JP5301358B2 - Liquid feed container - Google Patents

Abstract

Provided is a container for advancing liquid capable of eliminating a residual pressure in a tank after advancing the liquid, and capable of preventing the subsequent leakage of the liquid from a tank portion (T). Provided are a main body (12) which incorporates the tank portion (T) for storing liquid and which is capable of advancing the liquid from a supply port provided at a tip of the body, a piston (22) and a piston rod (24) which slide in the tank portion (T) to press the liquid toward the supply port at the tip, an operation tube (26) which is movable with respect to the main body (12) and which can be externally operated, and a conversion mechanism which converts the operation of the operation tube to an advancing movement of the piston (22) and the piston rod (24) in the axial direction in the tank portion (T), wherein after the advancing movement of the piston (22) and the piston rod (24) on the basis of the operation of the operation tube (26), the conversion mechanism generates a predetermined amount of retreating movement of the piston (22) and the piston rod (24).

Description

  The present invention relates to a liquid delivery container for delivering a liquid such as makeup, writing, and correction media.

  Conventionally, what was described in patent document 1 and patent document 2 is known as a liquid delivery container of this kind.

  In the liquid delivery container disclosed in Patent Document 1, a main body having a tank portion for storing liquid and having a supply port on the front end side, a piston moving forward in the tank portion, and a piston integrally connected to the rear are provided. A piston rod that extends and has a male screw formed on its peripheral surface, an operation cylinder that is attached to the rear part of the main body so as to be relatively rotatable, and a female screw hole that engages with the male screw of the piston rod. A piston rod guide that rotates integrally with the main body, and a ratchet cylinder that is fixed in the rear interior of the main body and that has an insertion hole through which the piston rod is inserted so as not to be relatively rotatable. At the rear end of the ratchet cylinder, there are ratchet teeth that mesh with the saw teeth and can be projected and retracted in the axial direction.When the operation cylinder is rotated, the piston rod guide rotates. Piston liquid forward is adapted to be unrolled from the supply port of the tip.

  In addition, in the liquid delivery container disclosed in Patent Document 2, a tank that contains liquid and has a supply port on the front end side, a piston that slides inside the tank, and a piston that is integrally connected to the piston and extends backward, There are a screw shaft that has a male screw formed on its peripheral surface and cannot rotate relative to the tank, a rotary cam that has a female screw hole that engages with the male screw on the screw shaft, and a rear side of the rotary cam. A knock cam that rotates the rotating cam in one direction and a knock body that is ejected rearward with respect to the knock cam and is operable to knock, and a protrusion is formed on one of the knock body and the knock cam. In addition, an inclined path is formed which is inclined in the axial direction on the other side and into which the protrusion is inserted. The knock cam is rotated by the knocking operation of the knock body, the rotating cam is rotated, the piston is advanced, and the liquid is supplied at the tip. As paid out more Going on.

JP 2001-299442 A JP 2001-232273 A

  As described above, in the conventional liquid feeding device, the piston moves forward by rotating operation or knocking operation, the pressure in the tank is increased, and the liquid is fed out from the supply port. Depending on the viscosity of the liquid being used, the liquid may continue to gradually exit the supply port until the pressure in the tank and the liquid viscosity are balanced, and even after the cap is closed and the supply port is closed, the liquid may leak out. There is a problem that there is.

  The present invention has been made in view of such problems, and provides a liquid delivery container that can remove the residual pressure in the tank after the delivery of the liquid and prevent the subsequent leakage of the liquid from the tank section. That is the purpose.

In order to achieve the above object, the first invention of the present invention includes a main body that has a built-in tank portion that stores liquid and is capable of delivering the liquid from its tip supply port,
A feeding body that slides in the tank portion and pushes the liquid toward the tip supply port;
An operating body that is movable with respect to the main body and can be operated from the outside,
A conversion mechanism for converting the operation of the operating body into an axial forward movement in the tank portion of the feeding body;
In a liquid delivery container provided with
The conversion mechanism is characterized in that a predetermined amount of backward movement of the feeding body is generated after the feeding body moves forward based on the operation of the operating body.

According to a second aspect of the invention, the conversion mechanism of the first aspect of the invention includes a screwing member that is screwed with the feeding body, and causes the relative rotation between the screwing member and the feeding body by the operation of the operation body. Then, the feed body is converted into a forward movement in the axial direction, and the backward movement of the feed body is generated by retracting the screwing member.

