JPH05263427A - Washing device in water flow hole and washing method - Google Patents

Abstract

PURPOSE:To improve washing efficiency by providing a water jet nozzle and an air jet nozzle at the tip of a cylindrical main body having the feed passages of high-pressure water and high-pressure air, and injecting the mixture of water and air. CONSTITUTION:A cylindrical device main body 11 and a conduit tube 12 are connected to a terminal 13 having an air port 22 and a water port 23, and an air feed passage 21 and a water feed passage 24 are formed. A water nozzle 25 having a conical head section is provided at the tip of the tube 12, an air jet nozzle 26 communicated with the passage 21 is arranged on its outside, and the injection axes of the nozzles 25, 26 are crossed. A backward inclined propelling water jet nozzle 31 is provided on the peripheral wall of the main body 11, and it is communicated with a water passage 32 formed on the tube 12. This device is inserted into an underground water collecting/draining hole provided in the ground, and it is advanced while the sediment in the hole is excavated and removed by the water/air mixed jet. The hole can be washed at high efficiency.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention relates to a cleaning device for a groundwater collecting / draining hole, a water supply pipe or a sewer pipe, etc. provided in the ground for the purpose of landslide prevention measures and the like. It relates to the cleaning method.

[Conventional technology]

 As shown in Fig. 1, groundwater collection and drainage holes 2 with an inclination of 2 to 3 degrees from the horizontal plane have been conventionally provided in the ground 1 as a measure for landslide prevention. The water collection / drainage hole 2 is formed by inserting a hole holding pipe 5 having a large number of water collection holes 4 into a bore hole 3 having a diameter of about 5 cm. It is designed to be collected inside and drained outside the natural ground 1.

 As described above, the drainage hole 2 gradually deteriorates in drainage due to the accumulation of earth and sand inside the drainage hole 2 and clogging of the water collection hole 4.

 For this reason, conventionally, the inside of the water collection and drainage hole 2 has been regularly cleaned, and for this purpose, a self-propelled cleaning device equipped with a water jet nozzle for cleaning is used.

 Also, in water pipes such as waterworks and sewers, water stains adhere to and accumulate on the inner walls of the pipes, so they are cleaned by the same cleaning device.

[Problems to be Solved by the Invention]

 However, the conventional cleaning device equipped with the water jet nozzle for cleaning as described above sprays the water jet in the water passage hole where a large amount of water sprayed by itself and the water flowing inside exist. Since it is for cleaning, the water jet pressure is significantly attenuated. Therefore, there is a problem that the cleaning effect is low.

 Therefore, it is an object of the present invention to provide a cleaning device and a cleaning method for enhancing the cleaning effect of a water jet nozzle inside a narrow water passage having a diameter of about 5 cm.

[Means for Solving the Problems]

 In order to achieve the above object, the first means relating to the cleaning apparatus of the present invention is to provide a high-pressure water supply passage and a high-pressure gas supply passage inside the main body of the apparatus, and to provide the above-mentioned respective passages at the tip of the main body of the apparatus. A water jet nozzle and a gas jet nozzle for washing that are in communication with each other are provided, and the extension of the nozzle axes of these water jet nozzle and gas jet nozzle is set to intersect in front of the main body of the device. ..

 A second means relating to the cleaning device is to provide a high-pressure water supply passage and a high-pressure air supply passage inside the device main body, provide a closing member at the tip of the device main body, and form an annular member between the closing member and the device main body. A nozzle member is rotatably attached, a water jet nozzle communicating with the high pressure water supply passage is provided in the nozzle member, the high pressure gas supply passage is communicated with the peripheral wall of the tip of the main body of the apparatus, and the nozzle of the water jet nozzle is also provided. It is configured with a gas jet nozzle for cleaning that is oriented in a direction that intersects with the extension of the shaft.

 A third means relating to the cleaning device is to provide a high-pressure water supply passage and a gas supply passage inside the device main body, provide a high-pressure water and gas mixing chamber at the tip of the device, and provide a mixing chamber of the device main body in the mixing chamber. The structure is such that the mixing jet nozzle installed at the tip is in communication.

 A fourth means relating to the cleaning apparatus is provided with a plurality of mixing jet nozzles in the above-mentioned third means, and the center line of each mixing jet nozzle is with respect to the center line of the apparatus within an angle range of 0 to 90 degrees. The configuration is set radially.

