to the air flowing through the air passage B, and while the air is heated, the refrigerant itself is cooled and condensed to become a high-pressure liquid refrigerant from the second heat exchanger 7. leak. The liquid refrigerant flowing out of the second heat exchanger 7 is decompressed by the expansion valve 6 and becomes a low-pressure two-phase refrigerant. Thereafter, the refrigerant flows into the first heat exchanger 5, absorbs heat from the air flowing through the air passage B, and while cooling the air, the refrigerant itself is heated and evaporated to become a low-pressure gas. Thereafter, the refrigerant is sucked into the compressor 3 through the flow path switching device 4.

(Second operation mode: air operation)
Next, the operation of air in the second operation mode will be described with reference to FIG. FIG. 5 is an air wetting diagram showing changes in the air state in the second operation mode, where the vertical axis represents the absolute humidity of the air and the horizontal axis represents the dry bulb temperature of the air. Moreover, the curve of FIG. 5 shows saturated air, and the relative humidity in saturated air is 100%.

  The air around the air conditioner 1 (point “a” in FIG. 5) flows into the air conditioner 1 and is then cooled by the first heat exchanger 5. The refrigerant circuit A is operated such that the refrigerant temperature in the first heat exchanger 5 is lower than the dew point temperature of the air, and the air is cooled and dehumidified by the first heat exchanger 5, It will be in the state of high relative humidity at low temperature (point e in FIG. 5). Thereafter, the air flows into the desiccant block 8, but since the relative humidity of the air is high, moisture is adsorbed on the desiccant block 8, the amount of moisture contained in the air is reduced, and further dehumidified. On the other hand, the air that has flowed into the desiccant block 8 is heated by adsorption heat due to adsorption, and its temperature rises to a high temperature and low humidity state (point f in FIG. 5). Thereafter, the air flows into the second heat exchanger 7 and is heated to a high temperature (point g in FIG. 5). Thereafter, the air flows into the blower 9 and is discharged from the air outlet 10b to the outside of the air conditioner 1.

  As described above, in the second operation mode, in addition to dehumidification by cooling with the refrigerant in the first heat exchanger 5 (FIG. 5: difference in absolute humidity ae), dehumidification by adsorption of the desiccant block 8 (FIG. 5: absolute A difference in humidity ef is also implemented. Therefore, as apparent from a comparison between FIG. 4 and FIG. 5, the second operation mode can secure a larger amount of dehumidification than the first operation mode. Therefore, the main dehumidification in the air conditioning apparatus 1 is performed in the second operation mode.

  In the air conditioner 1 of the first embodiment, the first operation mode and the second operation mode are alternately repeated. For example, when the second operation mode is continuously performed, the amount of moisture contained in the desiccant block 8 has an upper limit, and therefore, when the operation is performed for a certain period of time, moisture is not adsorbed on the desiccant block 8 and the dehumidification amount is reduced. Therefore, when the amount of moisture retained in the desiccant block 8 is close to the upper limit, the operation mode is switched to the first operation mode and the operation of releasing moisture from the desiccant block 8 is performed. Thus, by alternately performing the first operation mode and the second operation mode, the adsorption / desorption action of the desiccant block 8 is sequentially performed, and the effect of increasing the dehumidification amount by the adsorption / desorption action of the desiccant block 8 is maintained.

  In addition, when the desiccant block 8 is detached, the second heat exchanger 7 acts as an evaporator, but moisture (condensation water) held between the fins of the evaporator, which is a plate fin tube heat exchanger, is held between the fins. If it does not fall, when the desiccant block 8 is adsorbed, that is, when the second heat exchanger 7 acts as a condenser, the water held between the fins may be re-evaporated and conversely humidify. . In order to avoid this, the second heat exchanger 7 has a structure that improves the sliding property of moisture, and when the second heat exchanger 7 operates as an evaporator, moisture is not retained between the fins. Yes.

