JP5209823B1 - Component extraction accelerator - Google Patents

Abstract

Extraction time is shortened by subjecting a component extraction target immersed in a container using a shaft to revolve and rotate.
A rotating part 2 that rotates about a shaft 1 is provided on the shaft 1, and an attaching part that can attach an extraction object T to the rotating part 2 is provided, and the extraction object is provided in the attaching part. Is attached to the rotating part 2 by rotating and rotating the rotating part 2 by allowing the rotating part 2 to rotate and rotating. Further, a component extraction accelerating device that accelerates the extraction of the component by rotating the extraction target T and allowing the rotation to rotate is created.
[Selection] Figure 1

Description

  A rotating part that rotates about an axis is provided on the axis, and an attaching part that can attach an extraction object to the rotating part is provided. The extraction object is attached to the attaching part, and the axis is placed in a container. The rotating object is rotated and revolved by allowing the rotating part to revolve and rotate, and the extraction object attached to the revolving part is revolved and rotated. The present invention relates to a component extraction accelerating device that accelerates the extraction of components by enabling rotation.

  A solid material with an extractable component, or a teapack or cartridge containing a powdery extract (hereinafter collectively referred to as “extractable object”) is inserted into the container and extracted. Extraction of components by attaching the extraction object to a rotating part and immersing it in a container and providing a swing function to rotate the extraction object and rotate and rotate the rotating part. There is no component extraction device characterized by accelerating the process.

  The swing function in the invention of the present application defines a function in which the rotating component provided on the shaft rotates around the shaft as a fulcrum.

  In the invention described in Japanese Patent Publication No. 2003-063562, when an existing tea pack is placed in water, the tea pack floats on the surface of the water by buoyancy, so that the powdery extract contained in the tea pack It was developed to solve the floating problem caused by the buoyancy of the tea pack, which takes time to extract ingredients. However, this structure is made only for the purpose of immersing the tea pack attached to the end of the bar in the container by providing a bar instead of the string of the tea pack. It does not have a function to make

  The invention described in the registered utility model No. 3017534 is provided with a cartridge on the bottom surface of the plastic bottle cap. However, this structure merely immerses the cartridge containing the powdered extract with the container closed, and the powdered extract sealed in the cartridge rises, so the extract in the cartridge Can not be soaked. Even if the cartridge is made into two layers and the powdery extract is fixed and dipped in the lower part, since the cartridge is fixed, there is a function to revolve and rotate the cartridge of the extraction object. Not.

Patent publication 2003-063562 Registered Utility Model No. 3017534

  The said prior art makes it a subject to just immerse an extraction target object in a container, and does not have a function to revolve and rotate an extraction target object in a container.

  Create a component extraction device with a rotating part with a function to attach the extraction object on the shaft, immerse it in the container using the shaft, and provide a swing function to extract it immersed in the container An object of the present invention is to reduce the extraction time of an extraction object by revolving and rotating the object and enabling rotation.

  The present invention is provided with the following means in order to solve the above problems.

  A rotating part that rotates about an axis is provided on the axis, and an attaching part that can attach an extraction object to the rotating part is provided. The extraction object is attached to the attaching part, and the axis is placed in a container. The rotating object is rotated and revolved by allowing the rotating part to revolve and rotate, and the extraction object attached to the revolving part is revolved and rotated. A component extraction accelerating device characterized by accelerating component extraction by enabling rotation is created.

  In addition, a component extraction acceleration device is produced in which the shaft is flexible.

  And the effect of this invention can be exhibited by producing the component extraction acceleration apparatus characterized by providing the said rotary component in the end vicinity of the said axis | shaft. .

  A rotating part that rotates about an axis is provided on the axis, and an attaching part that can attach an extraction object to the rotating part is provided. The extraction object is attached to the attaching part, and the axis is placed in a container. The rotating object is rotated and revolved by allowing the rotating part to revolve and rotate, and the extraction object attached to the revolving part is revolved and rotated. A component extraction accelerating device characterized by accelerating component extraction by enabling rotation is created. This effect will be described below.

  Provided with a swing function, the rotating component revolves around the shaft as a fulcrum, and the rotation rotation is enabled, the extraction object attached to the rotating component is revolved and rotated. By making it possible, it is possible to shorten the extraction time by accelerating the extraction speed of the extraction object by two kinds of rotations of revolution and rotation.

  In addition, by the revolution rotation with the shaft as a fulcrum, a rotating water flow is generated in the container in the direction in which the shaft rotates. This rotating water flow allows the rotating part rotating around the axis to rotate.

  A component extraction acceleration device is produced in which the shaft is flexible. This effect will be described below. When the shaft is made flexible and the shaft is made to swing, the shaft performs a motion like a whip (hereinafter referred to as a whip motion). This whip motion has the effect of increasing the revolution of the rotating component.

  Due to the effect of increasing the revolution rotation described in the item 0016, the rotating water flow generated by the revolution rotation becomes strong, so that the rotation rotation of the rotating component can be promoted. The extraction object attached to the attachment part of the rotating part can rotate more or less by the whipping motion due to the flexibility of the shaft described in the paragraph 0016. Is stronger and lasts longer, so that the rotation of the extraction object can be promoted.

  Here, the flexibility of the shaft means that the shaft itself is made of a flexible material such as rubber, or the shaft itself is shaped to have flexibility such as a spring, and the shaft and the shaft are joined. Create a joint or a joint to join the shaft described later in 0069 into the container, and make the joint flexible by using a flexible material or shape. Including providing.

  A component extraction accelerating device is produced in which the rotating component is provided near the end of the shaft. This effect will be described below. When the rotating component performs the revolving rotation with the tip of the shaft as a fulcrum, the rotating component can perform the largest revolving rotation when it is provided near the end of the shaft. As a result, the extraction object attached to the attachment part included in the rotating component can be further rotated and rotated, and the vicinity of the end of the shaft is strongly affected by the rotating water flow generated by the rotating rotation. Rotational rotation is promoted.

