KR102597628B1 - Hybrid Desiccant Dehumidifier Without Regenerative Exhaust And Dehumidification Method - Google Patents

Abstract

The present invention relates to a hybrid desiccant dehumidifier and dehumidifying method without regenerative exhaust. More particularly, the present invention relates to a hybrid desiccant dehumidifier and dehumidifying method without regenerative exhaust that heats the ventilation air in a dehumidification space from a regeneration condenser and supplies the regeneration air to a desiccant rotor regeneration part as regeneration air, re-desorbs the moisture from a desiccant rotor, dehumidifies the high humidity air at the cooling dew point from an evaporator, adsorbs and dehumidifies it in a desiccant rotor processing part, heats or radiates it from a reheating condenser, and supplies it to the dehumidification space.

Description

Hybrid Desiccant Dehumidifier Without Regenerative Exhaust And Dehumidification Method}

The present invention relates to a hybrid desiccant dehumidifier and dehumidifying method without regenerative exhaust. More specifically, the ventilation air in the dehumidifying space is heated in a regenerative condenser and supplied to the desiccant rotor regeneration unit as regenerative air to regenerate moisture in the desiccant rotor. It relates to a hybrid desiccant dehumidifier and dehumidification method in which desorbed high humidity air is dehumidified by cooling dew point in an evaporator, then adsorbed and dehumidified in a desiccant rotor processing unit, heated or radiated in a reheat condenser, and then supplied to a dehumidifying space.

Generally, an industrial dehumidifier is a dehumidifying system that adjusts the humidity of the air to lower the humidity of the air when supplying air to the dehumidifying space where the production process takes place in order to minimize problems caused by moisture in battery production or the production of food and pharmaceutical products. Hire.

When applying a desiccant dehumidifier to the manufacturing process and storage of such products, an outdoor air duct for regeneration and a duct for regenerative exhaust are required. When process equipment is located inside a large space or when dehumidification is performed during process changes, it is very difficult to add ducts, so duct installation costs increase.

For example, in the case of a thermal power plant, when equipment is maintained during the idle period, a desiccant dehumidifier is required to prevent corrosion due to the large amount of moisture inside the low-pressure turbine. The duct length required to construct this is more than 100m, making it difficult to install and cost. In this case, a hybrid dehumidifier without a duct for regenerative exhaust is needed.

To regenerate the desiccant regeneration unit without a duct for regeneration exhaust, a sensible heat exchanger must be installed on the regeneration side to condense the moisture in the regeneration air to determine the amount of dehumidification. The dew point temperature obtained by heat exchange at room temperature is over 20℃, so in this case, It is difficult to lower the dew point temperature required for regeneration by sensible heat exchange when the relative humidity is below 20%, so it is difficult to lower the relative humidity because a low dew point temperature cannot be obtained.

Additionally, existing desiccant dehumidifiers have the disadvantage of only being able to provide positive pressure to the dehumidifying space.

Prior Patent Document 1 includes a dehumidifying rotor 110 that absorbs moisture in the incoming air; A condenser 120 installed in the air passage flowing into the dehumidification rotor 110 and condensing the refrigerant compressed at high temperature/high pressure in the compressor 122; an air supply fan 130 that supplies air to discharge the air dehumidified by the dehumidification rotor 110 into the interior; a pre-cooler (140) that cools and dehumidifies the air supplied from the air supply fan (130); A dehumidifier including a heater 150 that heats the air passing through the pre-cooler 140 is presented.

The prior patent document 1 uses waste heat from a condenser as a regenerative heat source, but ventilation is not used for desiccant regeneration, and in the case of a desiccant dehumidifier, it has the disadvantage of only being able to provide positive pressure in the dehumidifying space.

Prior Patent Document 2 includes a first external air introduction line through which external air is introduced; an evaporator installed in the first outdoor air inlet line and cooling and dehumidifying outdoor air through heat exchange; A compressor that compresses the refrigerant that has passed through the evaporator; A condenser that condenses the refrigerant that has passed through the compressor; an expansion valve that expands the refrigerant that has passed through the condenser; A desiccant rotor that dehumidifies and warms the outdoor air cooled and dehumidified in the evaporator; A regenerative air supply line that heats outdoor air introduced from a second outdoor air introduction line connected to the condenser using condensation heat and then passes through the desiccant rotor; An exhaust line that passes through the desiccant rotor and recovers and discharges the regenerated and heat-exchanged air; An air supply line that passes through the desiccant rotor and supplies dehumidified and heated treated air to the dehumidifying space; A hybrid desiccant dehumidifier consisting of a dehumidifying space that receives treated air supplied from the air supply line and maintains internal temperature and humidity, and a control unit that selectively controls the cooling, dehumidifying, and warming operation of the introduced outside air according to external temperature and humidity conditions. A device is presented.

Korean Patent Publication No. 10-1568785 (registered on November 6, 2015) Korean Patent Publication No. 10-0943285 (registered on February 11, 2010)

The present invention relates to a hybrid desiccant dehumidifier and dehumidifying method without regenerative exhaust. More specifically, the ventilation air in the dehumidifying space is heated in a regenerative condenser and supplied to the desiccant rotor regeneration unit as regenerative air to regenerate moisture in the desiccant rotor. The purpose is to provide a hybrid desiccant dehumidifier and dehumidification method without regenerative exhaust that dehumidifies the desorbed high humidity air in the evaporator, dehumidifies it by adsorption in the desiccant rotor processing unit, heats or dissipates heat in the reheat condenser, and supplies it to the dehumidifying space. there is.

The hybrid desiccant dehumidifier without regenerative exhaust of the present invention includes a compressor (111), a regenerative condenser (103), a reheat condenser (109), and an expansion valve to supply low-humidity air to the dehumidifying space and ventilate high-humidity air to the outside of the dehumidifying space. (117), the refrigerant circulation device of the evaporator (107), the desiccant rotor (104), the air supply fan (106), the external air damper (101) on the regeneration inlet side, the external air damper on the regeneration outlet side (105), and the bypass damper. (108), an air circulation device consisting of a supply air volume control damper (110), and an exhaust damper (121), and the refrigerant circulation device and the air circulation device are characterized in that they are integrated.

In the hybrid desiccant dehumidification method without regenerative exhaust of the present invention, the ventilation air 201 of the dehumidifying space is supplied to the regenerative condenser 103 and heated to become the heated desiccant rotor regeneration unit inlet air 204, and the heated desiccant rotor regenerative unit inlet air 204 is used. The rotor regeneration unit inlet air 204 is supplied to the desiccan rotor 104 regeneration unit, and moisture from the desiccan rotor 104 regeneration unit is regenerated and desorbed to become high humidity desiccan rotor regeneration unit outlet air 205. The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106), which sucks the outlet air (205) from the Kantrotor regeneration unit, and the moisture is condensed in the evaporator to produce the cooling dew point and dehumidified evaporator outlet air (208). The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified, and the desiccant rotor dehumidified air 210 is reheated. Heat is exchanged in the condenser 109 to become dehumidification space supply air 212, and the dehumidification space supply air 212 is circulated in the order of being supplied to the dehumidification space.

