JP2011098745A - Storing container with collecting mechanism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable collection of polyhedrons, columnar bodies, and irregular three-dimensional objects which can not be collected smoothly by using a rubber, and to facilitate to clear away such hardly collectable bodies as scattered spherical bullets of playing guns and beads. <P>SOLUTION: In a container 15 equipped with a collecting mechanism for collecting three-dimensional objects, the storing container 15 with the collecting mechanism is characterized in that the bottom face opening part of the container is stretched and passed by a plurality of linear bodies 3, and the bottom face opening part is a collecting face where the linear bodies 3 are arranged in parallel by narrower intervals than the minimum diameter of the objects to be collected to form gaps, and the linear bodies 3 forming the collecting face are bent along the object faces to spread out the gaps and when the object enters into the container 15, the linear bodies 3 are bent back to return the gap to smaller than the minimum diameter of the object, to hold the object in the container 15. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a container having a mechanism for collecting three-dimensional objects.

The three-dimensional object refers to a sphere, a pillar, and a polyhedron, for example, a bullet used for a playgun or a bead used for handicrafts.

The bullets of game guns are generally spherical bullets called “BB bullets” made of synthetic resin material, and they are produced in diameters of 6 mm and 8 mm, and weigh 0.1 to 0.3. It is about gram.

“BB bullets”, which are bullets, may spill on the floor, etc., when they are packed in a grenade device of a playgun or fired from a gun. BB bullets made of plastic material jump well when dropped, and roll and scatter well because they are spherical. These scattered BB bullets with a size of about 6 mm are time consuming to collect.

Beads used in handicrafts are made from natural materials such as metal and stone, or synthetic resin materials such as glass and plastic, and are less than 1 mm in size, and are three-dimensional such as spheres, columns, and polyhedrons of several millimeters. It is an object. In particular, small beads of less than 1 mm are spilled on the table or floor, especially carpets and buried in the eyes of carpets, so it is very troublesome to pick them up with fingers and store them in containers. A laborious work is required.

If it is difficult to pick up and collect small beads of less than 1 mm with your fingers, you can collect them by sticking them with adhesive tape or by passing a wire or needle tip through the hole in the beads. The method of transferring this to a container is used.

  The container is generally a bottle or a wide-mouth bottle made of synthetic resin or glass. Beads and BB bullets are stored into the container from the opening above the container, and then the opening is covered so that it does not spill outside.

  In the present invention, a BB bullet or bead is not inserted from the opening above the container, but a pickup mechanism is provided below the container to collect and store the container from the bottom of the container into the container.

  Those similar to the present invention include ping-pong balls and golf balls such as Japanese Utility Model Publication No. 51-53961 of Patent Document 1, Japanese Utility Model Registration No. 3001277 of Patent Document 2, and Japanese Patent Application Laid-Open No. 2005-152568 of Patent Document 3. A ball that is a ball for ball games such as a ball has been proposed.

   Japanese Patent Application Laid-Open No. 51-53961 discloses a ping-pong ball collecting tool, Japanese Patent Application Laid-Open No. 3001277 discloses a ping-pong ball collecting device, and Japanese Patent Application Laid-Open No. 2005-152568 discloses a spherical object. In all devices, for example, the elastic material is made of elastic rubber and is arranged in the opening on the bottom of the container at an interval narrower than the diameter of a sphere such as a ping-pong ball or golf ball. It has been devised to take in the sphere into the container by utilizing the property that the rubber extends along the surface of the sphere by pressing. Hereinafter, in this specification, an operation in which a linear object expands and contracts is referred to as elastic deformation.

  Since all of the devices disclosed in Patent Documents 1 to 3 are intended for only a sphere, the rubber can be picked up by elastic deformation and elongation. However, when a cubic object other than a sphere or an object having fine irregularities on the surface is used, the method of passing through the array of linear rubbers causes rubber deformation on the object surface due to deformation, elasticity, and friction of the rubber. When an object is caught and pressed, or the rubber shrinks, the object is caught and difficult to pass.