The figure which inserted the tip of the axis | shaft 1 of the component extraction acceleration apparatus of this invention to the bottom face of the plastic bottle cap 11 with the press-fit joint 12 mentioned later, and inserted in the plastic bottle 10 is shown. FIG. 1 shows an operation when the plastic bottle 10 is rocked with the hand 18. The exploded view of the component extraction acceleration apparatus of this invention in FIG. 1 is shown. The figure which fixed the front-end | tip of the axis | shaft 1 of the component extraction apparatus of this invention using the press-fit joint 12 mentioned later to the existing plastic bottle cap 11 is shown. A bottom view of the press-fit joint 12 is shown. The figure which attached the PET bottle cap 11 of the state which fixed the axis | shaft 1 to the press injection joint 12 shown in FIG. FIG. 3 shows a sketch of the operation of shaking the plastic bottle 10 with the hand 18 shown in FIG. 2 as seen from the bottom surface of the plastic bottle 10. The component extraction acceleration apparatus of this invention is fixed to the bottom face of the plastic bottle cap 11 with the frenzy joint 16b mentioned later, and the figure inserted and sealed in the plastic bottle 10 is shown. FIG. 8 shows an operation when the plastic bottle 10 is grabbed with the hand 18 and shaken. The exploded view of the component extraction acceleration apparatus of this invention in FIG. 8 is shown. The component extraction acceleration apparatus of this invention is fixed to the bottom face of the exclusive plastic bottle cap 11a mentioned later by the term 0072, and the figure inserted and sealed in the plastic bottle 10 is shown. The plastic bottle cap 11a provided with the joint 13a of the rubber tube which can join the front-end | tip of the axis | shaft 1 to the bottom face of a container lid is shown. A plastic bottle cap 11b having a joint joint 13b having a protrusion 17 capable of joining the tip of the shaft 1a to the bottom surface of the container lid, and the shaft 1a to be joined to the PET bottle cap 11b are shown. FIG. 6 shows a press-fit joint 12a including a rubber pipe joint 13a that can join the tip of the shaft 1 to the bottom surface of the press-fit joint 12 shown in FIG. 5 shows a joint joint 13b having a projection 17 that can join the tip of the shaft 1a to the bottom surface of the press-fit joint 12 shown in FIG. 5, and the shaft 1a to be joined thereto. The exploded view in the case of joining to the axis | shaft 1 using the joining joint 13a of a rubber tube is shown to the frenzy joint 16b shown in FIG. A frenzy joint 16b including a joint joint 13b having a protrusion 17 capable of joining the tip of the shaft 1a to the bottom surface of the frenzy joint 16 shown in FIG. An example of use in which dedicated tea packs 7 and 7 ′, which will be described later in Section 0082, are fixed to tenbin-like attachment portions 3b and 3b ′ on the side surface of the rotating component 2 will be described. An example of use in which a dedicated cartridge 8 ′ and a weight 6, which will be described later in Section 0084, are fixed to tenbin-like attachment portions 3 b and 3 b ′ on the side surface of the rotating component 2 will be described. A use example in which the tea pack 7, the floating means 5, and the weight 6 are fixed to the three-direction tenbin-shaped attachment portions 3a, 3b, and 3b 'on the side surface of the rotating component 2 is shown. An example of use having tenbin-like attachment portions 3b and 3b ′ having a rotation function on the side surface of the rotating component 2α will be described. A use example in which the floating means 5 and the weight 6 are provided in the attachment portion 3b on the same side of the tenbin-like side of the rotating component 2 and the attachment portion 3a is provided on the opposite side of the tenbin is shown. An example of use is shown in which the floating means 5 is provided in the attachment portion 3b on the side surface of the rotating part 2 on the tenbin-like side and the movable weight 6 is provided in the attachment portion 3a on the opposite side of the tenbin. An example of use in which the cartridge 8 fixed by the attachment part 3b on the side surface of the tenbin-like side of the rotating component 2α has the attachment part 3a will be described. An example of use having mounting portions 3b and 3b 'having a rotating function provided with a floating means 5 having four blades on the tenbin-shaped side surface of the rotating component 2α will be described. An example of use having two rotating parts 2, 2 ′ on the shaft 1 is shown. An example of use in which the detachable attachment portion 3a is provided on the side surface of the rotating component 2 provided with the floating means 5 will be described. An example of use in which the tip 3α of the mounting portion 3 is made spherical and fitted into the hollow key at the end of the shaft 1 is shown. An example of use in which the mounting part 3a having a rotation function is provided on the bottom surface of the rotating component 2α ′ rotating around the shaft 1 will be described. An example of use in which a mounting part 3b having a rotating function is provided on the bottom surface of a rotating component 2α ′ that rotates about a shaft 1 and a cartridge 8 ′ that has a floating effect is fixed thereto is shown. An example of use in which the rotating parts 2α ″ rotating around the shaft 1 have attachment portions 3a, 3b, 3b ′ having a rotation function on the side surfaces and the bottom surface thereof will be described. An example of use of the component extraction acceleration apparatus of the present invention in which the shaft itself has a rotation function by using the joint joints 13α and 13α ′ having the rotation function will be described.

The first embodiment will be described using a component extraction acceleration device of the following form.

  As shown in FIG. 1, a spherical rotating component 2 is created, a vertical hole (a) is made in the rotating component 2, and a shaft 1 having a diameter smaller than the diameter of the vertical hole (a) is penetrated through the vertical hole (a). The rotating component 2 is fixed upside down by a pair of fixing components 4a and 4b in the vicinity of the end. A mounting portion 3 a having a hook-like tip is provided on the side surface of the rotating component 2 so as to protrude.

  The floating means 5 is mounted by providing a mounting portion 3b in the form of a tenbin on the opposite side surface of the rotating part provided with the mounting portion 3a.

  The end of the attachment portion 3b is formed as a screw, and the end of the screw is joined to a screw hole (A) provided in the rotating part. The tip of the screw is joined to a screw hole (A ') provided in the floating means 5. The floating means 5 has a buoyancy at the center and a blade on its side.

Further, the shaft 1 passing through the vertical hole (a) of the rotating part 2 is provided with a mounting portion 3b 'having a screw at the lower end, and a weight 6 having a screw hole (I ") that fits the screw is a screw hole. To be joined.
The weight 6 has a spiral groove (c) on its surface.

  Since the floating means 5 and the lead 6 are provided on the rotating component 2 and the shaft 1 by the above-described means, they can be detached.

  In the first embodiment, the upper tip of the shaft 1 of the component extraction accelerator is attached to the bottom surface of the existing plastic bottle cap 11 by a press-fit joint 12 described later in the paragraph 0048 shown in FIGS. It is fixed so that it can be removed.

