KR101272643B1 - Positive air pressure attenuation device for drainage systems - Google Patents

Abstract

PURPOSE: A positive air pressure attenuation device for a drainage system is provided to prevent backflow and the transfer of smell or noise due to pressure wave and to significantly reduce spatial occupation and difficulties in an installation site. CONSTITUTION: A positive air pressure attenuation device for a drainage system comprises a lower casing(1), a deceleration impeller(2), a tube clone(3), a reflection impeller(4), an upper casing(5), an attenuation master(6), an exterior casing(7), and a clone shaft(8). The lower casing is combined with the pipe nipple of a Y-pipe branched from a standing pipe. The deceleration impeller is combined with the inside of the lower casing for inducing flowed pressure wave and mixing with a collision in order to primarily attenuate the pressure wave. The tube clone is combined with the deceleration impeller for initiatively attenuating the pressure wave. The reflection impeller is combined with the upper side of the tube clone and attenuates the residual pressure wave. The upper casing is combined with the reflection impeller for supporting the tube clone at both sides along with the lower casing. The attenuation master is joined to the upper side of the upper casing for completely and finally attenuating the residual pressure wave. The exterior casing is combined with the lower and upper casings and protectively covers the outside of the tube clone. The clone shaft is combined with the lower and upper casings, maintains the distance between the lower and upper casings, and keeps the balance of the tube clone.

Description

Positive Air Pressure Attenuation Device for Drainage Systems

The present invention relates to a pressure wave attenuator for attenuating pressure waves generated in a wastewater drainage line, and more particularly, to positive air transitions, that is, water discharged from a wastewater drainage pipe of a building. The potential energy is changed into kinetic energy and falls vertically due to acceleration, and the flow of fluid is rapidly cut off at the lower elbow. Therefore, it absorbs and extinguishes the high pressure wave generated in the reverse direction. The high pressure waves that attenuate, secondary attenuate in the tube clone, and eventually disappear in the reflex impeller or occur unexpectedly are related to a four stage pressure wave decay device that finally dissipates in the abatement master.

The purpose of a drainage system installed in a building is to deliver wastewater from sanitary facilities such as toilets, washbasins, bathtubs and the like to the sewer which is normally located in the basement of the building. In the case of a multi-story building, the drainage system comprises a branch pipe for delivering wastewater from each of the sanitary facilities present in each floor to a vertical stack using a connector, And one vertical stack. Even the stack and / or branch or each individual sanitary installation may have a vent valve or other suitable ventilation device and / or a positive air pressure device.

Water traps or water seals are generally used for most sanitary equipment. The purpose of the water trap or water seal is to prevent contaminated air from the sewers from entering the surrounding space or living space. Typically the water trap consists of U-shaped or bottle-shaped housings, generally connected to each sanitary device, and a quantity of water remains in place to block air from the stack or sewer. The flush toilet has a water trap installed in the fixed installation itself.

Under certain conditions, such as negative air pressure or positive air pressure conditions, the water traps can collapse, which means that there is not enough water left in place to insure isolation from the discharge line, It means to get into space. Such defects can lead to paths of pathogen transfer due to overpressure or to system destruction resulting in contamination of the living space.

Therefore, the ventilation of the drainage system is important to prevent the difference in the air pressure of the system, and most systems use aeration pipes and air admittance valves (AAV).

The vent valve allows the air to enter the drainage system through the one-way air valve when the sanitary equipment is activated and water flows through the pipe. When the wastewater column falls through the vertical stack, it is accompanied by airflow and local suction or negative pressure is generated due to the presence of its necessity. These can be delivered through the network and induce a siphon action in the facility water trap seals. To compensate for this negative pressure, the membrane of the vent valve is temporarily raised to allow ambient air to enter the drainage system. The degree of this pressure fluctuation is determined by the fluid volume of the water discharged. Excessive air negative pressure may draw water from the water seal of the traps of the sanitary installation if no vent valve is present.

On the other hand, if the air pressure in the drain is suddenly higher than the surroundings, this positive transient can cause wastewater and air to be pushed into the sanitary system, destroying the trap seal, resulting in terrible hygiene and health consequences. Positive air pressure attenuator devices have therefore been developed and proposed to reduce the risk of such contamination, particularly in high rise or multi-storey buildings.

In other words, in a high-rise building of more than 10 stories, the fluid drained into the drainage system flows around the inside of the pipe when the limit speed is reached and induces air to the middle of the pipe.

If the direction of the pipe is changed from the vertical pipe to the horizontal pipe (below the riser or the direction of the pipe change), a curtain of water is created, and when the air hits the curtain, the air pressure is directed backwards, which is positive. Positive Air Transients.

Positive Air Transients are very high pressure waves with low wavelengths traveling along the drainage system, at a speed of nearly sound velocity of 321 m / sec, about half a gallon of air, and in some cases fluid to be.

This pressure wave reduces the depth of the seal, such as causing the seal to oscillate or minimize.

Positive Air Transients have been demonstrated to cause resonance in conventional piping systems for up to three days. In addition, Positive Air Transients can cause adverse odors or pathogens without destroying the trap's seal. It can also be a factor in the delivery of foam to enable room penetration.

In order to eliminate the positive air pressure (Positive Air Transients) as described above, the evacuation ventilator.

The Sovent system is an indirect method of gradually reducing the positive pressure transition by preventing positive air pressure transients from reaching the critical speed in the piping system.The positive air pressure is used by using a special ventilation or raising part for each branch of the pipe. It is important to prevent the formation of positive air transients.