 A fifth means relating to the cleaning apparatus is configured such that the mixing jet nozzle of the above-mentioned fourth means is a slit continuous in the circumferential direction.

 A sixth means relating to the cleaning device is to provide a high-pressure water supply passage and a high-pressure gas supply passage inside the device body, provide a closing member at the tip of the device body, and form an annular member between the closing member and the device body. A nozzle member is rotatably attached, a mixing jet nozzle is provided on the above nozzle member, a mixing chamber communicating with a high pressure water supply passage and a high pressure gas supply passage is provided at the tip of the main body of the apparatus, and the above nozzle is provided in the mixing chamber. The structure is such that an open communication hole is provided on the inner surface of the member.

 The seventh means relating to the cleaning device is configured such that the center line of the mixing jet nozzle in the sixth means is inclined forward within a range of up to 90 degrees with respect to the center line of the device. is there.

 An eighth means relating to the cleaning device is configured such that the mixing jet nozzle in the seventh means is a slit continuous in the circumferential direction.

 In the first method relating to the cleaning method, a fluid jet is injected into the water passage to remove obstacles in the water passage. In the method for cleaning the water passage, a water jet and a gas jet are mixed as the fluid jet. It uses a mixed jet.

 The second means relating to the cleaning method is to inject at least one of the water jet and the gas jet in the first step in a pulsed manner.

 The third means relating to the cleaning method is a method for cleaning the inside of the water passage in which a fluid jet is injected into the water passage to remove obstacles inside the water passage. It uses a mixing jet in which

 The fourth means relating to the cleaning method is to inject the mixed jet in the third means relating to the above-mentioned cleaning method to the diagonally upper side of the front of the device, thereby forming a strainer hole or a socket joint formed on the inner surface of the water passage hole. Cavitation is generated at the edges such as.

 A fifth means relating to the cleaning method is such that the mixing jet in the fourth means relating to the above-mentioned cleaning method is a film-shaped jet that expands obliquely upward in front of the apparatus.

[Action]

 According to the first means of the cleaning device, the cleaning device is inserted into the open end of the drain hole, and then high-pressure water and high-pressure air are supplied thereto. The supplied high-pressure water and high-pressure air are jetted from the water jet nozzle and the gas jet nozzle for cleaning the tip of the main unit, respectively. The jet of water and the jet of gas collide and mix in front of the main body of the equipment, and the mixed jet removes obstacles accumulated in the drain hole.

 Also, the second means of the cleaning device supplies high-pressure water and high-pressure gas as in the case described above.

The high-pressure water is jetted from a water jet nozzle for cleaning, and the reaction force rotates the nozzle member. Further, the high-pressure gas is jetted from a gas jet nozzle for cleaning, collides and mixes with the above water jet, and the mixed jet is jetted to the inner peripheral wall of the water passage hole.

 The third means of the cleaning device supplies high-pressure water and gas to mix them in a mixing chamber at the tip of the device, and then jets a mixing jet from a mixing jet nozzle.

 According to the fourth means of the cleaning apparatus, as a result of jetting of the mixing jet radially or in the outer diameter direction, cavitation occurs at a stepped portion such as a strainer hole in the water passage hole, causing collision of the mixing jet. In addition to the cleaning effect due to, the cleaning effect due to cavitation is exhibited.

 The fifth means of the cleaning device sprays in a film form from slits continuous in the circumferential direction.

 In the sixth aspect of the cleaning device, the nozzle member is rotated by the reaction force at the time of jetting the mixed jet, and the mixed jet is jetted from the nozzle.

 According to the seventh means of the cleaning device, the mixing jet injected from the rotary nozzle is injected obliquely upward in the front of the device to generate cavitation at the socket joint of the water passage hole and the edge of the strainer hole. In addition to the cleaning effect due to the collision of the mixed jets, the cleaning effect due to cavitation is exerted.

 According to the eighth means of the cleaning apparatus, the mixing jet in the above seventh means is jetted in a film shape that expands obliquely above the apparatus.

[First Embodiment] The first embodiment shown in Figs. 2 to 5 is mainly for excavating / removing earth and sand and foreign substances accumulated inside the water pipe ahead of the traveling direction to clean the inside. Is.

