JPH0581837B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field] The present invention relates to a heat exchange device, which is different from conventional heat exchange devices such as heat recovery devices in which the heat source is biological. They are either physically and sometimes chemically highly polluted and cannot be used in them, or their heat exchange efficiency is very low and they can only be used after spending a large amount of money on manufacturing and operation. This device can be advantageously used in such cases.

In addition to the basic advantage that it can be used with any flowing heat source, the method and installation of the present invention can actively treat wastewater from toilets, kitchens, industrial wastewater containing various filth, natural running water, etc. 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) is transferred through a stationary wall or transfer surface. .

Such a system presents no problems when used with heat sources that are free or have little contamination.
However, some problems occur in materials containing medium to strong solids or highly concentrated substances, such as trays and kitchen wastewater. In almost all cases, no matter how the material is installed due to the bulky dirt, adhesion occurs on the contact surface and rapidly increases in size. When this happens, the heat exchange efficiency decreases rapidly, pressure loss increases, and it is not uncommon for the heat source passage to be completely closed.

A number of special proposals have been made to alleviate the above-mentioned disadvantageous phenomena. These proposals include mechanical or other auxiliary means for carrying out the cleaning action independently, such as by driving contact surfaces or parts of the device, or by carrying out a timed and intensive manual cleaning cycle. proposed an expensive and ad hoc method and heat exchange system.

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 heat exchange device, and it is well known that this heat exchange device is maintained in a fluid but highly polluted heat source at all times while maintaining its complete function. presents a very simple and reliable solution to the main solutions of The aim is to have the desired effect.

[Configuration of the present invention]

In accordance with the above-mentioned object, the present invention creates a heat exchange device to prevent blockage in the passageway, that is, the basin of the heat source body, and the adhesion and increase of dirt on the contact surface of the heat exchange device, while keeping the minimum amount of particles for a long time. The basic challenge is to prevent sedimentation.

Furthermore, it can be installed in any type of heat source, including strongly polluted heat sources, moderately polluted heat sources, or clean heat sources, and a high heat exchange rate can be obtained.
Further, for example, in a passage such as a drain pipe, that is, a passage through which a heat source flows, a constant heat exchange state is maintained even if the water level is constantly fluctuating.

The essential problem in realizing this is to reduce the pressure loss caused by the heat exchange device in the flow path of the heat source.
This can be kept to a minimum by optimizing the shape of the heat exchange element.

The present invention solves this problem by making the contact surfaces of the heat exchange device completely independent and free to move along the flow of the heat source in the flow region of the heat source. There is.

What is essentially required is that in the passage of the heat source,
The aim is to minimize the pressure loss caused by the heat exchanger 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. It consists of a tubular heat exchange element installed in a flow pipe for a particularly heavily polluted and flowing heat source.
In a heat exchange device whose forward and reverse flow distribution parts are fixed by connecting members, each heat exchange element is arranged so as to be freely movable in the flow direction in the heat medium, and the elements are arranged in a single or It is formed from a plurality of elastic flow tubes which are folded back in such a way that the direct heat exchange medium flows directly back through the flow tubes, with the direct heat exchange medium flowing only at one end of the individual heat exchange element. and a connecting member for performing backflow.

In a first basic embodiment, the heat exchange element is an elastic flow pipe with connecting members at both ends, one of which is connected to the main inflow pipe and the other to the main outflow 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 comprises a plurality of resilient, composite tubes or bundles of flow tubes, at one end of which a connecting member is attached. and the other ends are interconnected to form flow tubes through which heat carriers from heat-requiring systems enter and exit.

It is preferable for the flow pipes to be arranged in a line, for example in a vertical or horizontal plane, in order to make the product uniform and homogeneous in terms of material.In addition, for the purpose of extending the service life, an intermediate layer of woven plastic fabric is preferably used. It is good to adopt.

Particular consideration should be given to heat exchange elements consisting of 2.3 or 4 flow tubes arranged in bundles next to each other in one plane. 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 and its flexibility, which allows it to freely oscillate and the associated favorable self-cleaning properties, it has the following advantages on both the heat source side and the heat utilization side: ing.

- Heat exchange elements are free to swing and are positioned in the direction of least resistance, minimizing fluid resistance and pressure losses.