Single-standing piping (Philadelphia systems) are vented through the roof, resulting in multiple roof penetrations.

There is a problem that a lot of material cost and labor installation space such as the escape escape as described above.

In order to attenuate positive air pressure (Positive Air Transients), there is a problem that has been posted as a pneumatic pressure reducing device defined in the drainage system, but installed in the drainage line or installed on the top.

The wastewater pressure wave attenuation device filed by the present invention includes: attenuation means for attenuating the pressure wave; A housing in which the damping means is built-in and the waste water and the pressure wave flow in and out; It is inserted into the upper part of the housing and connected to the wastewater drainage pipe (VP), and consists of the upper inlet to draw the wastewater and drainage of the upper layer and reduce the falling speed of the wastewater, but it should be installed in the main vertical pipe and the fixing and strength of the damping means There was a weak issue.

In addition, the pressure wave attenuator of the present inventors filed 10-1009571 is a pressure wave having a rising wave to the middle portion of the pipe and a pressure wave having a rising wave hitting the pressure wave rising back to the granular pipe to the wall surface of the pipe. A pressure wave distributor for distributing; A lower cover installed inside the pressure wave splitter and connected to a granular pipe; An external clone installed on an upper portion of the outer wall of the lower cover and collided with a pressure wave having a large wavelength distributed by the pressure wave distributor, and acting as an outer wall of the pressure wave attenuating device; An attenuation tube installed at a portion where the small pressure wave is distributed in the pressure wave distributor, and the small pressure wave is drawn in and attenuated; It is installed in the upper part of the pressure wave splitter and the attenuation tube is coupled to the outside in the middle and the passage of the wastewater and drainage descending from the upper part of the granular pipe is lowered to the bottom, and after the pressure wave with the large wavelength is attenuated, An internal clone that becomes a passage through which the pressure wave exits the granular tube; A return adapter installed on the inner clone and having a large pressure wave attenuated by the outer clone and into which the remaining pressure wave enters; The top of the outer clone is installed as a top cover for the connection with the prized pipe, but should be installed vertically on the prized pipe had a problem that takes up a lot of installation place.

The present invention for solving the above problems can be installed branched from the granular pipe to the Y pipe and can be functional even when installed horizontally or vertically, the first attenuation of the pressure wave in the deceleration impeller, 2 in the tube clone The high pressure wave which attenuates and finally disappears in the reflex impeller or unexpectedly occurs is provided by a pressure wave dissipation device composed of four stages that finally disappear in the reduction master.

The present invention is a pressure wave that is positive air pressure (Positive Air Transients) generated as opposed to the direction of the fluid as the fluid drained into the waste water drain pipe of the high-rise building is changed from the vertical pipe (vertical pipe) to the horizontal pipe It is a pressure quenching device to dissipate.

The pressure quenching device includes: a lower casing coupled with a pipe nipple of a Y pipe branched from the granular pipe, and having a structure in which pressure waves inside the pipe are introduced into and returned without resistance, and thus are not attenuated and are not attenuated; A deceleration impeller coupled to the inside of the lower casing to induce the introduced pressure wave to firstly attenuate the pressure wave by collision and mixing process; A tube clone coupled to the deceleration impeller and acting as a dove at the inner edge of the first attenuated pressure wave at a small aperture, leading to attenuation; A reflection impeller coupled with an upper portion of the tube clone to receive and attenuate a residual amount of pressure waves that are not extinguished from the tube clone; An upper casing coupled with the reflective impeller to allow the tube clone to be supported on both sides together with the lower casing; A reduction master coupled to an upper portion of the upper casing to completely extinguish a pressure wave that is not finally extinguished in the reflection impeller by an unexpected pressure wave generated in an ultra high layer; An outer casing having a lower portion coupled to the lower casing and an upper portion coupled to the upper casing to protect the tube clone so that the tube clone is no longer expanded; It is coupled to the lower casing and the upper casing and is balanced with the tube clone so that no distortion or deformation occurs and consists of a clone axis that serves to maintain the distance between the lower casing and the upper casing.

The lower casing has a cylindrical outer outer wall portion engaging with the outer casing, a pipe coupling portion having a fixed cap for introducing a pressure wave and engaging with the pipe nipple of the Y pipe, and connecting the lower outer wall portion and the pipe coupling portion. And a deceleration impeller casing which is formed in a cylindrical shape at a predetermined interval inwardly from the lower outer wall portion and is joined to the deceleration impeller to become a passage through which pressure waves pass, and the deceleration inside the lower outer wall portion A plurality of deceleration impeller fixing grooves are formed to be coupled to the impeller, and two clonal shaft coupling holes are formed at the inner curved portion of the deceleration impeller casing to which the clone shaft is inserted.

The upper casing includes a cylindrical upper outer wall portion coupled to the outer casing, a reduction master coupling portion having a fixed cap for coupling with the reduction master, a curved portion connecting the upper outer wall portion and the reduction master coupling portion, and It is formed in a cylindrical shape at a predetermined interval inwardly with the upper outer wall portion and is composed of a reflective impeller casing which is joined to the reflective impeller and becomes a passage through which residual pressure waves pass, and inside the upper outer wall portion, a plurality of coupled to the reflective impeller Two reflective impeller fixing grooves are formed, and two inner side of the reflective impeller casing are formed with two clone shaft coupling holes into which the clone shaft is inserted.