  In the first embodiment, the shaft 1 has flexibility by using a flexible rubber having a flexible material for the shaft 1, so that the swing function defined in the paragraph 0003 is realized. As a result, the extraction object 7 provided in the attachment portion 3a can revolve around the shaft 1 provided in the press-fit joint 12 as a fulcrum.

  The component extraction accelerating device of the present invention described in the first embodiment is inserted into a pre-made plastic bottle 10 which is almost full of water, and the tea pack 7 of the extraction object attached to the attachment portion 3a in the plastic bottle 10 is FIG. 1 shows a state in which the PET bottle cap 11 is closed and sealed by being immersed in the container. In addition, the component extraction acceleration apparatus of this invention in an Example is expanded and drawn for description.

  Hereafter, the operation | movement in Example 1 of the component extraction acceleration apparatus of this invention is demonstrated in FIG.

  In FIG. 1, the component extraction acceleration device of the present invention is fixed to the bottom surface of the PET bottle cap 11 with a press-fit joint 12 described later in the paragraph 0048 and immersed in the PET bottle 10 and sealed, and the upper part of the PET bottle 10 is sealed. The operation of the component extraction accelerating device of the present invention, which is grasped with the hand 18 and manually shaken the PET bottle 10 in the direction of arrow A, will be described with reference to FIG.

  In FIG. 2, when the upper part of the plastic bottle 10 is grasped with the hand 18 and is manually shaken in the direction of the arrow A, the shaft 1 which has realized the swing function by having flexibility is attached with the press-fit joint 12. An operation of drawing a circle in the direction of arrow B with the portion as a fulcrum is performed.

  As a result, the rotating component 2 provided on the shaft 1 revolves in the direction of the arrow B, and this revolving rotation produces a rotating water flow D. This rotating water flow D enables the rotating component 2 to rotate in the direction of arrow E. The swing function includes a weight 6 in the vicinity of the end of the shaft 1 so that the inertia in the vicinity of the end of the shaft 1 can be increased and the revolution of the rotating component 2 with the shaft 1 as a fulcrum can be greatly increased. Thus, there is an effect of promoting the generation and sustaining of the rotating water flow D in the container. In this embodiment, the weight 6 has a conical shape in order to reduce resistance in water, and a spiral groove (c) is provided in order to aim at the amplification effect of the rotating water flow.

  In FIG. 2, the shaft 1 performs an operation of drawing a circle in the direction of the dotted line 1 ′, 1 ″ in the direction of the arrow B. As described above in the paragraph 0016, the shaft 1 has flexibility. Since the shaft 1 can realize the whip motion, the revolution rotation becomes large.

  This revolution rotation causes a rotating water flow in the direction of arrow D in the container. This rotating water flow promotes the rotation of the revolution and allows the rotating component 2 to rotate. In this way, extraction of components is accelerated by rotating the tea pack 7 fixed to the attachment portion 3a of the rotating component 2 and allowing the rotating rotation of the tea pack 7 by the rotating component 2. It can be made.

  2 shows how the shaft 1 and the rotating component 2 perform revolving rotation and rotation by the operation of FIG. 2 of the first embodiment described above from the bottom of the bottle 10. Is FIG. When the top end of the shaft 1 is fixed to the press-fit joint 12 indicated by the center of the circle in FIG. 7, the rotating component 2 performs revolution rotation about the shaft 1 fixed to the press-fit joint 12.

  The rotating water flow D generated in the container by the revolving rotation with the shaft 1 fixed to the press-fit joint 12 as a fulcrum is a 2 ′ drawing of the rotating component 2 provided near the lower end of the shaft 1 in FIG. The rotation of the revolving rotation B indicated by 2 ″, 2 ″ ″, 2 ″ ′ ″ is promoted, and the rotation rotation E of the rotating component 2 is enabled.

  As illustrated in FIG. 2, the rotating component 2 provided near the end of the shaft 1 performs the revolving rotation B as indicated by 2 ′ and 2 ″ in the arrow B direction by the swing function. The rotating component 2 is provided with the floating means 5 shown in FIG. 2 as means for accelerating the revolution rotation and the rotation rotation by strongly receiving the water flow effect of the rotating water flow D generated by the revolution rotation B.

  Due to the floating means 5, the rotating component 2 is strongly influenced by the water flow of the rotating water flow D and drifts in the direction of the rotating water flow D inside the container. or. When the floating means 5 receives the rotating water flow D, rotation of the rotating component 2 is promoted. Further, since the tea pack 7 itself of the extraction object is also provided with a floating means, by providing the attachment part 3 in the rotating part 2 in the form of a tenbin, both can balance each other's floating means with the tenbin. The rotating component 2 is urged to rotate smoothly around the shaft 1.

  2, the rotating part 2 is moved to the position of the laundry of the washing machine, as shown in FIG. 7 described in the paragraph 0037, by grasping the upper part of the plastic bottle 10 with the hand 18 and manually swinging it in the direction of arrow A. Thus, since the revolution rotation is performed while rotating, when the tea pack 7 is fixed to the rotating component 2, the extraction of the tea pack 7 is accelerated and the extraction time is shortened.

  When the present invention shown in FIG. 1 is used in the operation shown in FIG. 2, the state of shortening the component extraction time in the room temperature water of the component extract contained in the tea pack 7 as the extraction object will be described below.

  Without using the component extraction accelerating device of the present invention, the plastic bottle 10 is filled with room temperature water, the pre-made tea pack 7 is inserted into the plastic bottle 10 and the plastic bottle cap 11 is closed and sealed. The component extraction time will be described. In this state, the ready-made tea pack 7 is lifted to the upper part in the bottle 10 by buoyancy. Even if the bottle 10 is manually shaken, it remains floating above the bottle 10, so it does not rotate and takes time to extract components. It takes time to extract components even if the bottle 10 is turned upside down and repeatedly moved up and down to float up and down using the buoyancy of the existing tea pack 7. Even if the bottle 10 is rotated, the rotating water flow D shown in FIG. 2 is unlikely to occur and cannot be used. Further, in the prior art described in Japanese Patent Publication No. 2003-063562, in which a tea pack 7 is provided with a stick, the tea pack 7 is revolved and rotated even if the bottle 10 is rocked or rotated. Since the pack 7 cannot be rotated, the extraction effect due to the rotation was not observed.

