JP6157149B2 - Nipple with artificial nipple and artificial nipple - Google Patents

Description

  The present invention relates to an artificial nipple and a baby bottle having an artificial nipple.

  An artificial nipple to be attached to a main body of a baby bottle such as a bottle for containing a beverage for infants such as milk or milk that has been preliminarily extracted, and a baby bottle having an artificial nipple are widely used for feeding infants. When the infant sucks to hold the artificial nipple and feed the baby from the sucker, the pressure in the sucker decreases as the beverage decreases. As the pressure in the sucker decreases, it becomes increasingly difficult for infants to breastfeed. Thus, an artificial nipple having a check valve that can guide external air into the sucker so that the pressure in the sucker does not decrease and a sucker having an artificial nipple are known (Patent Document 1).

JP 2011-92551 A

  However, since the artificial nipple described in Patent Document 1 and the sucker having the artificial nipple have only a single check valve, the pressure in the sucker is reduced, that is, the pressure difference between the sucker and the sucker is reduced. It cannot be adjusted to decrease the flow rate of the air flowing into the sucker according to the increase. Therefore, the flow rate of the air flowing into the sucker increases as the differential pressure between the sucker and the sucker increases. Therefore, although the amount of beverage that can be fed by an infant in a single feeding operation increases, an excessive amount of beverage is not preferable for the infant. In other words, in the case of an infant with a strong suction force at the time of breastfeeding, the time required for drinking the beverage in the sucker (lactation time) is shortened. On the other hand, in the case of an infant with weak suction force at the time of breastfeeding, the breastfeeding time becomes long. Therefore, in the sucker having the artificial nipple and the artificial nipple described in Patent Document 1, the feeding time cannot be appropriately adjusted according to the suction force of the infant, that is, according to the differential pressure between the inside and outside of the sucker.

  An object of the present invention is to provide an artificial nipple capable of adjusting a feeding time or a beverage flow rate suitable for an infant by a simple method, and a sucker that shakes the artificial nipple.

According to the first aspect of the present invention, the artificial nipple body, the first ventilation member having a plurality of ventilation holes having different opening areas under the same differential pressure, and the second ventilation member having the ventilation holes are provided. An artificial nipple that is attached to a main body of a baby bottle that contains a beverage, wherein the ventilation holes of the second ventilation member are selectively communicated with the plurality of ventilation holes of the first ventilation member. by, Ri adjustable der the flow rate of the gas flowing in from the outside of the feeding device through a vent through 該連, the artificial nipple body through the first vent member and the second ventilation member It is formed to be attached to the mammal body, communicating the vent artificial nipple, characterized in Rukoto done by overlapping the first vent member and the second vent member.

  That is, according to the first aspect of the present invention, the ventilation holes of the second ventilation member are appropriately selected and communicated with the plurality of ventilation holes of the first ventilation member in accordance with the suction force at the time of feeding the infant. To adjust the flow rate of the gas flowing from the outside to the inside of the sucker. For example, in the case of an infant who has a strong suction force at the time of breastfeeding, the ventilation hole of the first ventilation member is selected so that the flow rate of the gas flowing in from the outside of the sucker is reduced. As a result, the pressure in the sucker, which has been reduced by suction, does not increase easily, and the amount of beverage that can be fed by an infant can be reduced. On the other hand, in the case of an infant who has a weak suction force at the time of breastfeeding, the ventilation hole of the first ventilation member is selected so that the flow rate of the gas flowing in from the outside of the sucker increases. As a result, the pressure in the sucker reduced by suction increases immediately, and the amount of beverage that can be fed by an infant can be increased. Therefore, it is possible to adjust the feeding time or beverage flow rate suitable for infants by a simple method. In addition, the appropriate lactation time in this specification means that the time required for drinking the drink in a sucker is about 15 to 20 minutes, for example.

  According to the invention described in claim 2, in the invention described in claim 1, the plurality of ventilation holes of the first ventilation member or the ventilation holes of the second ventilation member are check valves. A featured artificial nipple is provided.

  That is, in the invention according to claim 2, the plurality of ventilation holes of the first ventilation member or the ventilation holes of the second ventilation member are check valves, so that the beverage can be fed from the inside of the sucker through the communication ventilation holes. Leakage is prevented.