A third aspect of the invention is characterized in that the conversion mechanism of the second aspect of the invention generates a forward movement of the feeding body by advancing a screwing member with the start of operation of the operating body.

A fourth invention, the conversion mechanism of the second or third invention, characterized in that it comprises a return spring for urging the engagement member in the backward direction.

According to a fifth aspect of the invention, the conversion mechanism of the fourth aspect of the invention includes a first saw tooth formed on the screw member and a second saw tooth that meshes with the first saw tooth and cannot move in the axial direction. The first saw blade and the second saw blade rotate relative to each other in a direction of disengagement based on an operation from the operation body, and the screw member moves back and forth in the axial direction according to the relative rotation. And

A sixth invention is the said threaded member of the fifth invention non rotates relative to said body,
The conversion mechanism includes a first transmission member that transmits a rotation operation in one direction of the operation body to the feeding body, and the second sawtooth is in the same direction with respect to the rotation of the first transmission member in the one direction. While rotating, the rotation of the first transmission member in the direction opposite to the one direction does not rotate by meshing with the first sawtooth.

A seventh aspect of the invention, the conversion mechanism of the fourth invention, wherein a first engaging portion formed on the screw member, the second engagement of immovable in engaging direction to the first engagement portion And a screwing member moves forward in the axial direction in a direction in which the engagement between the first engagement portion and the second engagement portion is released when the operation body is operated. After the relative rotation of the coupling member and the feeding body, the screwing member is retracted in the axial direction and the first engagement portion and the second engagement portion are engaged.

In an eighth aspect of the invention, the conversion mechanism of the seventh aspect of the invention includes a second transmission member that converts the knock operation of the operating body into one-way rotation and transmits the rotation to the screwing member. Along with the start of operation of the operating body, it advances together with the operating body to advance the screwing member, and then rotates relative to the operating body to rotate the screwing member, and then relatively to the operating body The screw member is retracted to retract.

  In the specification and claims, the term “according to the start of operation of the operating body” includes immediately after the start of the operation including delays such as idling of members and play at the same time as the start of the operation. It is not limited to the case where the feeding body or the screwing member starts moving forward simultaneously with the operation start. The feeding body or the screwing member only needs to start moving forward with the start of operation of the operating body as a trigger.

  According to the present invention, the conversion mechanism can generate a predetermined amount of backward movement of the feeding body after the feeding body has moved forward based on the operation of the operating body. Residual pressure can be eliminated, and leakage of liquid from the tank can be prevented.

It is a whole longitudinal cross-sectional view showing 1st Embodiment of the liquid delivery container of this invention. It is a disassembled perspective view of the principal part components of the liquid delivery container by 1st Embodiment. (A) of the piston rod guide by 1st Embodiment is a side view, (b) is a longitudinal cross-sectional view, (c) is sectional drawing seen along the cc line of (b). (A) of the ratchet cylinder by 1st Embodiment is a side view, (b) is a longitudinal cross-sectional view. (A) of the inside screw cylinder by 1st Embodiment is a side view, (b) is a longitudinal cross-sectional view. (A) of the detent cylinder by 1st Embodiment is a side view, (b) is a longitudinal cross-sectional view. It is a longitudinal cross-sectional view at the time of using the liquid delivery container by 1st Embodiment. It is a longitudinal cross-sectional view at the time of using the liquid delivery container by 1st Embodiment, and is a figure when an operation cylinder is rotated to the positive direction. It is a longitudinal cross-sectional view at the time of using the liquid delivery container by 1st Embodiment, and is a figure when an operation cylinder is rotated in the reverse direction. It is a whole longitudinal cross-sectional view showing 2nd Embodiment of the liquid delivery container of this invention. It is a disassembled perspective view of the principal part components of the liquid delivery container by 2nd Embodiment. (A) of the tail cap according to the second embodiment is a plan view, (b) is a longitudinal sectional view taken along line bb in (a), and (c) is along line cc in (b). (D) is a transverse sectional view taken along the line dd of (b), and (e) is a transverse sectional view taken along the line ee of (b). . It is a top view of the operation cylinder by 2nd Embodiment. (A) of the sliding cam by 2nd Embodiment is a top view, (b) is a longitudinal cross-sectional view. (A) of the rotating cam by 2nd Embodiment is a top view, (b) is a longitudinal cross-sectional view. It is a longitudinal cross-sectional view at the time of using the liquid delivery container by 2nd Embodiment. It is a longitudinal cross-sectional view at the time of using the liquid delivery container by 2nd Embodiment, and is a figure when the knocking of an operation cylinder is started. It is a longitudinal cross-sectional view at the time of using the liquid delivery container by 2nd Embodiment, and is a figure in the middle of knocking of an operation cylinder. It is a longitudinal cross-sectional view at the time of using the liquid delivery container by 2nd Embodiment, and is a figure when knocking an operation cylinder completely.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
In FIG. 1, reference numeral 10 denotes a liquid supply container. The liquid supply container 10 has a tank portion T in which a liquid L such as a cosmetic, writing, or correction medium is stored, and has a tip supply port at the tip. It has a main body 12 having 12b.