  In the experimental results, when the pre-made tea pack 7 is inserted, the plastic bottle cap 11 is closed, and the plastic bottle 10 is left as it is after being manually shaken several times, the extraction time of 30 minutes or more is required. It was. In addition, when repeating the situation where the plastic bottle 10 is manually shaken and rotated and rotated and rotated and left and left repeatedly, the prior art described in Japanese Patent Publication No. 2003-063562 is also extracted for 18 minutes. It took time.

  Moreover, the vertical movement of the bottle 10 is manually repeated, and the means for rotating the bottle 10 together with the means for floating the tea pack 7 up and down using the buoyancy of the tea pack 7 and the situation of leaving the bottle 10 are repeated. And a means for manually shaking, moving up and down, and rotating the bottle 10 in a state where the prior art bar described in Japanese Patent Publication No. 2003-066352 is fixed and immersed in the PET bottle cap 11; Even when the situation of leaving the bottle 10 was repeated, the component extraction time required 12 minutes. Also for the prior art provided with the cartridge 8 on the bottom surface of the plastic bottle cap 11 described in the registered utility model No. 3017534, the above operation required an extraction time of 12 minutes or more.

  When the component extraction accelerating device of the present invention of the form shown in FIG. 1 is used in the operation shown in FIG. 2, when the situation where the bottle 10 is manually shaken and the situation where the bottle 10 is left is repeatedly performed, The extraction time is complete in 3 minutes. This shortening of the component extraction time is significantly different in normal temperature water and cold water as compared with the conventional extraction method described above.

  FIG. 3 is an exploded view of the component extraction acceleration apparatus of the present invention. In this figure, the component extraction accelerating device of the present invention fixed to the plastic bottle cap 11 by the press-fit joint 12 described later in section 0048 is inserted into the plastic bottle 10 and immersed in the bottle 10 as shown in FIG. Sealed.

The above-described press-fit joint 12 is newly created and manufactured by the inventor and is not a ready-made product.
Hereinafter, the detailed structure of the main body of the press-fit joint 12 will be described. As shown in FIG. 4, when the cap 11 is closed, an inner ring projection 15 is provided on the bottom surface of the existing plastic bottle cap 11 to prevent water leakage by tightly inserting and fixing the outer periphery thereof to the mouth of the plastic bottle. There are many things.

  As shown in FIG. 5, the press-fit joint 12 used in the present invention is an inner part of the inner ring projection 15 for preventing water leakage provided in the existing plastic bottle cap 11 shown in FIG. It can be fixed to the bottom of the PET bottle cap 11 by press-fitting using a spring force. Further, as shown in FIG. 5, the press-fit joint 12 has a space (d) in the center. In this way, the component extraction accelerating device of the present invention is fixed to the plastic bottle cap 11 by press-fitting and fixing the upper tip of the shaft 1 in the space (d) in the center of the press-fit joint 12 fixed to the bottom surface of the plastic bottle cap 11. It is fixed to the bottom. In order to ensure the pressure input of the shaft 1, the press-fit joint 12 has a thickness corresponding to at least the height of the inner ring projection 15.

  Many of the ready-made plastic bottle caps 11 are provided with the inner ring projections 15 on the bottom surface of the cap. Therefore, by using the press-fit joint 12, the shaft 1 of the component extraction accelerating device of the present invention is attached to the bottom surface of the cap. Since it can be fitted, it can be used as it is for a conventional existing plastic bottle cap 11, so that it is not necessary to make a new plastic bottle cap 11.

  As shown in FIG. 5, the main body of the press-fit joint 12 has a space (D) for press-fitting and fixing the upper tip of the shaft 1 at the center. Further, a part of the outer periphery has a C-shaped opening space (e), and when the outer periphery of the press-fit joint 12 is press-fitted into the inner ring projection 15 shown in FIG. Enables press-fitting using the deformation elasticity of (e). Furthermore, as shown in FIGS. 3, 4, 5, and 6, a wire spring 14 is provided on the inner side of the outer periphery of the press-fit joint 12 on the opposite side of the C-shaped opening space (v) to prevent the drop-off. The arm protruding outward from the hole formed in the outer periphery of the wire spring 14 has a function of being caught inside the inner ring projection 15.

  The press-fit joint 12 is press-fitted and fixed to the cap 11 by the wire spring 14. As shown in FIG. 6, the present invention is implemented in a state where the upper end of the shaft 1 is press-fitted and fixed to the cap 11, and the operation when the bottle 10 is rotated in the direction of arrow A in this state is shown in FIG. 1. This is shown in FIG.

  Depending on the shape of the inner ring projection 15 of the PET bottle cap 11, even if the wire spring 14 is not used, the deformation elasticity of the C-shaped opening space (e) provided in a part of the outer periphery of the press-fit joint 12 is improved. In some cases, it can be fixed only by force.

  FIG. 8 shows a second embodiment. FIG. 1 is a diagram in which an existing tea pack 7 containing a component extract is used as an extraction target. In FIG. 8, instead of the tea pack 7, a cartridge 8 containing a component extract is used as an extraction target. Use. There are two types of component extracts: powder and solid. The solid component extract 9 shown in FIG. 11 can be fixed to the mounting part 3 as it is, but the powder extract is a tea pack shown in FIG. 7 and the cartridge 8 shown in FIG.

  FIG. 8 shows a second embodiment different from the first embodiment in which the tea pack 7 containing the component extract shown in FIG. 1 is used as an extraction target, and a cartridge 8 incorporating the component extract. It is the figure which was attached to the component extraction acceleration apparatus of this invention as an extraction object. The cartridge 8 is newly created and manufactured by the inventor and is not a ready-made product.

  Since this cartridge 8 is made of metal, it has a weight. In the second embodiment shown in FIG. 8, the weight 6 is not provided as compared with the first embodiment shown in FIG. The reason is that the cartridge 8 itself has a weight, and this serves as the weight 6 described above in 0033. Also in the second embodiment, the floating means 5 is fixed to the attachment portion 3b ′ as in the first embodiment. A mounting portion 3b is provided in the form of a tenbin on the opposite side of the rotating component 2, and a cartridge 8 is mounted on the mounting portion 3b.