The hybrid desiccant dehumidification method without regenerative exhaust of the present invention uses desiccant rotor bypass air 209 and the desiccant rotor bypass air 209 that bypasses a portion of the evaporator outlet air 208 when the temperature required in the dehumidifying space is 30° C. or less. It is mixed with the desiccant rotor dehumidified air (210) adsorbed and dehumidified in the processing unit of the canister rotor (104) to become mixed air (211), and the mixed air (211) is heat exchanged in the reheat condenser (109) to supply air to the dehumidifying space ( 212), and the dehumidifying space supply air 212 is circulated in the order in which it is supplied to the dehumidifying space.

In the hybrid desiccant dehumidification method without regenerative exhaust of the present invention, when the pressure required in the dehumidifying space is positive pressure (+) higher than atmospheric pressure, the mixed air of the ventilation air 201 and the outside air 202 of the dehumidifying space ( 203) is supplied to the regeneration condenser 103, or is supplied to the air supply fan 106 that sucks the mixed air 206 of the desiccant rotor regeneration unit outlet air 205 and external air 202. .

In the hybrid desiccant dehumidification method without regenerative exhaust of the present invention, when the pressure required in the dehumidifying space is negative pressure (-) lower than atmospheric pressure, the outlet air 205 of the desiccant rotor regeneration unit is transferred from the air supply fan 106 to the air supply fan. The outlet air (207) is supplied to the evaporator (107), and some of the outlet air (207) from the air supply fan is exhausted to the exhaust air (213).

The hybrid desiccant dehumidifier without regenerative exhaust of the present invention includes a compressor (111), a regenerative condenser (103), an external condenser (118), and an expansion valve to supply low-humidity air to the dehumidifying space and ventilate high-humidity air to the outside of the dehumidifying space. (117), the refrigerant circulation device of the evaporator (107), the desiccant rotor (104), the air supply fan (106), the external condenser fan (119), the external air damper (101) on the regeneration inlet side, and the external air damper on the regeneration outlet side ( 105), an air circulation device consisting of a bypass damper 108, a supply air volume control damper 110, and an exhaust damper 121, and the refrigerant circulation device and the air circulation device are configured as an integrated unit.

The hybrid desiccant dehumidifier without regenerative exhaust of the present invention is characterized in that the external condenser 118 and the external condenser fan 119 are excluded from the integrated type.

In the hybrid desiccant dehumidification method without regenerative exhaust of the present invention, the ventilation air 201 of the dehumidifying space is supplied to the regenerative condenser 103 and heated to become the heated desiccant rotor regeneration unit inlet air 204, and the heated desiccant rotor regenerative unit inlet air 204 is used. The rotor regeneration unit inlet air 204 is supplied to the desiccan rotor 104 regeneration unit, and moisture from the desiccan rotor 104 regeneration unit is regenerated and desorbed to become high humidity desiccan rotor regeneration unit outlet air 205. The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106), which sucks the outlet air (205) from the Kantrotor regeneration unit, and the moisture is condensed in the evaporator to produce the cooling dew point and dehumidified evaporator outlet air (208). The evaporator outlet air 208, whose cooling dew point has been dehumidified in the evaporator, is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified, and the desiccant rotor dehumidified air 210 is dehumidified. It is characterized by circulation in the order in which it is supplied to space.

The hybrid desiccant dehumidification method without regenerative exhaust of the present invention uses desiccant rotor bypass air 209 and the desiccant rotor bypass air 209 that bypasses a portion of the evaporator outlet air 208 when the temperature required in the dehumidifying space is 30° C. or less. It is mixed with the desiccant rotor dehumidified air (210) adsorbed and dehumidified in the processing unit of the canister rotor (104) to become mixed air (211), and the mixed air (211) is circulated in the order of being supplied to the dehumidifying space. .

In the hybrid desiccant dehumidification method without regenerative exhaust of the present invention, when the pressure required in the dehumidifying space is positive pressure (+) higher than atmospheric pressure, the mixed air of the ventilation air 201 and the outside air 202 of the dehumidifying space ( 203) is supplied to the regeneration condenser 103, or is supplied to the air supply fan 106 that sucks the mixed air 206 of the desiccant rotor regeneration unit outlet air 205 and external air 202. .

In the hybrid desiccant dehumidification method without regenerative exhaust of the present invention, when the pressure required in the dehumidifying space is negative pressure (-) lower than atmospheric pressure, the outlet air 205 of the desiccant rotor regeneration unit is transferred from the air supply fan 106 to the air supply fan. The outlet air (207) is supplied to the evaporator (107), and some of the air supply fan outlet air (207) is exhausted to the exhaust air (213).

The hybrid desiccant dehumidification method without regenerative exhaust of the present invention heats the ventilation air in the dehumidifying space in a regenerative condenser to regenerate and desorb the desiccant rotor regenerative part, and dehumidifies the cooling dew point of the high-humidity air by an evaporator through an air supply fan to generate condensation water. In order to control the temperature of the dehumidifying space, the low-temperature air dehumidified by the evaporator is bypassed without passing through the desiccant rotor, or is heated by a reheat condenser and supplied to the dehumidifying space. The temperature and humidity of the air supplied to the dehumidifying space There is an effect of controlling .

The hybrid desiccant dehumidification method without regenerative exhaust of the present invention has the effect of reducing the driving energy of the regenerative fan by regenerating and desorbing moisture from the regenerative part of the desiccant rotor using condenser waste heat and then supplying it to the evaporator, eliminating the need for a separate regenerative fan.

The hybrid desiccant dehumidification method without regenerative exhaust of the present invention has the effect of maintaining positive pressure in the dehumidifying space by introducing external air into the inlet side of the desiccant rotor regeneration section or the outlet side of the desiccant rotor regeneration section.

The hybrid desiccant dehumidification method without regenerative exhaust of the present invention has the effect of maintaining the negative pressure in the dehumidifying space even without a separate exhaust fan by discharging the air to the exhaust damper through the air supply fan on the outlet side of the desiccant rotor regenerative unit.

The hybrid desiccant dehumidification method without regenerative exhaust of the present invention can operate efficiently by configuring one compressor with a regenerative condenser, a reheat condenser, or an external condenser depending on the dehumidifying load, and can operate multiple compressors depending on the dehumidifying load or the capacity of the dehumidifying space. There is an effect that can be applied.