Further, in the invention according to claim 1 or 2, according to the invention described in claim 3, prior Symbol first vent member and the second vent member is formed in a donut shape and tabular and wherein Tei Rukoto An artificial nipple is provided.

  That is, in the invention according to claim 3, the artificial nipple is attached to the main body of the baby bottle through the first ventilation member and the second ventilation member which are formed in a donut shape and a flat plate shape. Appropriate breastfeeding time or beverage flow rate can be adjusted.

  According to the invention described in claim 4, in the invention described in any one of claims 1 to 3, each of the plurality of vent holes of the first vent member is formed in one of the concave portion or the convex portion. The vent hole of the second ventilation member is formed in the other of the concave portion or the convex portion, and the communication of the vent hole is performed by fitting the concave portion and the convex portion of the first vent member and the second vent member. An artificial nipple is provided that is characterized by being performed.

  That is, in the invention according to claim 4, since the communication of the vent holes is performed by fitting the concave portions and the convex portions of the first vent member and the second vent member, the vent holes can be more reliably communicated. Is possible.

  According to a fifth aspect of the present invention, there is provided a sucker comprising the artificial nipple according to any one of the first to fourth aspects and a sucker body.

  According to the invention described in each claim, there is a common effect that the feeding time or the beverage flow rate suitable for the infant can be adjusted by a simple method.

1 is a perspective view of a baby bottle according to an embodiment of the present invention. It is a fragmentary longitudinal cross-section containing the artificial nipple of the sucker of FIG. It is a top view of the attachment member of the sucker of FIG. It is a front view of the attachment member of FIG. It is sectional drawing in line AA of the attachment member of FIG. It is a top view of the 1st ventilation member of the artificial nipple of the sucker of FIG. It is a bottom view of the 1st ventilation member of FIG. It is sectional drawing in line AA of the 1st ventilation member of FIG. It is sectional drawing in line BB of the 1st ventilation member of FIG. It is sectional drawing in line CC of the 1st ventilation member of FIG. It is a top view of the 2nd ventilation member of the artificial nipple of the sucker of FIG. It is a front view of the 2nd ventilation member of FIG. It is sectional drawing in line AA of the 2nd ventilation member of FIG. It is a top view of the artificial nipple main body of the artificial nipple of the sucker of FIG. It is a front view of the artificial nipple main body of FIG. It is a right view of the artificial nipple main body of FIG. It is sectional drawing in line AA of the artificial nipple main body of FIG. It is sectional drawing in line BB of the artificial nipple main body of FIG. It is a perspective view which shows fitting with the 1st ventilation member and the 2nd ventilation member. It is a figure explaining the flow measurement of the sucker of FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Corresponding components are denoted by common reference symbols throughout the drawings.

  FIG. 1 is a perspective view of a sucker 1 according to an embodiment of the present invention, and FIG. 2 is a partial longitudinal sectional view including an artificial nipple 2 of the sucker 1 of FIG. In the present specification, in the description of each component of the baby bottle 1, it is defined as “upper” or “lower” on the basis of the arrangement in the baby bottle 1 standing on a horizontal plane.

  The sucker 1 has an artificial nipple 2, a mounting member 3, and a sucker body 4. The artificial nipple 2 includes a first ventilation member 5 that is a vent part, a second ventilation member 6 that is a vent stopper, and an artificial nipple body 7. The sucker main body 4 is a bottle or the like for containing a beverage for infants such as milk or breast milk previously extracted, and is made of, for example, glass or hard synthetic resin. The artificial nipple body 7 is attached to the sucker body 4 via the first ventilation member 5 and the second ventilation member 6, and the attachment member 3 is screwed to the sucker body 4 as will be described later. It is fixed by.

  3 is a top view of the attachment member 3 of the nursing bottle 1 of FIG. 1, FIG. 4 is a front view of the attachment member 3 of FIG. 3, and FIG. 5 is a line A- of the attachment member 3 of FIG. It is sectional drawing in A. FIG.