  In Example 2 shown in FIG. 8, a frenzy joint 16b including a joint joint 13b having a bump-like projection 17 on the bottom surface described later in 0077 is used. Further, a space (sole) having a tongue that can be fitted and joined to the projection 17 is provided at the tip of the shaft 1a. A swing function is realized by this joining means. In some cases, the effect of the swing function may be increased by providing a plurality of joining means provided with the joining joint 13b on the shaft 1a.

  In the state where the component extraction accelerating device shown in FIG. 8 is immersed in the PET bottle 10 and sealed, the upper part of the PET bottle 10 is grasped with the hand 18 shown in FIG. 2, and the PET bottle 10 is manually shaken in the direction of arrow A. FIG. 9 shows the operation of the component extraction acceleration apparatus of the present invention when the same operation is performed. Also in the case of the second embodiment, the shaft 1a and the rotating component 2 show the same movement as the first embodiment shown in FIG.

  Further, when the bottle 10 is turned sideways and manually swung in the direction of the arrow A shown in FIG. 9, rotation by the restoring force of buoyancy and gravity can be used. That is, when the bottle 10 is turned sideways in the attached state shown in FIG. 8 and the arrow A shown in FIG. 9 is rotated, the floating means 5 having buoyancy fixed to the attachment part 3b ′ on the side surface of the rotating component 2 is The rotation of the rotating component 2 transmitted to the rotation of the shaft 1a is pushed downward. Further, the metal cartridge 8 having a weight fixed to the opposite side of the tenbin with respect to the floating means 5 is pushed upward.

  The rotating component 2 rotates about the shaft 1a by the force that the floating means 5 having buoyancy and the metal cartridge 8 having weight are restored to the original state. By repeating the rotation of the bottle 10 in the vertical state and the rotation in the horizontal state, the extraction time of the components in the cartridge 8 can be shortened in the second embodiment shown in FIG.

  FIG. 10 shows an exploded view of the component extraction accelerating device of the present invention in the case where the frenzy joint 16b is used. The present invention provided with this flange joint 16b is used for the lids of various types of containers in which the PET bottle cap 11 'not provided with the inner ring projection 15 shown in FIG. Make things possible.

  In the first or second embodiment, when the shaft 1 passes through the vertical hole (a) of the rotating component 2, the rotating component 2 that is penetrated through the shaft 1 and is fixed and secured by the fixing components 4 a and 4 b is centered on the shaft 1. The embodiment of the component extraction acceleration device of the present invention in the case of rotating in the above has been described.

  In Example 3 shown in FIG. 11, the upper tip 3α of the attachment portion 3 is inserted into a hole (g) on the bottom surface of the hollow (f) provided at the end of the shaft 1 and is secured by a fixing component 4C. Thus, an embodiment in which this part becomes a rotating part and has a function of rotating around the end of the shaft 1 will be described.

  As shown in FIG. 11, in Example 3, the end of the shaft 1 is humped (seed) to provide a hollow (f), and a hole (g) is provided on the bottom surface of the hollow (f) to attach the mounting portion 3. Is inserted into the hole (ki) and fixed with the fixing component 4c. By making the diameter of the upper tip 3α smaller than the diameter of the hole (ki), it is possible to rotate around the hole (ki). A solid component extract 9 is fixed below the attachment portion 3. By this means, the solid extraction object 9 fixed to the attachment portion 3 rotates around the hole (g) on the bottom of the shaft 1 at the end of the shaft 1.

  In FIG. 11, in order to increase the inertia near the end of the shaft 1, a weight 6 penetrating through the shaft 1 is placed near the upper portion of the hump (se) provided at the end of the shaft 1. Secure with 4b. If the weight 6 is attached to the shaft 1 in this way, there is an effect of increasing the inertia of the shaft 1.

  Further, as a means for strongly receiving the rotating action by the rotating water flow D shown in the first or second embodiment, the upper end 3α of the mounting portion is placed downward from the hump-shaped bottom hole (g) at the end of the shaft 1. Attach floating means 5 with blades on all sides to the protruding part.

  In Example 3 shown in FIG. 11, when the shaft 1 is provided in the container 10, the shaft 1 is used by using a plastic bottle cap 11 a provided with a rubber tube joint joint 13 a on the bottom surface of the container lid, which will be described later in 0072. Are inserted into the joint joint 13a and joined. A swinging function is realized by this joining means. The effect of the swing function may be increased by providing a plurality of joining means provided with the joining joint 13a on the shaft 1.

  In the third embodiment shown in FIG. 11, when the upper part of the bottle 10 is swung in the direction of the arrow A shown in the first or second embodiment, the same movement as in the first or second embodiment is performed, and the joint joint 13a is moved. With the portion where the shaft 1 is joined as a fulcrum, the extract 9 fixed to the attachment portion 3 performs revolving rotation and rotation is possible, so that component extraction is accelerated. Needless to say, even when an extraction object containing a component extract is fixed in the attachment portion 3, the same movement is performed.

  In FIG. 11, the PET bottle cap 11a provided with the joint 13a of the rubber tube which can insert and fix the upper end of the shaft 1 of the component extraction acceleration apparatus of the present invention is used. By creating a container lid having a joint joint 13a that can fix the tip according to various containers, the component extraction acceleration device of the present invention can be used in various containers other than the PET bottle 10. Become.

  In the fourth embodiment, the joint joint 13 that realizes the swing function will be described.

  In other words, in order to realize the swing function defined in Section 0003, it is conceivable to create and use various joint joints 13 as shown in the fourth embodiment.

  In Example 4 below, an example in which the joint joint 13 is used in the PET bottle cap 11 will be described. However, the swing function can be realized by creating the joint joint 13 having the same specifications as the present Example 4 in various containers. Can be made.

  FIG. 12 shows the plastic bottle cap 11a having the rubber tube joint joint 13a described above in 0066. By inserting the tip of the shaft 1 into the joint joint 13a, the effect of the joint joint 13a enables the shaft 1 to have a swing function by providing flexibility at the joint portion as described above in 0018. I can do it. In this embodiment, the plastic bottle cap 11 provided with a shaft or protrusion capable of inserting the rubber pipe joint joint 13a on the bottom surface can also be joined.

  FIG. 13 shows a plastic bottle cap 11 b provided with a joint joint 13 b having protrusions 17. The tip of the shaft 1a is provided with a space (sole) provided with a tongue that can be fitted and joined to the projection 17, and the swing function can be realized by fitting.