  On the distal end side of the main body 12, a tip tool 14 fixed to the tip supply port 12 b at the tip of the main body 12, a pipe holder 16 fixed to the rear part of the tip tool 14, and a tip fixed to the tip of the pipe holder 16. A pipe 18 and a brush (tip application body) 20 in which the tip of the tip pipe 18 is inserted into the base and the base is fixed in the tip 14 are provided.

  Further, on the rear end side of the main body 12, a piston 22 that is slidable in the tank portion T, a piston rod 24 that is integrally connected to the piston 22, and an operation cylinder attached to the rear portion of the main body 12. 26, and a piston rod guide 28, a ratchet cylinder 30, an intermediate screw cylinder 32, a rotation stopper cylinder 34, and a return spring 36 are provided in the operation cylinder 26 and in the rear end portion of the main body 12. . The piston rod 24 and the piston 22 constitute a feeding body, and the piston rod guide 28, the ratchet cylinder 30, the intermediate screw cylinder 32, the rotation stopper cylinder 34, and the return spring 36 are used to extend the operation of the operation cylinder 26. It constitutes a conversion mechanism that converts it into an axial forward movement in the body tank. Hereinafter, these members will be described in detail.

  The piston rod 24 extends rearward from the piston 22, and as shown in FIG. 2, the cross-section thereof is a non-circular shape in which a part is cut out from a circular shape, and in this embodiment, has an oval shape, A male screw 24a is formed on the peripheral surface.

  An annular recess 26a (FIG. 2) is formed on the outer peripheral surface of the operation cylinder 26, and the annular recess 26a is fitted into an annular protrusion 12d (FIG. 1) formed on the rear inner peripheral surface of the main body 12. Accordingly, the operation cylinder 26 is attached to the main body 12 so as to be rotatable relative to the main body 12. A plurality of anti-rotation ribs 26c (FIG. 1) projecting in the inner diameter direction are formed at the inner rear portion of the operation cylinder 26.

  As shown in FIGS. 2 and 3, the piston rod guide 28 is formed with a plurality of vertical ribs 28a at the rear end thereof, for preventing the operation cylinder 26 from rotating between the adjacent vertical ribs 28a, 28a. The rib 26c is inserted, whereby the operation cylinder 26 and the piston rod guide 28 are rotated together. Further, inside the piston rod guide 28, a cylindrical portion 28b having an oblong insertion hole 28c that matches the cross-sectional shape of the piston rod 24 is formed, and the piston rod 24 is inserted into the insertion hole 28c of the cylindrical portion 28b. , The piston rod 24 rotates together with the piston rod guide 28. Further, the piston rod guide 28 is formed with saw teeth 28d in the circumferential direction facing the front.

  As shown in FIGS. 2 and 4, the ratchet cylinder 30 is formed with a pair of ratchet teeth 30b at its rear end, which are elastically deformable in the axial direction by an L-shaped slit 30a and can be swung. The ratchet teeth 30b mesh with the saw teeth 28d of the piston rod guide 28. Further, the ratchet cylinder 30 is formed with a sawtooth 30c in the circumferential direction facing the front at the front end thereof, and the sawtooth 30c has a direction opposite to the direction of the tooth of the sawtooth 28d of the piston rod guide 28. It has become. The ratchet cylinder 30 is sandwiched between a piston rod guide 28 and an intermediate screw cylinder 32 described later, and cannot move in the axial direction.

  As shown in FIGS. 2 and 5, the middle screw cylinder 32 is formed with a sawtooth 32 a in the circumferential direction facing the rear at the rear end, and this sawtooth 32 a can mesh with the sawtooth 30 c of the ratchet cylinder 30. It has become. A plurality of rotation-preventing ribs 32 b are formed on the outer peripheral surface of the middle screw cylinder 32. Further, a female screw hole 32c is formed inside the middle screw cylinder 32, and the male thread 24a of the piston rod 24 is screwed into the female screw hole 32c, and the middle screw cylinder 32 constitutes a screwing member. .