  As in the prior art, in the configuration using the desiccant rotor in the air conditioner 1, a motor for rotationally driving the desiccant rotor and a fixing structure thereof are required, which complicates the apparatus configuration. Conventionally, it is necessary to divide the air path between the adsorbing part and the desorbing part, and a seal structure that hermetically separates the boundary part between the adsorbing part and the desorbing part is required. On the other hand, in the first embodiment, there is only one air passage B, and the adsorption and desorption of the desiccant block 8 can be switched by switching the flow path switching device 4, so that a conventional seal structure is used. Is not required, the device configuration can be simplified, and the cost can be reduced. Furthermore, since the apparatus configuration can be simplified, the desiccant block 8 can be easily replaced.

  Further, in the second operation mode of the present embodiment, dehumidification by the first heat exchanger 5 and dehumidification by the desiccant block 8 are performed on the conveyed air. When dehumidification (dehumidification only of the 1st heat exchanger 5) is performed only by a refrigerating cycle like before, if the temperature of the air conveyed becomes about 10 degrees C or less, it will frost on the 1st heat exchanger 5. For this reason, frequent defrosting is required and dehumidification cannot be continued, so that the dehumidifying ability is extremely reduced. On the other hand, in this embodiment, in addition to dehumidification by the first heat exchanger 5, dehumidification by the desiccant block 8 is also performed. For this reason, even if the temperature of the conveyed air is about 10 ° C. or less and the dehumidifying capacity of the first heat exchanger 5 is reduced, the dehumidification by the desiccant block 8 is burdened accordingly. And it can suppress that a dehumidification capability falls extremely.

  In addition, when the dehumidification is performed only in the refrigeration cycle as in the prior art, it is a limit to obtain a relative humidity of about 40%. In contrast, in the second operation mode of the present embodiment, heating by the second heat exchanger 7 is performed in addition to dehumidification by the first heat exchanger 5 and dehumidification by the desiccant block 8. For this reason, the blown air of the air conditioning apparatus 1 is in a state where the amount of moisture is low at a high temperature (FIG. 5, point g), and the relative humidity can be set to a low relative humidity of 20% or less, for example. Such air having a low relative humidity is air suitable for drying applications. If such air is directly applied to an object to be dried such as laundry, drying of the object to be dried can be promoted. And a higher performance drying function can be realized.

(Operation time in the first operation mode and the second operation mode)
Next, the operation time in the first operation mode and the second operation mode will be described. The operation time in the first operation mode and the second operation mode may be a predetermined time, but the operation time in each operation mode depends on the air condition, the operation state of the air conditioner 1, and the like. There is an appropriate value. Therefore, each operation mode may be determined based on the air condition, the operation state of the air conditioner 1 and the like so that the operation can be performed with the appropriate value.

  In the first operation mode, an appropriate amount of moisture is released from the desiccant block 8, and the time required for the amount of moisture remaining in the desiccant block 8 to be an appropriate amount becomes an appropriate value. When the first operation mode is ended and the second operation mode is switched to the desiccant block 8 in a state where a larger amount of moisture remains in the desiccant block 8, the amount of water adsorbed by the desiccant block 8 in the second operation mode is suppressed. Therefore, the amount of dehumidification in the second operation mode is reduced. On the other hand, if the first operation mode is made too long, in the latter half of the first operation mode, a state in which moisture can hardly be desorbed from the desiccant block 8 will continue, and the second dehumidifying amount is achieved higher than in the first operation mode. Switching to operation mode is slow. Therefore, also in this case, the total dehumidification amount is reduced.

  In the second operation mode, moisture is adsorbed on the desiccant block 8, so that the time during which the amount of moisture adsorbed on the desiccant block 8 is an appropriate amount is an appropriate value. When the operation is switched to the first operation mode even though there is room to be adsorbed by the desiccant block 8, the operation time of the second operation mode with the high dehumidification amount is shorter than that of the first operation mode, and the total is seen. Sometimes dehumidification is reduced. On the other hand, if the second operation mode is made too long, the desiccant block 8 cannot continue to be adsorbed in the second half of the second operation mode, and the dehumidification amount is reduced in this case as well.