Insert the water conduit 12 into the cylindrical device body 11, screw one end of the water conduit 12 to the center of the terminal 13, and keep one end of the device body 11 airtight at the stepped portion 14 of the terminal 13. And is fitted. A flange 15 is formed at the tip of the water conduit 12 so as to project in the outer diameter direction, and a screw cylinder 16 is formed at the front end surface of the flange 15.

 The front end of the apparatus main body 11 is brought into contact with the rear end surface of the collar 15 while maintaining airtightness.

 The outer diameter surface of the water conduit 12 is formed with large diameter portions 17 and 18 which are in close contact with the apparatus main body 11 at two front and rear positions, and longitudinal air passages 19 and 20 are formed in the large diameter portions 17 and 18 in the circumferential direction. Are provided at regular intervals.

 Together with these air passages 19 and 20, an air supply passage 21 is formed between the inner peripheral surface of the apparatus main body 11 and the outer peripheral surface of the water conduit 12.

 The terminal 13 is provided with an air port 22 and a water port 23, respectively, the air port 22 is connected to the air supply passage 21, and the water port 23 is connected to the water supply passage 2 of the water conduit 12. 4 is communicated.

 A water jet nozzle member 25 having a conical head is fitted to the open end of the water conduit 12, and an air jet nozzle member 26 is screwed to the screw cylinder 16. The air jet nozzle member 26 has a conical inner peripheral surface 27, and is fitted on the outer peripheral surface of the head portion of the water jet nozzle member 25.

 A water jet nozzle 29 is formed at the tip of the water jet nozzle member 25 in the axial direction thereof. Further, four air jet nozzles 28 are formed in the circumferential direction along the conical inner peripheral surface 27.

 The nozzle axis of the air jet nozzle 28 is inclined so as to intersect with the nozzle axis of the water jet nozzle 29.

 A plurality of holes 30 are formed in the collar 15 (see FIG. 4) to connect the air supply passage 21 and the inside of the air jet nozzle member 26.

 On the other hand, on the peripheral wall near the tip of the apparatus main body 11, that is, on the peripheral wall where the large-diameter portion 17 is provided in front of the water conduit 12, there are four water jet nozzles 31 for propulsion inclined in the rear direction. The water jet nozzles 31, which are provided at equal positions, communicate with the water supply passage 24 via a radial water passage 32 provided in the water conduit 12. An air jet nozzle 33 is provided between the water jet nozzles 31 (see FIG. 3). The air jet nozzle 33 communicates with the above-mentioned air supply passage 21, and the nozzle axis of the air jet nozzle 33 intersects with the extension of the nozzle axis of the water jet nozzle 31 at the outer peripheral portion of the apparatus main body 11. It is set.

 In the above device, when high pressure water and high pressure air are supplied by the hoses connected to the water port 23 and the air port 22, the high pressure water is jetted forward as a water jet from the water jet nozzle 29 through the water supply passage 24. It At the same time, the water is jetted obliquely rearward from the water jet nozzle 31 for propulsion through the water passage 32. The high-pressure air is jetted forward as an air jet from the air jet nozzle 28 through the air supply passage 21, and the water jet and the air jet collide with each other and are mixed on the extension line of the nozzle axis of the water jet nozzle 29. , The mixed jet collides with sediment such as sediment, excavates and removes it, and simultaneously cleans it. The high-pressure air is also jetted from the propelling air jet nozzle 33, and the air jet collides with the air jet jetted from the water jet nozzle 31 on the outer circumference of the main body 11 of the apparatus to mix the jet pressure. The reaction force of exerts a propulsive force on the entire device.

 For this reason, the equipment excavates and removes sediment such as soil, and at the same time moves forward while cleaning. The injected water flows in the inclination direction of the water pipe. As shown in Fig. 1, when the inlet side is low, it flows backward to the inlet side. In addition, if there is an original flow of water in the water conduit, it merges with that flow. In many cases, the cleaning device moves forward while ejecting a mixing jet into the muddy water in which these flows and the excavated earth and sand are mixed.

 When mixing the water jet and the air jet, the pressure of the air jet is increased stepwise while keeping the pressure of the water jet constant, or at least one of the water jet and the air jet is pressure-pulsed. It may be changed and injected.

