JP2008161829A - Bubble generator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bubble generator generating fine and uniform bubbles. <P>SOLUTION: The bubble generator is provide with a body 31 formed with an inlet passage 40 receiving air-dissolved water and decompressed, and a nozzle 32 formed with multiple outlet passages 42 receiving distributed water from the inlet passage 40 and jetting. A hemispherical circular recess 43 is formed at an end face 39 of the nozzle 32. Respective outlet passages 42 are disposed around an axis of the nozzle 32 and composed so that the jetting directions cross at one point P on the axis of the nozzle 32 in the recess 43. Water streams jetted from respective outlet passages 42 impinge at one point, bubbles in water become fine and uniform, and rebounding water by impingement is collected in the recess 43 and flows back again to the front side. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

    The present invention relates to a bubble generator, and particularly relates to uniformization and refinement of bubbles.

    2. Description of the Related Art Conventionally, a bubble generator for generating a bubble by decompressing a liquid in which a gas is dissolved and supplying the liquid containing the bubble to a bathtub or the like is known.

    For example, Patent Literature 1 discloses a bubble generator attached to a bathtub wall surface so as to face the bathtub. The bubble generator includes an inlet channel into which a liquid (water) in which gas (air) is dissolved, a distribution channel connected to the inlet channel, and a plurality of outlet channels branched from the distribution channel. And. The inlet channel is provided with a throttle for reducing the cross section of the water channel on the outflow side. The distribution channel is formed in a flat disk shape having the inlet channel as an axis, and the channel is formed narrower than the throttle part of the inlet channel. Each outlet channel is connected to the outer peripheral edge of the distribution channel, and is arranged at equal intervals around the axis of the distribution channel.

In this bubble generator, water in which air is dissolved flows through the inlet channel and the distribution channel in order. At that time, water is decompressed in the throttle part and the distribution channel of the inlet channel, and the air dissolved in the water is released to generate bubbles. The water containing bubbles is diverted from the distribution channel to each outlet channel, and is injected into the bathtub. The jet of fine bubbles is expected to improve the comfort of bathing in anticipation of the thermal effect and massage effect.
JP-A-2005-118542

    However, in this type of bubble generator, by making the size of the bubbles finer and uniform, the thermal effect and the massage effect during bathing are enhanced. However, in the bubble generator described above, the bubbles are made finer and uniform. There was a problem that it was not fully planned.

    The present invention has been made in view of this point, and an object of the present invention is to achieve uniform and fine bubble formation in a bubble generator in which a plurality of bubble outlets are arranged in a circle.

    In the first invention, an inlet channel (40) into which a liquid in which air is dissolved flows and a plurality of outlet channels (42) through which the liquid in the inlet channel (40) flows in and flows out are formed. It assumes a bubble generator with a nozzle (32). The nozzle (32) is formed with an arc recess (43) at the tip, while the ejection direction of each outlet channel (42) intersects at one point in the arc recess (43). The outlet end of the outlet channel (42) is open to the surface of the circular arc recess (43).

    In the above invention, the liquid that has flowed into the inlet channel (40) is diverted to each outlet channel (42) of the nozzle (32). At that time, the liquid is depressurized, air is liberated from the liquid, and bubbles are generated. The liquid containing the bubbles is ejected to the outside from each outlet channel (42). For example, when the bubble generator (30) of the present invention is provided in a bathtub, a liquid containing bubbles is ejected into the bathtub.

    Here, in the present invention, since the ejection direction of each outlet channel (42) intersects at one point in the circular arc recess (43), the liquid ejected from each outlet channel (42) They flow toward one point (collision point) and collide with each other. Due to this collision, the bubbles in the liquid are crushed finely and the size becomes uniform. Then, the collided liquid flows forward of the nozzle (32) and is supplied to, for example, the entire bathtub. However, not all liquid flows forward, and a part of the collided liquid rebounds backward. The rebounded liquid flows into the circular arc recess (43) of the nozzle (32), and flows along the circular arc surface to the outlet end (ejection end) of each outlet channel (42). This is because the vicinity of the outlet end of the outlet channel (42) is in a negative pressure state due to the ejection of the liquid, and the bounced liquid is attracted. That is, the bounced liquid is collected in the arc recess (43). The liquid flowing to the outlet end of each outlet channel (42) flows together with the liquid ejected from the outlet end and collides again at the above-described collision point. By this collision, the bubbles in the bounced liquid are more finely crushed and made uniform. Thereafter, most of the liquid flows forward, while a part of the liquid bounces backward, and the above-described operation is repeated.

