JPS6089684A - Method of using heat exchanger and heat exchanger for executing said method - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] [Technical Field] The present invention relates to a method of using a heat exchanger and a corresponding heat exchange device. They can only be used under poor conditions, such as when they are so polluted biologically, physically, and sometimes chemically that it is impossible to use them, or because they require a large amount of money to manufacture and operate. This can be advantageously used in cases such as totoru.

In addition to the basic advantage of being able to be used with any flowing heat source, the method and device of the present invention can be used to positively apply wastewater from toilets and kitchens, industrial wastewater containing various types of filth, and natural water bodies. It has advantages that can be exploited.

[Prior art]

There are a number of indirect heat exchange systems, known as rekuperative heat exchange systems, in which energy (heat) transfer occurs through stationary walls, slats, or immovable transfer surfaces. It is being said.

Such an h-system poses no problem when used with a heat source that is free of contamination or is completely free of contamination. However, for example, some problems occur with the drainage of toilets and kitchens, and with substances containing medium to strong solids or highly concentrated substances.

In almost all cases, no matter how the surface material is installed, due to coarse dirt, adhesion occurs on the contact surface and rapidly increases in size. During the heat exchange operation, such a problem cannot be removed by means that apply a sudden action, increasing the pressure loss and, in the end, it is very rare that the heat source passage is completely closed.

A number of special proposals have been made to alleviate the above-mentioned disadvantageous phenomena. These are mechanical or other aids that perform their own cleaning action, such as by driving contact surfaces or parts of the equipment, or by performing timed and intensive manual cleaning cycles. , costly or ad hoc methods and heat exchange systems.

Considering various requirements, it is often decided that the recovery of energy for reuse from a contaminated heat source must be abandoned and heat losses must be accepted. In other words, a solution that is both technically and economically sufficient does not yet exist.

[Object of the present invention]

This invention proposes a method for using a heat exchanger, and develops a corresponding heat exchange device that maintains complete functionality at all times in a fluid but strongly polluted heat source body. It is a very simple and reliable solution to the previously known main solutions, which provides a stable and improved heat exchange action, as well as substantially lower manufacturing costs and materials. The purpose is to be able to expect outstanding effects such as low costs and low installation costs.

[Configuration of the present invention]

In accordance with the above-mentioned object, the present invention has discovered a use for a heat exchanger, and created a heat exchange device necessary therefor to prevent blockage in the passageway, that is, a region of the heat source body, and to avoid the accumulation of dirt on the contact surface of the heat exchange device. and its increase, while
The basic challenge is to minimize the amount of modification and to minimize installation time.

In addition, heat sources that are highly contaminated, moderately contaminated,
Alternatively, it can be installed in any heat source with a clean one, and high heat exchange efficiency can be obtained. To maintain a constant heat exchange state even if it fluctuates.

The essential problem in realizing this is in the flow path of the heat source.
The aim is to minimize the pressure loss caused by the heat exchange device by appropriately selecting the form of the heat exchange element.

The present invention solves these problems by making the contact surfaces of the heat exchanger able to move freely and completely independently along the flow of the heat source in the flow region of the heat source. are doing.

It is essentially necessary to minimize the pressure loss caused by the heat exchanger in the passage of the heat source body by appropriate design of the heat exchange element. This problem is solved by allowing the contact surfaces in the heat exchanger to move freely in the passage of the heat source, depending on the flow of the heat source and completely independently.

The heat exchange device of the invention therefore comprises a heat exchange element, which is formed from a single flow tube or from a plurality of flow tubes of elastic material, which are elongated and tubular and can be formed into various cross-sections. .

In a first basic embodiment, the heat exchange element is an elastic flow pipe with connecting members at both ends, one of which connects to the main inlet pipe and the other to the main outlet pipe. There is. The main pipes for inflow and outflow are provided inside or outside the flow pipe through which the heat source flows, and are assembled in advance to form a heat exchange device with a composite configuration.

In a second basic embodiment, the flexible heat exchange element has a plurality of resilient holes, a composite tube or a bundle of flow tubes, at one end of which a connecting member is provided. The other ends are interconnected to form flow tubes through which the heat transfer medium from the heat-requiring system enters and exits.