The fixing cap is formed with an female screw screwed to the screw portion, an O-ring insertion groove into which an O-ring is inserted to prevent leakage of waste water or air, and a rotary tooth to be fastened or loosened by a tool.

The deceleration impeller is coupled to the lower casing and consists of a cylindrical lower casing coupling portion, and a deceleration portion in which the pressure wave is introduced and attenuated first, the lower casing coupling portion is coupled to the deceleration impeller fixing hole of the lower casing A plurality of fixing protrusions are formed.

The deceleration unit has a plurality of deceleration blades inclined at a predetermined angle by firstly attenuating the pressure wave by collision and mixing; One side of the deceleration blade is bonded to the inside and the outer support of the cylindrical shape in which the tube clone is inserted and coupled to the outside; The other side of the reduction blade is joined and supported and consists of a support inner cylinder formed at the center, the support outer cylinder is formed with a tube clone fixing groove for coupling the tube clone.

The reflective impeller is coupled to the upper casing and consists of a cylindrical upper casing coupling portion, and a reflection deceleration portion into which the residual pressure wave attenuated by the tube clone is introduced and attenuated, and the upper casing coupling portion includes the upper casing portion of the upper casing. A plurality of fixing protrusions are formed to engage with the reflective impeller fixing groove.

The reflection deceleration unit includes a plurality of reflection wings that are attenuated at a predetermined angle by attenuating and mixing the residual pressure wave by collision and mixing; A cylindrical reflection support outer cylinder through which a residual amount of pressure waves attenuated inward is introduced and into which the tube clone is inserted and coupled; A cylindrical reflection wing support on which one side of the reflection wing is bonded and supported; The other side of the reflective wing is bonded and supported by a conical column formed in the center of the center, the reflective support outer cylinder is formed of a tube clone fixing groove for coupling the tube clone.

The reduction master has a structure in which a plurality of reduction blades are installed obliquely to remove pressure waves that are not completely removed from the reflective impeller with unexpected pressure waves, and a reduction center ring for supporting the reduction wings in the center.

The above-mentioned pressure quenching device of the waste water pipe can solve the problem to be solved of the present invention.

The pressure wave quenching device of the present invention uses a granular piping or a preventive device, which is an evacuation vent installed to remove pressure waves caused by positive air pressure transients. Since it is installed on the main body instead of the main body, there is no restriction in horizontal or vertical installation, and there is no problem in parallel or serial installation, so the size of the device is not limited by the installation location. There is an advantage.

In addition, it is possible to dissipate the backflow, odor or noise transition that may be caused by the pressure wave, and to prevent the secondary damage such as viral bacteria or pathogens by lowering the depth of the seal by drying the fluctuations or seals of the seal due to the pressure wave It can be released from various bacteria, and when the pressure in the pipe becomes higher than the atmospheric pressure, there is an effect of preventing the factors that may destroy the seals of the trap such as the toilet bowl sink.

1 is an overall front view and a plan view according to the pressure quenching device of the waste water pipe of the present invention
Figure 2 is an overall cross-sectional view according to the pressure quenching device of the waste water pipe of the present invention
Figure 3 is a system diagram of the installation according to the pressure quenching device of the waste water pipe of the present invention
Figure 4 is a vertical installation example according to the pressure quenching device of the waste water pipe of the present invention
5 is a horizontal installation example according to the pressure quenching device of the waste water pipe of the present invention
Figure 6 is a perspective view of the lower casing according to the pressure quenching device of the waste water pipe of the present invention
Figure 7 is a schematic diagram of the lower casing according to the pressure quenching device of the waste water pipe of the present invention
8 is a perspective view of the upper casing according to the pressure quenching device of the waste water pipe of the present invention
Figure 9 is a schematic diagram of the upper casing according to the pressure quenching device of the waste water pipe of the present invention
10 is a perspective view of the deceleration impeller according to the pressure quenching device of the waste water pipe of the present invention
11 is a schematic diagram of a deceleration impeller according to the pressure quenching device of the waste water pipe of the present invention
12 is a perspective view of the impeller according to the pressure quenching device of the waste water pipe of the present invention
Figure 13 is a schematic diagram of the reflection impeller according to the pressure quenching device of the waste water pipe of the present invention
14 is a schematic diagram of the reduction master according to the pressure quenching device of the waste water pipe of the present invention
15 is a schematic view of the tube clone according to the pressure quenching device of the waste water pipe of the present invention
Figure 16 is a schematic diagram of the outer casing according to the pressure quenching device of the waste water pipe of the present invention
17 is a schematic view of the clone shaft according to the pressure quenching device of the waste water pipe of the present invention
18 is a perspective view of the fixing cap according to the pressure quenching device of the waste water pipe of the present invention
19 is a schematic view of a fixed cap according to the pressure quenching device of the waste water pipe of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS First, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In addition, the terms to be described later are defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or the operator, and the definition thereof describes the "pressure quenching device of the waste water pipe" according to the present invention. It should be made based on the contents throughout the specification.

Hereinafter, a preferred embodiment of the "pressure quenching device of the waste water pipe" according to the present invention will be described in detail with reference to the drawings. The following examples are merely illustrative of the present invention and are not intended to limit the scope of the present invention.