The hybrid desiccant dehumidification method without regenerative exhaust of the present invention has no contact with outdoor air with severe air pollution, is easy to design when it is difficult to add dehumidifying space inside a building or introduces outdoor air, and does not require a regenerative exhaust duct, so it reduces the installation cost of regenerative exhaust ducts. There is a saving effect.

The hybrid desiccant dehumidification method without regenerative exhaust of the present invention has the effect of recycling the condensed water generated in the evaporator and using it as industrial water.

Figure 1 is a configuration diagram of a hybrid desiccant dehumidifier without a regenerative exhaust duct of the present invention.
Figure 2 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust when maintaining positive pressure (+) and using a reheat condenser according to the present invention.
Figure 3 is a flow chart of another dehumidification method of Figure 2
Figure 4 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust when maintaining equal pressure (=) and using a reheat condenser according to the present invention.
Figure 5 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust duct when maintaining negative pressure (-) and using a reheat condenser according to the present invention.
Figure 6 is a configuration diagram of a hybrid desiccant dehumidifier without regenerative exhaust, which is another embodiment of the present invention.
Figure 7 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust when maintaining positive pressure (+) and using an external condenser according to the present invention.
Figure 8 is a flow chart of another dehumidification method of Figure 7
Figure 9 is a flow chart of another dehumidification method of Figure 7
Figure 10 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust when maintaining equal pressure (=) and using an external condenser according to the present invention.
Figure 11 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust when maintaining negative pressure (-) and using an external condenser according to the present invention.

Preferred embodiments of the present invention will be described in detail with reference to the attached drawings. For reference, the sizes of components, thickness of lines, etc. shown in the drawings used to describe the present invention may be somewhat exaggerated for ease of understanding.

In addition, the terms used in the description of the present invention are defined in consideration of the functions of the present invention and may vary depending on the user, operator intention, custom, etc. Therefore, the definition of this term should be based on the overall content of this specification.

In the present application, terms such as 'comprise', 'have', etc. refer to the existence of specific numbers, steps, operations, components, parts, or combinations thereof described in the specification, and do not refer to the presence of one or more other numbers, steps, operations, components, parts, or combinations thereof. It should be understood that this does not exclude in advance the possibility of the presence or addition of features, numbers, steps, operations, components, parts, or combinations thereof.

In addition, the present invention is not limited to the embodiments disclosed below and will be implemented in various different forms, but the present embodiments only serve to ensure that the disclosure of the present invention is complete and to convey the scope of the invention to those skilled in the art. It is provided for complete information.

Therefore, since the present invention can make various changes and take various forms, implementation examples (or embodiments) will be described in detail in the specification. However, this is not intended to limit the present invention to a specific disclosed form, and should be understood to include all changes, equivalents, and substitutes included in the technical idea of the present invention, and the singular expressions used in this specification are clearly different from the context. Unless otherwise intended, plural expressions are included.

However, in describing the present invention, detailed descriptions of well-known or known functions or configurations will be omitted to make the gist of the present invention clear.

Hereinafter, preferred embodiments of the present invention will be described in detail based on the attached drawings.

1 and 6, the square box indicated by a dashed line is a hybrid desiccant dehumidifier without regenerative exhaust of the present invention, and the outside of the square box represents a space outside the hybrid desiccant dehumidifier without regenerative exhaust of the present invention.

In the attached drawings, reference numeral 1** indicates a device, and 2** indicates air flowing.

(+) represents positive pressure, which is a pressure higher than atmospheric pressure, (-) represents negative pressure, which is lower than atmospheric pressure, and (=) represents a pressure equal to atmospheric pressure.

Figure 1 is a configuration diagram of a hybrid desiccant dehumidifier without regenerative exhaust of the present invention.

The hybrid desiccant dehumidifier without regenerative exhaust of the present invention as shown in FIG. 1 includes a compressor 111, a regenerative condenser 103, and a reheat condenser ( 109), expansion valve 117, refrigerant circulation device of the evaporator 107, desiccan rotor 104, air supply fan 106, external air damper on the regeneration inlet side (101), external air damper on the regeneration outlet side (105), It consists of an air circulation device consisting of a bypass damper (108), an air supply air volume control damper (110), and an exhaust damper (121).

The hybrid desiccant dehumidifier without a regeneration duct of the present invention, in which the refrigerant circulation device and the air circulation device are integrated, has no contact with outdoor air with severe air pollution, and is easy to design when adding a dehumidification room inside a building or when it is difficult to introduce outdoor air. There is no need for a regenerative exhaust duct.

As shown in Figure 1, in the hybrid desiccant dehumidifier without regenerative exhaust according to the present invention, when explained in terms of the circulation process of treated air,

The ventilation air (201) of the dehumidifying space alone or the mixed air (203) of the ventilation air (201) of the dehumidifying space and the outside air (202) is supplied to the regeneration condenser (103) and heated, and the heated desiccant rotor regeneration unit inlet. Air (204) is supplied to the regeneration part of the desiccan rotor (104), and the moisture in the regeneration part of the desiccan rotor (104) is regenerated and desorbed to become the high humidity desiccan rotor regeneration part outlet air (205). From the air supply fan (106), which sucks air (205) alone or the mixed air (206) of the desiccant rotor regeneration unit outlet air (205) and external air (202), the air supply fan outlet air (207) is supplied to the evaporator (107). The moisture is supplied and condensed in the evaporator to become the cooled dew point dehumidified evaporator outlet air (208).

The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified. At this time, if the temperature required in the dehumidifying space is 30°C or lower, the desiccan rotor bypass air (209), in which a part of the evaporator outlet air (208) is bypassed, is adsorbed and dehumidified in the processing section of the desiccan rotor (104). It becomes mixed air (211) of dehumidified air (210) and desiccant rotor bypass air (209).

The mixed air 211 of the desiccant rotor dehumidified air 210 and the desiccant rotor bypass air 209 is supplied to the dehumidified space through the dehumidified space supply air 212 after passing through the reheat condenser 109.

The mixed air 203 of the ventilation air 201 of the dehumidifying space and the outside air 202, and the mixed air 206 of the desiccant rotor regeneration unit outlet air 205 and the outside air 202 are required in the dehumidifying space. If the pressure required in the dehumidifying space is a positive pressure (+) higher than atmospheric pressure, it is mixed, and if the pressure required in the dehumidifying space is negative pressure (-) lower than atmospheric pressure, the outside air 202 is not mixed, and ventilation of the dehumidifying space is performed. Only air (201) and desiccant rotor regeneration unit outlet air (205) are used, respectively.

