WO2022035351A1

WO2022035351A1 - Device for dehumidifying air

Info

Publication number: WO2022035351A1
Application number: PCT/RU2021/050152
Authority: WO
Inventors: Павел Михайлович ЗЕЕМАН
Original assignee: Общество с ограниченной ответственностью "ГОРОДСКИЕ ТЕПЛИЦЫ"
Priority date: 2020-08-11
Filing date: 2021-06-02
Publication date: 2022-02-17
Also published as: RU2745532C1

Abstract

A device for dehumidifying air comprises an evaporator, a compressor, a condenser and a capillary tube that are interconnected and form a circuit for the movement of a heat transfer agent, and a fan, a recuperator, a channel for a main air stream, and a channel for an auxiliary air stream. According to the claimed technical solution, the recuperator is disposed in the path of the main air stream and the auxiliary air stream and is designed so as to enable heat exchange between them. In a first embodiment, the recuperator is disposed between the evaporator and the condenser. In a second embodiment, the condenser is an external air conditioning unit. The technical result of the claimed invention is increased efficiency of air dehumidification.

Description

Air dryer

Technical field

The technical solution relates to an indoor air treatment device, in particular to a condensing type dehumidifier.

Prior Art

In the prior art, a device for dehumidifying air is known, including an inlet for air flow from the room and an inlet for outside air flow into the room. The device contains a heat pump, including an evaporator, a condenser and a compressor forming a coolant circulation circuit. At the entrance for the air flow from the room and the entrance for the external air flow into the room there is a heat exchanger for heat exchange of the external cold and internal warm air flows. Patent for invention No. FR 2944587, IPC F24F1/02, published on 05/11/2012.

The main disadvantage of this technical solution is the inability to process a sufficient volume of indoor air. This design does not differ in the efficiency of removing excess moisture from the room. In addition, this placement of the heat exchanger involves the supply of still moist air flows to it. They are dried after heat exchange. Such a configuration of the device elements does not allow either effective regulation of the temperature of the treated air, or its dehumidification.

Known technical solution, selected as the closest analogue, which is a device for dehumidifying the air, including connected compressor, evaporator, throttle device and condenser, forming a circuit for circulation of the coolant. The device has an inlet for supplying air from the room, part which is subjected to pre-cooling and dehumidification due to the heat exchanger and evaporator located on the path of its cyclic flow. The other part of the flow, not being involved in the process of dehumidification and heat exchange at the recuperator, passes through the condenser, meeting with the dried flow already at the outlet. Utility model patent No. CN 208983827, IPC: F26B21/08, published 2019.06.14.

Disclosure of invention

Distinctive features of the proposed solution is the location of the heat exchanger on the path of the main and additional air flows and its implementation with the possibility of heat exchange of these flows.

In the known technical solution, only one part of the stream is subjected to drying and cooling. The other part essentially remains wet. Such a design cannot fully solve the problem of effective air dehumidification.

The technical result of the proposed technical solution is manifested in an increase in the efficiency of air drying.

The efficiency of dehumidification, in particular, is achieved by increasing the volume of processed air while maintaining the energy consumed by the device.

The technical result is achieved by the fact that in the air drying device, which includes an evaporator, a compressor, a condenser and a capillary tube connected to each other, forming a circuit for the movement of the coolant, a fan configured to force an air flow from the evaporator to the condenser, a recuperator, a channel for the main flow air, including an inlet for supplying the main air flow from the room and an outlet for returning the treated main air flow to the room, and passing through the evaporator, heat exchanger and condenser, a channel for additional air flow, including an inlet for supplying an additional air flow from the room and an outlet for returning the processed additional air flow to the room, the heat exchanger is located between the evaporator and the condenser, on the path of the main and additional air flows, and is made with the possibility of their heat exchange. Preferably, the heat exchanger includes a heat exchanger, a storage tank for condensed water and a pipe for draining condensed water to the drain. The technical result is also achieved by the fact that in the air drying device, which includes an evaporator, a compressor, a condenser and a capillary tube connected to each other, forming a circuit for the movement of the coolant, a fan configured to pump air flow from the evaporator to the condenser, a recuperator, a channel for the main air flow, including an inlet for supplying the main air flow from the room and an outlet for returning the treated main air flow to the room, and passing through the evaporator and heat exchanger, a channel for additional air flow, including an inlet for supplying an additional air flow from the room and an outlet for returning the treated additional air flow into the room, the heat exchanger is located on the path of the main and additional air flows, and is made with the possibility of their heat exchange, the condenser is an external unit of the air conditioner.