    In the second invention, an inlet channel (40) into which a liquid in which air is dissolved flows and a plurality of outlet channels (42) through which the liquid in the inlet channel (40) flows in and flows out are formed. It assumes a bubble generator with a nozzle (32). The nozzle (32) is formed with an arc recess (43) at the tip, while the nozzle (32) is at least rearward because the liquid ejected from the outlet channels (42) collides at one point. The liquid that bounces back is collected in the arc recess (43).

    In the above invention, the liquid that has flowed into the inlet channel (40) is diverted to each outlet channel (42) of the nozzle (32). At that time, the liquid is depressurized, air is liberated from the liquid, and bubbles are generated. The liquid containing the bubbles is ejected to the outside from each outlet channel (42). For example, when the bubble generator (30) of the present invention is provided in a bathtub, a liquid containing bubbles is ejected into the bathtub.

    Here, in the present invention, the liquid ejected from each outlet channel (42) collides at one point (collision point). Due to this collision, the bubbles in the liquid are crushed finely and the size becomes uniform. And most of the liquid which collided flows ahead of a nozzle (32), for example, is supplied to the whole bathtub, but a part of liquid. Bounce backwards. The rebounded liquid is collected in the circular arc recess (43) of the nozzle (32). The collected liquid flows along the arc surface of the arc recess (43) to the outlet end (ejection end) of each outlet channel (42). This is because the vicinity of the outlet end of the outlet channel (42) is in a negative pressure state due to the ejection of the liquid, and the bounced liquid is attracted. The liquid flowing to the outlet end of each outlet channel (42) flows together with the liquid ejected from the outlet end and collides again at the above-described collision point. By this collision, the bubbles in the bounced liquid are more finely crushed and made uniform. Thereafter, most of the liquid flows forward, while a part of the liquid bounces backward, and the above-described operation is repeated.

    In a third aspect based on the first aspect, the inlet channel (40) has a channel restricting portion (35). In the nozzle (32), each outlet channel (42) is arranged around the axis of the inlet channel (40), while the ejection direction of each outlet channel (42) is the inlet channel ( It intersects at one point on the axis of 40).

    In the above invention, the liquid flowing into the inlet channel (40) is depressurized by the channel restrictor (38), and air is released from the liquid to generate bubbles. The liquid containing bubbles is diverted to each outlet channel (42) and ejected to the outside. Here, in this invention, the ejection direction of each exit flow path (42) cross | intersects in the circular arc recessed part (43) and one point on the axial center of an entrance flow path (40). That is, the liquid ejected from each outlet channel (42) collides at one point on the axis of symmetry within the arc recess (43) and passing through the arc center of the arc recess (43). Therefore, the liquid that has collided and rebounded flows reliably into the arc recess (43) and is collected.

    According to a fourth invention, in the first or third invention, the crossing angle in the ejection direction of the outlet channel (42) is 60 ° or more and 90 ° or less.

    In the above invention, the liquid ejected from each outlet channel (42) collides with each other at an angle (collision angle) of 60 ° or more and 90 ° or less. Accordingly, an appropriate liquid collision force is ensured, and the liquid rebounded by the collision surely flows into the arc recess (43).

    According to a fifth invention, in the first or second invention, the arc recess (43) is hemispherical.

    In the above invention, since the arc recess (43) is hemispherical, that is, the arc angle of the arc recess (43) is 180 °, the liquid after the collision is appropriately supplied forward and the liquid bounced back Is extensively collected in the arc recess (43).