In addition, even when the relative humidity of the ventilation air (201) ventilated from the dehumidification space at the beginning of the dehumidification operation is more than 70%, and mixing outside air (202) with a relative humidity lower than that of the ventilation air (201), ventilation of the dehumidification space The mixed air (203) of the air (201) and the outside air (202) and the mixed air (206) of the desiccant rotor regeneration unit outlet air (205) and the outside air (202) are used when the required pressure of the dehumidifying space is positive pressure. The mixed air (206) of the desiccant rotor regeneration unit outlet air (205) and the external air (202) is supplied to the evaporator (107), and when the required pressure of the dehumidifying space is negative pressure, the desiccant rotor regeneration unit outlet air (205) is supplied to the evaporator (107). ) and external air (202) are supplied to the evaporator (107) and simultaneously exhausted through the exhaust air (213). However, in order to prevent moisture from being released, a water tank is prepared to absorb water.

As shown in Figure 1, in the hybrid desiccant dehumidifier without regenerative exhaust according to the present invention, when explained in terms of the refrigerant circulation process of the cooling device,

The high-temperature vapor refrigerant compressed in the compressor 111 is supplied to the regeneration condenser 103 and used as dehumidification space ventilation air 201 alone or as mixed air 203 of dehumidification space ventilation air 201 and outside air 202. After heat exchange, it is supplied to the reheat condenser (109) and heat-exchanged with the desiccant rotor dehumidified air (210) alone or the mixed air (211) of the desiccant rotor bypass air (209) and desiccant rotor dehumidified air (210) for reheating. After condensing, it is supplied to the receiver 113.

The refrigerant in the receiver 113 is supplied to the refrigerant dryer filter 114, the refrigerant level gauge 115, and the refrigerant electromagnetic valve 116 in that order, expands in the expansion valve 117, and is then supplied to the evaporator 107. Evaporator 107 In the , heat exchange with the supply fan outlet air 207 dehumidifies the cooling dew point of the supply fan outlet air 207 to become the evaporator outlet air 208, and the refrigerant in the evaporator is vaporized and supplied to the compressor 111.

As shown in Figure 1, the hybrid desiccant dehumidifier without a regeneration duct of the present invention, which is configured as an integrated device, does not come into contact with outdoor air with severe air pollution, and is easy to design and requires a regenerative exhaust duct when adding a dehumidification room inside the building or when it is difficult to introduce outdoor air. does not exist.

Figure 2 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust when maintaining positive pressure (+) and using a reheat condenser according to the present invention.

The air flow is heated by supplying the ventilation air (201) from the dehumidifying space to the regeneration condenser (103), and supplying the heated inlet air (204) to the regeneration part of the desiccan rotor (104) to the regeneration part of the desiccan rotor (104). (104) The moisture from the regeneration unit is regenerated and desorbed to become the high humidity desiccant rotor regeneration unit outlet air (205), and the mixed air (206) of the desiccant rotor regeneration unit outlet air (205) and external air (202) is sucked. The supply fan outlet air (207) is supplied from the air supply fan (106) to the evaporator (107), and moisture is condensed in the evaporator to become the cooled dew point dehumidified evaporator outlet air (208).

The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccan rotor 104 processing unit to become desiccant rotor dehumidified air 210 that has been adsorbed and dehumidified. At this time, if the temperature required in the dehumidifying space is 30°C or lower, the desiccan rotor bypass air (209), in which a part of the evaporator outlet air (208) is bypassed, is adsorbed and dehumidified in the processing section of the desiccan rotor (104). It becomes mixed air (211) of dehumidified air (210) and desiccant rotor bypass air (209). The temperature of the mixed air 211 can be controlled by the low temperature desiccant rotor bypass air 209.

The desiccant rotor dehumidified air (210) alone or the mixed air (211) of the desiccant rotor dehumidified air (210) and the desiccant rotor bypass air (209) is supplied to the dehumidifying space through the reheat condenser (109) (212). is supplied to the dehumidifying space.

According to the hybrid desiccant dehumidification method according to the control method of FIG. 2, it is applied when dehumidifying the dehumidifying space temperature is 30°C or less, maintaining positive pressure (+) in the dehumidifying space, heating it with a reheat condenser, and supplying air to the dehumidifying space through temperature and humidity control. (212) Positive pressure (+) can be maintained.

Figure 3 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust when maintaining positive pressure (+) and using a reheat condenser according to the present invention.

The air flow is heated by supplying the mixed air (203) of the ventilation air (201) of the dehumidifying space and the outside air (202) to the regeneration condenser (103), and the heated desiccant rotor regeneration unit inlet air (204) is supplied to the desiccant rotor. It is supplied to the regeneration part of the rotor 104, and the moisture from the regeneration part of the desiccan rotor 104 is regenerated and desorbed to become the high humidity desiccan rotor regeneration part outlet air (205), and the desiccan rotor regeneration part outlet air (205) is sucked. The supply fan outlet air (207) is supplied from the air supply fan (106) to the evaporator (107), and moisture is condensed in the evaporator to become the cooled dew point dehumidified evaporator outlet air (208).

The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified. At this time, when the temperature required in the dehumidification space is low, the desiccan rotor bypass air (209), which bypasses a part of the evaporator outlet air (208), is used to adsorb and dehumidify the desiccan rotor dehumidified air in the processing unit of the desiccan rotor (104). It becomes the mixed air (211) of (210) and desiccant rotor bypass air (209).

The desiccant rotor dehumidified air (210) alone or the mixed air (211) of the desiccant rotor dehumidified air (210) and the desiccant rotor bypass air (209) is supplied to the dehumidifying space through the reheat condenser (109) (212). is supplied to the dehumidifying space.

According to the hybrid desiccant dehumidification method according to the control method of FIG. 3, it is applied when dehumidifying the dehumidifying space temperature is 30℃ or higher. The dehumidifying space is maintained at positive pressure and heated with a reheat condenser to supply air to the dehumidifying space through temperature and humidity control ( 212), positive pressure (+) can be maintained.

Figure 4 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust when maintaining equal pressure (=) and using a reheat condenser according to the present invention.

The air flow is heated by supplying the ventilation air (201) from the dehumidifying space to the regeneration condenser (103), and supplying the heated inlet air (204) to the regeneration part of the desiccan rotor (104) to the regeneration part of the desiccan rotor (104). (104) The moisture from the regeneration unit is regenerated and desorbed to become the high humidity desiccant rotor regeneration unit outlet air (205), and from the air supply fan (106) which sucks the desiccant rotor regeneration unit outlet air (205), the supply fan outlet air (207) ) is supplied to the evaporator (107), moisture is condensed in the evaporator and becomes the cooled dew point dehumidified evaporator outlet air (208).

The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified. At this time, when the temperature required in the dehumidification space is low, the desiccan rotor bypass air (209), which bypasses a part of the evaporator outlet air (208), is used to adsorb and dehumidify the desiccan rotor dehumidified air in the processing unit of the desiccan rotor (104). It becomes the mixed air (211) of (210) and desiccant rotor bypass air (209).

