KR20220087897A - Movable moisture removal apparatus for rehabilitation of non-excavated pipelines - Google Patents

Abstract

In the present invention, the mobile moisture removal device for non-excavated pipeline regeneration is connected to the construction vehicle through a rope and moved along the inner surface of the thermosetting liner inserted for pipeline regeneration. The heating temperature and time of the heater included in the cylindrical casing are selectively controlled a controlled heater module; And at least one is provided in a portion of the casing of the heater module to continuously measure the presence or absence of moisture such as condensed water inside the thermosetting liner while the heater module is moving. and a moisture sensor module for evaporating and removing moisture such as condensed water inside the thermosetting liner by heating the heater.

Description

Movable moisture removal apparatus for rehabilitation of non-excavated pipelines

The present invention relates to a mobile water removal device for rehabilitating non-excavated pipelines, and more particularly, condensate accumulated on the bottom surface of the inner liner that moves along the inner surface of the thermosetting liner and prevents the attachment of the liner by steam injected into the liner. A removable water removal device for non-digging pipeline regeneration that can detect all moisture inside the liner including is about

Water and sewage conduit facilities are very important facilities that are in charge of the basic fields of social capital supporting the state. Water and sewage pipes composing conduit facilities have a long service life and need to be replaced if deterioration progresses severely.

In addition, regardless of the number of years of use, cracks, joint failure, corrosion, etc. may occur depending on the buried environment.

Although the maintenance rate of water and sewage conduit facilities is very high in urban areas, it is often almost impossible to replace old conduits due to roads and various facilities on the ground. The need for management skills is increasing.

In order to solve this problem, a non-excavation pipe rehabilitation method that can repair conduit facilities in a non-excavating type without excavation work has been developed and distributed using a rehabilitation liner. In the case of using a liner, excavation work can be omitted, so the construction period is shortened, and there are advantages to preventing traffic disturbances and safety accidents during excavation.

In such a non-excavating pipeline rehabilitation method, a liner impregnated with a cured resin is inserted into the pipeline to be repaired, the liner is expanded to adhere to the inner wall of the pipeline, and heat (steam) is blown into the inner surface of the liner to attach the liner to the inner wall of the pipeline. It is a method to rehabilitate pipelines by curing them in

In this thermosetting process, a liner for maintenance of the upper and lower sewer pipes impregnated with a thermosetting resin is usually moved to the site using a refrigeration vehicle, the maintenance liner is inverted with water or air pressure, and then inserted into the existing pipe, and then into the maintenance liner. It consists of a process of thermosetting the thermosetting resin impregnated in the liner by injecting hot air (steam).

However, in order to harden the repair liner, steam is usually supplied into the liner. At this time, the steam supplied to one side of the liner flows along the liner and gradually decreases in temperature and condenses when it reaches the outlet near the other side of the liner. and get stuck on the floor.

The condensed water formed in this way delays curing of the liner, thereby delaying the construction time, and the locally generated condensate may cause a safety problem by non-uniform construction quality of the liner.

In order to solve this problem, conventionally, an Excel pipe was disposed on the bottom surface of the inner liner to discharge condensed water accumulated in the lower part of the liner. The condensed water was introduced into the inside of the unit and discharged to the outside.

However, in the condensed water removal method using the accelerator pipe as described above, not only the condensate inside the liner is discharged, but also the steam is discharged together with the condensed water, resulting in a large heat loss, and the temperature of the steam is lowered, thereby lowering the curing efficiency of the liner. .

In addition, since the steam and condensed water inside the liner are discharged regardless of whether the condensate is actually stagnant when the accelerator pipe is inserted in the lower part of the liner, there is a problem in that unnecessary steam is discharged.

In order to solve the above problem, a device for detecting, draining, and removing condensed water while moving along the liner by putting a specific device into the liner instead of the excel pipe has been developed.

One example of such a portable condensate detection and drain device (Patent Registration No. 10-2043315, a condensate detection sensor used for unexcavated water and sewage maintenance and a condensate drain system using the same) is disclosed in the attached FIG. 1 .