  The attachment member 3 is a cylindrical member, and is formed by integrally molding a hard synthetic resin, for example, polypropylene. The attachment member 3 includes an attachment member main body 31 and an annular flange portion 32 that extends radially inward from the upper end of the attachment member main body 31. The flange portion 32 defines an upper opening 33. The artificial nipple 2 protrudes upward through the opening 33. An annular fitting protrusion 34 (FIG. 5) extending downward is formed on the lower surface of the flange portion 32. The fitting protrusion 34 is fitted with the fitting groove 75a of the artificial nipple body 7 as will be described later. The lower end edge of the attachment member main body 31 defines an opening 35 having a diameter larger than that of the upper opening 33. On the inner peripheral surface of the attachment member main body 31, a female screw portion 36 is formed which is screwed with a male screw portion 41 (FIG. 2) provided on the outer peripheral surface of the upper end portion of the sucker main body 4.

  6 is a top view of the first ventilation member 5 of the artificial nipple 2 of the nursing bottle 1 of FIG. 1, FIG. 7 is a bottom view of the first ventilation member 5 of FIG. 6, and FIG. FIG. 9 is a cross-sectional view of the first ventilation member 5 taken along line AA, FIG. 9 is a cross-sectional view of the first ventilation member 5 taken along line BB of FIG. 6, and FIG. It is sectional drawing in line CC of the member 5. FIG.

  The first ventilation member 5 is a donut-shaped and flat-plate member, and is formed by integrally molding an elastic material such as a soft synthetic resin, for example, a silicon resin. Below the outer peripheral surface of the first ventilation member 5, there is an annular flange portion 51 that extends radially outward. Further, four circular fitting holes 52a, 52b, 52c, and 52d are formed on the upper surface of the first ventilation member 5. Each of the fitting holes 52 a, 52 b, 52 c, 52 d is disposed at equal intervals around the central axis of the first ventilation member 5. Check valves 53, 54, and 55 are provided in the fitting holes 52a, 52b, and 52c, respectively. A check valve is not provided in the fitting hole 52d and is closed. Therefore, it can be said that the first ventilation member 5 has three ventilation holes 53, 54, 55 as check valves 53, 54, 55. A closed boss portion 56 is formed on the back surface of the first ventilation member 5 corresponding to the fitting hole 52d, and an opening 57 is formed in the center of the first ventilation member 5.

  Each of the check valves 53, 54, 55 has a pair of valve bodies. For example, the check valve 53 includes a pair of valve bodies 53a and 53b as shown in FIGS. The valve bodies 53a and 53b are flat movable pieces extending obliquely downward from the inner peripheral surface of the fitting hole 52a. A slit 53c extending along the radial direction of the first ventilation member 5 is formed between the tips of the valve bodies 53a and 53b. Since FIG. 8 is a cross-sectional view through the slit 53c, the slit 53c is not shown in FIG. 8, and only one valve body 53a is shown. A partition wall 53 d is formed around the valve bodies 53 a and 53 b on the lower surface of the first ventilation member 5.

  In normal times, as shown in FIG. 10, the slit 53c is closed so that the valve bodies 53a and 53b have a wedge-shaped cross section. Accordingly, the pressure due to the flow of gas or the like from the lower side to the upper side of the first ventilation member 5 acts in a direction in which the valve bodies 53a and 53b are more closed. That is, the slit 53c remains closed, and the check valve 53 is closed against the flow from the lower side to the upper side of the first ventilation member 5. On the other hand, the pressure generated by the flow from the upper side to the lower side of the first ventilation member 5 acts in the direction in which the tips of the valve bodies 53a and 53b are separated from each other. Accordingly, the slit 53c is opened, and the check valve 53 is opened with respect to the flow from the top to the bottom of the first ventilation member 5.

  The other check valves 54 and 55 are the same as the check valve 53 except for the shape of the valve body, and thus will be described briefly. The check valve 54 has a pair of valve bodies 54a and 54b. The valve bodies 54a and 54b are curved movable pieces extending obliquely downward from the inner peripheral surface of the fitting hole 52b. A slit 54c extending along the radial direction of the first ventilation member 5 is formed between the tips of the valve bodies 54a and 54b. A partition wall 54d is formed around the valve bodies 54a and 54b on the lower surface of the first ventilation member 5. In normal times, the slit 54c is closed so that the valve bodies 54a and 54b have an arcuate cross section. That is, in normal times, the valve bodies 54a and 54b form one convex curved surface as a whole.