In addition, rubber has characteristics of “deforms when force is applied” and “extends well under the same load” compared to other substances. If it is installed on the assumption that the linear rubber is elastically deformed along the sphere surface of the collected object, the sphere easily stretches and passes through the rubber, but the sphere that passes through and enters the container passes through. Since it is supported by the power of the rubber and is left in the container, the number of spheres in the container increases, so the weight of the spheres and the force of collecting them are repeated, and the linear rubber stretches. It is conceivable that deformation occurs and the collected object spills out of the container from the collecting part on the bottom surface of the container.

From the above, since picking up a golf ball in the spherical object picking tool disclosed in Japanese Patent Application Laid-Open No. 2005-152568 of Patent Document 3 has a large mass of a sphere, it is difficult to place many in a container. Even in the ping-pong ball picking tool disclosed in Japanese Utility Model Publication No. 51-53961 of Patent Literature 1 and the device for collecting the ping-pong ball of Patent Utility No. 3001277 registered in Patent Literature 2, many ping-pong balls are stable in the container. It is difficult to keep it. If a plurality of linear rubbers are arranged and stretched strongly, the force applied to the installation site is increased due to the shrinking force of the rubber, making it difficult to simplify the container.

In addition, when picking up beads with a size of about 1 mm, which is one of the purposes of the present invention, it is troublesome to pick up with fingers, because there are many three-dimensional shapes other than spherical shapes in the shape of the beads, Rubber is caught on the surface of the beads, and beads with a size of about 1 mm are pressed and difficult to pass. Also, when beads enter the eyes of the carpet, in order to collect the beads in such a state, it is necessary to scrape the carpet at the pickup site on the bottom of the container and scrape the beads from the carpet eyes. By rubbing the carpet, the rubber is caught in the irregularities of the carpet's eyes and deformed, and the collected beads may pass through and flow out of the container.

On the other hand, when the object is about 1 mm like a bead, it is necessary to stretch a linear rubber very finely. In order to stretch the rubber as thin as possible, if it is installed in the collecting container in a state of being pulled strongly, the strong tension will be sustained, so if the rubber is left in this state for a long time, it will easily deteriorate and the container will not lose the tension. It is difficult to simplify the container.

In view of the above, in the present invention, yarns and twisted yarns that are distinguished from rubber in the field of materials, and materials that are less elastically deformed such as piano wires and bamboo baskets are made into yarns, strings, rods, and these are linear bodies. Thus, this linear body is arranged in parallel with the bottom surface of a container for storing a conventional BB bullet, bead, or the like to constitute a pick-up surface, thereby forming a pick-up surface.

Japanese Utility Model Publication No. 51-53961 Registered Utility Model No. 3001277 JP 2005-152568 A

In the idea of passing and collecting spheres by elastic deformation of the rubber by stretching the rubber common to the above prior art documents to the bottom of the container and pressing this part, a three-dimensional object such as a polyhedron or a column If the object is to be picked up, it cannot be picked up smoothly due to deformation or friction of the rubber. In addition, since the collected objects are supported by the bottom surface of the container over which the passed rubber is stretched, it is difficult to stably place many objects in the container. In addition, there is a problem that it takes a lot of time and effort to collect and store in a container what is scattered by small objects such as BB bullets and beads.

Specifically, in order to solve the above-described problems, the following means are used.

(1) In a container equipped with a pick-up mechanism for picking up a three-dimensional object, the bottom opening of the container is stretched with a plurality of linear bodies, and the bottom opening is the top of the object picked up by the linear body. A pick-up surface in which gaps are formed in parallel with an interval smaller than a small diameter, the linear body forming the pick-up surface is bent along the object plane, and the gap is pushed and the object is The problem is solved by a storage container with a pick-up mechanism characterized in that when the wire enters the container, the linear body is bent back so that the gap returns to less than the minimum diameter of the object and the object is retained in the container. is there.

(2) The storage container with the pick-up mechanism is divided into a pick-up room for temporarily storing the object collected inside the two rooms and a storage room for stably storing the object, and the boundary between the two rooms is picked up. The object is moved from the room to the storage room, but the object is not moved from the storage room to the pickup room. The storage container with the pickup mechanism according to (1) is provided. To do.