    In a sixth aspect based on the third aspect, each outlet flow path (42) includes an inflow side parallel passage (42a) extending in parallel with the axis of the inlet flow path (40), and the parallel passage ( 42a) is formed by an inclined passage (42b) on the ejection side that extends inclinedly toward the axial center side of the inlet channel (40) and opens to the surface of the arc recess (43). The nozzle (32) is divided into a first block (32a) in which all the parallel passages (42a) are formed and a second block (32b) in which all the inclined passages (42b) are formed. It is what.

    In the above invention, the nozzle (32) is provided in the first block (32a) having all the parallel passages (42a) and in the second block (32b) having all the inclined passages (42b) and the circular arc recess (43). Divided. That is, the nozzle (32) is divided at the connection position between the parallel passage (42a) and the inclined passage (42b).

    Therefore, according to the present invention, the ejection direction of each outlet channel (42) intersects at one point, and the ejected liquid collides at one point (collision point). Therefore, the size of the bubbles can be made finer and uniform. As a result, for example, when the bubble generator (30) of the present invention is used in a bathtub, the thermal effect and the massage effect by the jet of bubbles can be enhanced, and the comfort of the bather can be improved.

    Furthermore, according to the present invention, the arc recess (43) is formed at the tip of the nozzle (32), the collision point of the liquid is set in the arc recess (43), and the liquid bounced back by the collision is returned to the arc. It was made to collect in a recessed part (43). Therefore, the bounced liquid can be caused to flow together with the liquid ejected from each outlet channel (42) and collide again at the collision point. Thereby, the air bubbles made fine and uniform can be flowed forward without waste, and can be supplied to the whole bathtub. Moreover, by making it collide again, refinement | miniaturization and uniformization of a bubble can be achieved further. As a result, the comfort of the bather can be effectively achieved.

    According to the third invention, the outlet channels (42) are arranged around the axis of the inlet channel (40), and the collision point of the liquid ejected from each outlet channel (42) (43) and on the axis of the inlet channel (40). Therefore, the liquid bounced off by the collision can be reliably collected in the arc recess (43). As a result, it is possible to reliably make the bubbles finer and uniform.

    Further, according to the fourth invention, since the intersection angle in the ejection direction of each outlet channel (42) is set to 60 ° or more and 90 ° or less, the liquid collision force and the amount of water flowing forward after the collision (the amount of bubbles) are set. The liquid that has collided and bounced back can be reliably collected in the circular arc recess (43) while being appropriately secured. Therefore, it is possible to more effectively achieve fine and uniform bubble formation.

    In other words, if the crossing angle is excessively large, the impact force of the liquid increases and the bubbles can be made finer and more uniform, but the amount of liquid supplied to the front decreases and the collection rate of the bounced liquid decreases. Resulting in. On the other hand, if the crossing angle is too small, the forward liquid supply amount and the bounced liquid collection rate can be secured, but the liquid collision force is reduced, so that the bubbles cannot be expected to become so fine and uniform.

    Furthermore, according to the fifth invention, since the arc recess (43) is formed in a hemispherical shape, the liquid after the collision can be reliably supplied to the front, and the water bounced back can be collected extensively. Can do. Thereby, refinement | miniaturization and uniformization of a bubble can be achieved effectively.

    According to the sixth aspect of the invention, since the nozzle (32) is divided at the connection position between the parallel passage (42a) and the inclined passage (42b), the parallel passage (42a) and the inclined passage (42b) Each block (32a, 32b) can be formed as one through passage. Therefore, cutting of the parallel passage (42a) and the inclined passage (42b), and in turn, cutting of the arc recess (43) of the second block (32b) is facilitated.

    Embodiments of the present invention will be described in detail with reference to the drawings.

    The bubble generator (30) according to the present invention is provided in the fine bubble supply device (10) for supplying water containing fine bubbles to the bathtub (5).

<Overall configuration of microbubble supply device>
As shown in FIG. 1, the fine bubble supply device (10) of this embodiment includes a circulation channel (11) having an inlet and an outlet connected to a bathtub (5), respectively. An air introducer (12), a pump mechanism (13), a gas dissolver (14), and the bubble generator (30) are connected to the circulation channel (11) in order from the upstream side to the downstream side. Has been.