  The check valve 55 has a pair of valve bodies 55a and 55b. The valve bodies 55a and 55b are flat plate-like movable pieces extending laterally from the inner peripheral surface of the fitting hole 52c. A slit 55c extending along the radial direction of the first ventilation member 5 is formed between the tips of the valve bodies 55a and 55b. A partition wall 55 d is formed around the valve bodies 55 a and 55 b on the lower surface of the first ventilation member 5. In normal times, the slit 55c is closed so that the valve bodies 55a and 55b have a linear cross section. That is, in normal times, the valve bodies 55a and 55b form one plane as a whole.

  The above-described three check valves 53, 54, and 55 increase in pressure according to the flow required to open, that is, the pressure required to open each of the slits 53c, 54c, and 55c in the order described. This means that when the pair of valve bodies receives pressure due to the flow from the upper side to the lower side of the first ventilation member 5, the magnitude of the force component acting in the direction of separating the tips of the valve bodies is reduced. Dependent. When each check valve receives the same pressure in the flow direction in which it opens, that is, when it is arranged under the same differential pressure, the magnitude of the force acting on each valve element is arranged in a wedge shape. The valve body arranged is larger than the valve body arranged in the arc shape, and the valve body arranged in the arc shape is larger than the valve body arranged in the straight line shape. Therefore, the opening areas of the slits 53c, 54c, and 55c when arranged under the same differential pressure are reduced in the order of description, and the flow rates of the check valves 53, 54, and 55 are also reduced in this order.

  11 is a top view of the second ventilation member 6 of the artificial nipple 2 of the sucker 1 of FIG. 1, FIG. 12 is a front view of the second ventilation member 6 of FIG. 11, and FIG. It is sectional drawing in line AA of the 2nd ventilation member 6 of.

  The second ventilation member 6 is a donut-shaped and flat-plate member, and is formed by integrally molding a hard synthetic resin, for example, polypropylene. An annular support wall 62 extending upward is formed in the vicinity of the opening 61 on the upper surface of the second ventilation member 6. Further, an annular peripheral wall 63 extending downward from the outer peripheral edge portion is formed on the lower surface of the second ventilation member 6. Accordingly, a recess 64 defined by the peripheral wall 63 is formed on the lower surface of the second ventilation member 6. As will be described later, the first ventilation member 5 is fitted into the recess 64.

  A hollow boss 65 extending downward is formed in a part of the lower surface portion corresponding to the upper surface portion of the second ventilation member 6 in which the support wall 62 is formed. A groove 66 having a semicircular cross section extending from the outer peripheral surface of the second ventilation member 6 toward the radially inner side is formed on the upper surface of the second ventilation member 6. The semicircular groove 66 communicates with the hollow boss 65 to form a ventilation hole 67.

  14 is a top view of the artificial nipple body 7 of the artificial nipple 2 of the baby bottle 1 of FIG. 1, FIG. 15 is a front view of the artificial nipple body 7 of FIG. 14, and FIG. 16 is the artificial nipple body of FIG. FIG. 17 is a right side view of the nipple body 7, FIG. 17 is a cross-sectional view taken along line AA of the artificial nipple body 7 in FIG. 14, and FIG. 18 is a cross section taken along line BB of the artificial nipple body 7 in FIG. FIG.

  The artificial nipple body 7 is a hollow member as a whole, and is formed by integrally molding an elastic material such as a soft synthetic resin, for example, a silicon resin. The artificial nipple main body 7 has a base 71, a first nipple trunk 72, a second nipple trunk 73, and a nipple 74. The base portion 71 has a flange portion 75, a neck portion 76, and an overhang portion 77.

  The flange portion 75 extends annularly from the lower end of the cylindrical neck portion 76 outward in the radial direction. On the upper surface of the flange portion 75, an annular fitting groove 75a that fits with the fitting protrusion 34 provided on the lower surface of the flange portion 32 of the mounting member 3 is formed (FIG. 2). The outer diameter of the flange portion 75, the outer diameter of the flange portion 51 of the first ventilation member 5, and the outer diameter of the second ventilation member 6 are substantially the same. The inner diameter of the opening 78 of the flange portion 75, the inner diameter of the opening 57 of the first ventilation member 5, and the inner diameter of the opening 61 of the second ventilation member 6 are substantially the same (FIG. 2).

  The neck portion 76 is formed slightly longer in the axial direction than the thickness of the flange portion 32 of the mounting member 3 so as to fit in the opening 33 of the mounting member 3. Further, the outer diameter of the neck portion 76 is slightly thinner than the lower flange portion 75 and the upper overhang portion 77.