(3) The return blocking means is a passage having a configuration in which a partition wall that forms a boundary between the pickup chamber and the storage chamber narrows from the pickup chamber toward the storage chamber, and the passage extends from the pickup chamber. With a pickup mechanism according to (1) or (2), wherein the object is allowed to move to the storage room, and the object in the storage room is prevented from moving to the pickup room. This is solved by the storage container.

(4) The storage container with a pickup mechanism has a trap structure in which the surface on the pickup chamber side excluding the opening of the passage exit as viewed from the storage chamber side takes a return form, and once enters the storage chamber. The object is solved by the storage container with a pickup mechanism according to (1) to (3), wherein the object is prevented from returning to the pickup room.

(5) The storage container with a pickup mechanism is made of a material having a Young's modulus of the linear body constituting the pickup surface greater than 0.1 (GPa). A storage container with a pickup mechanism according to (3).

(6) In the storage container with a pick-up mechanism, the linear body forming the pick-up surface is made of metal, a synthetic resin, or a rod-shaped member made of wood containing bamboo, natural fiber, or chemical fiber. The problem is solved by the storage container with a pickup mechanism according to any one of (1) to (5), which is configured in the form of a thread or string.

(7) The storage container with a pickup mechanism has a pickup mechanism by a bamboo craft characterized in that the linear body and the storage container are made of bamboo, and the collected sphere hits the container and makes a sound. This is solved by the storage container with a pickup mechanism described in (1) to (5).

(8) The storage container with a pickup mechanism is solved by the storage container with a pickup mechanism according to any one of (1) to (6), wherein the object to be picked up is a bead or a bullet of a playgun. Is.

The present invention is not intended to pick up only the spheres by utilizing the elastic deformation of the linear rubber, but is a thread, string, rod or the like made of a material that does not expand and contract like rubber. By arranging wire, twisted yarn, piano wire, bamboo basket, etc. in a linear body, they are arranged in parallel on the bottom of the container, and by using the flexibility of the linear body and the elasticity of the container, rubber can be collected smoothly. By collecting polyhedrons, pillars, and uneven three-dimensional objects, the interior of the container is divided into two chambers, and a trap structure is provided as a return prevention means between the two chambers. Collect and store objects quickly and easily. This makes it easy to clean up objects that are difficult to pick up, such as spherical bullets and beads of scattered game guns.

Figure of conventional container Illustration of container 11 of the present invention Cross section of container 11 Sectional view of container 12 of the present invention Cross section of container 13 Illustration of collecting and storing BB bullet 1A The figure which showed the pick-up surface 4 passage process of BB bullet 1A Diagram of relationship between BB bullet 1A and linear body 3 Diagram of linear body 3 installation Bamboo pick-up container 14 Diagram showing the diameter of object 1 The figure showing the container 15 of the present invention The figure which showed the pick-up surface 4 passage process of the bead 1B Figure showing collection of beads 1B on the carpet Diagram showing storage process from collecting beads 1B Illustration of object 1C and container Game commentary illustration

An object to be picked up in the present invention is an object 1. The object 1 includes spheres, pillars, and polyhedrons such as a BB bullet 1A, which is a spherical bullet of a playgun, beads 1B used for handicrafts, and other objects 1C. A container considered to be the best for each object 1 can be considered. Hereinafter, the collection and storage of the object 1 will be described with reference to examples.

The object 1 picked up in the first embodiment is a BB bullet 1A. The BB bullets 1A are spherical bullets used for game guns, and those with a diameter of 6 mm and 8 mm mainly made of synthetic resin are in circulation. There are various weights such as 0.12 g, 0.20 g, 0.25 g, and 0.30 g.

The container for storing the BB bullet 1A is generally a cylindrical bottle-shaped container as shown in FIG. This container is open at the top and includes a lid 20 that closes the top opening J. The lid 20 has a protruding outlet 21 through which the BB bullet 1A can be taken out little by little. In order to clear the scattered BB bullet 1A, the BB bullet 1A is picked into the container from the upper opening J of the container with a finger, and then the lid 20 is put on the upper opening J to be stored. It is. Although there are differences in the shape and size of the containers for storing the BB bullet 1A, those of the above-mentioned type are distributed as dedicated containers.