  The change in the amount of moisture retained in the desiccant block 8 is determined by the relative humidity of the air flowing into the desiccant block 8. When air with a high relative humidity flows in, the moisture in the desiccant block 8 is difficult to be released, and conversely the amount of moisture adsorbed Will be more. In addition, when air having a low relative humidity flows into the desiccant block 8, moisture in the desiccant block 8 is easily released, and conversely, the moisture adsorption amount decreases.

  Next, the operation time of the first operation mode and the second operation mode is determined based on the state of the intake air detected by the state detection device that detects the state of the intake air sucked into the air passage B from the dehumidification target space. A case of determination will be described. This state detection device is, for example, a temperature / humidity sensor 11 provided in the air passage chamber 10. The temperature / humidity sensor 11 detects the relative humidity of the intake air, and the operation mode is set according to the relative humidity. Each driving time is determined.

  The relative humidity (hereinafter referred to as “reference relative humidity”) serving as a reference for the intake air is determined in advance, and the reference operation time of each operation mode that provides a high dehumidification amount when the intake air of the reference relative humidity passes through the air passage B, Each is obtained in advance by experiments or simulations. Then, according to the magnitude relationship between the actual relative humidity of the intake air and the reference relative humidity, the operation time for each operation mode is determined by appropriately increasing or decreasing the reference operation time for each operation mode.

  The actual relative humidity of the intake air is obtained from the state of the intake air obtained by the temperature / humidity sensor 11 at the start of the dehumidifying operation. When the relative humidity is higher than the preset relative humidity, the amount of moisture released from the desiccant block 8 in the first operation mode is less than the amount of moisture released when the relative humidity is the reference relative humidity, and the second The moisture adsorption amount of the desiccant block 8 in the operation mode is larger than the moisture adsorption amount when the relative humidity is the reference relative humidity. Therefore, when the actual relative humidity of the intake air is higher than the reference relative humidity, the operation time in the first operation mode is set longer than the reference operation time corresponding to the first operation mode, and conversely, the operation in the second operation mode is performed. The time is made shorter than the reference operation time corresponding to the second operation mode. On the other hand, when the actual relative humidity of the intake air is lower than the reference relative humidity, the control device 12 shortens the operation time of the first operation mode to the reference operation time corresponding to the first operation mode, The operation time of the second operation mode time is set longer than the reference operation time corresponding to the second operation mode.

  Thus, by adjusting the operation time of the first operation mode and the second operation mode, the moisture retention amount of the desiccant block 8 can be appropriately maintained, and therefore the dehumidification amount of the air conditioner 1 is improved. Can do.

Embodiment 2. FIG.
Next, the air conditioning apparatus 1 according to Embodiment 2 will be described. FIG. 6 is a schematic diagram showing the desiccant block 8 in the second embodiment. The present embodiment is different from the first embodiment in that the dimensional relationship between the mesh width in the filter 14 and the fin pitch in the first heat exchanger 5 is specified. In the second embodiment, the description of the parts common to the first embodiment will be omitted, and the difference from the first embodiment will be mainly described.

In the present embodiment, the first heat exchanger 5 is a plate fin tube heat exchanger as in the first embodiment, and has a plurality of fins 5a on its inner wall as shown in FIG. The width of the mesh in the filter 14 is smaller than the pitch of the fins 5a of the first heat exchanger 5. The width of the mesh of the filter 14, as in the first embodiment, is smaller than the shortest side length D ₂ of the cell 8a desiccant block 8. Therefore, when the pitch of the fins 5a of the first heat exchanger 5 and _{D 3,} the width of the mesh of the filter 14 is smaller than the _{D 2} and _{D 3.} That is, when comparing the mesh width of the filter 14, the length of the shortest side of the cell 8a of the desiccant block 8, and the pitch of the fins 5a of the first heat exchanger 5, the mesh width of the filter 14 is the smallest. Yes.