Referring to FIG. 1, in the conventional portable condensate detection and drain device, the condensate detection sensor (A) is composed of a case 10, a cap 30, a heater (not shown), and a condensate detection module (not shown), the case (10) is a configuration that covers the outside of the condensed water detection sensor (A), the slot 12 for the inflow of the condensed water is formed on one side.

In addition, the cap 30 is coupled to both sides of the case 10 to close both sides of the case 10 , and a heater (not shown) is disposed inside the case 10 and is heated to a temperature exceeding the boiling point of condensate.

At this time, the condensate detection module detects the temperature of the heater, and when the temperature of the heater is sensed below the boiling point of the condensed water, it is determined that the condensed water is stagnant inside the case 10. When the heater is immersed in the , it is a principle of determining that the temperature of the heater does not rise above the boiling point of the condensed water.

Therefore, in the above-described conventional invention, the heater is heated to a temperature higher than the boiling point of the condensed water, for example, about 120 degrees Celsius, and when the measured temperature of the heater is lowered to 100 degrees Celsius or less, it is determined that the heater is submerged in the condensate and condensed water to determine the existence of

However, the conventional mobile condensate detection and drain device provides a solution for detecting and draining only a fairly large amount of condensate accumulated on the bottom surface of the liner, and a small amount of condensed water that the heater cannot be submerged in condensate cannot be detected. There were structural problems.

In addition, in addition to the above-mentioned condensed water, there may be dents or water between the old water and sewer pipe and the liner. In the end, due to moisture including condensate accumulated in the tube, the liner was thermoset firmly on the inner surface of the pipe, and there was still a problem in that it was not firmly adhered.

Korean Patent Registration No. 10-2043315 (Registered on Nov. 5, 2019)

Accordingly, the present invention was devised to solve the above problems, and the present invention is to remove condensed water accumulated on the inner bottom surface of the liner, which prevents the attachment of the liner by steam injected into the liner while moving along the inner surface of the thermosetting liner. It is possible to detect all moisture in the liner including intended to provide

The present invention for achieving the above object, the heating temperature and time of the heater included in the cylindrical casing is selectively controlled while moving along the inner surface of the thermosetting liner that is connected through a construction vehicle and a rope and inserted for pipeline regeneration. heater module; and at least one provided in a part of the casing of the heater module to continuously measure the condensed water inside the thermosetting liner while the heater module is moving. and a moisture sensor module for evaporating and removing moisture such as condensed water inside the liner.

In addition, according to an embodiment, at least one tension wheel that rolls while in contact with the inner surface of the liner is further provided on the casing of the heater module.

In addition, according to an embodiment, the moisture sensor module may include: a sensor unit configured to collect moisture data in the form of an elastic wave; a conversion unit converting the moisture data output from the sensor unit into a digital signal; and a processing unit that analyzes the digital signal input from the conversion unit in the frequency domain to determine the presence or absence of moisture.

In addition, according to an embodiment, a pair of metal probes are further protruded from the sensor unit so as to be in contact with the inner bottom surface of the liner, and as the heater module is moved, condensed water in the pair of probes is formed. When electricity is conducted between the probes through contact, the processing unit calculates the amount of condensed water on the inner bottom surface of the liner through the magnitude of electrical conductivity between the probes.

In addition, according to an embodiment, when it is determined that a certain amount of condensed water is present on the inner bottom surface of the liner by the processing unit, at least one of a heating temperature or a heating time of the heater module is increased in proportion to the amount of condensed water to evaporate the condensed water promote

In addition, according to an embodiment, the thermosetting liner may include: blending and preparing a thermosetting unsaturated polyester resin (isophthalic); Preparing a tube composed of a non-woven fabric, a woven fabric or a material in which a non-woven fabric and a woven fabric are combined flexibly woven in one or two layers, and an impermeable plastic film coated on an outer surface of the felt; and injecting the blended resin into a tube under vacuum to impregnate the resin so that the felt of the tube is completely saturated.

As described above, the present invention removes all moisture from the inside of the liner, including condensed water accumulated on the bottom of the liner, which prevents the attachment of the liner by steam injected into the liner while the mobile moisture removal device moves along the inner surface of the thermosetting liner. After detection, the thermosetting liner is firmly attached to the inner surface of the pipeline without lifting by heating and evaporation immediately on site.