  As shown in FIGS. 2 and 6, a part of the outer peripheral surface of the rotation stopper cylinder 34 is a polygonal outer peripheral surface 34 a, and a polygonal hole 12 c formed in a part of the inner peripheral surface of the main body 12 (FIG. 1). The polygonal outer peripheral surface 34 a and the polygonal hole 12 c form a rotation prevention structure, and the rotation prevention cylinder 34 is not rotatable relative to the main body 12. Further, an outer step portion 34 b formed adjacent to the polygonal outer peripheral surface 34 a of the rotation stopper cylinder 34 and facing forward is in contact with an inner step portion 12 a formed on the inner peripheral surface of the main body 12 and facing rearward. Yes. The rotation stopper cylinder 34 is sandwiched between the inner step portion 12 a of the main body 12 and the tip of the operation cylinder 26 and is fixed to the main body 12. A plurality of vertical ribs 34c are formed on the inner peripheral surface of the rotation prevention cylinder 34, and the rotation prevention rib 32b of the intermediate screw cylinder 32 is inserted between the adjacent vertical ribs 34c, 34c. As a result, the middle screw cylinder 32 cannot rotate with respect to the main body 12 together with the rotation prevention cylinder 34.

  A return spring 36 is inserted between the rear end of the rotation prevention cylinder 34 and the middle screw cylinder 32, and the return spring 36 always urges the middle screw cylinder 32 rearward.

  A cap 38 that protects the brush 20 when not in use is detachably attached to the tip of the main body 12.

  When using the liquid delivery container 10 configured as described above, as shown in FIG. 7, the cap 38 is removed and application is performed using the brush 20, but when further liquid is desired to be supplied from the brush 20, The operation cylinder 26 is rotated in a certain direction (a positive direction, for example, clockwise) with respect to the main body 12.

  When the operation cylinder 26 is rotated with respect to the main body 12, the piston rod guide 28 is rotated in the same direction together with the operation cylinder 26, and the piston rod 24 is also rotated in the same direction.

  On the other hand, since the middle screw cylinder 32 screwed with the piston rod 24 is not rotatable by the rotation prevention cylinder 34 fixed to the main body 12, relative rotation between the piston rod 24 and the middle screw cylinder 32 is prevented. As a result, the piston rod 24 moves forward in the axial direction, and the piston 22 moves forward in the tank portion T, so that the liquid L in the tank portion T is pressed to the supply port 12b provided on the front end side of the main body 12. Then, it passes through the tip pipe 18 and is supplied from the tip of the brush 20 so that it can be used.

  When the piston rod guide 28 rotates in the forward direction, the rotation of the piston rod guide 28 is transmitted to the ratchet cylinder 30 by the engagement between the saw teeth 28d and the ratchet teeth 30b of the ratchet cylinder 30. However, as described above, since the middle screw cylinder 32 is non-rotatable, as shown in FIG. 8, slip occurs between the saw tooth 30c of the ratchet cylinder 30 and the saw tooth 32a of the middle screw cylinder 32, The saw tooth 30c of the ratchet cylinder 30 rotates while sliding on the slope of the saw tooth 32a of the intermediate screw cylinder 32, and the intermediate screw cylinder 32 moves forward in the axial direction against the spring force of the return spring 36. As a result, the piston rod 24 screwed into the middle screw cylinder 32 also moves with the forward movement of the middle screw cylinder 32. When the saw tooth 30 c of the ratchet cylinder 30 gets over the top of the saw tooth 32 a of the intermediate screw cylinder 32, the intermediate screw cylinder 32 is retracted by the repulsive force of the return spring 36.

  Thus, when the middle screw cylinder 32 is retracted, the piston rod 24 and the piston 22 are also retracted, the inside of the tank T is decompressed, and the pressure inside the tank T can be made equal to the outside air by sucking the outside air from the supply port 12b. it can.

  When the operation of the operation cylinder 26 is finished, the middle screw cylinder 32 is always retracted, so that leakage of liquid from the tank T can be prevented.