1 is an overall front view and a plan view according to the pressure quenching device of the wastewater pipe of the present invention, Figure 2 is a full cross-sectional view of the pressure quenching device of the wastewater pipe of the present invention, Figure 3 is a pressure quenching of the wastewater pipe of the present invention 4 is a vertical installation example according to the pressure quenching device of the wastewater pipe of the present invention, FIG. 5 is a horizontal installation example of the pressure quenching device of the wastewater pipe of the present invention, and FIG. Figure 7 is a perspective view of the lower casing according to the pressure quenching device of the drainage pipe of the present invention, Figure 7 is a schematic diagram of the lower casing according to the pressure quenching device of the drainage pipe of the present invention, Figure 8 is a perspective view of the upper casing according to the pressure quenching device of the drainage pipe of the present invention 9 is a schematic view of the upper casing according to the pressure quenching device of the wastewater pipe of the present invention, Figure 10 is a perspective view of the deceleration impeller according to the pressure quenching device of the wastewater pipe of the present invention, Figure 11 is Figure 12 is a schematic diagram of a deceleration impeller according to the pressure quenching device of the wastewater pipe of the present invention, Figure 12 is a perspective view of the impeller according to the pressure quenching device of the wastewater pipe of the present invention, Figure 13 is a reflection according to the pressure quenching device of the wastewater pipe of the present invention It is a schematic diagram of the impeller, Figure 14 is a schematic diagram of the reduction master according to the pressure quenching device of the wastewater pipe of the present invention, Figure 15 is a schematic diagram of a tube clone according to the pressure quenching device of the wastewater pipe of the present invention, Figure 16 is a wastewater pipe of the present invention Figure 17 is a schematic view of the outer casing according to the pressure quenching device of the present invention, Figure 17 is a schematic view of the clone shaft according to the pressure quenching device of the drainage pipe of the present invention, Figure 18 is a perspective view of the fixed cap according to the pressure quenching device of the waste water pipe of the present invention, 19 is a schematic view of a fixed cap according to the pressure quenching device of the waste water pipe of the present invention.

As shown in Figure 1 and 2, the present invention is the amount of the fluid drained to the drainage pipe of the high-rise building as the direction of the pipe is changed from the standing pipe (vertical pipe) to the horizontal pipe as opposed to the direction of the fluid It is a pressure quenching device (A) to dissipate the pressure waves which are positive air transients.

The pressure quenching device (A) includes a lower casing (1) coupled to the pipe nipple of the Y pipe branched from the granular pipe and having a structure in which a pressure wave inside the pipe flows in without resistance and is returned and hardly attenuated; A deceleration impeller (2) coupled to the inside of the lower casing (1) to induce pressure waves introduced therein to primarily attenuate the pressure waves by collision and mixing process; A tube clone (3) coupled to the deceleration impeller (2) for dominantly attenuating the primary attenuated pressure wave at the inner edge extended at a small aperture; A reflection impeller (4) coupled to an upper portion of the tube clone (3) to receive and attenuate a residual amount of pressure waves not extinct in the tube clone; An upper casing (5) to which the reflective impeller (4) is coupled so that the tube clone (3) can be supported on both sides together with the lower casing (1); A reduction master (6) coupled to the upper portion of the upper casing (5) to completely extinguish the pressure wave not finally extinguished in the reflection impeller (4) by an unexpected pressure wave generated in the ultrahigh-rise; A lower casing (7) is coupled to the lower casing (1) and the upper part is coupled to the upper casing (5) to surround the outer tube so that the tube clone (3) no longer inflated to protect the tube clone (3) (7) )and; It is coupled to the lower casing (1) and the upper casing (5) and balances the tube clone (3) so as not to warp or deformation occurs to maintain the distance between the lower casing (1) and the upper casing (5) It consists of a clone shaft (8) to play a role.

The pressure quenching device (A) is an active damping device, the pressure wave is first attenuated in the deceleration infeller (2) at the initial entry, it is possible to process a larger amount in the tube clone (3), The pressure wave not completely extinguished in the tube clone (3) is designed to be completely extinguished in the reflective impeller (4), but the unexpected pressure wave generated in the ultra high rise is completely extinguished in the reduction master (6), and is equipped with a safety device. It is free to install horizontally and vertically and can be operated in various places and conditions and is semi-permanently designed so that there are no failures. It is a device that can prevent bad smell and can be installed vertically or horizontally.

As shown in FIG. 3, the fluid (shown in blue) drained into the waste water drain pipe of the high-rise building is generated in a manner opposite to the direction of the fluid while the pipe direction is changed from a standing pipe (vertical pipe) to a horizontal pipe. It shows that a positive wave (Positive Air Transients) of the pressure wave (shown in red) occurs, the pressure quenching device of the drainage pipe of the present invention is installed branched from the standing main pipe (vertical main pipe), It is preferable that the vent air vent is installed at the upper part of the (vertical main), and the vent air vent is installed at the horizontal main, and since it can be installed vertically or horizontally, it can be installed inside the ceiling by branching from the main. There is an advantage not to be tied to.

The pressure quenching device of the present invention is preferably installed branching at a distance of at least 1m from the horizontal main pipe.

The pressure wave inside the pipe is different from the normal pressure, so even if there is a resistance curve inside the pipe, it is a pressure wave with a singularity that rises regardless of the resistance.

4 is an example in which the pressure quenching device (A) of the present invention is installed vertically, and as shown, the pressure quenching device (A) of the present invention branches from a standing main pipe (vertical pipe) to a 45 ° Y pipe. After using 45 ° elbow, it is connected to the device by pipe nipple (9), and it can be installed in the pipe pit where the standing main pipe (vertical pipe) passes, or it can be branched and installed in the ceiling if the height of the ceiling is not a problem. On the lower side, even if two or more pressure quenching devices (A) are used in series to prepare for unexpected pressure waves, there is no problem in operation. By combining the device and the fixed cap of the rear end.