A storage container provided with a pick-up mechanism in the present invention will be described below (FIG. 2).

What is shown in FIG. 2 is a cylindrical bottle-shaped container 11 having a diameter of about 6 cm and a height of about 10 cm. A storage container 11 having a pickup mechanism is formed by processing the bottom surface and the inside of the conventional container shown in FIG. 1.

What is shown in FIG. 2A is a bottom opening K formed by opening the bottom surface, which is the lower part of the conventional container shown in FIG. As shown in FIG. 2B, the peripheral edge of the bottom opening K is defined as the bottom opening frame 2, and as shown in FIG. 2B, linear bodies 3 are arranged in parallel on the bottom opening frame 2 and stretched to block the bottom opening K. The surface is a pickup surface 4 shown in FIG. 2C.

As shown in FIG. 2C, the pickup surface 4 has a configuration in which the linear bodies 3 are arranged in parallel at intervals smaller than the diameter of 6 mm of the BB bullet 1A and have a gap H. The gap H formed by the outer edge and the outermost linear body 3 is also arranged at a distance narrower than the diameter of 6 mm of the BB bullet 1A.

It is preferable that the pick-up surface 4 has a flat shape with no space between the floor surface and the surface of the carpet by picking up the BB bullet 1A. With this configuration, BB bullets with a diameter of 8 mm can also be collected.

The internal structure of the container 11 will be described with reference to FIG.
What is shown in FIG. 3A is a cross-sectional view of the container 11 as viewed from the side. Below the container 11 is the pickup surface 4 described in FIG. 2B. A pickup room 6 for temporarily detaining the BB bullet 1A that has passed through the pickup surface 4 and a storage room 7 for transferring and stably storing the BB bullet 1A are provided. The boundary between the pickup room 6 and the storage room 7 Is partitioned by a funnel-shaped partition wall 9 to divide both chambers.

As shown in FIG. 3B, the funnel-shaped partition wall 9 is composed of a conical portion P and a straw-shaped portion Q, and the tip portion 16 of the conical portion P has a hole that is wide enough to allow passage of a BB bullet. The passage opening 17 on the pickup chamber 6 side is widened to facilitate the movement of the BB bullet 1A to the storage chamber 7, and the passage outlet 18 on the storage chamber 7 side is narrowed to move to the storage chamber 7. The passage 8 has a shape protruding toward the upper portion of the container so that the passage of the BB bullet 1A from the passage outlet 18 to the collecting chamber 6 is difficult.

As shown in FIG. 3C, by tilting the container 11, the BB bullet 1A temporarily placed in the pickup chamber enters from the passage opening 17 and moves from the passage exit 18 to the storage chamber 7 through the passage 8. It is. The BB bullet 1A moved into the storage chamber 7 is a concave space (valley) formed by a partition wall 9 and a container wall 5 formed in a funnel shape in the storage chamber 7 when the container 2 is stood up as shown in FIG. 3D. It moves to Y and accumulates below the storage chamber 7. The passage outlet 18 is located in the upper part of the storage chamber 7 and the opening of the passage outlet 18 is made narrow so that a trap structure in which the BB bullet 1A cannot easily come out from the storage chamber 7 is obtained. It is a prevention means.

Since there is a shape that seems to be the best in addition to the above-described conventional container processed in the form of the storage container that collects the BB bullet 1A, Examples 2, 3, and 4 will be described below.

The container 12 shown in FIG. 4 is a rectangular parallelepiped having a length of 12 cm, a width of 6 cm, and a height of 6 cm and having a size that can be grasped with one hand.

4A is a cross-sectional view of the rectangular parallelepiped container 12 as viewed from above, FIG. 4B is a cross-sectional view of the container 12 as viewed from the side, and FIGS. 4C and 4D are views from below.