- 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. Such particles have a strong adhesive force and also exhibit a very strong adhesive force in relation to the material of the heat exchange element.

- Vertical and tangential stresses 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 of the heat exchange element that is suitable for each case, highly corrosive,
It can also be used on 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. Heat exchange element 1
consists of heat medium inflow and outflow pipes 2 and 3, and a blind pipe 4 which, for example, is filled with air. 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 and 3 to a ring-shaped main tube 7,
Connect to 8. The main pipes 7 and 8 are formed in an annular shape surrounding the mounting flange 9, and the heat medium flows therethrough.
The flange fixing means 10 is for inserting and fixing the mounting flange 9 into the flow tube 11 of the heat source.

Rod-shaped heat exchange elements having a free end on one side and a connecting member 6 on the other side are shown in FIGS. 2, 14, 15 and 16, 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 maximized. Similar effects can be expected whether the tubes are arranged circularly or concentrically.

3, 11 and 13 disclose in more detail preferred examples of such heat exchange elements. In these, instead of a heat exchange element suspended vertically from top to bottom in the purification sedimentation tank,
Although not shown, various device states are possible, such as arranging the elements horizontally or in a three-dimensional combination of vertical and horizontal elements. Also not shown, in some devices heat exchange element 1
For example, it is characterized in that it is submerged substantially parallel to a drainage pipe without a cleaning pipe or opening to perform its function.

As shown in FIGS. 5, 7, and 9, the heat exchanger includes a loop-shaped flow pipe equipped with connecting members 6 at both ends, and configured into 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 offset by 90 degrees. This element can also basically be arranged in a purification sedimentation tank 13 as shown in FIG. By modifying the Y-shape of the flow tube 11 as shown in FIG. 11 into an X-shape, the heat exchange element 12 can be arranged horizontally in the flow tube 11 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 tangled or form knots in the violently agitated and undesirable fluid.
If there is such a risk, it may be advisable to use, for example, strings, ropes, or other suitable devices to help maintain the distance.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal section along the tube axis, relating to a heat exchange device with heat exchange elements arranged elongately in flow tubes. This heat exchange element is rod-shaped. FIG. 2 is a cross-sectional view taken along the - line 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. Figure 4 shows - in Figure 3.
FIG. 3 is a cross-sectional view taken along a line. 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. 7th
The figure 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 sectional view taken along the - line in FIG. 7. FIG. 9 is a longitudinal sectional view of a heat exchange device in which heat exchange elements are arranged along the longitudinal direction of the flow tube. The heat exchange element has no free ends. FIG. 10 is a cross-sectional view taken along the - line in FIG. 9. 11th
The figure is a longitudinal cross-sectional view of a heat exchange device in which heat exchange elements are arranged along the longitudinal direction of a flow tube into which branched flow tubes are arranged. FIG. 12 is a cross-sectional view taken along the - line in FIG. 11, and FIG. 13 is a longitudinal cross-sectional view of the heat exchange device in which the heat exchange element is submerged in a purification and settling tank. FIG. 14 shows a two-passage heat exchange element with free ends. FIG. 15 shows a three-passage heat exchange element with free ends. FIG. 16 shows a four-passage heat exchange element with free ends. DESCRIPTION OF SYMBOLS 1... Heat exchange element with a free end, 2... Outflow pipe, 3... Inflow pipe, 4... Blind pipe, 5... Protection pipe,
6... Connection member, 7... Outflow main pipe, 8... Inflow main pipe, 9... Flange, 10... Flange fixing means, 1
1... Flow tube for heat source body, 12... Heat exchange element without free end, 13... Purification settling tank.

Claims (1)

[Claims] 1. Consisting of a tubular heat exchange element installed in a flow pipe for a particularly heavily polluted and flowing heat source, the forward and reverse flow distribution section is fixed by a connecting member. In a heat exchange device, each heat exchange element 1 is disposed so as to be freely movable in the flow direction of the heat medium, and each element has a single elasticity or a plurality of elasticities.
3, which is folded back in the flow tube for a direct counterflow of the heat exchange medium, with only one end of each heat exchange element 1 having a direct counterflow and a direct counterflow of the heat exchange medium. A heat exchange device characterized in that a connecting member 6 is attached.