5 is an example in which the pressure quenching device (A) of the present invention is installed horizontally, and as shown, the pressure quenching device (A) of the present invention branches from a standing main pipe (vertical pipe) to a 45 ° Y pipe. After using 45 ° elbow, pipe nipple (9) is connected to this device. It should be installed by lifting the rear part more than 3 ° upwards, and there is no problem in operation. Horizontal installation is mainly used when installing in ceiling.

In case of using two or more pressure quenching devices (A) horizontally in series for the unexpected pressure wave on the lower side of the high-rise, there is no problem in operation. When using two, only the reduction master (6) is removed from the device of the front end. The pipe nipple can be used to attach the device to the rear end with a fixed cap.

As shown in FIGS. 6 and 7, the lower casing 1 has a cylindrical lower outer wall portion 11 engaging with the outer casing 7, a pressure wave is introduced therein, and is coupled to the pipe nipple of the Y pipe. Pipe coupling portion 12 having a fixing cap 121 for the purpose, a curved portion 13 connecting the lower outer wall portion 11 and the pipe coupling portion 12, the lower outer wall portion 11 and the inner side It is formed in a cylindrical shape at regular intervals, and is composed of a deceleration impeller casing 14, which is joined to the deceleration impeller 2 and becomes a passage through which pressure waves pass, and is coupled with a pipe nipple of a Y pipe branched from the granular pipe. As a result, the pressure wave inside the pipe flows in without resistance, returns, and is not attenuated.

The pipe coupling portion 12 is formed with a screw portion 122 for screwing the fixed cap 121.

A plurality of reduction impeller fixing grooves 111 coupled to the reduction impeller 2 are formed in the lower outer wall part 11 so that the fixing protrusion 211 of the lower casing coupling part 21 of the reduction impeller enters. When fully engaged, the bond strength is increased, and the quantity of the reduction impeller fixing groove 111 is generally preferably at least four or more.

In the inner curved portion of the deceleration impeller casing 14, two clone shaft coupling holes 15 are formed to which the clone shaft 8 is inserted and the clone shaft 8 is inserted.

The fixing cap 121 has a female screw 1211 screwed to the screw 122, an O-ring insertion groove 1212 into which an O-ring is inserted to prevent leakage of waste water or air, and a tool is fastened or loosened. The rotary teeth 1213 is formed so that the pipe nipple of the Y pipe and the pipe coupling portion 12 is tightly coupled so that no waste water or air leak from the coupling portion and the pipe nipple and the present invention The pressure quenching device (9) of the close contact so that the pressure wave flows in the middle is not subjected to resistance.

As shown in FIGS. 8 and 9, the upper casing 5 has a cylindrical upper outer wall portion 51 coupled to the outer casing 7, and a fixing cap for engaging the reduction master 6. A reduction master coupling portion 52 having a 521, a curved portion 53 connecting the upper outer wall portion 51 and the reduction master coupling portion 52, and a predetermined distance inwardly from the upper outer wall portion 51; It is formed in a cylindrical shape with a reflection impeller casing 54 is joined to the reflection impeller to pass through the remaining pressure waves, the reflection impeller (4) is coupled to the tube clone (3) the lower It serves to be supported on both sides together with the casing (1).

The pipe coupling portion 52 is formed with a screw portion 522 for screwing the fixed cap 521.

A plurality of reflective impeller fixing grooves 511 coupled to the reflective impeller 4 are formed in the upper outer wall portion 51 to fix the protrusion 411 of the upper casing coupling portion 41 of the reflective impeller 4. ) Is inserted to increase the coupling strength when fully engaged, and the number of the reflective impeller fixing grooves 511 is generally preferably at least four or more.

On the inner curved portion of the reflective impeller casing 54, two clone shaft coupling holes 55 are formed, into which the clone shaft 8 is inserted, and the clone shaft 8 is inserted into the tube clone 3. To prevent deformation.

The fixing cap 521 has a female screw 5211 for screwing into the screw portion 522, an O-ring insertion groove 5212 into which an O-ring is inserted to prevent leakage of waste water or air, and a tool is fastened or loosened. Rotating teeth (5213) is formed so that the pipe nipple of the Y pipe and the pipe coupling portion 52 is tightly coupled so that no waste water or air leakage from the coupling portion and the pipe nipple and the present invention The reduction master 6 is in close contact with each other, and when the two pressure quenching devices (A) are installed in series, it is in close contact with the pipe nipple (9).

As shown in FIGS. 10 and 11, the deceleration impeller 2 is engaged with the lower casing 1 and the lower casing engaging portion 21 having a cylindrical shape, and a deceleration portion into which a pressure wave is introduced and attenuated firstly. Composed of (22), it is coupled to the inside of the lower casing (1) to guide the introduced pressure wave serves to attenuate the pressure wave primarily by collision and mixing process.

The lower casing coupling portion 21 has a plurality of fixing protrusions 211 are formed to be coupled with the deceleration impeller fixing groove 111 of the lower casing 1 is inserted into the deceleration impeller fixing groove 111 when fully engaged. Further increase the coupling strength, the number of the fixing projections 211 is generally preferably at least four or more.