[Second Embodiment] A second embodiment shown in FIGS. 6 to 8 is mainly used for cleaning the adhering material on the pipe wall of the water passage pipe and the clogged water collecting hole. In this device, the basic structure of the device main body 11, the water conduit 12 and the terminal 13 and the structure of the water jet nozzle 31 and the air jet nozzle 33 for propulsion are the same as those described above, but other structures are different. ing.

 That is, the tubular portion 35 is provided at the tip of the water conduit 12, and the annular rotary nozzle member 36 is rotatably fitted to the outer peripheral surface of the tubular portion 35. Further, a set screw 38 is screwed into a screw hole 37 formed on the inner diameter surface of the tubular portion 35 to close the tip of the water conduit 12, and the head 39 of the set screw 38 prevents the rotary nozzle member 36 from coming off. .. The other end of the rotary nozzle member 36 contacts the tip end surface of the mounting body 11 and is supported in the thrust direction.

 Four water passages 40 are formed in the radial direction in the tubular portion 35 at the tip of the water conduit 12. Further, an annular passage 41 in the circumferential direction is formed on the inner diameter surface of the rotary nozzle member 36, and the water passage 40 described above communicates with the annular passage 41. As shown in FIG. 8, the rotary nozzle member 36 is provided with cleaning water jet nozzles 42 corresponding to the water passages 40 at positions offset from the center by a certain distance and parallel to the water passages 40. It is formed at four locations. Each of these water jet nozzles 42 communicates with the annular passage 41.

 Further, an air jet nozzle 43 for cleaning, which communicates with the air passage 19, is provided at the tip of the apparatus body 11. The nozzle axis of this nozzle 43 is directed obliquely forward, and is set so as to intersect the extension line of the water jet nozzle 42 at the outer peripheral portion of the rotary nozzle member 36. The shapes of the water jet nozzle 42 and the air jet nozzle 43 are usually circular holes, but may be slits long in the circumferential direction.

In the case of slits, the jet jet expands like a film.

 Further, an annular ultrasonic transducer 45 may be attached to the outer peripheral surface of the apparatus main body 11 via a vibration absorbing filler 44 such as silicone rubber.

 The apparatus of the second embodiment has the above-mentioned configuration, and high-pressure water and high-pressure air are supplied from the water port 23 and the air port 22.

 The high-pressure water is jetted from the water jet nozzle 42 via the water supply passage 24, the water passage 40, and the annular passage 41. The rotating nozzle member 36 rotates due to the reaction force of the injection pressure. Further, the high-pressure water is jetted obliquely rearward from the water jet nozzle 31 for propulsion.

 On the other hand, the high pressure air is jetted from the cleaning air jet nozzle 43 through the air supply passage 21.

The jet of air jets collide and mix with the water jet, and the mixed jet cleans the inner wall surface of the water passage hole. When the water passage hole is the hole-holding pipe 5 as shown in FIG. 1, the mixing jet is uniformly jetted into the water collection hole 4 by the rotation of the nozzle member 36, and the clogging of the water collection hole 4 is efficiently cleaned. To do.

 Further, it is also ejected from the propelling air jet nozzle 33. The jetted air jet is collided and mixed with the water jet for propulsion, and the propulsive force is given by the jet pressure of the mixed jet.

 Also in this case, as in the case of the first embodiment described above, the device is often submerged in muddy water or close to it, and a mixed jet of a water jet and an air jet is injected into the muddy water. As a result, the soil, etc. adhering to the inner wall of the water passage hole is washed away, and the clogging of the water collection hole is eliminated.

 In addition, those equipped with an ultrasonic transducer are supplied with power via the lead wire 47 and are operated at the same time as cleaning, and apply ultrasonic vibration to water around the apparatus main body 11 and the hole holding tube 5 The inside of 5 is ultrasonically cleaned. Further, by applying ultrasonic vibration to the gravel and the like deposited outside the water collecting hole 4, a strong filter is formed by the compaction of the gravel.

 Further, as in the case of the first embodiment, a method of sequentially increasing the pressure of the air jet in a stepwise manner while keeping the pressure of the water jet constant, or changing the pressure of at least one of the water jet and the air jet in a pulse shape. In some cases, it may be ejected.