As shown in FIG. 4D, the bottom surface of the container 12 has a bottom surface opening K, and the periphery of the bottom surface opening K is defined as the bottom surface opening frame 2, and the bottom surface opening is formed as shown in FIG. 1C. A surface in which the linear bodies 3 are arranged in parallel on the frame 2 and stretched to close the bottom opening K is referred to as a collecting surface 4.

The pickup surface 4 is formed by arranging linear bodies 3 in parallel at intervals smaller than the diameter of 6 mm of the BB bullet 1A, and of course, is formed by the bottom opening frame 2 and the outermost linear body 3. The gap H is also arranged at a distance narrower than the diameter 6 mm of the BB bullet 1A.

As shown in FIG. 4B, the container 12 includes a pickup chamber 6 in which the BB bullet 1A that has passed through the pickup surface 4 and entered the container 12 by the pickup work is temporarily placed, and the BB bullet 1A. A storage room 7 is provided for transferring and storing, and a boundary between the pickup room 6 and the storage room 7 is a passage 8. This passage 8 serves as a return blocking means configured so that the BB bullet 8A moved into the pickup chamber 7 does not return to the pickup chamber 6.

As shown in FIG. 4A, the return blocking means is configured such that the boundary between the pickup chamber 6 and the storage chamber 7 is partitioned by a partition wall 9, and this partitioned space is moved from the pickup chamber 6 toward the storage chamber 7 in the BB bullet 1A. Is a path 8 that moves. The passage 8 faces the upper part of the container in the collection chamber 6. In the upper part of the container, the direction of the passage opening 17 in which the opening on the side of the collecting chamber 6 is widened and the direction of the passage outlet 18 on the side of the storage chamber 7 is narrowed to form an eight-letter shape.

Since the BB bullet 1A passes through the passage 8, the space is opened larger than the diameter of the BB bullet, and the passage outlet 18 is wide enough to allow the BB bullet to pass through.

As shown in (FIG. 4A), as shown in FIG. 4A, the BB bullet 1A moves from a wide-open passage opening 17 through a passage 8 configured in an eight shape and passes through a narrow passage outlet 18. It falls to the lower part of the storage chamber 7 and accumulates in the lower part of the storage chamber 7. The passage outlet 18 has a narrow opening and is positioned above the storage chamber 7, so that even if the container is tilted, the BB bullet 1 </ b> A in the storage chamber 7 does not return to the pick-up chamber 6, thereby forming a trap structure. It is.

Further, the return preventing means has a configuration in which a valve 10 is installed at the boundary between the pickup chamber 6 and the storage chamber 7, and an example of the specification will be described as a container 13 (FIG. 5). What is shown in FIG. 5 is a cross-sectional view of the container 13 having the valve 10 divided into the pickup chamber 6 and the storage chamber 7 as viewed from the side.

As shown in FIG. 5A, the partition wall 9 that partitions the pickup chamber 6 and the storage chamber 7 configures the passage 8 so as to be located from the pickup chamber 6 to the storage chamber 7 and in the upper part of the container. By installing a movable valve 10 that opens only in the direction of the storage chamber 7 at the passage outlet 18, as shown in FIG. 5B, when the BB bullet 1A moves from the pickup chamber 6 to the storage chamber 7, it is stored. Although the valve 10 opens in the direction of the chamber 7 and the BB bullet 1A passes through, the inclination of the container is such that the BB bullet 1A moved to the storage chamber 7 moves in the direction of the pickup chamber 6 as shown in FIG. 5C. Even if it happens, the valve 10 serves as a return prevention means by adopting a trap structure that does not open toward the collection chamber 6.

As shown in FIG. 5C, the sweeping portion 19 made of rubber or hairy soft material is installed on the outer side of the bottom opening frame 2 so as to be scattered in the corners of the room or the depressions of the sofa. It is convenient that the BB bullet 1A can be swept out to a place where it can be easily picked up. The wall 5 of the storage chamber 7 is provided with an outlet 21 for the BB bullet 1A.