  The overhang part 77 is an annular convex curved surface whose diameter gradually increases upward from the upper end of the neck part 76, and the overhang part 77 has a maximum diameter part 77 a that is an annular part having the maximum outer diameter. To the first nipple torso 72. Note that the overhang portion 77 may be formed in a flange shape that extends annularly outward from the upper end of the neck portion 76 in the radial direction.

  The first nipple trunk 72, the second nipple trunk 73, and the nipple 74 have a substantially conical shape as a whole with the tip of the nipple 74 as a vertex. The substantially conical middle line axis C <b> 1 is inclined to the upper jaw side with respect to the central axis C <b> 2 of the base 71. In other words, the artificial nipple main body 7 has a base 71, that is, a portion below the maximum diameter portion 77a of the overhang portion 77 has a rotationally symmetric bobbin shape centering on the central axis C2, but above the maximum diameter portion 77a, The shape is such that a substantially conical body is inclined and disposed on the base 71. Accordingly, the baby bottle 1 according to the present invention has directionality for proper use, and when breastfeeding, it is necessary to make an infant bare so that the right side is the upper jaw side and the left side is the lower jaw side in FIG. There is. In the present embodiment, the inclination angle is 7 °, but may be other angles.

  The 1st nipple trunk part 72 and the 2nd nipple trunk | drum 73 are cyclic | annular convex curved surfaces in which a diameter reduces gradually toward upper direction. A space between the first nipple barrel portion 72 and the second nipple barrel portion 73 is defined by a first constricted portion 79 formed of an annular concave curved surface. In other words, the first nipple barrel 72 and the second nipple barrel 73, both of which are convex curved surfaces, are continuously connected by the first constricted portion 79. Therefore, the first nipple trunk portion 72 is defined by the maximum diameter portion 77 a of the overhang portion 77 and the first constricted portion 79.

  The nipple 74 has a substantially spherical shape, and a milk hole 74a (FIG. 14) that is a through hole for breast feeding is formed in the vicinity of the apex near the upper jaw. Since the milk hole 74a is disposed in the vicinity of the top near the upper jaw, the discharged beverage is prevented from directly hitting the back of the throat when the infant feeds. The milk hole 74a is preferably arranged at a position where the discharged beverage reaches the throat along the upper jaw. A concave curved surface 74 b is formed in a slightly upper part of the lower jaw side of the nipple 74. The concave curved surface 74b is formed at an angle inclined further to the upper jaw side than the central axis C1.

  A space between the second nipple barrel 73 and the nipple 74 is defined by a second constricted portion 80 formed of an annular concave curved surface. In other words, the second nipple body 73 having a convex curved surface and the teat 74 having a substantially spherical shape are continuously connected by the second constricted portion 80. Therefore, the second nipple trunk 73 is defined by the first constricted portion 79 and the second constricted portion 80.

  Next, further features of the artificial nipple body 7 will be described while explaining the sucking movement of the infant holding the artificial nipple body 7. The infant squeezes out while sucking the beverage from the artificial nipple body 7 by the peristaltic movement of the tongue. At this time, the infant sends the protuberance to the back of the throat while crushing the artificial nipple body 7 against the upper jaw with the tip of the raised tongue. That is, the artificial nipple body 7 is pressed while moving from the lower side to the upper side by the raised portion of the tongue on the lower jaw side surface. The degree of freedom of tongue movement can be improved by adjusting the path followed by the tongue in the artificial nipple body 7, that is, the region R of the lower jaw side portion shown in FIGS. As a result, the function of the artificial nipple body 7 itself is to induce a peristaltic movement of the infant's tongue, so that the infant can perform a sucking movement more smoothly. This will be described with reference to FIG.

  The infant's suckling movement is started by pressing the tip of the raised tongue against the abutment portion 73a which is the lower jaw side portion of the second nipple trunk 73. Therefore, first, it is necessary to form the artificial nipple body 7 so that this portion is easily crushed. This is realized by the presence of the cavity 81 formed by the inner surface of the overhang portion 77 and the inner surface of the first nipple trunk portion 72. That is, when the contact portion 73 a of the second nipple barrel 73 is pressed by the raised tip of the tongue, the upper portion of the first nipple barrel 72 is elastically deformed into the cavity 81. Next, as the tip of the raised tongue moves upward, the upper portion of the first nipple trunk 72 is restored, and the restoring force assists the upward movement of the tongue. At this time, the beverage is gradually compressed toward the teat 74 inside the artificial nipple body 7.