  Further, since the meshing with the saw teeth 30c, 32a is repeated according to the forward / backward movement of the middle screw cylinder 32, it is possible to generate a click feeling. When the user operates in accordance with the click feeling, the piston 22 moves forward by a rotation corresponding to a predetermined screw pitch of the piston rod 24, and the reciprocating motion of the middle screw cylinder 32 in the back and forth direction in response to one click. The pressure in the tank T is reduced each time the middle screw cylinder 32 is retracted.

  Next, as shown in FIG. 9, when the operation cylinder 26 is rotated in the opposite direction (reverse direction, for example, counterclockwise) with respect to the main body, the piston rod 24 is also rotated in the same direction.

  On the other hand, as with the rotation in the forward direction, since the middle screw cylinder 32 is not rotatable, relative rotation occurs between the piston rod 24 and the middle screw cylinder 32, and the piston rod 24 moves in the axial direction. Since the piston 22 moves backward in the tank portion T, the liquid L in the tank portion T is sucked from the supply port 12b.

  When the piston rod guide 28 rotates in the reverse direction, the ratchet cylinder 30 cannot rotate due to meshing of the saw teeth 30c with the saw teeth 32a. The piston rod guide 28 rotates while the ratchet teeth 30b swing in the axial direction. Since the meshing of the saw teeth 28d and the ratchet teeth 30b is repeated according to the swinging of the ratchet teeth 30b, a click feeling can be generated. Thus, when the user operates according to the click feeling, the piston 22 moves backward by the amount corresponding to the predetermined screw pitch of the piston rod 24. However, during this backward operation, no relative rotation occurs between the ratchet cylinder 30 and the middle screw cylinder 32, so that the middle screw cylinder 32 does not move back and forth.

  As described above, according to the present embodiment, when the operation cylinder 26 is rotated by the rotation operation, the middle screw cylinder 32 is rotated, and the two threads are engaged by relative rotation between the middle screw cylinder 32 and the piston rod 24. In addition to the forward movement of the piston rod 24, the piston rod 24 is moved back and forth together by the back and forth movement of the intermediate screw cylinder 32. In particular, since the middle screw cylinder 32 always moves forward with the start of the operation of the operation cylinder 26, the piston rod 24 and the piston 22 greatly advance together to apply a large pressure in the tank T, and the liquid in the tank T Can be pushed out from the supply port 12b at once. Further, when the rotation operation of the operation cylinder 26 is stopped, the middle screw cylinder 32 is always retracted, so that the piston rod 24 and the piston 22 can be largely retracted together to reduce the pressure in the tank T. Since the residual pressure in the tank T can be released, the liquid does not leak from the supply port 12b after the operation is completed.

  In this embodiment, the operation cylinder 26 can be operated forward and backward, and the piston 22 can be moved forward and backward in the tank portion T. However, the present invention is not limited to this. The ratchet cylinder 30 can be omitted when the piston 22 is caused to advance only in the tank portion T except for the longitudinal movement of the piston 22 accompanying the movement. The omission of the ratchet tube 30 can be dealt with by changing the direction of the saw teeth 28d of the piston rod guide 28 so that the saw teeth 28d of the piston rod guide 28 mesh with the saw teeth 32a of the intermediate screw tube 32.

(Second Embodiment)
Next, FIG. 10 shows a second embodiment of the present invention.
In the figure, reference numeral 100 denotes a liquid supply container. The liquid supply container 100 has, for example, a tank portion T in which a liquid L such as a cosmetic, writing, or correction medium is stored, and has a tip supply port 112b at the tip. A main body 112 having

  On the distal end side of the main body 112, a tip tool 114 fixed to the tip supply port 112 b at the tip of the main body 112, a pipe holder 116 fixed to the rear part of the tip tool 114, and a tip fixed to the tip of the pipe holder 116 A pipe 118 and a brush (tip application body) 120 in which the tip of the tip pipe 118 is inserted into the base and the base is fixed in the tip 114 are provided.

  Further, on the rear end side of the main body 112, a piston 122 that can slide in the tank portion T, a piston rod 124 that is integrally connected to the piston 122, and a tail fixed to the rear end of the main body 112. A crown 126 is provided, and an operation cylinder 128, a sliding cam 130, a rotating cam 132, a return spring 134, and a knock spring 136 are provided in the tail crown 126 and in the rear end portion of the main body 112. . The piston rod 124 and the piston 122 constitute a feeding body, and the sliding cam 130, the rotating cam 132, the return spring 134, and the knock spring 136 operate the operation cylinder 128 in the axial direction in the tank portion of the feeding body. The conversion mechanism which converts into the forward motion of is comprised. Hereinafter, these members will be described in detail.