In addition, according to the present invention, since the heating temperature or heating time of the heater is controlled according to the amount of moisture, the inner surface of the thermosetting liner is excessively heated by the heater to prevent thermal damage from occurring, while the moisture inside the liner is completely evaporated and removed so that the liner There is an effect that the adhesion and adhesion quality are remarkably improved.

1 is a perspective view showing the configuration of a conventional condensate detection and drain system;
Figure 2 is an operating state diagram showing a mobile water removal device for the regeneration of the present invention non-excavated pipeline according to an embodiment;
3 is a cross-sectional view taken along line AA of FIG.
4 is an exemplary view showing a schematic configuration of a moisture detection module according to the present invention;
5 is an exemplary view showing a schematic configuration of a moisture sensor added to the moisture detection module of FIG. 4

The terms used in this specification are only used to describe specific embodiments, and the terms used in this specification for the present invention are used only to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present specification, terms such as "comprise" or "have" to "have" are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the present specification exist, but one It should be understood that it does not preclude the possibility of the presence or addition of or more other features or numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise herein, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present specification. shouldn't

Hereinafter, with reference to the accompanying drawings, it will be described in more detail according to an embodiment of the mobile water removal device for the regeneration of the non-excavated pipeline of the present invention.

2 is an operating state diagram showing a mobile water removal device for the regeneration of a non-excavated pipeline according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2 .

First, in the present invention, the mobile water removal device 100 for the regeneration of a non-excavated pipeline according to the present invention is provided with a heater module 110 having a cylindrical shape so that it can be inserted into the pipeline P and the liner L that require regeneration. .

The heater module 110 is connected to a construction vehicle (not shown) through a rope (R) and moved along the inner surface of the thermosetting liner (L) inserted for the regeneration of the pipeline (P). The heating temperature and time of the heater 112 are selectively controlled.

That is, when moisture such as condensed water on the inner bottom surface of the liner (L) or water accumulated between the outside of the liner (L) and the conduit (P) is detected while moving along the inside of the thermosetting liner (L), the heater 112 is immediately activated. is operated, and at this time, by further increasing the heating temperature of the heater 112 or moving the heater module 110 more slowly in order to evaporate and remove moisture, the heating time of the corresponding position in which there is moisture may be further increased.

In addition, it is preferable that a power cable is further added to one side of the casing 111 to apply power to the heater module 110 and the moisture sensor module 120 . (See Fig. 2)

In addition, the casing 111 of the heater module 110 may further include at least one tension wheel 130 that rolls while in contact with the inner surface of the liner L.

As shown in FIGS. 2 and 3 , four tension wheels 130 may be provided at the front end and rear end of the casing 111 of the heater module 110, respectively, in order to add tension to the wheel. A tension member 132 such as a spring may be provided at each support 131 portion of the 130 .

Accordingly, when the heater module 110 is moved while the tension wheel 130 is in contact with the inner surfaces of the pipeline P and the liner L, the inner surface of the pipeline P is aged and uneven even if the tension wheel ( It is possible to move while buffering the rolling motion along the curved surface by the tension member 132 of the 130).

In addition, at least one moisture sensor module 120 is provided in a portion of the casing 111 of the heater module 110 .

According to an embodiment, in Figs. 2 and 3, the moisture sensor module 120 is a cylindrical casing 111 of the heater module 110 so as to detect moisture for the entire circumferential surface of the conduit (P), up and down, left and right A moisture sensor module 120 may be provided in each of four places at regular intervals.

At this time, the moisture sensor module 120 continuously measures the presence or absence of moisture such as condensed water located inside the liner L while the heater module 110 moves inside the pipeline P and the liner L. And, if it is detected that there is more than a certain amount of moisture such as condensed water, by adjusting the heating temperature or heating time of the heater module 110, the evaporation of moisture such as condensed water in the thermosetting liner L is promoted and removed.

4 is an exemplary view showing a schematic configuration of a moisture detection module according to the present invention.