  The place to be formed so as to be easily crushed next to the second nipple torso 73, which is the starting point of the infant's feeding movement, is the boundary region between the nipple 74 and the second constricted portion 80, that is, the concave curved surface 74b of the nipple 74. This is a lower end portion K. This is realized by making the front and back of the portion K in the path followed by the tongue, that is, the upper portion J of the second constricted portion 80 and the center C of the concave curved surface 74b of the papilla 74 thinner. By forming the lower end portion K of the concave curved surface 74b so as to be easily crushed, the beverage can be efficiently discharged from the milk hole 74a. In one embodiment, the upper portion J of the second constricted portion 80 is 0.9 mm thick, the center C of the concave curved surface 74 b of the nipple 74 is 0.8 mm thick, and the lower end of the concave curved surface 74 b of the nipple 74 is used. The portion K is made 1.3 mm thick.

  Furthermore, the infant's feeding movement ends by crushing the tip of the raised tongue to the tip of the nipple 74 and returns to the starting point. However, if the entire nipple 74 is spherical, that is, has a convex curved surface, it is raised. The tip of the tongue may slip before the end point, fall off the path, and the beverage may not be discharged successfully. However, since the teat 74 of the artificial nipple body 7 has the concave curved surface 74b described above, the tip of the raised tongue can be moved to the end point without dropping off the path of the teat 74. Become.

  The artificial nipple body 7 has the above-described various characteristic configurations on the path followed by the infant's tongue, thereby inducing the peristaltic movement of the infant's tongue, so that the infant can perform a nursing movement more smoothly. Can do.

  Further, the upper jaw side surface of the first nipple trunk portion 72 and the second nipple barrel portion 73 are formed so that the projection of the convex curved surface is smaller than the lower jaw side surface. Therefore, the entire surface of the artificial nipple body 7 on the upper jaw side is formed with less unevenness. For this reason, the upper jaw side portion of the artificial nipple main body 7 is in close contact with the upper jaw of the infant and can perform a stable feeding exercise. Moreover, since the upper jaw side portion of the artificial nipple main body 7 is in close contact with the upper jaw of the infant, the inside of the oral cavity can be surely reduced in pressure by suction, and efficient breast feeding is possible. Furthermore, since there are few unevenness | corrugations as the whole upper jaw side surface of the artificial nipple body 7, the infant's upper lip is prevented from being caught inside the mouth due to friction with the artificial nipple body 7.

  Further, as described above, the artificial nipple main body 7 has a substantially conical middle axis C1 inclined to the upper jaw side with respect to the central axis C2 of the base 71, so that the artificial nipple main body 7 has an upper nipple side. A wide area and a large cavity 81 can be secured on the lower jaw side of the artificial nipple body 7 in a state where the portion is in close contact with the upper jaw of the infant. As a result, the degree of freedom of tongue movement can be improved.

  Since the artificial nipple body 7 is made of a soft synthetic resin or the like, it can be colored in various ways. Conventional artificial nipples are made of transparent or cloudy silicone resin. However, the artificial nipple body 7 may be colored with a warm color such as pink or skin color, or other colors. By coloring the entire artificial nipple main body 7 so as to have a color other than transparent or cloudy color, it is possible to prevent confusion with another person's sucker in a hospital or the like and to improve visibility. Furthermore, by coloring with a warm color system, it contributes to an increase in appetite of infants, and the infants can feel kindness and friendliness. Furthermore, the artificial nipple main body 7 can be partially colored to give a figure or pattern to make an artificial nipple with high design. In addition, you may use a marking etc. instead of coloring. For example, as shown in FIG. 14, characters such as “UP” indicating the upper side may be engraved so that the direction in use can be easily determined.