  The piston rod 124 extends rearward from the piston 122. As shown in FIG. 11, the cross-section of the piston rod 124 is a non-circular shape in which a part is cut out from a circular shape. A male screw 124a is formed on the top.

  As shown in FIGS. 11 and 12, the tail crown 126 is formed with an annular recess 126a on the outer peripheral surface thereof, and the annular recess 126a is formed on an annular protrusion 112d ( 10). In addition, a large number of anti-rotation ribs 126 b are formed on the outer peripheral surface, and the anti-rotation ribs 126 b are fitted into vertical grooves 112 c (FIG. 10) formed on the inner peripheral surface of the main body 112. As a result, the tail cap 126 is fixed to the main body 112.

  Further, the tail cap 126 is formed with a first opening 126c and a second opening 126d on the peripheral surface thereof. The rear end surface of the second opening 126d protrudes in the inner diameter direction from the surrounding inner peripheral surface (see FIG. 12e), and the engagement protrusion 126e protrudes forward into the second opening 126d on the rear end surface. Formed. Further, an inner cylindrical portion 126f having an oblong insertion hole 126g that matches the cross-sectional shape of the piston rod 124 is formed inside the tail crown 126, and the piston rod 124 is inserted into the insertion hole of the inner cylindrical portion 126f. The piston rod 124 is prevented from rotating with respect to the crown 126 and the main body 112 by passing through 126g.

  As shown in FIGS. 11 and 13, the operation cylinder 128 is formed with an inclined groove 128 a inclined on the side surface in the axial direction. The rear end portion of the inclined groove 128a is a recess 128b that is recessed backward. Further, three sides have elastic pieces 128d surrounded by slits 128c, and protrusions 128e are formed on the surface of the elastic pieces 128d. The projection 128e is fitted into the first opening 126c of the tail crown 126 so as to be movable in the axial direction, and the projection 128e slides in the first opening 126c, so that the operation cylinder 128 is moved within the sliding range. 126 and the main body 112 can be knocked.

  As shown in FIGS. 11 and 14, the sliding cam 130 has an elastic piece 130 b that is surrounded by a slit 130 a on three sides, and a protrusion 130 c is formed on the surface of the elastic piece 130 b. The protrusion 130c is slidably fitted in the inclined groove 128a of the operation cylinder 128, and the sliding cam 130 can rotate with respect to the tail crown 126 and the main body 112 by sliding in the inclined groove 128a. It has become. In addition, a pair of ratchet teeth 130e that are rockable by being elastically deformed in the axial direction by an L-shaped slit 130d are formed at the tip of the sliding cam 130. Further, a step portion 130 f is formed inside the sliding cam 130.

  As shown in FIGS. 11 and 15, the rotating cam 132 is formed with saw teeth 132 a in the circumferential direction facing the rear, and the saw teeth 132 a mesh with the ratchet teeth 130 e of the sliding cam 130. Further, an enlarged diameter portion 132b is formed in front of the saw tooth 132a, and a plurality of engaging recesses 132c are formed at the rear end of the enlarged diameter portion 132b so as to be spaced apart in the circumferential direction. ing. The enlarged diameter portion 132b is locked to the rear end surface of the second opening 126d of the tail crown 126, and the engagement recess 132c is engaged with an engagement protrusion 126e formed on the rear end surface of the second opening 126d. It is possible. The rear end of the rotating cam 132 abuts on the step portion 130 f of the sliding cam 130.

  Further, a female screw hole 132d is formed in the rotary cam 132, and the male screw 124a of the piston rod 124 is screwed into the female screw hole 132d. The rotary cam 132 constitutes a screwing member.

  A return spring 134 is inserted between the tail crown 126 and the rotating cam 132, and the return spring 134 always urges the rotating cam 132 rearward.

  Further, a knock spring 136 is inserted between the sliding cam 130 and the operation cylinder 128, and the knock spring 136 urges them in a direction away from each other.

  A cap 138 that protects the brush 120 when not in use is detachably attached to the tip of the main body 112.

  When using the liquid delivery container 100 configured as described above, the cap 138 is removed and application is performed using the brush 120 as shown in FIG. The cylinder 128 is knocked with respect to the main body 112.