Dehumidifiers are used to remove excess moisture from rooms with high heat and humidity content, such as warehouses, indoor swimming pools, vertical farms, hospitals, industrial plants with wet production, etc.

Excess moisture is the reason for the discrepancy between the parameters of the microclimate in the room to the optimal values, can lead to malfunction of the equipment, violation of the conditions of the technological process, storage and operation of various materials.

The interconnected evaporator, compressor, condenser and capillary tube form a circuit for the movement of a heat transfer medium such as a refrigerant. The compressor is needed to compress the refrigerant, which is accompanied by the release of heat. The capillary tube promotes the expansion of the refrigerant, which leads to its cooling. Thus, the evaporator heat exchanger has a low temperature to cool the air flow passing through it, and the condenser heat exchanger has a high temperature to heat the air flow passing through it.

The heat exchanger, located between the evaporator and condenser, in the path of the main air flow passing through the evaporator and the additional air flow, allows you to increase the volume of processed air. An additional air flow, dried and slightly cooled due to heat exchange, returns back to the room through one heat exchanger outlet, and slightly heated air from the evaporator is fed through the second heat exchanger outlet to the condenser, where it is additionally heated and also fed back into the room. Thus, the claimed technical solution makes it possible to obtain a two-stage dehumidification system with an increased volume of processed air per unit of energy expended.

In another embodiment, the condenser is an external unit of the air conditioner, while the heat exchanger is also located in the path of the main and additional air flows. In this option, the air from the outlets of the heat exchanger is supplied immediately back to the room. Thus, dehumidification will be associated with cooling the air inside the room. Here, too, an increase in the volume of treated air is achieved.

Brief description of the drawings The claimed technical solution is further explained with the help of figures, which conventionally shows possible versions of the device for dehumidifying the air.

In FIG. 1 is a schematic representation of the structure of the dehumidifier according to the first embodiment of the present invention.

In FIG. 2 is a schematic representation of the structure of the air dryer according to the second embodiment of the present invention.

In FIG. 1, 2 shows a device (1) for drying air, including an evaporator (2) containing a heat exchanger, a storage tank (10) for condensed water and a tube (11) for draining condensed water to the drain, a compressor (3), a condenser (4) , a capillary tube (5), a fan (not shown), a heat exchanger (6) containing a heat exchanger, a storage tank (12) for condensed water and a tube (13) for draining condensed water to the drain, an inlet (7) for supplying the main flow ( 14) air from the room and an outlet (8) for returning the treated main flow (14) of air to the room, an inlet (9) for supplying an additional flow (15) of air from the room and an outlet (16) for returning the treated additional flow (15) of air into the room.

Next, with reference to the figures, the structure of the device (1) for dehumidifying the air is described.

Embodiments of the invention

The air drying device (1) includes an evaporator (2), a compressor (3), a condenser (4) and a capillary tube (5) connected to each other, forming a circuit for the movement of a heat carrier, that is, a refrigerant such as freon. The device (1) includes a fan configured to pump air flows (14) and (15) from the evaporator (2) to the condenser (4).

The device (1) has an inlet (7) for supplying the main air flow (14) from the room and an outlet (8) for returning the treated main air flow (14) to the room, forming a channel for the main air flow (14). The device (1) also has an inlet (9) for supplying an additional air flow (15) from the room and an outlet (16) for returning the treated additional air flow (15) to the room, forming a channel for the additional air flow (15).

On the way of the main flow (14) and the additional air flow (15), a heat exchanger (6) is made with the possibility of their heat exchange. In the first embodiment (Fig. 1), the heat exchanger (6) is placed between the evaporator (2) and the condenser (4). In the second embodiment (Fig. 2), the condenser (4) is an external unit of the air conditioner, and the heat exchanger (6) is placed between the evaporator (2) and outlets (8) and (16) of the main and additional flows (14) and (15 ) air.