 The containers 11 to 13 are surrounded by a wall 5 from which the BB bullet 1A does not spill outside, and the material is a groove U or hole V for installing the linear body 3 on the bottom opening frame 2 in order to form the collecting surface 4. Various materials such as steel, aluminum, ceramics, plastics, and wooden frames can be used as long as they can be processed such as opening and the strength to prevent extreme deformation and breakage by repeatedly collecting the BB bullet 1A. .

With the configuration of the containers 11 to 13, 500 to about 1000 BB bullets 1A can be collected and stably stored, and can be easily carried and stored.

What is shown in FIG. 6 shows a series of work processes from the collection to the storage of the BB bullet 1A. When the pickup surface 4 is pressed against the BB bullet 1A as shown in FIG. 6A, the BB bullet 1A spreads the linear body 3 and enters the pickup chamber 6 as shown in FIG. 6B. Will be detained. As shown in (FIG. 6C), as shown in (FIG. 6D) from the state in which the container is tilted, the BB bullet 1A in the pickup chamber 6 is returned to the passage 8 by the action of returning the wrist as shown in D1 to D2. Is moved to the storage chamber 7 and stored. At this time, since the boundary between the pickup chamber 6 and the storage chamber 7 is the trap structure shown in FIGS. 4 and 5, pickup and storage can be facilitated.

What is shown in FIG. 7 shows a process in which the BB bullet 1A, which is a sphere, passes through the pickup surface 4 and enters the containers 11 to 13. When the pickup surface 4 is pressed against the BB bullet 1A as shown in (FIG. 7A), the BB bullet 1A below the linear body 3 turns the linear body 3 into a spherical surface as shown in (FIG. 7B). The linear body 3 opened from the place beyond the radius is bent back, and the gap H is changed to the BB bullet as shown in FIG. 7C. BB bullet 1A approach path is blocked by recovering its original shape to less than 1A diameter. As a result, the BB bullet 1A moves into the containers 11 to 13 and is collected.

What is shown in FIG. 8 is the relationship between the BB bullet 1 </ b> A and the linear body 3. A cross section is shown when the pick-up surface 4 is in contact with the floor surface when the pick-up surface 4 is pressed against the BB bullet 1A and the BB bullet 1A and the linear body 3 are aligned. When the linear body 3 is thicker than the diameter of the BB bullet 1A when the BB bullet 1A and the linear body 3 are aligned as shown in FIG. 8A, the curved surface of the linear body with the spherical surface facing upward facing downward It is pushed by and cannot move above the linear body 3. As shown in FIG. 8B, even if the diameters of the BB bullet 1A and the linear body 3 are the same, passage is difficult.

As shown in FIG. 8C, when the BB bullet 1A and the linear body 3 are aligned, if the radius of the linear body 3 exceeds the radius of the BB bullet 1A, the BB bullet 1A moves upward from below the linear body 3. To do. Therefore, it is preferable to use the linear body 3 having a diameter smaller than that of the BB bullet 1A. Further, the position of the linear body 3 installed in the bottom opening frame 2 is set so that the radius of the linear body exceeds the radius of the BB bullet 1A when the pickup surface 4 is pressed against the BB bullet 1A. Is preferred.

Based on the above, the linear body 3 used in Examples 1 to 3 uses, for example, Tegs which are fishing lines. Tegs are yarns made of chemical fibers such as nylon, polyethylene, and fluorocarbon. In Japan, the thickness is indicated by a number, and the larger the number, the thicker the number. According to the standard of the Japan Fishing Goods Manufacturers Association, No. 0.1 has a standard diameter of 0.053 mm, and even No. 100 has a standard diameter of about 1.660 mm. A considerable range of numbers is available. In selecting the thickness of the linear body 3, it is preferable to select in consideration of strength, durability, and the like. For picking up the BB bullet 1A, Tegs of No. 1 (standard diameter 0.165 mm) to No. 3 (standard diameter 0.285 mm) are sufficient.

The material of the linear body 3 is selected in consideration of the friction caused by the picking work depending on the type of the object 1 to be picked up. Depending on the type of thread, string or other object to be picked up, such as thread or string made of a chemical fiber material such as nylon, polyethylene, or fluorocarbon with excellent durability, Thus, a rod-shaped object can be used, and a synthetic resin material can be used in a rod shape.