  FIG. 19 is a perspective view showing the fitting between the first ventilation member 5 and the second ventilation member 6. Before assembling the baby bottle 1, it is necessary to first fit the first ventilation member 5 and the second ventilation member 6. That is, as described above, the first ventilation member 5 has the three check valves 53, 54, 55 corresponding to the ventilation holes. As described above, since the flow rates obtained by the check valves 53, 54, and 55 are different under the same differential pressure, one appropriate check valve is selected. Cover the first ventilation member 5 with the second ventilation member 6 from above so that the boss 65 of the second ventilation member 6 is inserted into the fitting hole in which the selected check valve is arranged. The match is completed. That is, the first ventilation member 5 is fitted into the recess 64 of the second ventilation member 6, and at this time, the lower end surface of the peripheral wall 63 of the second ventilation member 6 and the upper surface of the flange portion 51 of the first ventilation member 5 Abut. As a result, one ventilation hole communicating the upper and lower sides of the integrated first ventilation member 5 and second ventilation member 6, that is, a ventilation hole corresponding to the selected check valve is obtained. In other words, the first ventilation member 5 and the second ventilation member 6 constitute a flow rate adjusting mechanism. The shape of the hollow boss 65 and the groove 66 of the second ventilation member 6, that is, the ventilation hole 67 is designed so as not to inhibit the gas flow through the selected check valve.

  Furthermore, the artificial nipple main body 7 is attached to the attachment member 3 before assembling the sucker 1. That is, the artificial nipple body 7 is inserted from below the attachment member 3 through the opening 35 and the opening 33. At least the outer diameter of the maximum diameter portion 77a of the overhang portion 77 of the artificial nipple body 7 is larger than the inner diameter of the opening 33 of the attachment member 3, and therefore the artificial nipple body 7 is inserted while being elastically deformed. Finally, the artificial nipple body 7 is inserted until the flange portion 32 of the attachment member 3 is disposed on the neck portion 76 of the artificial nipple body 7. When the attachment of the artificial nipple body 7 to the attachment member 3 is completed (FIG. 2), the fitting protrusion 34 of the flange portion 32 of the attachment member 3 is fitted with the fitting groove 75a of the flange portion 75 of the artificial nipple body 7. doing. Therefore, even if the infant bites and pulls the artificial nipple main body 7 strongly, the artificial nipple main body 7 is not easily detached from the attachment member 3.

  Here, in a state where the artificial nipple 2 is attached to the attachment member 3, the flange portion 32 of the attachment member 3 and the overhang portion 77 of the artificial nipple body 7 are separated from each other. Furthermore, since the diameter of the overhang portion 77 gradually increases upward from the upper end of the neck portion 76, the distance between the two members increases toward the outside in the radial direction. With such a configuration, even if the infant holds the artificial nipple body 7 in the back, the lips are not sandwiched between the flange portion 32 of the attachment member 3 and the overhang portion 77 of the artificial nipple body 7.

  The final assembly of the baby bottle 1 will be described. First, as described above, for example, the first check valve 53 is selected and fitted in advance onto the open end of the baby bottle body 4 containing the beverage. The ventilation member 5 and the second ventilation member 6 are placed. Next, the assembly is completed by covering the attachment member 3 and the artificial nipple body 7 attached in advance from above and screwing the attachment member 3 to the main body 4 (FIG. 2). At this time, the support wall 62 formed on the upper surface of the second ventilation member 6 is in contact with the lower end surface of the artificial nipple body 7. Therefore, even when the attachment member 3 is screwed into the baby body 4, even if it is too tightly closed, the upper surface of the second ventilation member 6 and the lower end surface of the artificial nipple body 7 are prevented from coming into close contact with each other. The vent hole 67 is prevented from being blocked.

  When the infant sucks the artificial nipple 2 and the pressure in the sucker 1 decreases, a pressure difference occurs between the inside and outside of the sucker 1. The check valve is opened by this differential pressure, passes through the gap between the female threaded portion 36 of the mounting member 3 and the male threaded portion 41 of the main body 4, the vent hole 67, and finally external air passes through the check valve 53. Guided into a baby bottle. On the other hand, the presence of the check valve 53 prevents the beverage from leaking from the inside of the baby bottle 1.

  FIG. 20 is a diagram for explaining the flow rate measurement of the baby bottle 1 of FIG. In the measurement method, water at normal temperature is put into the baby bottle 1 and sucked with a vacuum pump P at a pressure of −13 kPa, and the flow rate of the sucked water is measured. The water sucked from the baby bottle 1 is accommodated in the container 100. In the case of aeration through a wedge-shaped check valve 53, the case of aeration through a circular check valve 54, and the case of aeration through a linear check valve 55, 26 respectively. The results were 0.1 (ml / min), 23.3 (ml / min), and 18.0 (ml / min). In addition, when ventilation was not carried out in the sucker 1, that is, when the pressure in the sucker 1 continued to decrease, the result was 14.1 (ml / min).