More specifically, the moisture sensor module 120 includes a sensor unit 121 that collects moisture data in an elastic wave form, and a converter 122 that converts moisture data output from the sensor unit 121 into a digital signal. , and a processing unit 123 that analyzes the digital signal input from the conversion unit 122 in the frequency domain to determine the presence or absence of moisture.

Accordingly, when it is determined that a certain amount or more of moisture remaining inside the thermosetting liner L is present in the processing unit 123 , at least one of a heating temperature or a heating time of the heater module 110 in proportion to the amount of moisture It is removed by evaporating the moisture.

The sensor unit 121 measures the acoustic wave signal transmitted through the pipe. Specifically, the sensor unit 121 converts an acoustic wave transmitted through a pipeline according to the behavior of moisture into an electrical signal, and transmits the electrical signal to the conversion unit 122 . In particular, the sensor unit 121 may include an acceleration sensor having superior low frequency characteristics compared to an acoustic emission sensor (AES).

In addition, the converter 122 may be an analog to digital converter (ADC) that converts the electrical signal output from the sensor unit 121 into a digital signal.

The processing unit 123 may determine the presence of moisture through frequency analysis of the acoustic wave signal converted into a digital signal by the converting unit 122 . The processing unit 123 is a micro-controller unit (MCU) and may process the digital signal converted from the converting unit 122 .

For example, the moisture sensor module 120 as described above detects a moisture signal in the form of an acoustic wave transmitted along the pipe line P, and in the form of an elastic wave through Fast Fourier Transform (FFT) through the processing unit 123 . By comparing the magnitude A of the fundamental frequency Xk(n) and the fundamental frequency Xk(n) of the moisture signal of , it is possible to accurately and easily determine the presence of moisture.

Since the configuration of the moisture sensor module described above is an exemplary configuration of an embodiment of a device for detecting the presence or absence of moisture (condensate, etc.) using sound waves, the scope of the present invention is limited by these detailed components. specify that it is not

5 is an exemplary diagram showing a schematic configuration of a moisture sensor added to the moisture detection module of FIG. 4 .

Referring to FIG. 5 , a moisture sensor 125 configuration for accurately measuring the amount of condensed water may be further added to the sensor unit of the moisture detection module of the present invention.

That is, in addition to the configuration of FIG. 4 discussed above, a moisture sensor 125 may be further added to the sensor unit 121 .

In the configuration of the moisture sensor 125, a pair of metal probes 125a and 125b are formed to further protrude so as to be in contact with the inner bottom surface of the liner L according to the embodiment shown in FIG. , as the heater module 110 is moved inside the pipeline (P) and the liner (L), condensed water comes into contact with the pair of probes (125a, 125b), and when electricity is conducted between the probes (125a, 125b), the processing unit 123 may calculate the amount of condensed water on the inner bottom surface of the liner L through the magnitude of electrical conductivity between the probes 125a and 125b.

At this time, if the processing unit 123 determines that a certain amount or more of condensed water is present on the inner bottom surface of the liner L, the heating temperature or heating time of the heater 112 inside the heater module 110 is proportional to the amount of the condensed water. By increasing at least one of these, the evaporation and removal time of the condensate may be accelerated in proportion to the increased heating temperature or heating time.

On the other hand, according to an embodiment, the thermosetting liner (L) used in the present invention is a liner impregnated with a thermosetting resin, has excellent corrosion resistance and durability, and has strength and elongation characteristics. It has the characteristics of improving convenience during construction and reducing costs by minimizing excavation during the rehabilitation of

For example, when the thermosetting liner according to the present invention is constructed, the heating temperature for restoring the liner to its original shape by applying heat (steam) to the inside of the liner may be 80 to 100°C.

To this end, the thermosetting liner may include: blending and preparing a thermosetting unsaturated polyester resin (isophthalic); Preparing a tube composed of a non-woven fabric, a woven fabric or a material in which a non-woven fabric and a woven fabric are combined flexibly woven in one or two layers, and an impermeable plastic film coated on an outer surface of the felt; and injecting the blended resin into a tube in a vacuum state and impregnating the resin so that the felt of the tube is completely saturated.

