JPH0366597B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION FIELD OF INDUSTRIAL APPLICATION The present invention relates to a heat exchange device used in an air conditioning ventilation fan or the like that effectively exchanges enthalpy between a primary airflow and a secondary airflow.

Conventional configurations and their problems Conventional enthalpy exchange between primary airflow and secondary airflow is performed using a sensible heat exchanger, which exchanges only sensible heat (temperature), and a total heat exchanger, which exchanges sensible heat and latent heat (humidity) at the same time. There is a vessel. Of these, the total heat exchange method is
There are two types: a heat storage rotary type that uses a rotating body to exchange residual heat by repeating heat storage and radiation, or moisture storage and moisture release, and a static transmission type that exchanges sensible heat and latent heat through a partition plate. In the case of the heat storage rotary type, there is a drawback that the heat storage capacity is small, and the effective amount of moisture adsorption to the element is reduced due to the effects of sensible heat storage and heat of adsorption and desorption of moisture. Furthermore, the stationary transmission type has the disadvantage that the total heat exchange efficiency is generally low because temperature and humidity exchange is conducted and diffused through partition walls (partition plates).

OBJECTS OF THE INVENTION The present invention aims to improve the above-mentioned drawbacks, and provides a heat storage/transmission rotary heat exchanger which is a new system that can realize higher efficiency than the conventional one.

Structure of the Invention A circle is formed in which a plurality of partition walls (partition plates) having moisture permeability and moisture absorption are stacked circumferentially at intervals, and primary airflow and secondary airflow alternately pass between these layers. The component is a columnar rotor. By rotating this, the primary airflow and the secondary airflow are periodically exchanged between the layers between the partition walls (partition plates), thereby performing total heat exchange. Heat exchange is performed not only by storing heat and moisture in the element, but also by using partition walls (partition plates).
There is a transmission of heat and humidity (moisture) through.
In other words, it is a combination of a heat storage rotation type and a stationary transmission type, and a higher heat exchange rate than before can be obtained. In the conventional heat storage rotary type, the amount of heat flowing into the heat storage plate is
Although limited by its heat capacity, the partition wall (partition plate) that becomes the heat storage body of the present invention allows heat and moisture to pass through to the other side, so the generated adsorption heat and inflow heat can be processed by means other than rotating the element. Therefore, the amount of heat flowing into the element increases, and a large amount of moisture permeates and adsorbs into the element.

DESCRIPTION OF EMBODIMENTS An embodiment of the present invention will be described based on the drawings. FIG. 1 shows a cylindrical heat exchanger in an embodiment of the present invention. In the figure, 1 is a first element and 2 is a second element, which are alternately stacked to form a cylindrical heat exchanger. FIG. 2 is a diagram showing the first and second elements. The element includes a partition wall (partition plate) 3 having moisture permeability and moisture absorption properties, an end face spacing plate 4 for preventing mixing of the primary air flow and the secondary air flow, and an end spacer plate 4 inside the element on one end face in the axial direction of the cylinder and on the outer periphery. It is composed of spacer plates 5 for allowing airflow to pass through the passage, and these materials are, for example, kraft paper coated or impregnated with colloidal silica as a moisture absorbent and dried. FIG. 3 shows the inflow and outflow paths of airflow within the heat exchanger 6. In the figure, the heat exchanger is completely partitioned into upper and lower parts. At the top of the heat exchanger, the primary airflow α enters from the outer periphery of the cylinder,
It comes out from the left end face in the axial direction of the cylinder. On the other hand, the secondary airflow B similarly enters from the outer circumference and exits from the right end face in the axial direction of the cylinder. Further, in the lower part of the figure, the primary air flow A enters from the right end face in the axial direction of the cylinder and exits from the outer circumference. Similarly, the secondary airflow B enters from the left end face in the axial direction of the cylinder and exits from the outer circumference. FIG. 4 shows a part of the heat exchanger, and shows the flow of air in each element in the upper part of FIG. As shown in the figure, the primary airflow A flows through the first element 1 through a passage that enters from the outer circumference and exits from the left end in the axial direction, and the secondary airflow B similarly flows through the second element 2 from the outer circumference. It flows through a passage that enters and exits from the other right end in the axial direction. Because the heat exchanger is rotating, the portion of the heat exchanger shown in FIG.
Let's move on to the part. As shown in Figure 3, primary airflow A
is the second airflow through which the secondary airflow B was passing at the top.
The secondary airflow enters the element in the opposite direction to the flow direction of the secondary airflow, that is, from the left end in the axial direction, and exits toward the outer circumference. Further, the secondary airflow B flows in the opposite direction to the flow of the primary airflow A through the first element through which the primary airflow A has passed. By rotating the elements in this way, the airflow flowing through the first element and the second element can be exchanged. The above is an example of the flow of air flowing inside the heat exchanger according to the present invention.

