JPS6268522A - Dry dehumidifier - Google Patents

Abstract

PURPOSE:To reduce the heating load in a regeneration part, by using a heat-exchange element formed by alternately laminating first hygroscopic elements and second moisture-impervious and non-hygroscopic elements and allowing the regeneration air stream after passing through a regeneration part to flow through the second elements of a treatment part immediately before being transferred to the regeneration part. CONSTITUTION:First elements 5a each comprising a hygroscopic heat transfer spacer plate 6a and second elements 5b each comprising a non-hygroscopic, and moisture- impervious, and heat-conductive spacer plate 6b are alternately laminated and partition plates 7 each having a moisture absorbent applied to the surface thereof in the side of each first element are interposed between the first and second elements to constitute a heat-exchange element 1 which is, in turn, rotated. A treating air stream A is blown to the first elements 5a of the treatment part 4a of the heat-exchange element 1 to be dehumidified. The regeneration air stream B after passing through a regeneration part 4b is made to flow to the second elements 5b (preheating parts 4c) of the treatment part 4a immediately before being transferred to the regeneration part 4b to raise the temp. of the heat-exchange element 1 by sensible heat exchange and the load of the heater 10 in the regeneration part 4b is reduced.

Description

[Detailed description of the invention] Industrial applications The present invention relates to a rotary dry dehumidifier.

BACKGROUND OF THE INVENTION Conventionally, a heat exchange element of a dry dehumidifier of this type has a structure as shown in FIG. That is, the rotor 5o impregnated with a moisture absorbent is divided into three parts in the circumferential direction. Each section is sequentially divided into a processing section 61 for dehumidifying the airflow, a preheating section 62 for preheating it, and so on. It is divided into a regeneration section 63 which heats and regenerates it. Also, the airflow 64 passing through the preheating section 62 is the processing airflow 6
Part of 6 is used. When the airflow 64 passes through the preheating section 52, it absorbs a small amount of moisture, so its temperature rises. By inputting this heat into the heater 56, the load of heating the regeneration airflow 64 can be reduced slightly.

Further, since the temperature of the rotor 6o is increased by the preheating section 52,
The reproduction section 53 can perform sufficient reproduction. Note that the rotor 50
is designed to rotate in the direction of arrow X around its axis. (For example, Japanese Unexamined Patent Publication No. 54-42840) Problems to be Solved by the Invention In such a conventional configuration, the airflow 6 flowing into the preheating section 52
4 utilizes a part of the processing airflow 56, so a separator and an air volume adjustment section are required, and moisture absorption in the preheating section 52 (
There was a problem in that the dehumidification (dehumidification) was slight and the temperature of the airflow 54 could not be expected to increase much. This problem can be solved by circulating the preheated airflow 54 in an independent flow path, but an extra blower is required.

In addition, the heater 66 only needs the sensible heat of the airflow 54, and in order to solve this problem, the airflow 64 can be exchanged with the regeneration airflow 57 before entering the heater 56 using a sensible heat exchanger. There is a problem that becomes large.

The present invention solves these problems.

By exchanging sensible heat between the high-temperature regeneration airflow that has passed through the regeneration section and the heat exchange element in the preheating section, without dividing the processing airflow or using an extra sensible heat exchange element or blower, The purpose is to raise the temperature, reduce the load on the heater, preheat the heat exchange element, and perform sufficient regeneration in the regeneration section.

Means for Solving the Problems In order to solve this problem, the present invention provides a first partition plate comprising a moisture-impermeable partition plate having heat conductivity and moisture absorption properties, and a spacing plate having heat conductivity and moisture absorption properties. A cylindrical heat exchange element is formed by alternately stacking elements in the circumferential direction, and a second element composed of non-moisture permeable, non-hygroscopic partition plates and spacing plates having heat conductive properties, forming a flow path so as to divide the airflow passing through the heat exchange element into two parts, a processing section and a regeneration section;
The processing airflow flowing through the processing section and the regeneration airflow flowing through the regeneration section pass through the first element, and the second airflow of the processing section immediately before the portion where the heat exchange element moves from the processing section to the regeneration section due to the rotation of the heat exchange element. A flow path through which a preheated airflow for preheating the heat exchange element passes through the element is partitioned into a preheating section so that it does not mix with the processing airflow, and the regeneration airflow is a preheated airflow that flows through the preheating section after passing through the first element. The flow path is formed so that