The desiccant rotor dehumidified air (210) alone or the mixed air (211) of the desiccant rotor dehumidified air (210) and the desiccant rotor bypass air (209) is supplied to the dehumidifying space through the reheat condenser (109) (212). is supplied to the dehumidifying space.

According to the hybrid desiccant dehumidification method according to the control method of FIG. 4, the dehumidification space can be maintained at equal pressure (=), heated with a reheat condenser, and air supplied (212) to the dehumidification space through temperature and humidity control.

Figure 5 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust duct when maintaining negative pressure (-) and using a reheat condenser according to the present invention.

The air flow is the ventilation air (201) of the dehumidifying space and The regenerative condenser (103) performs heat exchange. Heated desiccan rotor regeneration unit inlet air (204) is supplied to the desiccan rotor (104) regeneration unit, and high humidity desiccan rotor regeneration unit outlet air (205) is supplied by regenerating and desorbing moisture from the desiccan rotor (104) regeneration unit. The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106) which sucks the outlet air (205) of the desiccan rotor regeneration unit, and the moisture is condensed in the evaporator to dehumidify the cooling dew point of the evaporator. It becomes outlet air (208).

In this embodiment, in order to make the dehumidifying space negative pressure, the desiccant rotor regeneration unit outlet air 205 is supplied from the air supply fan 106, and the supply fan outlet air 207 is supplied to the evaporator 107, while simultaneously supplying the supply fan outlet air 207. ) is exhausted to the exhaust air (213), but in order to prevent moisture from being released, a water tank is prepared and absorbed into the water.

The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified. At this time, when the temperature required in the dehumidification space is low, the desiccan rotor bypass air (209), which bypasses a part of the evaporator outlet air (208), is used to adsorb and dehumidify the desiccan rotor dehumidified air in the processing unit of the desiccan rotor (104). It becomes the mixed air (211) of (210) and desiccant rotor bypass air (209).

The desiccan rotor dehumidified air 210 alone, the desiccan rotor dehumidified air 210, or the mixed air 211 of the desiccan rotor dehumidified air 210 and the desiccan rotor bypass air 209 is supplied to the dehumidifying space. .

According to the hybrid desiccant dehumidification method according to the control method of FIG. 5, the dehumidification space can be maintained at negative pressure, heated by the reheat condenser 109, and air supplied 212 to the dehumidification space through temperature and humidity control.

Figure 6 is a configuration diagram of another embodiment of the hybrid desiccant dehumidifier without regenerative exhaust of the present invention.

The hybrid desiccant dehumidifier without regenerative exhaust of the present invention as shown in Figure 6 includes a compressor 111, a regenerative condenser 103, and an external condenser ( 118), expansion valve (117), refrigerant circulation device of the evaporator (107), desiccan rotor (104), air supply fan (106), external condenser fan (119), external air damper (101) on the regeneration inlet side, external on the regeneration outlet side It consists of an air circulation device consisting of an air damper (105), a bypass damper (108), an air supply air volume control damper (110), and an exhaust damper (121).

The external condenser 118 may be integrated with the hybrid desiccant dehumidifier without regenerative exhaust of the present invention, or the external condenser 118 and the external condenser fan 119 may be installed separately from the hybrid desiccant dehumidifier without regenerative exhaust of the present invention. You can.

As shown in Figure 6, the hybrid desiccant dehumidifier without a regeneration duct of the present invention, which is configured as an integrated device, does not come into contact with outdoor air with severe air pollution, and is easy to design and requires a regenerative exhaust duct when adding a dehumidification room inside the building or when it is difficult to introduce outdoor air. does not exist.

As shown in Figure 6, in the hybrid desiccant dehumidifier without regenerative exhaust according to the present invention, when explained in terms of the circulation process of treated air,

The ventilation air (201) of the dehumidifying space alone or the mixed air (203) of the ventilation air (201) of the dehumidifying space and the outside air (202) is supplied to the regeneration condenser (103) and heated, and the heated desiccant rotor regeneration unit inlet. Air (204) is supplied to the regeneration part of the desiccan rotor (104), and the moisture in the regeneration part of the desiccan rotor (104) is regenerated and desorbed to become the high humidity desiccan rotor regeneration part outlet air (205). From the air supply fan (106), which sucks air (205) alone or the mixed air (206) of the desiccant rotor regeneration unit outlet air (205) and external air (202), the air supply fan outlet air (207) is supplied to the evaporator (107). The moisture is supplied and condensed in the evaporator to become the cooled dew point dehumidified evaporator outlet air (208).

The refrigerant in the external condenser (118) is condensed through heat exchange with the ventilation air (201) of the dehumidifying space alone or the mixed air (203) of the ventilation air (201) of the dehumidifying space and the outside air (202) in the regenerative condenser (103). The refrigerant is supplied to the external condenser (118).

The outside air 214 that has exchanged heat with the external condenser 118 is exhausted to the outside by the external condenser fan 119.

The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified. At this time, when the temperature required in the dehumidification space is low, the desiccan rotor bypass air (209), which bypasses a part of the evaporator outlet air (208), is used to adsorb and dehumidify the desiccan rotor dehumidified air in the processing unit of the desiccan rotor (104). It becomes the mixed air (211) of (210) and desiccant rotor bypass air (209).

The desiccant rotor dehumidified air 210 or the mixed air 211 of the desiccant rotor dehumidified air 210 and the desiccant rotor bypass air 209 is supplied to the dehumidifying space.

The mixed air 203 of the ventilation air 201 of the dehumidifying space and the outside air 202, and the mixed air 206 of the desiccant rotor regeneration unit outlet air 205 and the outside air 202 are required in the dehumidifying space. If the pressure required in the dehumidifying space is a positive pressure (+) higher than atmospheric pressure, it is mixed, and if the pressure required in the dehumidifying space is negative pressure (-) lower than atmospheric pressure, the outside air 202 is not mixed, and ventilation of the dehumidifying space is performed. Only air (201) and desiccant rotor regeneration unit outlet air (205) are used, respectively.

In addition, even when the relative humidity of the ventilation air (201) ventilated from the dehumidification space at the beginning of the dehumidification operation is more than 70%, and mixing outside air (202) with a relative humidity lower than that of the ventilation air (201), ventilation of the dehumidification space The mixed air (203) of the air (201) and the outside air (202) and the mixed air (206) of the desiccant rotor regeneration unit outlet air (205) and the outside air (202) are used when the required pressure of the dehumidifying space is positive pressure. The mixed air (206) of the desiccant rotor regeneration unit outlet air (205) and the external air (202) is supplied to the evaporator (107), and when the required pressure of the dehumidifying space is negative pressure, the desiccant rotor regeneration unit outlet air (205) is supplied to the evaporator (107). ) and the mixed air 206 of the external air 202 are supplied to the evaporator 107 and the exhaust air 213, respectively.