This type of system enables heat exchange with higher efficiency than the conventional stationary transmission type or heat storage rotating type. Let's talk about it. Exchange of heat and humidity (moisture) between the primary airflow A and the secondary airflow B takes place through a partition wall (partition plate) 3 between the first and second elements in FIG. In addition, since the heat exchanger 6 is rotating, heat storage and moisture storage are performed in the first element by repeating the alternation of the primary airflow and the secondary airflow, and as in the heat storage rotation type, Total heat exchange takes place. Note that the material of the spacer plate 5 may be any material such as moisture-permeable paper or moisture-impermeable metal.

As mentioned above, the advantage of the heat exchanger of the present invention is that high efficiency can be obtained because the total heat exchange is performed by both the stationary transmission type and the heat storage rotation type. this is,
In the conventional heat storage rotary type, heat and humidity (moisture) not only accumulate heat and moisture but also permeate through the partition walls, and as a result, the amount of heat flowing into the partition walls and the effective amount of moisture adsorption can be increased. caused by.

FIG. 5 is a structural diagram showing an embodiment of an air conditioning ventilation fan using the heat exchanger of the present invention. The primary airflow A exhausted from the indoor side to the outdoor side is heated by the exhaust Sirotskov fan (trade name) 7, and the secondary airflow B, which is supplied from the outdoor side to the indoor room, is heated by the air supply Sirotskov fan (trade name) 8. It flows through the passages in the exchanger, where it exchanges heat. Also, primary airflow A and secondary airflow B
In order to prevent the two from mixing, a blower section partition plate 9 and heat exchange section partition plates 10a to 10g are provided. In this way, the air conditioning ventilation fan using the heat exchanger of the present invention can have a thin overall structure and be easy to manufacture by placing the Sirotskov fan (product name) and the heat exchanger in parallel as shown in the diagram. become. In addition, since the primary airflow passage and the secondary airflow passage can be separated to the left and right in the figure, there is an advantage that they do not mix easily even after exiting the ventilation fan.

Effects of the Invention As described above, in the heat exchange device of the present invention, the total heat exchange efficiency can be higher than that of the conventional device due to the effects of both transmission from the partition wall (conduction and majority) and heat storage and moisture storage due to rotation.

[Brief explanation of drawings]

FIG. 1 is a perspective view of a heat exchanger according to an embodiment of the present invention, and FIG. 2 is a perspective view of first and second elements constituting the heat exchanger. Figure 3 is an explanatory diagram of the airflow passing through the heat exchanger, Figure 4 is a partial schematic diagram of the heat exchanger showing the airflow in Figure 3, and Figure 5 is an illustration of an air conditioning ventilation fan using the heat exchanger. It is a structural diagram. 1... First element, 2... Second element, 3... Partition wall (partition plate), 4... End face partition plate,
5... Spacer plate, 6... Heat exchanger, 7... Sirotskov fan for exhaust, 8... Sirotskov fan for air supply, 9
...Air blower section partition plate, 10a to 10g...Heat exchange section partition plate.

Claims (1)

[Claims] 1. First and second elements having heat storage properties are alternately stacked in the circumferential direction to form a column, and the partition wall existing between the first and second elements has heat conductivity. It has moisture permeability and hygroscopicity, one element is used as a primary air flow passage, the other element is used as a secondary air flow passage, and the passage for the primary air flow and the secondary air flow is created by rotating the cylindrical heat exchanger. can be replaced periodically, the first element allows airflow to pass from one end in the axial direction of the cylindrical heat exchanger to the opening on the outer peripheral side of the cylinder via the axial passage, and the second element A heat exchange device that allows airflow to pass from the other axial end of a cylindrical heat exchanger to an opening on the outer peripheral side of the cylinder via an axial passage. 2 The first element has openings at both ends in the axial direction of the cylinder, allowing airflow to pass from the opening at one end to the opening at the other end, and the second element has a plurality of openings at the outer circumference of the cylinder. 2. The heat exchange device according to claim 1, wherein the airflow is allowed to pass from one opening to the other opening.