[Third Embodiment] The third embodiment shown in FIGS. 9 and 10 differs from that of the first embodiment described above in the configuration of the distal end portion of the apparatus. The other parts are the same, so the illustration is omitted.

 That is, in this embodiment, the water jet nozzle member 25 having a conical outer peripheral surface is fitted to the front end of the water conduit 12, and the intermediate member 60 is screw-fitted to the screw cylinder 16 around it. The intermediate member 60 has a screw cylinder 61 at its tip, and the mixing jet nozzle member 62 is screwed into the screw cylinder 61.

 A mixing chamber 63 is formed between the screw cylinder 61 and the inside of the intermediate member 60 and the inner surface of the mixing jet nozzle member 62, and the tip of the water jet nozzle member 25 faces the inside of the mixing chamber. A passage 64 communicating with the hole 30 of the collar 15 is formed between the conical outer peripheral surface of the water jet nozzle member 62 and the inner peripheral surface of the intermediate member 60, and air is mixed through the passage 64. It leads to the chamber 63.

 The mixing jet nozzle member 62 is provided with a mixing jet nozzle 65 communicating with the mixing chamber 63, and the nozzle 65 is located on the same straight line as the water jet nozzle 29.

 When cleaning is performed using the above apparatus, air does not necessarily have to be pressurized and supplied, and only water may be pressurized and supplied. Then, the water jet that has passed through the water jet nozzle 29 entrains air in the mixing chamber 63, so that the air is mixed with the water jet, and the mixing jet is ejected from the mixing jet nozzle 65.

[Fourth Embodiment] The fourth embodiment shown in FIGS. 11 and 12 is provided with a plurality of mixing jet nozzles 65 of the third embodiment, and the direction of the center line of each nozzle 65 is set to the center line of the apparatus. , Is set in the radial direction. In addition, the water jet nozzle 29 of the water jet nozzle member 25 is branched into a plurality of branches so that the center line of each nozzle 29 coincides with the center line of each nozzle 65.

 The mixed jet ejected from the nozzle 65 is ejected toward the inner wall of the water passage hole. Since there are stepped portions of the strainer hole 66 and the joint 76 on the inner wall, when oblique jets of mixed jets are ejected on such stepped portions, cavitation occurs, and the cleaning effect by the mixing jet is combined. The cleaning effect of cavitation can be obtained.

 The inclination angle of the center line of the mixing jet nozzle 65 with respect to the device center line is set in the range of 0 to 90 degrees. However, as it approaches 90 degrees, it is bent as shown by the chain line in FIG.

 Further, the mixing jet nozzle 65 may be in the shape of a slit continuous in the circumferential direction.

In this case, the mixed jet is expanded and ejected in a film shape, so that the mixed jet can be reliably collided with the strainer holes scattered on the inner wall of the water passage hole.

[Fifth Embodiment] In the fifth embodiment shown in FIG. 13, a mixing chamber 70 is provided at the tip of the water supply passage 24 in the second embodiment, and the air passage 19 is communicated with the mixing chamber 70. Of.

 The other structure is similar to that of the second embodiment.

 In this case, the mixed jet is ejected from the nozzle 71.

 Further, the nozzle 71 may be inclined within a range of 90 degrees obliquely from the front, and the nozzle 71 may be formed in a slit shape continuous in the circumferential direction.

[Experimental example]

 As an experimental device, as shown in FIG. 14, a transparent inner pipe 51 (inner diameter 50φ) was inserted into a transparent outer pipe 50 (inner diameter 60φ), and a closing member 53 with a pressure receiving plate 52 attached to the tip was attached to the inner pipe 51. And a hose 55 having a jet nozzle 54 attached to its tip is inserted from the opposite side.

 The structure of the jet nozzle 54 is the same as that of the cleaning apparatus of the embodiment shown in FIG. A high-pressure water hose and a high-pressure air hose are housed inside the hose 55.

 In the above experimental apparatus, the outer pipe 50 corresponds to the boring hole 3 in FIG. 1 and the inner pipe 51 corresponds to the hole holding pipe 5, and the inner pipe 51 has a small hole corresponding to the water collecting hole 4. Many 56 are provided.