  When the operation cylinder 128 is knocked with respect to the main body 112 and moves forward, the projection 130c of the sliding cam 130 is fitted in the inclined groove 128a of the operation cylinder 128, so that the sliding cam 130 also starts to operate. At the start of the operation, the engaging recess 132c of the rotating cam 132 is engaged with the engaging protrusion 126e of the tail crown 126, the rotation of the rotating cam 132 is prohibited, and the sliding tooth 132a of the rotating cam 132 slides. Since the sliding cam 130 is also prevented from rotating due to the meshing of the moving cam 130 with the ratchet teeth 130 e, the sliding cam 130 moves forward together with the operation cylinder 128.

  As shown in FIG. 17, since the rotary cam 132 moves forward together with the sliding cam 130, the engagement between the engagement recess 132c of the rotary cam 132 and the engagement protrusion 126e of the tail crown 126 is released, and the rotation cam 132 rotates. The cam 132 and the sliding cam 130 can be rotated. Further, when the forward movement of the sliding cam 130 is also restricted, as shown in FIG. 18, the projection 130c of the sliding cam 130 moves relatively in the inclined groove 128a of the operation cylinder 128, and the sliding cam 130 As a result, the rotating cam 132 also rotates.

  Since the piston rod 124 is prevented from rotating by the tail crown 126, when the rotary cam 132 moves forward, the piston rod 124 moves forward in the axial direction, and thereafter, when the rotary cam 132 rotates, the rotary cam 132 and the piston rod Since relative rotation occurs between the piston rod 124 and the piston rod 124, the piston rod 124 moves forward in the axial direction. As the piston rod 124 moves forward, the piston 122 moves forward in the tank portion T, so that the liquid L in the tank portion T is pressed to the supply port 112b provided on the distal end side of the main body 112, and passes through the distal end pipe 118. As can be seen, it is supplied from the tip of the brush 120 and can be used.

  When the operation cylinder 128 is completely knocked within a range in which the operation cylinder 128 is slidable with respect to the tail crown 126, the protrusion 130c of the sliding cam 130 reaches the end of the inclined groove 128a. Then, due to the repulsive force of the return spring 134, the rotating cam 132 and the sliding cam 130 are retracted, and the protrusion 130c is fitted into the recess 128b at the end of the inclined groove 128a.

  When the rotary cam 132 moves backward, the piston rod 124 and the piston 122 also move backward, the inside of the tank T is decompressed, and the outside air is sucked from the supply port 112b, so that the pressure inside the tank T can be made equal to the outside air. . Therefore, leakage of the liquid from the tank T can be prevented.

  Further, when the rotating cam 132 moves backward, the engaging recess 132c of the rotating cam 132 is engaged with the engaging protrusion 126e of the tail crown 126, and the rotating cam 132 is prohibited from rotating again.

  Next, when the knock of the operation cylinder 128 is released, the operation cylinder 128 is retracted by the repulsive force of the knock spring 136, and the protrusion 130 c of the sliding cam 130 moves relatively in the inclined groove 128 a, and the sliding cam 130 is moved. Turns. At this time, since the rotation of the rotating cam 132 is prohibited, the ratchet teeth 130e of the sliding cam 130 rotate in the opposite direction while sliding on the slope of the saw tooth 132a of the rotating cam 132.

  By repeating this knocking operation, the sliding cam 130 repeats reciprocating rotation within a certain angular range. However, the rotating cam 132 rotates only in a certain direction, and the rotation of the rotating cam 132 causes the piston rod 124 and the piston to rotate. 122 can be reliably advanced by a fixed distance, and the liquid filled in the tank T can be fed out from the supply port 112b.

  As described above, according to the present embodiment, when the operation cylinder 128 is knocked out, the rotary cam 132 is rotated and the piston rod is engaged by the relative rotation between the rotary cam 132 and the piston rod 124. In addition to the forward movement of the piston 124, the piston rod 124 moves back and forth together by the back and forth movement of the rotating cam 132. In particular, since the rotation cam 132 always moves forward with the start of the operation of the operation cylinder 128, the piston rod 124 and the piston 122 greatly advance together to apply a large pressure in the tank T, so that the liquid in the tank T is discharged. It can push out from the supply port 112b at a stretch. In addition, when the operation cylinder 128 is completely knocked, the rotary cam 132 moves backward, so that the piston rod 124 and the piston 122 can move greatly together to reduce the pressure in the tank T. Since the residual pressure in the tank T can be released, liquid does not leak from the tip supply port 112b after the operation is completed.