  Thus, in the present embodiment, since the mesh width of the filter 14 is smaller than the length of the shortest side of the cell 8a of the desiccant block 8 and the pitch of the fins 5a of the first heat exchanger 5, the desiccant block 8 It can suppress that the foreign material which plugs up the cell 5a of this and the fin 5a of the 1st heat exchanger 5 mixes. Therefore, the reliability of the desiccant block 8 and the first heat exchanger 5 can be improved.

Embodiment 3 FIG.
Next, the air conditioning apparatus 1 according to Embodiment 3 will be described. FIGS. 7A and 7B are schematic diagrams showing the cell 8a of the desiccant block 8 in the third embodiment. Among these, Fig.7 (a) is a figure which shows the structure of the cell 8a, FIG.7 (b) is a figure which shows that the foreign material 15 has adhered to the cell 8a. The present embodiment is different from the first embodiment in that the shape of the cell 8a of the desiccant block 8 is a substantially triangular wave shape. In the third embodiment, description of parts common to the first embodiment will be omitted, and description will be made focusing on differences from the first embodiment.

In this embodiment, as shown in FIG. 7 (a), the shape of the cells 8a of the desiccant block 8, a corrugated, the length of the base of the cell 8a and D _4, the length of one of the hypotenuse It was a _{D 5,} and the length of the other oblique side and _{D 6, D 4} is smaller than _{D 5} and _{D 6.} That is, this cell 8a has the shortest base. Further, since the cell 8a has a corrugated shape, the foreign matter 15 is unlikely to be clogged at the apex portion facing the bottom side. On the other hand, since the apex portions at both ends of the bottom side are narrower than the apex portions facing the bottom side, the foreign matter 15 is easily clogged. Thus, in the present embodiment, the narrow portion in the cell 8a is the apex portion of the both ends of the base, that is, two places.

  The standard for replacement of the humidifying filter such as the desiccant block 8 is determined to be 50% of the rated performance in the Japan Electrical Manufacturers' Association standard (JEM1467). In the desiccant block 8, the size of the surface area inside the cell 8a corresponds to the dehumidifying / humidifying ability. For this reason, for example, when 50% of the circumference of the cell 8a is blocked by the foreign matter 15 or the like, the performance is considered to be 50%. The performance of the desiccant block 8 is preferably 60 to 80% of the initial performance even if the performance is deteriorated due to adhesion of the foreign matter 15 or the like in order to obtain long-term reliability.

  As shown in FIG. 7B, when the foreign substance 15 such as dust is clogged in two narrow portions (the apex portions at both ends of the bottom side) in the cell 8a, the peripheral length of the cell 8a is reduced. When the foreign matter 15 is clogged in the narrow portion, the narrow portion has an acute angle, so that it is considered to have a substantially triangular shape. Then, at the bottom side of the cell 8a, the circumference is shortened by the length of the bottom side of the two foreign objects 15. Further, the circumference of one hypotenuse of the cell 8a is shortened by the length of the hypotenuse of one foreign substance 15, and the circumference of the other hypotenuse of the cell 8a is also equal to the length of the hypotenuse of one foreign substance 15. Only the circumference becomes shorter. Assuming that the shape of the foreign material 15 is, for example, an equilateral triangle and the length of each side is x, the circumference of the cell 8a is shortened by four times (4 × x) the length of the side of the foreign material 15. .