 Air jets, water jets, or mixed jets of these jets were jetted from the jet nozzles 54 while changing the pressures using the above experimental apparatus, and the distance L between the pressure receiving plate 52 and the jet nozzle 54 and the collision at the pressure receiving plate 52. The force was measured by a collision force measuring device.

Figure 15 shows the measurement results. The horizontal axis shows the water jet pressure, and the vertical axis shows the collision force. In the figure, when the pressure of the water jet exceeds 100 kg / cm ² , the collision force tends to decrease, and becomes zero when the distance L is 10 to 30 cm. It is considered that this is because the pressure receiving plate 52 is placed in a narrow space, so that the pressure in the vicinity of the pressure receiving plate 52 reaches a saturated state even if the pressure of the water jet increases.

Under such a saturated condition, if the water jet is switched to the mixed jet in which the air jet (8 kg / cm ² ) is mixed, the collision force increases sharply as shown by the dotted line in Fig. 15.

 The reason why the collision force rises rapidly in this way is not clear, but it is presumed that it is because the air jet breaks the saturated state of the water jet, and the kinetic energy of both reaches the pressure receiving plate 52.

In Fig. 16, the pressure of the air jet is plotted on the horizontal axis, the pressure of the water jet is kept constant (200 kg / cm ² ), and the collision force is plotted on the vertical axis when the gap L is 10 cm and 20 cm. Is. It can be seen that the collision force gradually increases as the pressure of the air jet is increased.

In this case, in order to know how much the pressure of the air jet contributes to the rise of the collision force, if the air jet pressure is set to 0 when it reaches 8 kg / cm ² , it is shown by the constant chain line in the figure. Thus, the collision force was significantly reduced.

 FIG. 17 shows the collision force when a mixed jet is jetted, with the interval L taken on the vertical axis. In order to know the influence of the air jet, the comparison with the case where the air jet pressure is 0 is also shown here.

 Looking at any of the above experimental data, it can be seen that a larger impact force can be exhibited by the mixing jet in which the air jet is mixed with the water jet alone. Therefore, it has been found that it is effective to use a mixed jet when jetting a large amount of high-pressure water jets in a narrow space such as a water passage for cleaning.

〔The invention's effect〕

 As described above, since the cleaning apparatus and the cleaning method of the present invention cleans the inside of the water passage hole by the mixed jet of the water jet and the air jet, it has a higher cleaning effect than the one using only the water jet. Can be demonstrated.

[Brief description of drawings]

 FIG. 1 is a sectional view showing an example of the water passage hole, FIG. 2 is a sectional view of the first embodiment, FIG. 3 is a sectional view taken along line III-III of FIG. 2, and FIG. 4 is also IV-IV. 5 is a sectional view taken along line V-V of FIG. 6, FIG. 6 is a sectional view of the second embodiment, FIG. 7 is a sectional view taken along line VII-VII of FIG. 6, and FIG. Is also a sectional view taken along the line VIII-VIII, FIG. 9 is a partially omitted sectional view of the third embodiment, FIG. 10 is a sectional view taken along line XX of FIG. 9, and FIG. 11 is a sectional view of the fourth embodiment. Partially omitted sectional view, FIG. 12 is a left side view of FIG. 11, FIG. 13 is a partially omitted sectional view of the fifth embodiment, FIG. 14 is a sectional view of the experimental apparatus, and FIGS. The figure is a graph of experimental data. 11 ... Device main body, 12 ... Water pipe, 13 ... Terminal, 14 ... Step portion, 15 ... Collar, 16 ... Screw tube, 17 ... Large diameter portion, 18 ... Large diameter portion, 19 ... ... Air passage, 20 ... Air passage, 21 ... Air supply passage, 22 ... Air port, 23 ... Water port, 24 ... Water supply passage, 25 ... Water jet nozzle member, 26 ... Air Jet nozzle member, 27 ... Conical inner peripheral surface, 28 ... Air jet nozzle, 29 ... Water jet nozzle, 30 ... Hole, 31 ... Water jet nozzle, 32 ... Water passage, 33 ... Air jet Nozzle, 35 ... Cylindrical part, 36 ... Rotating nozzle member, 37 ... Screw hole, 38 ... Set screw, 39 ... Head, 40 ... Water passage, 41 ... Annular passage, 42 ... Water jet Nozzle, 43 ... Air jet nozzle, 4 ... Filling material, 45 ... Ultrasonic transducer, 47 ... Lead wire, 50 ... Outer pipe, 51 ... Inner pipe, 52 ... Pressure receiving plate, 53 ... Closing member, 54 ... Jet nozzle, 55 ... Hose, 56 ... Small hole, 60 ... Intermediate member, 61 ... Screw cylinder, 62 ... Mixing jet nozzle member, 63 ... Mixing chamber, 64 ... Passage, 65 ... Mixing jet nozzle, 66 ...... Strainer hole, 67 …… Coupling, 70 …… Mixing chamber, 71 …… Mixing jet nozzle.