In the preferred embodiment, the heat exchanger (6) includes a heat exchanger, a storage tank (12) for condensed water and a pipe (13) for draining condensed water to the drain. Preferably, the evaporator (2) includes a heat exchanger, a storage tank (10) for condensed water and a pipe (11) for draining condensed water to a drain.

The device (1) can have several recuperators (6) installed in cascade.

Preferred options for using the claimed device (1) for drying air are shown below with examples.

The dehumidifier (1) is installed in a room with high humidity. According to the first embodiment (Fig. 1), the main flow (14) of moist warm air enters through the inlet (7) for moist warm air from the room, and the additional flow (15) of moist warm air enters through an additional inlet (9) for moist warm air from the room. Then the main stream (14) of humid warm air passes through the evaporator (2), through which the main stream (14) of moist warm air becomes dry and cold, and is fed to the heat exchanger (6). An additional flow (15) of humid warm air is immediately supplied to the heat exchanger (6).

By means of the recuperator (6), the main stream (14) of dry cold air becomes heated, and the additional stream (15) of humid warm air becomes cooled and dried.

Next, the main stream (14) of heated dry air passes through the condenser (4), through which the stream (14) becomes warm dry air and exits through the corresponding outlet (8) into the room. An additional flow (15) of cooled dried air exits through the corresponding outlet (16) into the room.

According to the second embodiment (Fig. 2), the main flow (14) of moist warm air enters through the inlet (7) for moist warm air from the room, and the additional flow (15) of moist warm air enters through an additional inlet (9) for moist warm air from the room. Then, the main stream (14) of humid warm air passes through the evaporator (2), through which the main stream (14) of moist warm air becomes dry and cold, and is fed to the heat exchanger (6). An additional flow (15) of humid warm air is immediately supplied to the heat exchanger (6).

By means of the recuperator (6), the main stream (14) of dry cold air becomes heated, and the additional stream (15) of humid warm air becomes cooled and dried. Further, the main flow (14) of heated dry air and the additional flow (15) of cooled dried air exit through the respective outlets (8) and (16) into the room, where they are further processed (heated or cooled) by means of an air conditioner.

The presented figures, description of the design and use do not exhaust the possible options for execution and do not limit in any way the scope of the claimed technical solution. Other variants of execution and use within the scope of the claimed formula are possible. The above examples of the implementation of the device for drying air and its use do not limit the scope of the claimed solution to the presented private forms of execution of individual components or stages.

Industrial Applicability

The dehumidifier can be used to remove excess moisture from high heat and humidity environments such as warehouses, indoor swimming pools, vertical farms, hospitals, wet factories, greenhouses, etc. The claimed device is characterized by increased efficiency, in particular, by means of a heat exchanger located on the path of the main and additional air flows, and made with the possibility of their heat exchange.

Claims

Formula

1. A device for dehumidifying air, including an evaporator, a compressor, a condenser and a capillary tube connected to each other, forming a circuit for the movement of a heat carrier, a fan configured to force an air flow from the evaporator to the condenser, a recuperator, a channel for the main air flow, including an inlet for supply of the main air flow from the room and an outlet for returning the treated main air flow to the room, and passing through the evaporator, heat exchanger and condenser, a channel for additional air flow, including an inlet for supplying additional air flow from the room and an outlet for returning the treated additional air flow to a room characterized in that the heat exchanger is located between the evaporator and the condenser, on the path of the main and additional air flows, and is configured to carry out their heat exchange.

2. A device for dehumidifying air along and. 1, characterized in that the heat exchanger includes a heat exchanger, a storage tank for condensed water and a pipe for draining condensed water into the drain.

3. A device for dehumidifying the air, including an evaporator, a compressor, a condenser and a capillary tube connected to each other, forming a circuit for the movement of the coolant, a fan configured to force the air flow from the evaporator to the condenser, a recuperator, a channel for the main air flow, including an inlet for supply of the main air flow from the room and an outlet for returning the treated main air flow to the room, and passing through the evaporator and the heat exchanger, a channel for additional air flow, including an inlet for supplying an additional air flow from the room and an outlet for returning the processed additional flow

nine air into the room, characterized in that the heat exchanger is located on the path of the main and additional air flows, and is made with the possibility of their heat exchange, the condenser is an external unit of the air conditioner.