As shown in Figure 6, in the hybrid desiccant dehumidifier without regenerative exhaust according to the present invention, when explained in terms of the refrigerant circulation process of the cooling device,

The high-temperature steam refrigerant compressed in the compressor 111 is supplied to the regeneration condenser 103 and used as dehumidifying space ventilation air 201 alone or as mixed air 203 of dehumidifying space ventilation air 201 and outside air 215. After being condensed through heat exchange, it is supplied to the external condenser (118). The external condenser 118 exchanges heat with the outside air 202, re-condenses it, and then supplies it to the receiver 113.

The refrigerant in the receiver 113 is supplied to the refrigerant dryer filter 114, the refrigerant level gauge 115, and the refrigerant electromagnetic valve 116 in that order, expands in the expansion valve 117, and is then supplied to the evaporator 107. Evaporator 107 In the , heat exchange with the supply fan outlet air 207 dehumidifies the cooling dew point of the supply fan outlet air 207 to become the evaporator outlet air 208, and the refrigerant in the evaporator is vaporized and supplied to the compressor 111.

Figure 7 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust when maintaining positive pressure (+) and using an external condenser according to the present invention.

The air flow is generated by heat exchange between the mixed air (203), which is a mixture of the ventilation air (201) of the dehumidifying space and the outdoor air (202), and the regeneration condenser (103), and the heated desiccan rotor regeneration unit inlet air (204) is transferred to the desiccan rotor ( 104) It is supplied to the regeneration unit and becomes the high humidity desiccan rotor regeneration unit outlet air (205) in which moisture from the regeneration unit of the desiccan rotor (104) is regenerated and desorbed, and the desiccan rotor regeneration unit outlet air (205) and the external The air supply fan outlet air (207), which sucks in the mixed air (206) of the air (202), is supplied to the evaporator (107) to condense the moisture in the evaporator to produce a cooling dew point dehumidified evaporator outlet air (208). It becomes.

The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified. At this time, when the temperature required in the dehumidification space is low, the desiccan rotor bypass air (209), which bypasses a part of the evaporator outlet air (208), is used to adsorb and dehumidify the desiccan rotor dehumidified air in the processing unit of the desiccan rotor (104). It becomes the mixed air (211) of (210) and desiccant rotor bypass air (209).

The desiccant rotor dehumidified air 210 or the mixed air 211 of the desiccant rotor dehumidified air 210 and the desiccant rotor bypass air 209 is supplied to the dehumidifying space.

The hybrid desiccant dehumidification method of FIG. 7 is applied when the dehumidifying space temperature is below 30°C, and improves cooling efficiency by maintaining positive pressure (+) in the dehumidifying space and lowering the condensation pressure using an external condenser.

Figure 8 is a flow chart of a hybrid desiccant dehumidification method without regenerative exhaust, which is another embodiment of the present invention when maintaining positive pressure (+) and using an external condenser.

The air flow is the ventilation air (201) of the dehumidifying space and The regenerative condenser (103) performs heat exchange. Heated desiccan rotor regeneration unit inlet air (204) is supplied to the desiccan rotor (104) regeneration unit, and high humidity desiccan rotor regeneration unit outlet air (205) is supplied by regenerating and desorbing moisture from the desiccan rotor (104) regeneration unit. The air supply fan (106), which sucks in the mixed air (206) of the desiccant rotor regeneration unit outlet air (205) and the external air (202), supplies the air supply fan outlet air (207) to the evaporator (107). The moisture condenses to become the cooling dew point dehumidified evaporator outlet air (208).

The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified. At this time, when the temperature required in the dehumidification space is low, the desiccan rotor bypass air (209), which bypasses a part of the evaporator outlet air (208), is used to adsorb and dehumidify the desiccan rotor dehumidified air in the processing unit of the desiccan rotor (104). It becomes the mixed air (211) of (210) and desiccant rotor bypass air (209).

The desiccant rotor dehumidified air 210 or the mixed air 211 of the desiccant rotor dehumidified air 210 and the desiccant rotor bypass air 209 is supplied to the dehumidifying space.

The hybrid desiccant dehumidification method of Figure 8 is applied when the dehumidifying space temperature is below 30°C, and improves cooling efficiency by maintaining positive pressure (+) in the dehumidifying space and lowering the condensation pressure using an external condenser.

Figure 9 is a flow chart of a hybrid desiccant dehumidification method without regenerative exhaust, which is another embodiment of the present invention when maintaining positive pressure (+) and using an external condenser.

The air flow is mixed air (203), which is a mixture of ventilation air (201) of the dehumidifying space and outdoor air (2202). The regenerative condenser (103) performs heat exchange. Heated desiccan rotor regeneration unit inlet air (204) is supplied to the desiccan rotor (104) regeneration unit, and high humidity desiccan rotor regeneration unit outlet air (205) is supplied by regenerating and desorbing moisture from the desiccan rotor (104) regeneration unit. The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106) which sucks the outlet air (205) of the desiccan rotor regeneration unit, and the moisture is condensed in the evaporator to dehumidify the cooling dew point of the evaporator. It becomes outlet air (208).

The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified. At this time, when the temperature required in the dehumidification space is low, the desiccan rotor bypass air (209), which bypasses a part of the evaporator outlet air (208), is used to adsorb and dehumidify the desiccan rotor dehumidified air in the processing unit of the desiccan rotor (104). It becomes the mixed air (211) of (210) and desiccant rotor bypass air (209).

The desiccant rotor dehumidified air 210 or the mixed air 211 of the desiccant rotor dehumidified air 210 and the desiccant rotor bypass air 209 is supplied to the dehumidifying space.

The hybrid desiccant dehumidification method of Figure 9 improves cooling efficiency by maintaining positive pressure (+) in the dehumidifying space and lowering the condensation pressure using an external condenser.

Figure 10 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust when maintaining equal pressure (=) and using an external condenser according to the present invention.

The air flow is the ventilation air (201) of the dehumidifying space and The regenerative condenser (103) performs heat exchange. Heated desiccan rotor regeneration unit inlet air (204) is supplied to the desiccan rotor (104) regeneration unit, and high humidity desiccan rotor regeneration unit outlet air (205) is supplied by regenerating and desorbing moisture from the desiccan rotor (104) regeneration unit. The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106) which sucks the outlet air (205) of the desiccan rotor regeneration unit, and the moisture is condensed in the evaporator to dehumidify the cooling dew point of the evaporator. It becomes outlet air (208).

The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified. At this time, when the temperature required in the dehumidification space is low, the desiccan rotor bypass air (209), which bypasses a part of the evaporator outlet air (208), is used to adsorb and dehumidify the desiccan rotor dehumidified air in the processing unit of the desiccan rotor (104). It becomes the mixed air (211) of (210) and desiccant rotor bypass air (209).