    The air introducer (12) introduces air as a bubble source from the outside into the circulation channel (11). This air introducer (12) is a so-called ejector-type air introducer that sucks air by using a negative pressure generated by the water flow inside. That is, in the air introducer (12), negative pressure is generated by the water flow passing through the inside thereof, and external air is introduced into the circulation channel (11) through the air introduction pipe (12a) by this negative pressure.

    The pump mechanism (13) is for circulating water in the bathtub (5) in the circulation channel (11). The pump mechanism (13) discharges water sucked from the air introducer (12) side to the gas dissolver (14) side.

    The gas dissolver (14) promotes dissolution of air into water in a cylindrical container. In this container, for example, a filler or the like is provided for increasing the contact time and contact area between air and water.

    The bubble generator (30) is for depressurizing water in which air is dissolved to generate fine bubbles. The bubble generator (30) is attached to the side wall surface of the bathtub (5) so as to face the bathtub (5). Details of the bubble generator (30) will be described later.

    The circulation channel (11) is provided with a flow meter (15) on the upstream side of the air introducer (12). This flow meter (15) constitutes a flow rate measuring means for measuring the flow rate of water circulating in the circulation channel (11). The circulation channel (11) is provided with a flow rate adjusting valve (16) between the gas dissolver (14) and the bubble generator (30). The flow rate adjusting valve (16) constitutes a flow rate adjusting means for adjusting the flow rate of the circulation channel (11) by changing the opening degree.

<Detailed structure of bubble generator>
Next, the detailed structure of the bubble generator (30) will be described. As shown in FIGS. 2 to 4, the bubble generator (30) includes a main body (31) provided on the flow rate adjusting valve (16) side of the circulation channel (11) and a nozzle provided on the bathtub (5) side. (32).

    The main body (31) is formed in a substantially cylindrical shape, and the nozzle (32) is formed in a substantially cylindrical shape having a smaller diameter than the outer diameter of the main body (31). A female thread portion (33) is formed on the inner peripheral wall of one end side (right end side in FIG. 2) of the main body (31). On the other hand, a male thread portion (34) is formed on the outer peripheral wall on one end side (left end side in FIG. 2) of the nozzle (32). The main body (31) and the nozzle (32) are combined together to form the bubble generator (30) by fastening the female screw portion (33) and the male screw portion (34).

    The main body (31) has an inlet channel (40) formed on the other end side (left end side in FIG. 2). Water that has flowed out of the gas dissolver (14) and in which the air is dissolved flows into the inlet channel (40). A main body side restricting portion (35) is formed on the outflow side of the inlet channel (40). The main body side restricting portion (35) constitutes a flow restricting portion for reducing the pressure of the water by reducing the cross section of the inlet flow passage (40), that is, a reduced pressure flow passage.

    Specifically, the main body side throttle part (35) has a tapered surface (35a) whose diameter is reduced toward the outflow side of the inlet channel (40) and a circumference formed on the tip side of the tapered surface (35a). Surface (35b). The inlet channel (40) is formed with the narrowed portion (35) on the main body side, so that the large-diameter passage (40a), the reduced-diameter passage (40b), and the small-diameter passage (40c) in order from the inflow side to the downstream side. ) And are formed. The large-diameter passage (40a) is formed in a relatively large-diameter columnar shape, the reduced-diameter passage (40b) is formed in a trapezoidal cone shape whose diameter decreases toward the outflow side, and the small-diameter passage (40c) is formed in a large-diameter passage ( It is formed in a cylindrical shape having a smaller diameter than that of 40a).

    A distribution channel (41) is formed between the main body (31) and the nozzle (32). The distribution channel (41) is connected to the small diameter passage (40c) of the inlet channel (40). The distribution channel (41) is formed in a disc shape that extends radially outward with the axis of the inlet channel (40) as the center. In the inner walls on both axial sides of the distribution channel (41), the inner wall on the main body (31) side constitutes the first inner wall (36), and the inner wall on the nozzle (32) side constitutes the second inner wall (37). Yes. That is, in the center of the first inner wall (36), the small diameter passage (40c) of the inlet channel (40) is opened.