Therefore, the linear body 3 used in the present invention is not a material that is elastically deformed and stretched by an external force, such as “rubber as an elastic body” expressed in all of the above-mentioned prior art documents, but a material close to a rigid body. By using the linear body 3 made from the above, a material that is bent by an external force and quickly returns to the current state is used.

The elongation deformation is considered to be the elongation rate due to elastic deformation, and this is expressed in terms of Young's modulus. The Young's modulus of rubber is 0.0015 to 0.1 (GPa), whereas low density polyethylene is 0.2 (Gpa). ), Steel is 201-216 (Gpa). (Source: Wikipedia ( <http://www.wiki.com> ))
As described above, the Young's modulus of rubber is about half that of the low-density polyethylene having the smallest Young's modulus among the materials used in the present invention, and it can be seen that the material is particularly susceptible to elastic deformation.

The linear body 3 constituting the pick-up surface 4 is sandwiched between a falling surface such as a floor and the bottom opening frame 2 by repeated pick-up work, and is rubbed and worn out or displaced by pick-up work to create a gap H It is conceivable that the interval of is changed. Therefore, as shown in FIG. 9, it is preferable to process the bottom opening frame 2 and install the linear body 3. As shown in FIG. 9A, by attaching a groove U to the bottom opening frame 2 and installing a linear body 3 in the groove U, the pickup surface 4 is pressed against the floor, or rubbed against a carpet or the like. It is preferable to adopt a configuration in which the linear body 3 is not displaced by the picking work.

When the groove U is installed so that the width of the groove is increased with respect to the thickness of the linear body 3 as shown in FIG. 9B and a force to stretch the linear body 3 is applied to the center of the groove U. Further, since the linear body 3 moves on the surface of the groove U by passing the linear body of the object 1 and returns to the center after the passage, an effect that the gap H between the linear bodies 3 is easily widened can be obtained.

As shown in FIG. 9C, there is an installation method in which a hole V is opened in the bottom opening frame 2 and the linear body 3 is passed through. However, as detailed in FIG. 8, in the case of the BB bullet 1A having a diameter of 6 mm, Since the BB bullet 1A does not pass unless the linear body 3 has a radius of 3 mm, the space between the linear body 3 and the floor may not be more than 3 mm when the pickup surface 4 is pressed against the floor. Preferably, the position where the hole V is opened is within 2 mm from the surface layer of the bottom opening frame 2.

Further, by making the portion where the linear body 3 of the bottom opening frame 2 is installed a soft member, the bottom opening frame 2 is distorted by the force applied to the linear body 3 when the object 1 passes through the collecting surface 4. When passing 1, the gap H is likely to widen and pass easily. At this time, the bottom opening frame 2 is a member that immediately returns to the current state even if it is distorted.

With reference to FIG. 10, the bamboo collection container 14 will be described with the BB bullet 1A as the object of collection. As shown in FIG. 10A, the pick-up and storage container 14 is obtained by dividing a bamboo node to a node having a length of about 15 cm and an outer diameter of about 7 to 8 cm in half.

As shown in (FIG. 10B), the bottom opening K formed by dividing it in half is used for the bottom opening K as shown in FIG. The pick-up surface 4 is configured by arranging the linear bodies 3. The wall 5 of the bamboo storage container 14 is provided with an outlet 21 for the BB bullet 1A.

As shown in FIG. 10D, the bamboo basket that becomes the linear body 3 is processed into a rod shape having a diameter of about 2 mm. This bamboo basket is provided with a groove U of about 1 to 2 mm in the bottom opening frame 2, and the gap H between the linear body 3 and the linear body 3 is arranged in parallel at an interval slightly narrower than the diameter 6 mm of the BB bullet 1A. A shim pick-up surface 4 is formed.