The desiccant rotor dehumidified air 210 or the mixed air 211 of the desiccant rotor dehumidified air 210 and the desiccant rotor bypass air 209 is supplied to the dehumidifying space.

The hybrid desiccant dehumidification method of Figure 10 maintains equal pressure (=) in the dehumidifying space and improves cooling (compressor) efficiency by lowering the condensation pressure using an external condenser.

Figure 11 is a flow chart of the hybrid desiccant dehumidification method without regenerative exhaust when maintaining negative pressure (-) and using an external condenser according to the present invention.

The air flow is the ventilation air (201) of the dehumidifying space and The regenerative condenser (103) performs heat exchange. Heated desiccan rotor regeneration unit inlet air (204) is supplied to the desiccan rotor (104) regeneration unit, and high humidity desiccan rotor regeneration unit outlet air (205) is supplied by regenerating and desorbing moisture from the desiccan rotor (104) regeneration unit. The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106) which sucks the outlet air (205) of the desiccan rotor regeneration unit, and the moisture is condensed in the evaporator to dehumidify the cooling dew point of the evaporator. It becomes outlet air (208).

In this embodiment, in order to make the dehumidifying space negative pressure, the desiccant rotor regeneration unit outlet air 205 is supplied from the air supply fan 106, and the supply fan outlet air 207 is supplied to the evaporator 107, and some of the air is supplied as exhaust air ( 213) to maintain negative pressure (-) in the dehumidifying space.

The evaporator outlet air 208 whose cooling dew point has been dehumidified in the evaporator is supplied to the desiccant rotor 104 processing unit to become desiccant dehumidified air 210 that has been adsorbed and dehumidified. At this time, when the temperature required in the dehumidification space is low, the desiccan rotor bypass air (209), which bypasses a part of the evaporator outlet air (208), is used to adsorb and dehumidify the desiccan rotor dehumidified air in the processing unit of the desiccan rotor (104). It becomes the mixed air (211) of (210) and desiccant rotor bypass air (209).

The desiccant rotor dehumidified air 210 or the mixed air 211 of the desiccant rotor dehumidified air 210 and the desiccant rotor bypass air 209 is supplied to the dehumidifying space.

The hybrid desiccant dehumidification method of Figure 11 maintains negative pressure in the dehumidifying space and improves cooling (compressor) by lowering the condensation pressure using an external condenser.

Although the invention made by the present inventor has been described in detail according to the above-mentioned embodiments, the present invention is not limited to the above-described embodiments and can of course be changed in various ways without departing from the gist of the invention.

101: External air damper on the regeneration inlet side 102: Air filter
103: Regeneration condenser 104: Desiccant rotor
105: External air damper on the regeneration outlet side 106: Air supply fan
107: Evaporator 108: Bypass damper
109: Reheat condenser 110: Supply air volume control damper
111: Refrigerant compressor 112: Refrigerant high and low pressure switch
113: Refrigerant receiver 114: Refrigerant dryer filter
115: Refrigerant level gauge 116: Refrigerant electromagnetic valve
117: expansion valve 118: external condenser
119: External condenser fan 120: Condensate drain valve
121: Exhaust damper
201: Dehumidifying space ventilation air 202: Outside air
203: Mixed air of dehumidifying space ventilation air + external air
204: Desiccant rotor regeneration unit inlet air
205: Desiccant rotor regeneration unit outlet air
206: Mixed air of external air + desiccant rotor regeneration unit outlet air
207: Supply fan outlet air 208: Evaporator outlet air
209: Desiccant rotor bypass air 210: Desiccant rotor dehumidifying air
211: Mixed air of desiccant rotor dehumidified air + desiccant rotor bypass air
212: Dehumidifying space supply air 213: Exhaust air
214: External condenser outlet outdoor air

Claims (11)