As described above, when 50% of the circumference of the cell 8a is blocked by the foreign matter 15 or the like, the performance is considered to be 50%. Therefore, in order to extend the replacement cycle of the desiccant block 8, the circumference of the cell 8a It is necessary to secure at least 50%. Since the cell 8a has a corrugated shape and the number of sides is 3, it is sufficient that at least 50% or more of at least three times the length of the shortest side of the cell 8a can be secured. As described above, the shortest side of the cell 8a is a bottom of the cell 8a, a _{D 4.} Therefore, in order to satisfy 50% of the circumferential length of the cell 8a, the length of the shortest side of the cell 8a: and D _4, the relationship between the length x of the side of the foreign matter 15, needs to be the following formula (1) There is.

(3 × D ₄ ) / 2 = 4 × x (1)

  When the above equation (1) is modified, the following equation (2) is obtained.

x = (3/8) × D ₄ (2)

  Thus, if the length of the side of the foreign matter 15 is smaller than 3/8 of the length of the shortest side of the cell 8a, the circumference of the cell 8a is reduced even if the foreign matter 15 is clogged in the narrow portion of the cell 8a. It is suppressed that 50% is obstructed. Therefore, in the present embodiment, the mesh width of the filter 14 is made smaller than 3/8 of the shortest side of the cell 8a of the desiccant block 8. Thereby, since 50% of the circumference of the cell 8a is suppressed, the exchange cycle of the desiccant block 8 can be extended.

Embodiment 4 FIG.
Next, the air conditioning apparatus 1 according to Embodiment 4 will be described. FIGS. 8A and 8B are schematic diagrams showing the cell 8a of the desiccant block 8 in the fourth embodiment. Among these, FIG. 8A is a diagram showing the configuration of the cell 8a, and FIG. 8B is a diagram showing that the foreign matter 15 is attached to the cell 8a. Although the present embodiment is common to the first embodiment in that the shape of the cell 8a of the desiccant block 8 is a triangle, the height of the triangle is different from that in the first embodiment. In the fourth embodiment, the description of the parts common to the first embodiment will be omitted, and the difference from the first embodiment will be mainly described.

In this embodiment, as shown in FIG. 8 (a), the shape of the cells 8a of the desiccant block 8, a triangle, a length of the base of the cell 8a and D _7, the length of one of the hypotenuse and D _5, and the length of the other oblique side and _{D 9, D 7} is less than _{D 8} and _{D 9.} That is, this cell 8a has the shortest base. Further, since the cell 8a has a triangular shape, each apex has an acute angle, and the foreign matter 15 is easily clogged. Thus, in the present embodiment, the narrow portion in the cell 8a is the portion of each vertex of the triangle, that is, three locations.

  As shown in FIG. 8B, when the foreign matter 15 such as dust is clogged in the three narrow portions (portions of the triangles) in the cell 8a, the peripheral length of the cell 8a is reduced. When the foreign matter 15 is clogged in the narrow portion, the narrow portion has an acute angle, so that it is considered to have a substantially triangular shape. Then, at the bottom side of the cell 8a, the circumference is shortened by the length of the bottom side of the two foreign objects 15. In addition, the circumference of one hypotenuse of the cell 8a is shortened by the length of the hypotenuse of the two foreign substances 15, and the other hypotenuse of the cell 8a is also the length of the hypotenuse of the two foreign substances 15. Only the circumference becomes shorter. Assuming that the shape of the foreign material 15 is, for example, an equilateral triangle and the length of each side is y, the circumference of the cell 8a is shortened by 6 times (6 × y) the length of the side of the foreign material 15. .

The cell 8a of the desiccant block 8 of the present embodiment is a triangle, but the number of sides is three, as in the second embodiment, and therefore has a length at least three times the shortest side of the cell 8a. Among these, if 50% or more can be secured, the performance is suppressed to 50%. As described above, the shortest side of the cell 8a is a bottom of the cell 8a, a _{D 7.} Therefore, in order to satisfy 50% of the circumferential length of the cell 8a, the length of the shortest side of the cell 8a: and D _7, the sides of the foreign matter 15 the relationship between the length y, should be the following formula (3) There is.