Effect: With this configuration, the high-temperature, high-humidity regeneration airflow that has passed through the regeneration section enters the preheating section as a preheating airflow and only exchanges sensible heat through the non-moisture-permeable partition plate, so the temperature of the heat exchange element increases. It is possible to reduce the load on the heater in the regeneration section and perform low dew point dehumidification to ensure sufficient regeneration, and by flowing the preheated airflow of the second element of the processing section immediately before entering the regeneration section, excess air can be removed. This means that the heat exchange element can be preheated without providing a preheating section.

Embodiment - An embodiment of the present invention will be described below with reference to FIGS. 1 to 3. FIG. 1 is a layout diagram of a dry dehumidifier according to an embodiment of the present invention. In the figure, 1 is a heat exchange element, and the electric motor 2
The belt 3 transmits the rotational force to the heat exchange element 1 to rotate it. The heat exchange element 1 is divided by a partition plate (not shown) into a processing section 4a, a regeneration section 4b, and a part of the second element of the processing section 4a as a preheating section 4c. Further, the heat exchange element 1 has first elements 5a and second elements 6b stacked alternately, as shown in FIGS. 2 and 3. The spacing plate 6d of the first element 5a is made of a material having heat conductivity and hygroscopicity (for example, impregnated with a hygroscopic agent such as lithium chloride).

The spacing plate 6b of the second element 6b is a thermally conductive but non-hygroscopic material. 1st and 2nd Elmmen) 5a,
The partition plate 7 interposed between the partition plates 5b is made of a moisture-impermeable material, and a moisture-absorbing agent is applied to the surface facing the first elm plate 5a. 1st
The airflow 8a flowing through the cylindrical element 5a flows from one end of the cylindrical shape to the other end, and the airflow 8b flowing through the second element 6b flows from the side surface on one end side of the outer periphery to the side surface on the other end side. In FIGS. 1 and 3, in the processing section 4a of the heat exchange element 1, the processed airflow A is transferred to the heat exchange element 1 by the blower 9a.
Air is blown to the first elmmen 1-5a section.

Still in the regeneration section 4b, the regeneration airflow B is heated by the heater 10 (for example, a heater, a burner, etc.) and the first
The current flows to the element 6a section. The regeneration airflow B that has passed through the regeneration section 4b turns into a preheated airflow C and flows into the second part 5b of the preheating section 4C.

In the above configuration, the second element 5b (
By flowing the preheating airflow C into the preheating section 4c), sensible heat exchange is performed via the moisture-impermeable partition plate 7, and the temperature of the heat exchange element 1 is increased. This is to reduce the load on the heater 10 in the regeneration section 4b, and if it enters the regeneration section 4b directly from the processing section 4a, heat exchanger 1 due to the generation of heat, etc. during moisture absorption.
Although the temperature of the portion increases, it is lower than the temperature of the regeneration airflow B after passing through the regeneration section 4b. Therefore, by increasing the temperature of the heat exchange element in the preheating section 4C, the temperature of the heat exchange element in the regeneration section 4b can be made higher than when it directly enters the regeneration section 4b, resulting in a load on the heater. can be reduced. Next, the preheated portion that has absorbed moisture enters the regeneration section 4b, and the absorbed moisture is removed by the regeneration airflow B that has become high in temperature with the heater 10. By providing the preheating section as described above, dehumidification with a low dew point can be performed with low power consumption.

Note that FIG. 4 is a diagram of another embodiment of the heat exchange element, and the air flow of the heat exchange element 11 is directed from the cylindrical end face to the outer peripheral part of the other end of both the first element 12 and the second element 13. The side surfaces are configured to flow, and the effect is similar to that of the previous embodiment.