  FIG. 14 shows the press-fit joint 12a shown in FIG. 5 provided with a rubber pipe joint joint 13a. By inserting the tip of the shaft 1 into the joint joint 13a, a swing function can be realized. In this embodiment, it is possible to join by creating a press-fit joint 12 having a shaft or a protrusion that can insert a joint 13a of a rubber tube on the bottom surface.

  FIG. 15 shows a press-fit joint 12 b provided with a joint joint 13 b having protrusions 17. The tip of the shaft 1a is provided with a space (sole) provided with a tongue that can be fitted and joined to the projection 17, and the swing function can be realized by fitting into the projection 17. .

  In FIG. 16, the upper part of the joint joint 13a of the rubber tube is inserted into the lower end of the flange joint 16b having the joint joint 13b having the protrusions 17, and the lower part of the joint joint 13a of the rubber pipe is inserted into the shaft 1. The swing function can be realized by joining. FIG. 16 shows an exploded view in this case. Of course, it goes without saying that the same effect can be obtained by the frenzy joint 16a provided with the joint 13a of the rubber tube.

  FIG. 17 shows a frenzy joint 16 b provided with a joint joint 13 b having protrusions 17. The tip of the shaft 1a is provided with a space (sole) provided with a tongue that can be fitted and joined to the protrusion 17, and the swing function can be realized by fitting.

  In the first, second, third, and fourth embodiments described above, the embodiments of the mode and operation of the present invention have been described.

  As shown in the first and second embodiments, the attachment part 3 of the rotating component 2 is formed in a tenbin shape, so that the extraction object, the floating means 5 and the weight 6 can be provided in the attachment part 3 in a tenbin shape. Become. Further, even when a plurality of extraction objects are attached, the balance can be adjusted by providing the extraction objects in the form of a tenbin, so that there is an effect of promoting the rotation of the rotating component 2. When the rotating part 2 is provided in the form of a tenbin and provided on the shaft 1, the rotating part 2 may rotate and rotate when the container is rotated even when the shaft 1 does not rotate.

  Furthermore, by providing the shaft 1, the rotating component 2, the mounting component 3, and the extraction object with the floating means 5 and the weight 6, there is an effect of increasing the rotation of the rotating component.

In other words, in order to promote the revolution and / or rotation of the object to be extracted, means for making the attachment part 3 of the rotating part 2 into a tenbin shape, means for using the floating means 5 and the weight 6 and the like. There are various forms for promoting the rotation of the extraction object attached to the attachment portion 3. These forms will be described in the following usage examples.
(Example of use)

  In FIG. 18, a screw portion is provided in a pair of attachment portions 3 b and 3 b ′ protruding in a tenbin shape on the side surface of the rotating component 2, and screw holes (A) and (A ′) that fit the screw portions are provided. In this example, tea packs 7 and 7 'are attached. The tea packs 7 and 7 'having the screw holes (A) and (A') are newly created and manufactured by the inventor and are not ready-made products. The tea packs 7 and 7 'are provided with floating means by buoyancy, and the tea packs 7 and 7' are balanced by fixing them in a pair of tenbins, The extraction of the 7 'component is accelerated.

  In the mounting example of FIG. 18, instead of the tea packs 7 and 7 ′ having the screw holes (A) and (B ′), a protrusion is provided at the tip of the mounting portions 3 b and 3 b ′. Needless to say, a method of press-fitting and fixing special tea packs 7 and 7 ′ having holes (B) and (B ′) for press-fitting may be used.

  FIG. 19 shows an example in which a cartridge 8 ′ made of a material having floating means such as blades and buoyancy is attached to the attachment portion 3 b on the side surface of the rotating component 2. The cartridge 8 'is newly created and manufactured by the inventor, and is not an off-the-shelf product, but has been devised that the mounting portion of the cartridge 8' main body has a rotation function.

  A weight 6 is attached to a tenbin-like attachment portion 3b 'opposite to the cartridge 8'. Thus, by attaching the cartridge 8 'having the floating means having buoyancy and the weight 6 in a tenbin shape, the same movement as that of the second embodiment described in the section 0053 is performed.

  The mounting portions 3b and 3b 'are used in the screw fixing method in the first or second embodiment. However, in the case of mounting these, the press-fitting and fixing are performed similarly to the means described in the paragraph 0083. It goes without saying that the method used is good.

  FIG. 20 shows an example in which the attachment portions 3a, 3b, and 3b ′ are made into three-direction tenbins, and the floating means 5, the weight 6, and the tea pack 7 of the extraction object are attached thereto. Also in this case, the floating means 5, the weight 6 and the tea pack 7 can be balanced by the effect of the tenbin, and the rotation can be performed smoothly. Therefore, the movement is the same as that of the second embodiment described in the section 0053.

  In FIG. 21, a spherical rotating part 2α with a hollow hole is created, and the shaft 1 is passed through the upper hole (A) of the vertical hole and the lower hole (A ') of the vertical hole, and a pair of fixing parts 4a and 4b are used. Secure the stopper. As in the first or second embodiment, the vertical holes (A) and (A ′) have a diameter larger than the diameter of the shaft 1, so that the rotating component 2α can rotate around the shaft.

  A pair of symmetrical holes are formed on the side surface of the rotating part 2α, and the end of the attachment portion 3b to which the helical thread weight 6 is fixed is inserted and fixed in the right hole. Secure with parts 4e. In this example, the attachment portion 3b ′ at the end where the attachment portion 3a is attached to the tip of the impeller-like floating means 5 is inserted into the left hole (co), and is fixed with the fixing component 4f.

  FIG. 21 operates in the same manner as the second embodiment described in the section 0053. In addition, since the spiral thread spindle 6 and the impeller-like floating substance 5 themselves rotate around the rotating component 2α, the rotation due to the influence of the rotating water flow D increases.

  FIG. 22 is an example in which the balance can be adjusted by adjusting the buoyancy of the floating means 5 by fixing both the floating means 5 and the weight 6 to the same side by the attachment portion 3b. In addition, the attachment part 3a is provided in the reverse side of the tenbin shape, and the same movement as the said Example 1 or 2 is shown.

  FIG. 23 shows an example in which the shaft portion 3α at the base of the attachment portion 3a on the opposite side of the floating means 5 is lengthened, and a plate weight 6 is provided on the shaft portion 3α at the base. Indicates. The plate lead 6 can move on the base shaft portion 3α, and the balance can be adjusted by this movement.