Claims (13)

[Claims] 1. A high-pressure water supply passage and a high-pressure gas supply passage are provided inside the main body of the apparatus, and a water jet nozzle for cleaning and a gas jet nozzle that communicate with each of the above passages are provided at the tip of the main body of the apparatus. The water jet nozzle and the gas jet nozzle are set so that the extension of the nozzle axes intersects in front of the main body of the equipment. 2. A high-pressure water supply passage and a high-pressure gas supply passage are provided inside the apparatus main body, a closing member is provided at the tip of the apparatus main body, and a ring-shaped nozzle member is provided between the closing member and the apparatus main body. A water jet nozzle that is rotatably mounted, has a water jet nozzle that communicates with the high-pressure water supply passage on the nozzle member, communicates with the high-pressure gas supply passage on the peripheral wall of the tip of the device, and has the nozzle shaft of the water jet nozzle described above. A cleaning device in the water passage characterized by the provision of a gas jet nozzle that intersects with the extension of the water. 3. A high-pressure water supply passage and a gas supply passage are provided inside the apparatus main body, a mixing chamber for high-pressure water and gas is provided at the tip of the apparatus, and a mixing jet provided at the tip of the apparatus main body in the mixing chamber. A device for cleaning the inside of water passages, characterized in that the nozzles are connected. 4. A plurality of mixing jet nozzles are connected to the mixing chamber, and the center line of each jet nozzle is set radially within an angle of 0 to 90 degrees with respect to the center line of the apparatus. The cleaning device for the inside of the water passage according to claim (3). 5. The apparatus for cleaning the inside of a water passage according to claim 4, wherein the mixing jet nozzle is a slit continuous in the circumferential direction. 6. A high-pressure water supply passage and a high-pressure gas supply passage are provided inside the apparatus main body, a closing member is provided at the tip of the apparatus main body, and an annular nozzle member is provided between the closing member and the apparatus main body. It is rotatably mounted, a mixing jet nozzle is installed on the nozzle member, a mixing chamber is connected to the high pressure water supply passage and a high pressure gas supply passage at the tip of the main body of the equipment, and the above nozzle part is installed in the mixing chamber. An apparatus for cleaning inside water passages, characterized in that an open communication hole is provided on the inner surface of the. 7. The water passage hole according to claim 5, wherein the center line of the mixing jet nozzle is inclined forward within a range of up to 90 degrees with respect to the center line of the device. Cleaning equipment. 8. The apparatus for cleaning the inside of a water passage according to claim 6, wherein the mixing jet nozzle is a slit continuous in the circumferential direction. 9. A method for cleaning an interior of a water passage for injecting a fluid jet into the water passage to remove obstacles therein, wherein the fluid jet is a mixed jet in which a water jet and a gas jet are mixed. A method for cleaning the inside of water passages, characterized by using. 10. The method for cleaning the inside of a water passage according to claim 9, wherein at least one of the water jet and the gas jet is jetted in a pulse shape. 11. A method for cleaning an interior of a water passage, in which a fluid jet is jetted into the water passage to remove obstacles therein, wherein a gas is mixed with the water jet in the washing device as the fluid jet described above. A method for cleaning the inside of water passages characterized by using a mixing jet. 12. A cavitation is generated by injecting a mixed jet in an obliquely upward direction in front of the apparatus to generate cavitation at an edge portion of a strainer hole or a socket joint formed on the inner surface of the water passage hole. The method for cleaning the inside of the water passage described in claim (11). 13. The cleaning device for cleaning the inside of the water passage according to claim 12, wherein the mixed jet is a film-like jet that expands obliquely upward and forward of the device.