JPS61173093A - Method of adjusting length of flowpath of heat exchanger and device therefor - Google Patents

Abstract

PURPOSE:To make it possible to adjust the length of the flowpath to change a heat exchange area and to adjust the heat exchange efficiency by making variable the pressurizing force in the overlapped direction of the heat exchange element, in a pi-flow type heat exchanger. CONSTITUTION:A pressurizing force 6 is applied to the heat exchanger in the laminated direction of the heat exchange element 1. In this case, the pressurizing force is released, and the heat exchange element 1 is caused to slide in the direction of the parallel flowpath 1a to narrow the width of the overlapped portion 5 of the heat exchange element 1. Then, the pressurizing force 6 is again applied to pressfit the overlapped portion 5 to prevent air leakage. Thus, by causing the heat exchange element 1 to slide, the length of the flowpath can be elongated, and the heat exchange efficiency can be increased by enlarging the heat exchange area.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of medical application] The present invention relates to a method for adjusting the flow path length of a heat exchanger and an apparatus therefor, which improve heat exchange efficiency.

[Conventional technology]

Conventionally, a heat exchanger has been proposed in Utility Model Publication No. 1IFJ52-56531 and the applicant's proposal, in which the opposing flow path length of the primary airflow and secondary airflow is increased to increase the heat exchange surface by 81 ft, thereby increasing the heat exchange efficiency χ. This is shown in Japanese Patent Application No. 59-94101.

FIG. 2 shows the latter example, in which 1 is a heat exchange element having a parallel flow @la, and 2 is a spacer having a guiding function for airflow. One end of the heat exchange element 1 in the parallel flow path 1a direction is stacked alternately, and the parallel flow path 1 is stacked on the other end of the heat exchange element 10.
A spacer 2 is provided to close the round part of the flow path 3 that continues to a and maintain the interval. Also, this reason is case 4
Store inside. a and a' are the inlet and outlet of the primary air flow M, and b and b' are the inlet and outlet of the two air flows N. The primary air flow M enters the flow 3 from the suction port a through the parallel flow path 1a, is guided by the spacer 4, bends forward, and blows out from the air outlet a'. The two popular streams N eject from the air outlet b' via the same route as the air inlet.

[Problem that the invention seeks to solve]

However, in the π flow type heat exchanger shown in Fig. 2, in order to prevent air leakage from the 9 parts of each type, each part is pressurized in the logging direction by a pressure plate including the case 4. It is difficult to change the mutual positions of the heat exchange elements l, and it is also difficult to adjust the heat exchange efficiency by changing the length of the flow path and changing the heat exchange surface m. This fact is true
The same applies to the one disclosed in Publication No. 531.

The present invention was made in order to solve the above problems, and an object of the present invention is to adjust the flow path length to change the heat exchange area and adjust the heat exchange efficiency.

[Means for solving problems]

In the present invention, the pressing force in the stacking direction of the heat exchange elements is made variable.

[Effect]

When the pressing force in the stacking direction of the heat exchange elements is released, the heat exchange elements are slid in the parallel flow path direction.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

Figure 1-(Q indicates the flow path length adjustment method according to the present invention,
First, as shown in FIG. 1(4), a pressing force 6 is applied to the heat exchanger in the stacking direction of the heat exchange elements 1.

Here, as shown in FIG. 1 (8), the pressurizing force 6 is released and the heat exchange element 1 is slid in the direction of the parallel flow path 1a to narrow the width of the overlapped portion 5 of the heat exchange cord 1. As shown in Fig. 1 (Q), a pressure force 6 is applied to press the stacked portion 5 to prevent air leakage. By sliding the heat exchanger rope 1 in this way, the length of the flow path is lengthened. It is possible to increase the heat exchange area and increase the heat exchange efficiency.

Next, FIG. 3 shows a flow path length adjustment device of a heat exchanger, in which 7 is a pressure plate provided on both sides of the stacking direction of the heat exchange elements, and a pressure band 8 that can be attached and detached from this pressure plate 7 is used. Tighten and apply pressure in the stacking direction. When changing the flow path length, as shown in FIG. 4, the pressure band 8 is removed, the pressure plate 7 is also removed, the heat exchange element 1 is moved in the direction of the parallel flow path 1a, and the flow path length is changed. Then, as shown in FIG. 3, tighten with a pressure band 8. In this case, Fig. 5(A)
, As shown in (B), pressure plates 7, 7a of different lengths
If the heat exchange element 1 is slid and the pressure plates 7 and 7a are used depending on the gap in which the length of the heat exchanger expands and contracts, the required air volume can be adjusted without changing the size of the heat exchange cord 1. The required heat exchange efficiency can be obtained, and the heat exchange cord 1 can be used in common for all machines.

In the above device as well, the heat exchange element l
By sliding the flow path length, you can control Klk and heat exchange efficiency.

〔Effect of the invention〕

As described above, in the present invention, the heat exchange element can be slid in the parallel flow path direction by varying the pressing force in the stacking direction of the heat exchange element, thereby changing the flow path length and increasing the heat exchange area. It is possible to adjust the heat exchange efficiency by changing vj4.

[Brief explanation of drawings]

Figures 1-C) are explanatory diagrams of the method of the present invention, Figure 2 is a perspective view of a conventional heat exchanger, and Figures 3 and 4 respectively show the pressurized state and The front view in the released state, FIG. 5 (4), @ is an explanatory view when pressure plates of different lengths are used in the apparatus of the present invention. l... Heat exchange element, 1a... Parallel flow path, 2... Spacer, 3... Channel, 5... Stacking part, 7, 7a
...Pressure plate, 8...Pressure band. Note that the same reference numerals in the figures indicate the same or corresponding parts.

Claims (2)

[Claims] (1) Equipped with a heat exchange element having a parallel flow path and a spacer having an air flow guide function, one end of the heat exchange element in the parallel flow path direction is stacked alternately, and a heat exchange element is placed on the other end of the heat exchange element. In a heat exchanger equipped with a spacer that closes the end of the flow path following the parallel flow path and maintains the gap between the parallel flow paths, the heat exchange element A method for adjusting the flow path length of a heat exchanger, characterized in that the flow path length of a heat exchanger is slidable in the direction of the flow path. (2) Equipped with a heat exchange element having a parallel flow path and a spacer having an air flow guide function, one end of the heat exchange element in the direction of the parallel flow path is stacked alternately, and the heat exchange element is placed on the other end of the heat exchange element. In a heat exchanger provided with a spacer that closes the end of the flow path following the parallel flow path and maintains the interval, pressure plates are provided at both ends in the stacking direction of the heat exchange elements,
A flow path length adjustment device for a heat exchanger, characterized in that the pressure plate is fastened by a detachable pressure band, and pressure is applied in the stacking direction via the pressure plate.