  FIG. 24 is an example in which a weighted metal cartridge 8 is provided in the attachment portion 3b of the tenbin opposite to the floating means 5 having four blades, and the attachment portion 3a is provided in the cartridge 8. The movement of Example 2 is shown. This structure can be balanced by what is attached to the attachment portion 3a. Further, since the method of attaching the shaft 1 and the attachment portions 3b and 3b 'to the rotating component 2α is the same as that shown in Fig. 21 described in the paragraph 0088, the attaching portions 3b and 3b' can rotate around the rotating component 2α. .

  FIG. 25 shows an example in which the floating means 5 and 5 ′ having four blades in a water wheel shape are attached to the rotating component 2α as a pair, and the same movement as in the first embodiment is performed. At the tips of the floating means 5 and 5 ', there are provided attachment parts 3a and 3a' that can fix the extraction object. Since the mounting method of the base mounting portions 3b and 3b 'of the floating means 5 and 5' is the same as that shown in Fig. 21 described in the paragraph 0088, 3a and 3a 'can rotate around the rotating component 2α. This rotation accelerates the component extraction of what is fixed to it.

  FIG. 26 shows an example in which two rotating parts 2 and 2 ′ are attached to the shaft 1, and the movement shown in the first embodiment is performed. A total of four tea packs 7a, 7b, 7c, 7d are fixed to the attachment portions 3a, 3b, 3c, 3d fixed to the rotating parts 2, 2 ′. When the weight 6a is attached to the end of the shaft 1, the rotating parts 2 and 2 'can be rotated by inertia, but when the plurality of rotating parts 2 and 2' are provided on the shaft, the upper rotating part 2 ' When the weights 6b and 6b 'are also attached to the nearby shaft 1, the effect of the flexible shaft joint 13 may be enhanced to amplify the revolution operation of the shaft 1. In FIG. 26, the weights 6b and 6b 'are detachable thread weights.

  FIG. 27 shows an example in which the rotating component 2 is provided with the blade-like floating means 5 and performs the same movement as in the first or second embodiment. The shaft 1 is passed through the vertical hole (a) of the rotating component 2, and the upper and lower portions are fixed by the fixing components 4a and 4b. The rotating component 2 includes a single blade-like floating means 5 and an attachment portion 3a. Even if the rotating component 2 is not provided with the blade-like floating means 5, a certain degree of rotation can be expected. However, the rotation component 2 includes one or more blade-like floating means 5, so that rotation due to the influence of the rotating water flow can be achieved. Promoted.

  27, the base of the end of the attachment portion 3a shown in FIG. 27 is a screw portion, and the rotary component 2 is provided with a hole (A) that fits the screw portion, so that the tip shown in FIG. 27 has a hook-like attachment portion 3a. Can be replaced with the mounting portion 3b having a screw-like tip as described in the first or second embodiment, and can correspond to the shape of the extraction object.

  The use example in the case where the rotating part 2 rotates around the shaft 1 through the shaft 1 through the vertical hole (a) of the rotating part 2 shown in the first or second embodiment has been described above.

  In the third embodiment, the embodiment has the function of rotating by inserting the tip 3α of the attachment portion 3 into the hole (g) on the bottom surface of the shaft 1 at the end of the shaft 1. The simplest shape of the rotation function of the attachment portion 3 in this case is shown in FIG.

  In FIG. 28, a cavity (k ′) provided with a hole (key ′) is provided at the end of the shaft 1, and the tip 3α of the mounting portion 3 is pushed into the hole (key ′) to enter the inside of the cavity (key ′) It is fitted. The tip 3α of the mounting portion 3 is spherical and can be rotated about the shaft 1 when fitted inside the cavity. This shows the same movement as in the third embodiment.

  In the following, a usage example of a mode in which a rotating part 2α ′ having a function of rotating about the shaft 1 is provided with a mounting part 3a or 3b having a function of rotating about the rotating part 2α ′, and A usage example of a form having a rotation function will be described.

  In FIG. 29, a spherical rotating part 2α ′ having a hollow (ku) is created, and the end of the shaft 1 is inserted into the upper hole (a) of the rotating part 2α ′, and fixed with a fixing part 4d. Indicates. Since the diameter of the hole (a) is larger than the diameter of the shaft 1, the rotating component 2α ′ has a function of rotating around the shaft 1.

  Further, by inserting the tip of the attachment portion 3a into the lower hole (a ') of the rotating component 2α' and fixing it with the fixing component 4c, the attaching portion 3a has a function of rotating around the rotating component 2α '. Therefore, the rotation part 2α ′ rotating around the axis 1 and the attachment part 3a rotating around the rotation part 2α ′ can be rotated. Compared with the third embodiment, the rotation part 2α ′ is the axis. In addition to rotating around 1, the mounting portion 3 a itself also rotates, so that the rotation effect may be enhanced by two rotations.

  FIG. 30 shows the shaft 1 and the attaching portion 3b attached to the rotating portion 2α ′ by the same means as FIG. 29 shown in the item 0102. A cartridge 8 'having a floating means is fixed to the end of the attachment portion 3b. This cartridge 8 'has the same function as the cartridge 8' described in FIG. Further, the bottom of the weight 6 penetrated by the shaft 1 is in contact with the upper part of the rotating part 2α ′, and the upper part of the weight 6 is fixed and secured by a fixing part 4g. The weight 6 increases the inertia in the vicinity of the end of the shaft 1. This form operates in the same manner as the item 0102 shown in FIG.

  In FIG. 31, the shaft 1 and the mounting portion 3b are fixed to the rotating portion 2α ″ by the fixing parts 4c and 4d using the same means as in FIGS. 29 and 30 shown in the items 0102 and 0104. In addition, symmetrical holes are formed on the side surface of the rotating part 2α ″, and the base end of the mounting portion 3a is inserted into the right hole, and the fixing part 4e is pulled out. The extraction target tea pack 7 is fixed to the attachment portion 3a, and the base end of the attachment portion 3b 'is inserted into the left hole (co) and fixed with the fixing component 4f. In this example, the floating means 5 is fixed to the attachment portion 3b ′.