The deceleration unit 22 includes a plurality of deceleration blades 221 inclined at a predetermined angle by firstly attenuating a pressure wave by colliding and mixing the pressure wave; A support outer cylinder 222 having a cylindrical shape in which one side of the reduction blade 221 is joined and supported inwardly and the tube clone 3 is inserted and coupled outwardly; The other side of the deceleration blade 221 is bonded and supported is composed of a support inner cylinder 223 formed in the center.

A pressure wave with a small amount of force flows into the support inner cylinder 223 and exits the tube clone 3 and is automatically extinguished.

The deceleration blades 221 are generally installed at an inclination of 20 to 30 ° with a quantity of six or more, so that pressure waves are introduced into the deceleration blades 221 so that the angle is changed and the pressure waves collide with each other to attenuate. In other words, when the pressure wave is initially introduced into the lower casing (1) is configured to be introduced without resistance, the deceleration part 22 is easily introduced when the start portion of the deceleration part 22 enters but cannot be returned after the deceleration. The angle and distance shape spacing of the wing 221 is designed to automatically extinguish inside the tube clone 3.

The support outer cylinder 222 has a tube clone fixing groove 2221 for coupling the tube clone (3) is formed so that the concave groove 31 of the tube clone (3) is entered into the support outer cylinder At 222, the tube clone 3 does not fall out, and the support outer cylinder 222 and the tube clone 3 are preferably bonded with a tie after being completely adhered with an adhesive.

As shown in FIG. 12 and FIG. 13, the reflective impeller 4 is coupled to the upper casing 5 and has a cylindrical upper casing engaging portion 41 and a residual amount attenuated by the tube clone 3. Composed of a reflection deceleration portion 42 is the pressure wave is drawn in and attenuated, it is combined with the upper portion of the tube clone (3) serves to attenuate the residual amount of pressure wave is not extinguished in the tube clone (3) .

The upper casing coupling portion 41 is formed with a plurality of fixing protrusions 411 to be combined with the reflective impeller fixing groove 511 of the upper casing 5 is inserted into the reflective impeller fixing groove 511 when fully engaged Further increase the coupling strength, the number of the fixing protrusions 411 is generally at least four or more preferably.

The reflection deceleration part 42 includes a plurality of reflection wings 421 which are attenuated at a predetermined angle by attenuating and mixing a residual amount of pressure waves; A cylindrical reflection support outer cylinder 422 into which the residual amount of pressure waves attenuated inward is introduced and into which the tube clone 3 is inserted and coupled; Cylindrical reflective wing support (423) that one side of the reflective wing (421) is bonded and supported; The other side of the reflecting wing 421 is bonded and supported is composed of a conical columnar upper center cylinder 424 formed in the center.

The reflection wings 421 are generally installed at an inclination of 20 to 30 ° with a quantity of eight or more, so that the pressure wave is introduced into the reflection wing 221 and the angle is changed when the pressure wave hits the reflection wing 221 so that the pressure waves collide with each other. Since the number of the reflecting wings 421 is larger than the number of the deceleration wings 221, the pressure waves are largely extinguished in the tube clone 3, so that the pressure is weak, so that the conditions that collide with each other are made more.

The reflection support outer cylinder 422 has a tube clone fixing groove (4221) for coupling the tube clone (3) is formed so that the concave groove (31) of the tube clone (3) enters the reflection when tied with a tie It is preferable that the tube clone 3 does not fall out of the support outer cylinder 422, and the reflective support outer cylinder 422 and the tube clone 3 are tied together by a tie after being completely bonded with an adhesive.

As shown in FIG. 14, the reduction master 6 is coupled to the upper portion of the upper casing 5 to receive a pressure wave that is not finally extinguished in the reflection impeller 4 by an unexpected pressure wave generated in the ultrahigh rise. It acts as a complete extinction.

The reduction master 6 has a plurality of reduction blades 61 obliquely installed to remove pressure waves not completely removed from the reflection impeller 4 with unexpected pressure waves, and to support the reduction blades 61 in the center. Reduction center ring 62 is formed for.

The reduction blades 61 are generally installed at an inclination of 20 to 30 ° with a quantity of eight or more, so that pressure waves flow into the reduction blades 61 so that angles are changed so that the pressure waves collide with each other to attenuate them. Or it hits the ceiling of the reduction master 6 and again strikes the reduction blade 61 to be completely extinguished.

Experimental results show that the height of the reduction blade 61 occupies 2/3 of the length of the overall reduction master 6 is suitable for the reflection disappearance of the pressure.

As shown in FIG. 15, the both ends of the tube clone 3 are coupled to the deceleration impeller 2 and the reflection impeller 4 to serve as the primary attenuated pressure wave at the inner edge extended at a small aperture. By acting to attenuate predominantly, a pressure wave with a small wavelength is introduced and attenuates and disappears while repeating the expansion and contraction of the tube clone 3.

Two concave grooves each having a circular shape so as to be inserted into and fixed in the tube clone fixing grooves 2221 and 4221 of the deceleration impeller 2 and the reflective impeller 4 in the upper and lower portions of the tube clone 3. 31) is formed.

It is preferable that the inside of the tube clone 3 is embossed in a block so as to cause diffuse reflection upon collision of pressure waves.

The tube clone 3 should be made of a material that does not corrode or rot from harmful gases such as sulfur, phosphoric acid, and ammonia, and it is preferable to use silicon rubber or raw rubber material.