    A plurality (six in this embodiment) of outlet channels (42) are formed in the nozzle (32). Further, the nozzle (32) is formed with an arc recess (43) in the center of the tip surface (39). That is, the center of the tip of the nozzle (32) is recessed in a hemispherical shape.

    Each said outlet channel (42) has penetrated over the axial direction both ends (left-right end in FIG. 2) of a nozzle (32). As shown in FIGS. 3 and 4, the six outlet channels (42) are arranged in the circumferential direction around the axis of the nozzle (32) (that is, the axis of the distribution channel (41)). Arranged at intervals. That is, the inlet channel (40), the distribution channel (41), and the nozzle (32) are formed coaxially, and each outlet channel (42) is arranged around the axis of the distribution channel (41). . Thus, in the bubble generator (30), the water that has flowed into the inlet channel (40) flows into the distribution channel (41) and is then distributed to each outlet channel (42) to be contained in the bathtub (5). Is ejected.

    Each of the outlet channels (42) includes a parallel passage (42a) and an inclined passage (42b).

    The parallel passage (42a) extends straight in parallel with the axial direction of the nozzle (32). The parallel passage (42a) has one end that is an inflow end connected to the outer edge of the distribution channel (41) (see also FIG. 3), and the other end connected to one end of the inclined passage (42b). A nozzle-side restricting portion (38) is formed in the middle of the parallel passage (42a). The nozzle side restricting portion (38) is integrally formed in a cylindrical shape bulging radially inward from the inner peripheral wall of the parallel passage (42a), and reduces the cross section of the parallel passage (42a). That is, the nozzle side throttle part (38) constitutes a flow path throttle part that depressurizes water, that is, a pressure reducing passage, like the main body side throttle part (35). By this nozzle side restricting portion (38), the bubbles in the water are made finer (subdivided).

    The inclined passage (42b) extends straight from the other end of the parallel passage (42a) to the axial center side of the nozzle (32). Specifically, the inclined passage (42b) has one end that is the inflow end connected to the other end of the parallel passage (42a), and the other end that is the outflow end (outlet end) is open to the surface of the circular arc recess (43). (See also FIG. 4). The inclined passages (42b) of the respective outlet channels (42) are formed so that the respective axes (that is, the ejection direction) intersect at one point (P point). This point P is the intersection of the axis of the nozzle (32) and the line of the tip surface (39) (that is, the arc center of the arc recess (43)). That is, in the nozzle (32), the water that flows out (spouts) from each outlet channel (42) is within the arc recess (43) and on the axis of the nozzle (32) (that is, the axis of the inlet channel (40)). It is configured to collide at one point. By this collision, bubbles in the water can be made finer and uniform.

Furthermore, the nozzle (32) has water (including bubbles) bounced back (leftward in FIG. 2) due to the collision along the surface of the arc recess (43) to the outflow end of each inclined passage (42b). It is configured to flow. That is, the circular arc recess (43) of the nozzle (32) has a function of collecting water that has collided and bounced back.

    Moreover, in this embodiment, it is comprised so that crossing angle (theta) of the axial center of each inclination channel | path (42b) may be 60 degrees or more and 90 degrees or less. The range of the crossing angle θ is an optimal range for effectively miniaturizing and uniformizing bubbles due to collision, and may be other crossing angles.

-Operation of fine bubble supply device-
Next, the operation of the fine bubble supply device (10) of the present embodiment will be described. In this microbubble supply device (10), when the pump mechanism (13) is activated, the water in the bathtub (5) is sucked into the inlet of the circulation channel (11) toward the outlet of the circulation channel (11). Circulate.

    The pump mechanism (13) is adjusted so that the flow rate of the circulation channel (11) is, for example, 35 liters / minute. In this state, the inside of the container of the gas dissolver (14) is pressurized to about 300 to 400 kPa. Further, during operation, the opening degree of the flow rate adjusting valve (16) is adjusted based on the flow rate measured by the flow meter (15).