Steps of blending and preparing a thermosetting unsaturated polyester resin (isophthalic):

As a thermosetting unsaturated polyester resin (isophthalic or higher) or capable of exhibiting equivalent or higher performance, the resin composition must satisfy the following characteristics.

Resin Characteristics Analysis items unit method of inspection standard acid KOH ml/g KS M 3331 24 or less non-volatile matter % KS M 3331 55 - 60 viscosity poise KS M 3331 900 or more thixotropy KS M 3331 1.5 - 2.5

At this time, in the case of various additives and curing agents used in the formulation of the resin composition, the curing reaction occurs at room temperature and ultraviolet rays, so it is stored in a cool and dark place. In particular, all causes of ignition are eliminated to prevent explosions and fires due to heat and shock. It should be stored in the

Preparing a tube composed of felt and a film coated on the felt:

The tube is composed of felt and film, and felt is a material that is a combination of a non-woven fabric and a woven fabric or a non-woven fabric or woven fabric woven flexibly in one or two layers, and functions to contain the resin so that it does not flow down. Depending on the type of the felt, it may also play a structural role.

On the other hand, the film is an impermeable plastic film coated on the outer surface of the felt (however, it is placed inside the tube when the liner is reversed during construction). do.

According to one embodiment, as the film, a polyethylene-based plastic film may be used, and if necessary, all kinds of plastic films having impermeability may further include an ethylene vinyl acetate copolymer to improve flexibility and toughness. Available.

At this time, all materials constituting the tube should be of a material that does not change physically and chemically by the resin used.

The tube should be easily impregnated with resin, and should be able to resist reversal and curing pressure and curing temperature.

The tube should have stretchability to match the irregular cross section of the pipe, and it should be made of a material that is flexible enough to allow installation in abnormal parts such as pipe steps, broken parts, separation of joints, and curved pipes of existing pipes.

In addition, in order to prevent the sealing part from bursting during high-temperature pressurization, the tube must satisfy the minimum allowable tensile strength (50 kg/cm 2 or more) in the longitudinal/transverse direction (KS K 0520).

On the other hand, when manufacturing the tube, the manufacturer designs the thickness of the liner as follows in consideration of the required design thickness of the liner, the insertion method, and the effect of expansion in the lateral and longitudinal directions during installation work.

- Circumferential length: When reversing, it expands in the circumferential direction and has a tolerance (small cut) so that it can be closely attached.

- Tube length: The length of the tube is based on continuous installation between manholes, and the maximum construction length must be considered.

- Thickness: When determining the liner thickness using more than one layer of felt, make sure to prevent local thickening of the finished liner at the tube joint. Also, the maximum allowable thickness considering the water permeability complies with the conditions suggested by the designer.

Impregnating the blended resin into the tube under vacuum so that the resin is completely saturated with the felt of the tube:

The impregnation step may be divided into a vacuum operation step and a resin injection step.

1) Vacuum operation step: The vacuum operation is a process of discharging the air in the tube to the outside, and should be performed throughout the entire process of resin injection, starting before resin is injected into the tube.

This is to promote a smooth injection operation when impregnating the resin into the tube, and to prevent the formation of dry spots due to air bubbles in the liner, and the following must be observed.

- Use a vacuum pump with suction capacity higher than the resin injection speed (35m ³ /hr).

- The vacuum standard before resin injection is maintained at 500∼600 mmHg.

- Maintain an appropriate distance in the longitudinal direction of the tube, and perform vacuum work at both ends and, if necessary, at the midpoint.

- In order to thoroughly exhaust the air in the felt, maintain the vacuum state for a certain period of time or more before the impregnation operation.

2) Resin injection step: This step is a process of injecting the resin into the tube using an injection pump, etc. At this time, after checking the vacuum inside the tube, the resin should be completely saturated in all layers.

In addition, by adjusting the thickness of the tube using a roller or the like so that the resin is evenly distributed in the felt, the finished liner should have a uniform thickness and exhibit the planned strength.

As described above, once the resin is injected into the tube, the process cannot be reversed, so the following items should be thoroughly checked before the impregnation operation.

- Check whether the length, diameter, and thickness of the tube are manufactured according to the design dimensions and whether the tube is sealed.