  In FIG. 31, the same movement as in the first embodiment is performed, but in addition to the rotation component 2α ″ rotating around the shaft 1 passed through the vertical hole (a), the rotation component 2α ″ is attached to the rotation component 2α ″. By rotating the attachment part 3b to which the weight 6 is fixed, the attachment part 3a to which the tea pack 7 is fixed, and the attachment part 3b ′ to which the floating means 5 is fixed, the generation of the rotating water flow D shown in the first embodiment is promoted. Moreover, the tea pack 7 as the extraction object rotates by this rotating water flow, so that the extraction of the component extract contained in the tea pack 7 is accelerated.

  FIG. 32 is a usage example in which the shaft 1 has a rotation function. In this usage example, the shaft 1 has a function of rotating by the joint joints 13α and 13α ′ having a rotation function. As in the third embodiment, the end of the shaft 1 ″ shown in this figure is provided with a hollow (cell) in the shape of a hump (cell). The tip of the attachment part 3b to which the weight 6 is fixed is inserted into the hole (g) at the bottom of the hollow (f), and is fixed with the fixing part 4c. In addition, symmetrical holes are formed on the left and right sides of the hollow (f), and the base end of the mounting portion 3a is inserted into the right hole (fixed) and fixed with a fixing part 4e. Then, the tea pack 7 of the extraction object is fixed to the attachment portion 3a. This is an example in which the base end of the attachment portion 3a ′ is inserted into the left hole (co) and secured with the fixing component 4f, and the tea pack 7 ′ as an extraction object is fixed to the attachment portion 3a ′. . The tip of the shaft 1 ″ is inserted into a hole (sa) on the bottom surface of a joint joint 13α having a rotation function described later, and is fixed with a fixing component 4h.

  The joint joints 13α and 13α ′ having a rotation function shown in FIG. 32 are provided by providing a hollow (su) and (su ′) in a cylinder, and a hole (sa) and (sa ′) at the bottom. ), (Sh ′). The diameters of these holes (sa), (sa ′), (si), (si ′) are made larger than the diameters of the shafts 1, 1 ′, 1 ″.

  The shaft 1 'has a function of rotating around the joint joint 13α by passing through the upper hole of the joint joint 13α having a rotation function and fixing it with a fixing component 4i. Further, the tip of the shaft 1 ′ is inserted into a hole (s ′) on the bottom surface of the joint joint 13α ′ having a rotation function, and is fixed with a fixing component 4h ′ so that the shaft 1 ′ has a rotation function. It can rotate around '.

  The shaft 1 is inserted into the upper hole (sh ′) of the joint joint 13α ′ having a rotation function, and the fixing joint 4i ′ is fixed to prevent the joint joint 13α ′ having the rotation function from being centered on the shaft 1. Has the ability to rotate.

  In this way, the shafts 1, 1 ′, 1 ″ themselves have a function of rotating by the rotating joint joints 13α, 13α ′.

  In FIG. 32, by providing the three-blade floating means 5 on the shaft 1 ″, the influence of the rotating water flow D shown in the first or second embodiment can be increased. As a result, the tea packs 7 and 7 ′ fixed to the attachment portions 3 a and 3 a ′ rotate in a revolving manner while rotating in the same manner as in the embodiment, so that the extraction of the components is accelerated.

  Depending on the object to be extracted, the joint joint 13b having the rubber tube and the joint joint 13b having the projections 17 and the rotating joint joint 13α may be used in combination, and either of them is used for a plurality of joint portions of the shaft 1. In some cases, the rotation of the shaft 1 and the rotating component 2 may increase.

  In the said Example 1, 2, 3, 4, although the case where the component extraction acceleration apparatus of this invention was used with the plastic bottle 10 was demonstrated, the component extraction acceleration apparatus of this invention is not only a PET bottle 10 but a water bottle. It can be used for various containers such as wide containers.

  Examples of the method of fixing the tip of the shaft 1 of the component extraction acceleration device of the present invention to the container lids of various containers including the PET bottle 10 include the press-fitting means of the first embodiment, the frenzy means of the second embodiment, In addition to the dedicated cap means of the third and fourth embodiments, an adsorbing means for fixing to a container with a suction cup or the like, an adhering means for adhering and fixing to the container, and the like can be considered.

  In addition, as long as the function described in the component extraction acceleration device of the present invention is fulfilled, the entire inside of the container is an attachment target of the shaft 1. In addition, the shaft 1 may be fixed not only to the container but also detachable to the container itself.

1 axis
2 Rotating part 3 Mounting part 4 Fixed part 5 Floating means 6 Weight 7 Tea pack 8 Cartridge 9 Solid component extract 10 PET bottle 11 PET bottle cap 12 Press-fit joint 13 Joint joint 14 Wire spring 15 Inner ring projection 16 Frenzy joint 17 Projection Object 18 Hand A Vertical hole of the rotating part 2 Screw hole that fits the screw part C Spiral groove on the surface of the weight D Space in the center of the press-fit joint 12 C Open space center of the outer surface of the press-fit joint 12 End of the shaft 1 The hollow key of the hump-like lump The hole at the bottom of the hollow hump of the hump-like lump The hollow hole of the rotating part 2α The right-side hole of the hollow side of the rotating part 2α The left side of the hollow side of the rotating part 2α Hole hole Hole on the bottom surface of the shaft joint joint 13α Hole hole on the top surface of the shaft joint joint 13α Hollow center of the shaft joint joint 13α Hump on the end of the shaft 1 ″ Cavity A with a lump of solid arrow A showing the direction of rocking the PET bottle 10 Arrow B showing the revolving rotation due to the swing motion of the shaft 1 Arrow D showing the rotation due to inertia near the end of the shaft 1 Arrow showing the rotating water flow E Arrow indicating rotation of rotating part 2

Claims (4)

A rotating part that rotates about an axis is provided on the axis, and an attaching part that can attach an extraction object to the rotating part is provided. The extraction object is attached to the attaching part, and the axis is placed in a container. The rotating object is rotated and revolved by allowing the rotating part to revolve and rotate, and the extraction object attached to the revolving part is revolved and rotated. A component extraction accelerating device that accelerates component extraction by enabling rotation. The component extraction acceleration device according to claim 1, wherein the shaft has flexibility. 3. The component extraction acceleration device according to claim 1, wherein the rotating component is provided near the end of the shaft. 4. The component extraction accelerating device according to claim 1, wherein the attachment portion of the rotating portion is formed into a tenbin shape.

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