    The water in the bathtub (5) that flows in from the inlet of the circulation channel (11) flows into the air introducer (12). In the air introducer (12), the air sucked from the air introduction pipe (12a) is mixed into the water. Air mixed in water becomes relatively small bubbles. The water containing the bubbles flows out from the air introducer (12), and flows into the gas dissolver (14) through the pump mechanism (13). In the gas dissolver (14), water is pressurized to promote dissolution of air in water. The water in which the air is dissolved flows out of the gas dissolver (14) and flows into the bubble generator (30).

    The water that has flowed into the bubble generator (30) flows through the inlet channel (40). This water is depressurized when passing through the main body side restricting portion (35). As a result, air dissolved in water is released, and bubbles are generated in water. Thereafter, the water containing bubbles flows into the distribution channel (41). In the distribution channel (41), the inflowing water flows radially from the axial center side toward the outer peripheral side. Also during this circulation, water is depressurized, and air still remaining in the water is released to generate bubbles. Thereafter, water containing bubbles is distributed and flows into each outlet channel (42).

    The water flowing into each outlet channel (42) is depressurized by the nozzle side throttle (38) of the parallel passage (42a), the air still remaining in the water is released, and more bubbles are generated. Large bubbles are subdivided. Thereafter, water containing bubbles is ejected from each inclined passage (42b) into the bathtub (5).

    As shown in FIG. 5, the water (R1) ejected from each inclined passage (42b) collides at one point (P point). Thereby, the size of the bubbles becomes finer and uniform. The size of the bubble after the collision is several tens of microns. And most of the impacted water (R2) flows forward and spreads throughout the bathtub (5), but the remaining water (F1, F2) bounces back. The bounced water (F1, F2) is collected in the arc recess (43). Here, since the crossing angle θ in the ejection direction of each inclined passage (42b) is not less than 60 ° and not more than 90 °, the collision force of water and the amount of water flowing forward after the collision (bubble amount) are appropriately secured and The bounced water is surely collected in the arc recess (43).

    The water (F1, F2) collected in the arc recess (43) hits the arc recess (43) surface and then flows along the arc recess (43) surface to the outflow end of each inclined passage (42b). . This is because the collected water (F1, F2) is attracted because the vicinity of the outflow end of the inclined passage (42b) is in a negative pressure state due to the ejection of water. Moreover, since the recess (43) has an arc shape, water (F1, F2) is easily attracted along the arc surface.

    The water (F1, F2) attracted to the outflow end of each inclined passage (42b) is mixed with the water (R1) ejected from each outflow end and collides again at one point (P point). Then, most of the colliding water (R2) flows forward, and the remaining water (F1, F2) is collected in the circular arc recess (43). As described above, the water flowing backward due to the collision is collected in the circular arc recess (43) and flows forward again, so that fine and uniform bubbles are supplied to the entire bathtub (5) without waste. Furthermore, since the water collected in the circular arc recess (43) is collided again, the bubbles can be further miniaturized and made uniform.

-Effect of the embodiment-
According to the present embodiment, the ejection directions of the outlet channels (42) intersect at one point, and the ejected water collides at one point. Therefore, the size of the bubbles can be made finer and uniform. As a result, the thermal effect and massage effect by the jet of bubbles can be enhanced, and the comfort of the bather can be improved.

    Furthermore, in the present embodiment, an arc recess (43) is formed on the tip surface (39) of the nozzle (32), and the collision point of the water is within the arc recess (43) and on the axis of the nozzle (32). The water that bounces back due to the collision is collected in the circular arc recess (43). Therefore, the bounced water can flow along the surface of the arc recess (43) to the outflow end of each outlet channel (42) and collide again with the water ejected from the outflow end. Thereby, the air bubbles made fine and uniform can be supplied to the whole bathtub (5) without waste. Moreover, by making it collide again, the refinement | miniaturization and uniformization of a bubble can be achieved further. As a result, the comfort of the bather can be effectively achieved.

    In addition, since the crossing angle in the ejection direction of each outlet channel (42) is set to 60 ° or more and 90 ° or less, the collision force of water and the amount of water flowing forward (the amount of bubbles) after the collision are ensured appropriately. It is possible to reliably collect the water bounced off in the arc recess (43). In other words, if the crossing angle is excessively large, the impact force of water is increased and the bubbles are expected to be made finer and uniform, but the amount of water flowing forward after the collision (the amount of bubbles) cannot be secured and bounces back. It becomes difficult to collect water in the arc recess (43). On the other hand, if the crossing angle is too small, the impact force of water is reduced and the bubbles are not very fine and uniform. Thus, in the present embodiment, it is possible to effectively reduce the size and uniformity of bubbles.