Effects of the Invention As described above, according to the present invention, the first element is composed of a moisture-impermeable partition plate that has heat conductivity and hygroscopicity, and a spacing plate that has heat conductivity and hygroscopicity; A cylindrical heat exchange element is formed by alternately stacking a second element composed of moisture-impermeable, non-hygroscopic partition plates and spacing plates in the circumferential direction, and the heat exchange element is connected to the air flow. A flow path is formed to divide into two parts, a processing section and a regeneration section, and the processing airflow flowing through the processing section and the regeneration airflow flowing through the regeneration section pass through the first element, and the rotation of the heat exchange element The flow path through which the preheating airflow for preheating the heat exchange element passes through the second element of the processing section immediately before the portion transitioning from the processing section to the regeneration section is partitioned as a preheating section so as not to mix with the processing airflow. By forming a flow path so that the regeneration airflow becomes a preheated airflow flowing through the preheating section after passing through the first element, the regeneration airflow that has become high temperature and high humidity in the regeneration section is transferred to the second processing section. It is passed through the preheating section of the element as a preheated air stream, and sensible heat is exchanged through the non-moisture permeable partition plate, increasing only the temperature of the heat exchange element, so that regeneration in the regeneration section is sufficient and dehumidification with a low dew point is possible. In addition, the load on the heater is reduced, resulting in significant energy savings.

[Brief explanation of drawings]

FIG. 1 is a layout diagram of a dry dehumidifier according to an embodiment of the present invention;
FIG. 2 is a schematic diagram of the heat exchange element, FIG. 3 is a schematic diagram of the first and second elements constituting the heat exchange element,
FIG. 4 is a schematic diagram of a heat exchange element in another embodiment, and FIG.
The figure is a layout diagram of a conventional dry dehumidifier. 1...Heat exchange element, 2...Electric motor, 4
a...Processing section, 4b...Reproducing section, 4c
...Preheating section, 5a...--First element, sb...Second element, 6a...
...First element spacing plate, sb...Second
element spacing plate, 7...partition plate, 9a. 9b...Blower, 10...Heater, A
...Processing airflow, B...Regeneration airflow, C.
...Preheating airflow. Name of agent: Patent attorney Toshio Nakao and 1 other person
1 Figure E state dislike t) 3---nothido* 41L-place! 4b ---A % evaluation 4c = -f balance whisper, qb - sparrow style befO --- 60 part jo bar hiri 5 type % type %

Claims (3)

[Claims] (1) A first element composed of a non-moisture-permeable partition plate that has heat conductivity and hygroscopicity, a spacing plate that has heat-conductivity and hygroscopicity, and a non-moisture-permeable, non-hygroscopic partition that has heat conductivity. A cylindrical heat exchange element is formed by alternately stacking second elements composed of plates and spacing plates in the circumferential direction, and the heat exchange element is divided into two parts: an airflow processing section and a regeneration section. forming a flow path so that the processing airflow flowing through the processing section and the regeneration airflow flowing through the regeneration section pass through the first element;
and a flow path through which a preheated airflow for preheating the heat exchange element passes through a second element of the processing section immediately before a portion where the heat exchange element transitions from the processing section to the regeneration section due to rotation of the heat exchange element is mixed with the processing air flow. a preheating section is formed so that the regeneration airflow flows through the preheating section after passing through the first element; a blower for flowing the processing airflow and the regeneration airflow; A dry dehumidifier equipped with an electric motor for rotating a replacement element. (2) The airflow flowing through the first element is formed to flow from one end surface side of the cylindrical heat exchange element to the other end surface side,
2. The dry dehumidifier according to claim 1, wherein the airflow flowing through the second element flows from a side surface on one end of the outer periphery to a side surface on the other end of the outer periphery. (3) The airflow flowing through the first element is formed to flow from one end side of the cylindrical heat exchange element to the outer peripheral side of the other end, and the airflow flowing through the second element is formed from the other end side to one end. The dry dehumidifier according to claim 1, wherein the air flows to the side surface of the outer periphery of the side.