As described above, the lower portion of the tube clone 3 is coupled to the support outer cylinder 222 of the deceleration impeller 2, and the tube clone 3 in the tube clone fixing groove 2221 of the support outer cylinder 222. When the concave groove 31 of the enclosed by the tie is in the structure of the tube clone (3) does not fall out of the support outer cylinder (222), the support outer cylinder (222) and the tube clone (3) with an adhesive It is preferable to tie with a tie secondly after complete adhesion.

The upper portion of the tube clone 3 is coupled to the reflective support outer cylinder 422 of the reflective impeller 4, the concave of the tube clone 3 in the tube clone fixing groove 4221 of the reflective support outer cylinder 422. When the groove 31 enters and is tied with a tie, the tube clone 3 does not come out of the reflective support outer cylinder 422, and the reflective support outer cylinder 422 and the tube clone 3 are made of adhesive. It is preferable to tie with a tie secondly after complete adhesion.

As shown in FIG. 16, the outer case 7 has a lower portion coupled to the lower casing 1 and an upper portion coupled to the upper casing 5 so that the tube clone 3 is no longer expanded. It wraps and serves to protect the tube clone (3).

The material of the exterior case 7 is preferably made of stainless steel or equivalent material for strength and corrosion protection.

The lower end of the outer case 7 is inserted into the lower outer wall 11 of the lower casing 1 and the depth of the outer case 7 is inserted into the lower outer wall 11 by the outer casing mounting jaw 112 and is completely filled with adhesive. Combine.

The upper end of the outer case 7 is inserted into the upper outer wall 51 of the upper casing 5 and the depth of the outer case 7 is inserted into the upper outer wall 51 by the outer casing mounting jaw 512, and is completely covered with adhesive. Combine.

As shown in FIG. 17, the clone shaft 8 is coupled to the lower casing 1 and the upper casing 5, and balances the tube clone 3 so that the tube clone 3 is not twisted or deformed. It serves to maintain the distance between the casing (1) and the upper casing (5), the material is preferably made of stainless steel or equivalent or more for strength and corrosion protection.

18 and 19, the fixing caps 121 and 521 are coupled to the pipe nipples of the Y pipes, or the reduction caps 6 to prevent the reduction masters 6 from coming out. Ensure that airtight or air in the pipes are joined while maintaining airtightness.

O-ring insertion grooves 1212 and 5212 into which the female caps 1211 and 5211 are screwed to the screw portions 122 and 522 and O-rings are inserted into the fixing caps 121 and 521 to prevent leakage of waste water or air. And, it is a structure in which the rotary teeth (1213, 5213) is formed to be able to tighten or loosen the tool.

The pressure wave quenching device of the present invention uses a granular piping or a preventive device, which is an evacuation vent installed to remove pressure waves caused by positive air pressure transients. Since it is installed on the main body instead of the main body, there is no restriction in horizontal or vertical installation, and there is no problem in parallel or serial installation, so the size of the device is not limited by the installation location. There is an advantage.

In addition, it is possible to dissipate the backflow, odor or noise transition that may be caused by the pressure wave, and to prevent the secondary damage such as viral bacteria or pathogens by lowering the depth of the seal by drying the fluctuations or seals of the seal due to the pressure wave It can be released from various bacteria, and when the pressure in the pipe becomes higher than the atmospheric pressure, there is an effect of preventing the factors that may destroy the seals of the trap such as the toilet bowl sink.

A: pressure quenching device
1: lower casing 11: lower outer wall
111: reduction impeller fixing groove 12: pipe coupling
121: fixed cap 1211: female thread
1212: O-ring insertion groove 1213: rotary teeth
122: screw portion 13: curved portion
14: deceleration impeller casing 15: clone shaft coupling
2: deceleration impeller 21: lower casing coupling part
211: fixed projection 22: reduction portion
221: deceleration wing 222: support outer cylinder
2221 tube tube fixing groove 223 support inner cylinder
3: tube clone 31: concave groove
4: reflective impeller 41: upper casing coupling portion
411: fixing protrusion 42: reflection deceleration part
421: reflection wing 422: reflection support outer cylinder
4221: tube clone fixing groove 423: reflective impeller support
424: upper center barrel 5: upper casing
51: upper outer wall portion 511: reflective impeller fixing groove
52: reduction master coupling portion 521: fixed cap
5211: Female thread 5212: O-ring insert groove
5213: Saw tooth 522: Screw part
53: curved portion 54: reflective impeller casing
6: reduction master 61: reduction wings
62: reduction centering 7: outer casing
8: clone shaft 9: pipe nipple

Claims (5)