    Moreover, since the circular arc recess (43) is hemispherical, the water after the collision can be reliably supplied to the front, and the water bounced back can be collected extensively. Thereby, refinement | miniaturization and uniformization of a bubble can be achieved effectively.

-Modification of the embodiment-
In this modification, as shown in FIG. 6, the configuration of the nozzle (32) in the above embodiment is changed. That is, the nozzle (32) of the present modification has a two-divided structure in place of the single embodiment described above.

    Specifically, the nozzle (32) of this modification is divided into a first block (32a) and a second block (32b). The first block (32a) and the second block (32b) are divided at the connection position between the parallel passage (42a) and the inclined passage (42b). That is, of the parallel passages (42a) and the inclined passages (42b), all the parallel passages (42a) are formed in the first block (32a), and all the inclined passages (42b) are formed in the second block (32b). Is formed.

    Both the blocks (32a, 32b) are formed in a substantially cylindrical shape. The second block (32b) has a larger outer diameter than the first block (32a). At the outflow side end (the right end in FIG. 6) of the first block (32a), a male screw portion (48) is formed on the outer peripheral surface, and a female screw portion (45) is formed on the inner peripheral surface of the central recess. Has been. An annular concave groove is formed in the inflow side end portion (left end portion in FIG. 6) of the second block (32b), and the external thread portion (1) of the first block (32a) is formed on the outer peripheral surface of the concave groove. 46) is formed, and a male screw portion (46) corresponding to the female screw portion (47) of the first block (32a) is formed on the inner peripheral surface of the concave groove. . Then, the female screw portions (45, 47) and the male screw portions (46, 48) are fastened, and both blocks (32a, 32b) are coupled. By this coupling, the parallel passage (42a) and the inclined passage (42b) are connected.

    As described above, since the nozzle (32) is divided at the connection position between the parallel passage (42a) and the inclined passage (42b), the parallel passage (42a) and the inclined passage (42b) are provided in the respective blocks (32a). 32b) is formed as a straight through passage. Therefore, cutting of the parallel passage (42a) and the inclined passage (42b), and in turn, cutting of the arc recess (43) of the second block (32b) is facilitated. Other configurations, operations, and effects are the same as those in the embodiment.

<< Other Embodiments >>
About the said embodiment, it is good also as the following structures.

    For example, in the above embodiment, the intersection in the ejection direction of each outlet channel (42) is set to the arc center (point P) of the arc recess (43), but in FIG. 2 and FIG. You may make it set to the position which shifted | deviated.

    In the above embodiment, the intersection in the ejection direction of each outlet channel (42) is set to a position other than the axis of the nozzle (32) (that is, the axis of the inlet channel (40)). May be.

    Moreover, in the said embodiment, although the some exit flow path (42) was arranged on one circle centering on the axial center (axis center of an inlet flow path (40)) of a nozzle (32), it is not restricted to this. Instead, the outlet channel (42) may be arranged on a plurality (double or triple) of concentric circles. In the present invention, the plurality of outlet channels (42) may not be arranged around the axis of the nozzle (32), and may be opened relatively irregularly on the surface of the arc recess (43). .

    In short, the nozzle (32) according to the present invention has a plurality of outlet channels (42) opening in the surface of the arc recess (43), and the ejection direction of each outlet channel (42) is within the arc recess (43). It is sufficient if it intersects at one point, that is, it is configured such that the water ejected from each outlet channel (42) collides at one point and the bounced water is collected in the arc recess (43). That's fine.

    In the above embodiment, the arc recess (43) is hemispherical. However, the present invention is not limited to this, and the collision force of water and the amount of water flowing forward (the amount of bubbles) can be adequately secured, and the bounced water is appropriately captured. Of course, as long as it can be collected, it may have an arc shape with an arc angle of less than 180 degrees.