For example, it is preferable for the flow pipes to be arranged in a line in a vertical or horizontal plane in order to make the product uniform and homogeneous in terms of material. It is better to use layers.

2, 3 or 4 arranged in a bundle next to each other on one side
Special consideration should be given to heat exchange elements consisting of solid flow tubes. In particular, when the water level fluctuates or a heat source with low fluidity is intended to recover a certain amount of heat, a three-pass heat exchange element with a closed blind pipe arranged between the inflow pipe and the outflow pipe is used. A substance compatible with the heat source and the heat medium is sealed in the blind tube at an appropriate concentration.

The selection of the material for the heat exchange element that has rocking performance and the inclusion of a substance that protects it from the effects of heat when the heat medium flows in and out improves the heat exchange efficiency at all times and under any circumstances. It's a way to improve.

Maintaining rocking performance in a flow tube filled with a heat source is useful in avoiding excessive frictional forces generated between the tube wall and the heat exchange element, which also act as lift forces.

In combination with the special configuration of the heat exchange element, its flexibility-based free-swinging properties, and the associated favorable self-cleaning properties, it has the following additional advantages on both the heat source side and the heat utilization side: There is.

Fluid resistance and pressure loss are minimized because the heat exchange elements are free to swing and are placed in the direction of least resistance.

The cleaning effect is further improved by repeated short-term pressure increases and decreases on the surface of the heat exchange element placed in the flow tube. By such means it is sometimes possible to separate even very small particles. These particles have strong adhesion and also exhibit very strong adhesion to the heat exchange element in relation to its material.

Normal stress and tangential stress resulting from thermal gradients due to temperature differences and loads due to flow conditions are appropriately dispersed by the free rocking of the heat exchange element.

By selecting the material for the heat exchange element that is appropriate for each case, it can be used even in highly corrosive and chemically contaminated heat sources.

[Explanation of Examples]

The heat exchange device according to the present invention includes a plurality of heat exchange elements 1, a protection tube 5, a connecting member 6, and a flange fixing means 10.
It consists of The heat exchange element 1 consists of inflow and outflow pipes 2.3 for the heat medium and a blind pipe 4, which is filled with air, for example. The protective tube 5 is for protecting the element from a large bending load due to the flow of the heat source, and the connecting member 6 connects the heat medium inflow and outflow tubes 2.8 to a ring-shaped main tube 7.
．． Connect to 8. The main pipe 7.8 is formed in an annular shape, including the mounting flange 9, through which a heat medium flows. The flange fixing means 10 is for inserting and fixing the mounting flange 9 into the flow tube 11 of the heat source.

The dedicated heat exchange elements with a free end on one side and a connecting member 6 on the other side, as shown in FIGS. 2.14.15 and 16, can have two, three Another characteristic is that four tubes are bundled together to form an element. The diameter of the element is selected in such a way that the contact surface for heat exchange is maximally large. Similar effects can be expected whether the tubes are arranged circularly or concentrically.

8.11i and 13 disclose preferred examples of such heat exchange elements in more detail. In these cases, instead of a heat exchange element suspended vertically from top to bottom in the purification sedimentation tank, the element may be arranged horizontally or in a three-dimensional combination of vertical and horizontal elements, although not shown. Various device states are possible. It is also best shown that in some installations, the heat exchange element 1 is submerged, for example, substantially parallel to a drainage pipe, without cleaning pipes or openings, to perform its function. It is characterized by its accomplishments.

As shown in Figures 5.7 and 9, the heat exchanger includes a loop-shaped flow pipe that is equipped with connecting members 6 at both ends and configured as a single element or a bundle of multiple elements. There is something.

In the example shown in FIG. 5, the heat exchange elements 12 are arranged to be shifted by 90 degrees. This element is basically the first
It is also possible to arrange it in a purification sedimentation tank 18 as shown in FIG. The Y-shape of the flow tube 11 shown in FIG.
1, it can be placed horizontally along the flow.

To summarize the embodiments including the heat exchange element, the maximum bending radius of this flexible element is smaller than the cross section of the flow pipe described above. Otherwise, the individual elements may become entangled or form knots in the violently agitated and unfavorable fluid. In cases where there is a danger of snow, it may be advisable to use, for example, strings, ropes or other suitable spacing aids.