- Check that the room temperature of the impregnation workshop is maintained within about 15℃ ~ 25℃.

- Check that the impregnation equipment is working properly.

When the resin is injected into the tube, the injection rate should be lower than the vacuum rate so that the tube is completely impregnated with the resin.

In addition, the roller spacing is determined so that the resin is properly distributed, and the impregnated tube is advanced between the rollers.

At this time, care must be taken when impregnating the tube for the traction method because an imbalance in the amount of resin impregnated in the upper and lower portions of the tube may be induced due to the nature of field work conditions.

The tube, which has been impregnated according to the above process, is directly loaded onto a refrigerating vehicle immediately upon completion of the impregnation operation, or wound on a reel of an inverter and stored at a low temperature.

The general equipment used in the above-described impregnation step may be composed of a mixer, a resin injection pump, a vacuum pump, a roller plate, an impregnation conveyor, a pinch roller, etc., and must satisfy the scale and function to facilitate the impregnation operation.

The liner manufactured as described above can be folded and stored in a cooling manner to manufacture a thermosetting liner used in the practice of the present invention that can be inserted into the water supply and sewerage pipe.

Meanwhile, during construction, the thermosetting liner is loaded onto a refrigeration vehicle, maintained and stored at about 0 to 5° C., and transported to the construction site for reverse construction.

In addition, the present invention is not limited only by the above-described embodiment, and since it is possible to create the same effect even when changing the detailed configuration, number, and arrangement of the device, those of ordinary skill in the art will present the present invention It is specified that various additions, deletions, and modifications are possible within the scope of the technical idea of

100: removable moisture removal device 110: heater module
111: casing 112: heater
120: moisture sensor module 121: sensor unit
122: conversion unit 123: processing unit
125: moisture sensor 130: tension wheel (wheel)
P : Pipe L : Liner
C: power cable R: rope

Claims (6)

a heater module connected to the construction vehicle through a rope and selectively controlling the heating temperature and time of the heater included in the cylindrical casing while moving along the inner surface of the thermosetting liner inserted for pipeline regeneration; and
At least one is provided in a portion of the casing of the heater module to continuously measure the presence or absence of moisture such as condensed water inside the thermosetting liner while the heater module is moving. Containing; contains;
A portable water removal device for the regeneration of non-excavated pipelines. The method of claim 1,
The casing of the heater module is further provided with at least one tension wheel that rolls in contact with the inner surface of the liner.
A portable water removal device for the regeneration of non-excavated pipelines. The method of claim 1,
The moisture sensor module,
a sensor unit that collects moisture data in the form of seismic waves;
a conversion unit converting the moisture data output from the sensor unit into a digital signal; and
A processing unit for determining the presence or absence of moisture by analyzing the digital signal input from the conversion unit in the frequency domain; including,
A portable water removal device for the regeneration of non-excavated pipelines. 4. The method of claim 3,
In the sensor unit,
A pair of metal probes are further protruded so as to be in contact with the inner bottom surface of the liner, and as the heater module is moved, condensed water comes into contact with the pair of probes to conduct electricity between the probes. Calculating the amount of condensate on the bottom surface of the inner liner through the magnitude of the electrical conductivity between the probes,
A portable water removal device for the regeneration of non-excavated pipelines. 5. The method of claim 4,
When it is determined that a certain amount of condensed water is present on the inner bottom surface of the liner in the processing unit, at least one of a heating temperature or a heating time of the heater module is increased in proportion to the amount of condensed water to promote evaporation of the condensed water,
A portable water removal device for the regeneration of non-excavated pipelines. The method of claim 1,
The thermosetting liner,
Blending and preparing a thermosetting unsaturated polyester resin (isophthalic);
Preparing a tube composed of a non-woven fabric, a woven fabric or a material in which a non-woven fabric and a woven fabric are combined flexibly woven in one or two layers, and an impermeable plastic film coated on an outer surface of the felt; and
An impregnation step of injecting the blended resin into a tube in a vacuum state so that the resin is completely saturated in the felt of the tube;
A portable water removal device for the regeneration of non-excavated pipelines.

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