    Moreover, in the said embodiment, although the exit flow path (42) was six, of course, 2-5 or seven or more may be sufficient.

    Moreover, in the said embodiment, although the exit flow path (42) was comprised by the parallel channel | path (42a) and the inclination channel | path (42b), it is not restricted to this, The ejection direction of an exit channel (42) is circular-arc recessed part. The outlet channel (42) may have any shape as long as it is configured to intersect at one point on the axis of the nozzle (32) within (43). For example, the parallel passage (42a) may not be parallel to the axis of the nozzle (32), and the entire outlet channel (42) may be connected to the distribution channel (41) from the connection center of the nozzle (32). It may be configured such that it extends straight and tilts toward the arc recess (43).

    Further, in the above embodiment, the nozzle side restricting portion (38) is integrally formed in the outlet flow path (42), but it may be configured separately from the outlet flow path (42). The nozzle side restricting portion (38) may be omitted.

    Moreover, in the said embodiment, although air is dissolved in water and a bubble is generated, a fragrance (aroma) component and a component useful for a human body are mixed in this water, and it goes in a bathtub (5) with a bubble. You may make it supply.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful as a bubble generator that generates bubbles by decompressing a liquid in which a gas is dissolved.

It is a piping system diagram which shows the structure of the fine bubble supply apparatus which concerns on embodiment. It is a longitudinal cross-sectional view which shows the structure of the bubble generator which concerns on embodiment. It is a front view which shows the bubble generator which concerns on embodiment from the nozzle side. It is AA sectional drawing of FIG. It is a longitudinal cross-sectional view which shows the ejection state of the liquid in a nozzle. The structure of the bubble generator which concerns on the modification of embodiment is shown, (A) shows a longitudinal cross-sectional view, (B) shows the front view seen from the front-end | tip.

Explanation of symbols

10 Fine bubble feeder
30 Bubble generator
32 nozzles
32a first block
32b 2nd block
35 Main unit side restrictor (channel restrictor)
40 Inlet channel
42 Outlet channel
42a Parallel passage
42b Inclined passage
43 Arc recess

Claims (6)

An inlet channel (40) into which a liquid in which air is dissolved flows, and a nozzle (32) in which a plurality of outlet channels (42) through which the liquid in the inlet channel (40) flows in and out is formed. A bubble generator comprising:
The nozzle (32) is formed with an arc recess (43) at the tip, while the outlet flow direction of the outlet channels (42) intersects at one point in the arc recess (43). A bubble generator, characterized in that the outlet end of the passage (42) is open to the surface of the circular arc recess (43). An inlet channel (40) into which a liquid in which air is dissolved flows, and a nozzle (32) in which a plurality of outlet channels (42) through which the liquid in the inlet channel (40) flows in and out is formed. A bubble generator comprising:
The nozzle (32) has an arc recess (43) formed at the tip,
The nozzle (32) is configured such that the liquid ejected from each outlet flow path (42) collides at one point, and at least the liquid that bounces back is collected in the arc recess (43). A bubble generator characterized by. In claim 1,
The inlet channel (40) has a channel restrictor (35),
In the nozzle (32), each outlet channel (42) is arranged around the axial center of the inlet channel (40), while the ejection direction of each outlet channel (42) is the inlet channel (40). A bubble generator characterized by intersecting at one point on the axis of the. In claim 1 or 3,
The bubble generator, wherein the outlet channel (42) has an ejection angle in the ejection direction of 60 ° or more and 90 ° or less. In claim 1 or 2,
The bubble generator, wherein the arc recess (43) is hemispherical. In claim 3,
Each of the outlet channels (42) includes an inflow side parallel passage (42a) extending in parallel with the axis of the inlet passage (40), and an axis of the inlet passage (40) from the end of the parallel passage (42a). An ejection-side inclined passage (42b) that is inclined and extends toward the center side and opens in the surface of the arc recess (43).
The nozzle (32) is divided into a first block (32a) in which all the parallel passages (42a) are formed and a second block (32b) in which all the inclined passages (42b) are formed. A bubble generator characterized by.

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