[Brief explanation of drawings]

FIG. 1 is a longitudinal cross-sectional view along the tube axis and relates to a heat exchange device with heat exchange elements arranged elongately in flow tubes. This heat exchange element is a tribute. FIG. 2 is a cross-sectional view taken along line II in FIG. 1. FIG. 3 is a longitudinal sectional view of a heat exchange device in which heat exchange elements are arranged in a radial direction. FIG. 4 is a cross-sectional view taken along the line ■--■ in FIG. 8. FIG. 5 is a longitudinal sectional view of a heat exchange device in which the heat exchange elements are arranged radially in the form of a hairpin. 6 is a cross-sectional view taken along the line ■-■ in FIG. 5. FIG. FIG. 7 is a longitudinal sectional view of a heat exchange device in which a heat exchange element is formed in a loop shape. The heat exchange element has no free ends. FIG. 8 is a cross-sectional view taken along line IV-1''v' in FIG. 7. FIG. 9 is a longitudinal cross-section of a heat exchange device in which heat exchange elements are arranged along the longitudinal direction of the flow tube. 10 is a cross-sectional view taken along the line V-■ in FIG. 9. FIG. 12 is a longitudinal cross-sectional view of a heat exchange device arranged along the longitudinal direction of the flow tube. FIG. 12 is a cross-sectional view taken along line VI-VI in FIG. 11. FIG. Figure 14 shows a two-pass heat exchange element with a free end; Figure 15 shows a heat exchanger element with a free end; , shows an eight-passage heat exchange element. FIG. 16 shows a four-passage heat exchange element with free ends. 1: Heat exchange element with free ends 2: Outflow tube 3: Inflow Service pipe 4: Blind pipe 5: Protection pipe 6: Connection member 7: Outflow main pipe 8: Inflow main pipe 9: Flange 10: Flange fixing means 11: Flow pipe for heat source 12: Long heat exchange element at free end 13: Purification and sedimentation tank agent Hikaru Esaki Good agent Hikaru Esaki Figure 3 Figure 4 Figure 7 - Figure 8 Figure 9 Figure 10 Figure 11 Figure 12

Claims (1)

[Claims] 1) A method of using a heat exchanger installed in a flowing heat source that is heavily polluted by 1%, in which the contact part of the exchanger is
The method described above is characterized in that the fluid path, that is, the region of the heat source body is deformed and oscillated freely according to changes in the flow. 2) In order to fully use a heat exchanger installed in a particularly heavily polluted and flowing heat source, the contact part of the exchanger should be located in the fluid passage, that is, in the region of the heat source, and be exposed to changes in the flow. In a heat exchange device equipped with a plurality of heat exchange elements for carrying out a method of freely deforming and rocking the heat exchange elements, each of 1 and 12'l is an elastic material with a single or multiple heat exchange elements. In the case of a loop-type heat exchange element (12) formed into a flow pipe that can be formed into various cross-sectional shapes, and made of a single flow pipe or a combination of multiple flow pipes, a connecting member (6) is attached to each end of the loop heat exchange element (12). In the case of a rod-shaped heat exchange element (1) that is equipped with a plurality of flow pipes (2, 8), one or more connectors (6) as described above are provided on one end thereof. , the other end is connected to each other to form a communication pipe through which a heat medium can flow. 8) The heat exchange device according to claim 2), which The flow pipes in (1, 12) are, in particular, arranged side by side in a vertical or horizontal plane and formed monolithically in terms of structure and material, or mechanically bonded, exploded or clamped. It is characterized by being constructed into a single distribution pipe bundle by means of practical means. 4) The heat exchange device according to claim 2) or 3), wherein the heat exchanger (1, 12) is a heat exchanger device (1, 12) in which a plurality of flow pipes (2, 8) are provided with different densities, such as air. characterized by having a single channel (4) filled with a substance having a 5) A heat exchange device according to any one of claims 2) to 4), in which the flow pipe (2゜3) made of an elastic material, particularly a plastic material, is made of metal or mineral. Characterized by the presence of fibers or other reinforcing and durable fabrics, i.e. reinforcing layers.