The fluid drained from the high-level drainage pipe in the high-rise building changes the direction of the pipe from the upright pipe (vertical pipe) to the horizontal pipe and dissipates the pressure waves, which are positive air transitions, created in the opposite direction of the fluid. In the pressure quenching device (A),
The pressure quenching device (A) includes a lower casing (1) coupled to the pipe nipple of the Y pipe branched from the granular pipe and having a structure in which a pressure wave inside the pipe flows in without resistance and is returned and hardly attenuated;
A deceleration impeller (2) coupled to the inside of the lower casing (1) to induce pressure waves introduced therein to primarily attenuate the pressure waves by collision and mixing process;
A tube clone (3) coupled to the deceleration impeller (2) to attenuate the primary attenuated pressure wave at its inner edge;
A reflection impeller (4) coupled to an upper portion of the tube clone (3) to receive and attenuate a residual amount of pressure waves not extinct in the tube clone;
An upper casing (5) to which the reflective impeller (4) is coupled so that the tube clone (3) can be supported on both sides together with the lower casing (1);
A reduction master (6) coupled to the upper portion of the upper casing (5) to completely extinguish the pressure wave not finally extinguished in the reflection impeller (4) by an unexpected pressure wave generated in the ultrahigh-rise;
A lower casing (7) is coupled to the lower casing (1) and the upper part is coupled to the upper casing (5) to surround the outer tube so that the tube clone (3) no longer inflated to protect the tube clone (3) (7) )and;
It is coupled to the lower casing (1) and the upper casing (5) and balances the tube clone (3) so as not to warp or deformation occurs to maintain the distance between the lower casing (1) and the upper casing (5) Pressure quenching device of wastewater pipe consisting of clonal shaft (8)
The method of claim 1,
The lower casing (1) is a pipe coupling having a cylindrical outer outer wall portion (11) coupled to the outer casing (7), and a pressure cap is introduced and a fixed cap 121 for coupling with the pipe nipple of the Y pipe A portion 12, a curved portion 13 connecting the lower outer wall portion 11 and the pipe coupling portion 12, and formed in a cylindrical shape at a predetermined interval inwardly with the lower outer wall portion 11 is It is composed of a deceleration impeller casing 14, which is joined to the deceleration impeller 2 and becomes a passage through which a pressure wave passes,
Inside the lower outer wall portion 11 is formed a plurality of deceleration impeller fixing grooves 111 are coupled to the deceleration impeller (2),
In the inner curved portion of the deceleration impeller casing 14 is formed two clone shaft coupling sphere 15 to which the clone shaft 8 is inserted,
The upper casing 5 is a reduction master coupling portion 52 having a cylindrical upper outer wall portion 51 coupled to the outer casing 7 and a fixing cap 521 for engaging the reduction master 6. And a curved portion 53 connecting the upper outer wall portion 51 and the reduction master coupling portion 52 and a cylindrical shape at a predetermined interval inwardly from the upper outer wall portion 51 to form the reflective impeller. It is composed of a reflective impeller casing 54 which is joined to be a passage through which residual pressure waves pass,
A plurality of reflective impeller fixing grooves 511 coupled to the reflective impeller 4 are formed in the upper outer wall 51.
On the inner curved portion of the reflective impeller casing 54 is formed two clone shaft coupling sphere 55 into which the clone shaft 8 is inserted,
The fixing caps 121 and 521 have female threads 1211 and 5211 screwed to the thread portions 122 and 522, and an O-ring insertion groove 1212 and 5212 into which an O-ring is inserted to prevent leakage of waste water or air. , Pressure quenching device of the waste water pipe, characterized in that the rotary teeth (1213, 5213) is formed so that the tool can be tightened or loosened
The method of claim 2,
The deceleration impeller (2) is coupled to the lower casing (1) and consists of a cylindrical lower casing engaging portion (21), a deceleration portion (22) in which the pressure wave is introduced and attenuated first,
The lower casing coupling portion 21 is formed with a plurality of fixing protrusions 211 to be coupled with the deceleration impeller fixing groove 111 of the lower casing (1),
The deceleration unit 22 includes a plurality of deceleration blades 221 inclined at a predetermined angle by firstly attenuating a pressure wave by colliding and mixing the pressure wave;
A support outer cylinder 222 having a cylindrical shape in which one side of the reduction blade 221 is joined and supported inwardly and the tube clone 3 is inserted and coupled outwardly;
The other side of the deceleration wing 221 is bonded and is composed of a support inner cylinder 223 formed in the center,
The support outer cylinder 222 is formed with a tube clone fixing groove 2221 for coupling the tube clone (3),
The reflective impeller (4) is coupled to the upper casing (5), the upper casing coupling portion 41 of the cylindrical shape, the reflection deceleration portion that is attenuated by attenuated the residual pressure wave attenuated from the tube clone (3) ( 42),
The upper casing coupling portion 41 is formed with a plurality of fixing projections 411 for coupling with the reflective impeller fixing groove 511 of the upper casing 5,
The reflection deceleration part 42 includes a plurality of reflection wings 421 which are attenuated at a predetermined angle by attenuating and mixing a residual amount of pressure waves;
A cylindrical reflection support outer cylinder 422 into which the residual amount of pressure waves attenuated inward is introduced and into which the tube clone 3 is inserted and coupled;
Cylindrical reflective wing support (423) that one side of the reflective wing (421) is bonded and supported;
The other side of the reflective wing 421 is bonded and supported and consists of a conical column-shaped upper center cylinder 424,
The pressure support device of the drainage pipe, characterized in that the reflective support outer cylinder 422 is formed with a tube clone fixing groove (4221) for coupling the tube clone (3)
The method of claim 1,
The reduction master 6 has a plurality of reduction blades 61 obliquely installed to remove pressure waves not completely removed from the reflection impeller 4 with unexpected pressure waves, and to support the reduction blades 61 in the center. Pressure quenching device of the waste water pipe, characterized in that the structure for the reduction center ring 62 is formed
The method of claim 1,
Two concave grooves each having a circular shape so as to be inserted into and fixed in the tube clone fixing grooves 2221 and 4221 of the deceleration impeller 2 and the reflective impeller 4 in the upper and lower portions of the tube clone 3. 31) is formed,
The pressure quenching device of the waste water pipe, characterized in that the embossing process in order to cause diffuse reflection in the impact of the pressure wave inside the tube clone (3)

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