  From the above, by appropriately selecting and communicating the vent hole 67 of the second vent member 6 with respect to the vent holes 53, 54, 55 of the first vent member 5 according to the suction force at the time of feeding the infant, The flow rate of the gas flowing in from the outside of the baby bottle 1 can be adjusted. For example, in the case of an infant who has a strong suction force at the time of breastfeeding, the ventilation hole 55 of the first ventilation member 5 is selected so that the flow rate of the gas flowing into the inside from the outside of the sucker 1 is reduced. As a result, the pressure in the sucker 1 that has decreased due to suction does not increase easily, and the amount of beverage that can be fed by an infant can be reduced. On the other hand, in the case of an infant whose suction force during feeding is weak, the vent hole 53 of the first vent member 5 is selected so that the flow rate of the gas flowing from the outside of the sucker 1 into the inside increases. As a result, the pressure in the sucker 1 that has decreased due to suction increases immediately, and the amount of beverage that an infant can feed in a single feeding operation can be increased. Therefore, it is possible to adjust the feeding time or the flow rate of the beverage appropriate for the infant (for example, the time required to fully drink the beverage in the sucker) by a simple method. Further, since the communication of the vent holes is performed by fitting the concave portions (fitting holes) and the convex portions (boss portions) of the first vent member 5 and the second vent member 6, the vent holes can be more reliably connected. Can be done.

  The communication of the air holes is not performed by fitting the concave portions and the convex portions of the first vent member and the second vent member, that is, by not having the convex portions and aligning the vent holes with each other. May be. Also, a plurality of hollow bosses extending upward are provided on the upper surface of the first ventilation member, the check valve as described above is provided in the boss portion, and the corresponding second ventilation member is provided with a through hole and fitted. It is also possible to adopt a configuration such as In addition, since the adjustment of the flow rate under the same differential pressure is substantially synonymous with the adjustment of the opening area of the vent hole, the first adjustment is simply performed without using a check valve having a different valve shape as in the above-described embodiment. The structure which provides the several through-hole from which opening area differs with respect to a ventilation member may be sufficient. Furthermore, when the 1st ventilation member has a some through-hole from which opening area differs, the structure which provides a check valve only in the hollow boss | hub part of a 2nd ventilation member may be sufficient. In the above-described embodiment, there are three adjustable air holes in the above-described flow rate adjusting mechanism, but two or four or more may be used.

  The features of the artificial nipple main body described above can be applied not only to the above-described suckers but also to conventional suckers.

DESCRIPTION OF SYMBOLS 1 Feeder 2 Artificial nipple 3 Attachment member 4 Feeder main body 5 1st ventilation member 6 2nd ventilation member 7 Artificial nipple body 53, 54, 55 Vent hole 67 Vent hole

Claims (5)

An artificial nipple body,
A first ventilation member having a plurality of ventilation holes having different opening areas under the same differential pressure;
A second ventilation member having a ventilation hole,
An artificial nipple that is attached to the body of the bottle in which the beverage is stored,
Gas that flows into the outside of the baby bottle through the connected vent hole by selectively communicating the vent hole of the second vent member with the plurality of vent holes of the first vent member. adjustable der the flow rate of is,
The artificial nipple body is formed so as to be attached to the sucker body through the first ventilation member and the second ventilation member, and the communication of the ventilation holes overlaps the first ventilation member and the second ventilation member. artificial nipple, characterized in Rukoto done by.   The artificial nipple according to claim 1, wherein the plurality of ventilation holes of the first ventilation member or the ventilation holes of the second ventilation member are check valves. Before SL artificial nipple according to claim 1 or 2, the first vent member and the second ventilation member, characterized in Tei Rukoto formed in a donut shape and a flat plate.   Each of the plurality of ventilation holes of the first ventilation member is formed in one of the recess or the projection, the ventilation hole of the second ventilation member is formed in the other of the depression or the projection, and the communication of the ventilation hole is The artificial nipple according to any one of claims 1 to 3, wherein the artificial nipple is performed by fitting the concave portion and the convex portion of the first ventilation member and the second ventilation member.   A baby bottle comprising the artificial nipple according to any one of claims 1 to 4 and a baby bottle main body.

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