In order to supply low-humidity air to the dehumidifying space and ventilate high-humidity air outside the dehumidifying space,
A refrigerant circulation device of a compressor (111), a regeneration condenser (103), a reheat condenser (109), an expansion valve (117), and an evaporator (107),
Desiccant rotor (104), air supply fan (106), regeneration inlet side external air damper (101), regeneration outlet side external air damper (105), bypass damper (108), supply air volume control damper (110), exhaust damper Air circulation device consisting of (121),
A hybrid desiccant dehumidifier without regenerative exhaust, characterized in that the refrigerant circulation device and the air circulation device are integrated. delete The ventilation air (201) from the dehumidifying space is supplied to the regeneration condenser (103) and heated, becoming the heated desiccant rotor regeneration unit inlet air (204),
Heated desiccan rotor regeneration unit inlet air (204) is supplied to the desiccan rotor (104) regeneration unit to regenerate and desorb moisture from the desiccan rotor (104) regeneration unit, and high humidity desiccan rotor regeneration unit outlet air (205). becomes,
The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106), which sucks the desiccant rotor regeneration unit outlet air (205), condenses moisture in the evaporator, and cools the dew point and dehumidifies the evaporator outlet air (208). ) becomes,
The evaporator outlet air 208, whose cooling dew point has been dehumidified in the evaporator, is supplied to the desiccant rotor 104 processing unit and becomes adsorption dehumidified desiccant dehumidified air 210,
The desiccant rotor dehumidified air (210) is heat exchanged in the reheat condenser (109) to become dehumidifying space supply air (212),
The dehumidifying space supply air (212) is circulated in the order in which it is supplied to the dehumidifying space,
If the temperature required in the dehumidifying space is below 30℃,
The desiccant rotor bypass air (209) obtained by bypassing a part of the evaporator outlet air (208) and the desiccant rotor dehumidified air (210) adsorbed and dehumidified in the processing section of the desiccant rotor (104) are mixed to produce mixed air (211). ) becomes,
The mixed air (211) is heat exchanged in the reheat condenser (109) to become dehumidifying space supply air (212),
A hybrid desiccant dehumidifying method without regenerative exhaust, characterized in that the dehumidifying space supply air (212) is circulated in the order in which it is supplied to the dehumidifying space. The ventilation air (201) from the dehumidifying space is supplied to the regeneration condenser (103) and heated, becoming the heated desiccant rotor regeneration unit inlet air (204),
Heated desiccan rotor regeneration unit inlet air (204) is supplied to the desiccan rotor (104) regeneration unit to regenerate and desorb moisture from the desiccan rotor (104) regeneration unit, and high humidity desiccan rotor regeneration unit outlet air (205). becomes,
The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106), which sucks the desiccant rotor regeneration unit outlet air (205), condenses moisture in the evaporator, and cools the dew point and dehumidifies the evaporator outlet air (208). ) becomes,
The evaporator outlet air 208, whose cooling dew point has been dehumidified in the evaporator, is supplied to the desiccant rotor 104 processing unit and becomes adsorption dehumidified desiccant dehumidified air 210,
The desiccant rotor dehumidified air (210) is heat exchanged in the reheat condenser (109) to become dehumidifying space supply air (212),
The dehumidifying space supply air (212) is circulated in the order in which it is supplied to the dehumidifying space,
If the pressure required in the dehumidifying space is positive pressure (+) higher than atmospheric pressure,
The mixed air (203) of the ventilation air (201) of the dehumidifying space and the outside air (202) is supplied to the regenerative condenser (103), or
A hybrid desiccant dehumidification method without regenerative exhaust, characterized in that the mixed air (206) of the desiccant rotor regeneration unit outlet air (205) and the external air (202) is supplied to the sucked air supply fan (106). The ventilation air (201) from the dehumidifying space is supplied to the regeneration condenser (103) and heated, becoming the heated desiccant rotor regeneration unit inlet air (204),
Heated desiccan rotor regeneration unit inlet air (204) is supplied to the desiccan rotor (104) regeneration unit to regenerate and desorb moisture from the desiccan rotor (104) regeneration unit, and high humidity desiccan rotor regeneration unit outlet air (205). becomes,
The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106), which sucks the desiccant rotor regeneration unit outlet air (205), condenses moisture in the evaporator, and cools the dew point and dehumidifies the evaporator outlet air (208). ) becomes,
The evaporator outlet air 208, whose cooling dew point has been dehumidified in the evaporator, is supplied to the desiccant rotor 104 processing unit and becomes adsorption dehumidified desiccant dehumidified air 210,
The desiccant rotor dehumidified air (210) is heat exchanged in the reheat condenser (109) to become dehumidifying space supply air (212),
The dehumidifying space supply air (212) is circulated in the order in which it is supplied to the dehumidifying space,
If the pressure required in the dehumidifying space is negative pressure (-) lower than atmospheric pressure,
A hybrid desiccant dehumidification method without regenerative exhaust, characterized in that supply fan outlet air (207) is supplied to the evaporator (107), and part of the supply fan outlet air (207) is exhausted as exhaust air (213). In order to supply low-humidity air to the dehumidifying space and ventilate high-humidity air outside the dehumidifying space,
A refrigerant circulation device of a compressor (111), a regenerative condenser (103), an external condenser (118), an expansion valve (117), and an evaporator (107),
Desiccant rotor (104), air supply fan (106), external condenser fan (119), external air damper on the regeneration inlet side (101), external air damper on the regeneration outlet side (105), bypass damper (108), supply air volume control damper (110), an air circulation device consisting of an exhaust damper (121),
A hybrid desiccant dehumidifier without regenerative exhaust, characterized in that the refrigerant circulation device and the air circulation device are integrated. delete delete The ventilation air (201) from the dehumidifying space is supplied to the regeneration condenser (103) and heated, becoming the heated desiccant rotor regeneration unit inlet air (204),
Heated desiccan rotor regeneration unit inlet air (204) is supplied to the desiccan rotor (104) regeneration unit to regenerate and desorb moisture from the desiccan rotor (104) regeneration unit, and high humidity desiccan rotor regeneration unit outlet air (205). becomes,
The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106), which sucks the desiccant rotor regeneration unit outlet air (205), condenses moisture in the evaporator, and cools the dew point and dehumidifies the evaporator outlet air (208). ) becomes,
The evaporator outlet air 208, whose cooling dew point has been dehumidified in the evaporator, is supplied to the desiccant rotor 104 processing unit and becomes adsorption dehumidified desiccant dehumidified air 210,
The desiccant rotor dehumidified air (210) is circulated in the order in which it is supplied to the dehumidifying space,
If the temperature required in the dehumidifying space is below 30℃,
A portion of the evaporator outlet air (208) is mixed with the desiccant rotor bypass air (209) bypassed and the desiccant rotor dehumidified air (210) adsorbed and dehumidified in the processing section of the desiccant rotor (104) to produce mixed air (211). ) becomes,
A hybrid desiccant dehumidification method without regenerative exhaust, characterized in that the mixed air (211) is circulated in the order in which it is supplied to the dehumidification space. The ventilation air (201) from the dehumidifying space is supplied to the regeneration condenser (103) and heated, becoming the heated desiccant rotor regeneration unit inlet air (204),
Heated desiccan rotor regeneration unit inlet air (204) is supplied to the desiccan rotor (104) regeneration unit to regenerate and desorb moisture from the desiccan rotor (104) regeneration unit, and high humidity desiccan rotor regeneration unit outlet air (205). becomes,
The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106), which sucks the desiccant rotor regeneration unit outlet air (205), condenses moisture in the evaporator, and cools the dew point and dehumidifies the evaporator outlet air (208). ) becomes,
The evaporator outlet air 208, whose cooling dew point has been dehumidified in the evaporator, is supplied to the desiccant rotor 104 processing unit and becomes adsorption dehumidified desiccant dehumidified air 210,
The desiccant rotor dehumidified air (210) is circulated in the order in which it is supplied to the dehumidifying space,
If the pressure required in the dehumidifying space is positive pressure (+) higher than atmospheric pressure,
The mixed air (203) of the ventilation air (201) of the dehumidifying space and the outside air (202) is supplied to the regenerative condenser (103), or
A hybrid desiccant dehumidification method without regenerative exhaust, characterized in that the mixed air (206) of the desiccant rotor regeneration unit outlet air (205) and the external air (202) is supplied to the sucked air supply fan (106). The ventilation air (201) from the dehumidifying space is supplied to the regeneration condenser (103) and heated, becoming the heated desiccant rotor regeneration unit inlet air (204),
Heated desiccan rotor regeneration unit inlet air (204) is supplied to the desiccan rotor (104) regeneration unit to regenerate and desorb moisture from the desiccan rotor (104) regeneration unit, and high humidity desiccan rotor regeneration unit outlet air (205). becomes,
The supply fan outlet air (207) is supplied to the evaporator (107) from the air supply fan (106), which sucks the desiccant rotor regeneration unit outlet air (205), condenses moisture in the evaporator, and cools the dew point and dehumidifies the evaporator outlet air (208). ) becomes,
The evaporator outlet air 208, whose cooling dew point has been dehumidified in the evaporator, is supplied to the desiccant rotor 104 processing unit and becomes adsorption dehumidified desiccant dehumidified air 210,
The desiccant rotor dehumidified air (210) is circulated in the order in which it is supplied to the dehumidifying space,
If the pressure required in the dehumidifying space is negative pressure (-) lower than atmospheric pressure,
A hybrid desiccant dehumidification method without regenerative exhaust, characterized in that supply fan outlet air (207) is supplied to the evaporator (107), and part of the supply fan outlet air (207) is exhausted as exhaust air (213).