  In this embodiment, since the rotary cam 132 has already moved backward when the operation cylinder 128 is fully knocked, the residual pressure in the tank T is already released even if the operation cylinder 128 is kept pressed for a long time. Therefore, the liquid can be prevented from leaking.

  However, the present invention is not limited to the above example, and the rotary cam 132 may be retracted after the operation cylinder 128 has knocked, or the rotation cam 132 is retracted as the operation cylinder 128 returns backward. May be.

  In the above embodiment, a part constituted by a plurality of members can be constituted by a single member, or a part constituted by a single member can be constituted by a plurality of members.

12, 112 Main body 12b, 112b Tip supply port 22, 122 Piston (feeding body)
24, 124 Piston rod (feeding body)
26, 128 Operation cylinder (operation body)
28 Piston rod guide (first transmission member)
30 ratchet cylinder 30c sawtooth (second sawtooth)
32 Medium thread cylinder (screwing member)
32a saw blade (first saw blade)
34 Non-rotating cylinder 36 Return spring 126e Engaging protrusion (second engaging portion)
130 Sliding cam (second transmission member)
132 Rotating cam (screwing member)
132c Engaging recess (first engaging part)
134 Return spring L Liquid T Tank

Claims (4)

Built-in tank part that stores liquid, and main body that can feed liquid from its tip supply port;
A feeding body that slides in the tank portion and pushes the liquid toward the tip supply port;
An operating body that is movable with respect to the main body and can be operated from the outside,
A conversion mechanism for converting the operation of the operating body into an axial forward movement in the tank portion of the feeding body, and generating a predetermined amount of backward movement of the feeding body after the feeding body moves forward based on the operation of the operating body ;
In a liquid delivery container provided with
The conversion mechanism includes a screwing member that is incapable of relative rotation with respect to the main body and is screwed with the feeding body, and generates relative rotation between the screwing member and the feeding body by operation of the operation body. Converting the forward movement of the feeding body into the axial direction and generating the backward movement of the feeding body by retracting the screwing member,
The conversion mechanism includes a return spring that urges the screwing member in a backward direction, a first sawtooth formed on the screwing member, and a second sawtooth that meshes with the first sawtooth and cannot move in the axial direction. The first saw blade and the second saw blade rotate relative to each other in the direction of disengagement based on an operation from the operation body, and the screw member moves back and forth in the axial direction according to the relative rotation. And
Furthermore, the conversion mechanism includes a first transmission member that transmits a rotation operation in one direction of the operation body to the feeding body, and the second sawtooth is in the same direction as the rotation of the first transmission member in the one direction. The liquid supply container is characterized in that it does not rotate due to meshing with the first sawtooth while rotating in the direction opposite to the one direction of the first transmission member . Built-in tank part that stores liquid, and main body that can feed liquid from its tip supply port;
A feeding body that slides in the tank portion and pushes the liquid toward the tip supply port;
An operating body that is movable with respect to the main body and can be operated from the outside,
A conversion mechanism for converting the operation of the operating body into an axial forward movement in the tank portion of the feeding body, and generating a predetermined amount of backward movement of the feeding body after the feeding body moves forward based on the operation of the operating body;
In a liquid delivery container provided with
The conversion mechanism includes a screwing member that is screwed with the feeding body, and the relative rotation is generated between the screwing member and the feeding body by the operation of the operation body so that the feeding body moves forward in the axial direction. Converting and generating a backward movement of the feeding body by retracting the screwing member ;
The conversion mechanism further includes a return spring that urges the screwing member in the backward direction, and a second transmission member that converts the knocking operation of the operating body into one-way rotation and transmits the rotation to the screwing member. The second transmission member moves forward together with the operating body as the operation body starts operating, advances the screwing member, and then rotates with respect to the operating body to rotate the screwing member. liquids feeding container with relatively backward you wherein Rukoto retracts the threaded member with respect. The conversion mechanism includes a first engagement portion formed on the screwing member and a second engagement portion that engages with the first engagement portion and cannot move in the axial direction, As the operation starts, the screwing member advances in the axial direction in a direction in which the engagement between the first engagement portion and the second engagement portion is released, and relative rotation between the screwing member and the feeding body is generated. 3. The liquid supply container according to claim 2, wherein the screwing member is retracted in the axial direction and the first engaging portion and the second engaging portion are engaged with each other. The conversion mechanism, the liquid feeding according to any one of claims 1 to 3, characterized in that to generate the forward movement of the feeding member by advancing the threaded member with the operation start of the operating body container.

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