(3 × D ₇ ) / 2 = 6 × y (3)

  When the above equation (3) is modified, the following equation (4) is obtained.

y = (1/4) × D ₇ (4)

  Thus, if the length of the side of the foreign material 15 is smaller than ¼ of the length of the shortest side of the cell 8a, even if the foreign material 15 is clogged in the narrow part of the cell 8a, the circumference of the cell 8a is reduced. It is suppressed that 50% is obstructed. Therefore, in the present embodiment, the width of the mesh of the filter 14 is made smaller than 1/4 of the shortest side of the cell 8a of the desiccant block 8. Thereby, since 50% of the circumference of the cell 8a is suppressed, the exchange cycle of the desiccant block 8 can be extended.

The embodiment of the present invention is not limited to the above-described embodiment. For example, although the case where the shape of the cell 8a is a triangle is illustrated, as shown in FIG. 9 (schematic diagram showing an air conditioner 1 according to a modification of the present invention), a square (for example, the length of a side is D). ₁₀ ) or a polygon.

  DESCRIPTION OF SYMBOLS 1 Air conditioning apparatus, 2 housing | casing, 2a machine room, 3 compressor, 4 flow-path switching apparatus, 5 1st heat exchanger, 5a fin, 6 expansion valve, 7 2nd heat exchanger, 8 desiccant block, 8a cell , 9 Air blower, 10 Air passage chamber, 10a Air inlet, 10b Air outlet, 11 Temperature / humidity sensor, 12 Control device, 14 Filter, 15 Foreign material.

Claims (11)

A refrigerant circuit in which a compressor, a flow path switching device, a first heat exchanger, a decompression device, and a second heat exchanger are connected by a refrigerant pipe;
A housing having an air passage in which the first heat exchanger and the second heat exchanger are disposed;
A desiccant block provided in the housing, performing moisture adsorption and desorption, and having a plurality of cells;
A mesh-like filter that is provided on the upstream side of the air passage from the desiccant block, and suppresses the mixing of foreign matters,
The air conditioner characterized in that the width of the mesh in the filter is smaller than the length of the shortest side of the cell of the desiccant block. The air conditioner according to claim 1, wherein the cell shape of the desiccant block is a triangle. The air conditioner according to claim 1 or 2, wherein a width of the mesh in the filter is smaller than ½ of the shortest side of the cell of the desiccant block. The air conditioner according to claim 1 or 2, wherein a width of the mesh in the filter is smaller than 3/8 of the shortest side of the cell of the desiccant block. The air conditioner according to claim 1 or 2, wherein a width of the mesh in the filter is smaller than 1/4 of a shortest side of the cell of the desiccant block. The first heat exchanger has a plurality of fins on the inner wall,
The filter is provided on the upstream side of the air path from the first heat exchanger,
The air conditioner according to any one of claims 1 to 5, wherein a width of the mesh in the filter is smaller than a pitch of fins of the first heat exchanger. The air filter according to any one of claims 1 to 6, wherein the filter adsorbs water. The air conditioner according to any one of claims 1 to 7, wherein the filter adsorbs exhaust gas. The air conditioner according to any one of claims 1 to 8, wherein the filter is impregnated with an alkaline substance that neutralizes an acidic substance. The air conditioner according to any one of claims 1 to 9, wherein the filter is impregnated with an acidic substance that neutralizes an alkaline substance. A control device for controlling the flow path switching device;
The controller is
A first operation mode in which the first heat exchanger operates as a condenser or a radiator, the second heat exchanger operates as an evaporator, and desorbs moisture held in the desiccant block; A second operation mode in which one heat exchanger operates as an evaporator and the second heat exchanger operates as a condenser or a radiator, and the desiccant block adsorbs moisture from the air passing through the air passage; The air conditioner according to any one of claims 1 to 10, wherein the air conditioner is alternately switched by flow path switching of the flow path switching device.

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