Alternatively, as shown in FIG. 10E, there is a method of making a hole V in the bottom opening frame 2 and passing a bamboo basket, but in this case the bamboo basket is much thicker than Tegs, so On the other hand, the case where the diameter of the bamboo basket is 2 mm will be described with reference to FIG. 8C. If the part of 1 mm which is the radius of the bamboo basket does not pass the part of the radius 3 mm of the BB bullet 1A, the sphere Since the BB bullet 1A cannot pass through the gap between the linear bodies 3, it is preferable to determine the installation position of the hole V in consideration of the thickness of the bamboo basket. When the bamboo basket is installed in the bottom opening frame 2, there are a method of fixing only one end of the stretched bamboo basket, a method of fixing both ends when passing through the hole V, and the like. By this method, when the BB bullet 1A passes through the gap H, the bamboo basket is easily bent.

The container 14 presses the picking surface 4 against the BB bullet 1A, the bamboo basket is bent along the surface of the sphere, the gap H is widened, and the center of the BB bullet 1A having a diameter of 6 mm is the center. After 3 millimeters, the bamboo basket that has been spread out by the sphere is bent back. At this time, the BB bullet 1A is bounced up inside the container 14 by the bending back force of the bamboo basket, and the sound of hitting the bamboo reverberates when it hits the inner wall. It is.

Since the BB bullet 1A has a spherical shape, if it is scattered, it will be scattered by people and will be left to be very troublesome, and reusable items may be thrown away. Although it is a small item, it is preferable to collect it for reuse if it can be used.

In the fourth embodiment, an object 1 that is symmetrically picked up is a bead 1B used in handicrafts. The bead 1B is a three-dimensional object having various shapes, and is a small object having a dimension of less than 1 mm to several millimeters. Although it is a small object, there are few things processed complicatedly, but there are various three-dimensional shapes not limited to a sphere like the BB bullet 1A.

The BB bullet 1A, which is the object of collection in the first to third embodiments, is a sphere, and the term representing the dimension is “diameter”. However, since the beads 1B are polyhedrons having various shapes, the terms representing the dimensions are, for example, the terms of the major axis and the minor axis for the elliptical ones, and the length, the inner diameter, and the outer one for the cylindrical ones. There is a term for the size of the object, such as the term diameter. The shape of the bead 1B includes a polyhedron, a streamlined object, and the like, and it is extremely complicated to explain these dimensions. Therefore, the dimensions of the object are defined using FIG.

What is shown in FIG. 11 represents a state in which the outer surface of various shaped beads 1B is sandwiched between two straight lines or two planes in parallel with each other by measurement using a caliper.

In FIG. 11A, when a spherical object is measured, the length of the line passing through the center of the sphere and having both end points on the spherical surface is the diameter. It is. Since the spherical shape has the same diameter even when measured from all directions, this diameter is the minimum diameter S.

Using this caliper measurement method, as shown in (FIG. 11B), when the distance between the faces is measured by sandwiching an approximately elliptical object with a caliper, as shown in (FIG. 11C), the most sandwiched between calipers The shortest place is the minimum diameter S, and the longest place is the maximum diameter L, as shown in FIG. 11D.

When a cylindrical object as shown in FIG. 11E is measured (FIG. 11F), the shortest part is set as the minimum diameter S, and the longest part is set as the maximum diameter L as shown in (FIG. 11G). To do. As shown in (FIG. 11I), the shape having a shape like a ridge as shown in (FIG. 11H) is measured with a caliper from all directions, and as shown in FIG. , (FIG. 11J), the longest place is the maximum diameter L. In addition, by measuring the star shape as shown in (Fig. 11K) or polyhedron like (Fig. 11L) with calipers, the shortest part of the passing length is set as the minimum diameter S, and the long part is maximized. This will be explained by defining the diameter L.

(FIG. 12) shows a container 15 for collecting and storing beads 1B having a size of about 1 mm. Since the symmetrical object is small, the container 15 may be small, and a cylindrical object having an outer diameter of about 2 to 3 cm and a height of about 7 cm will be described as an example.

What is shown in FIG. 12A shows a cylindrical container 15. A space about 1 to 2 cm below the inside of the container 15 is defined as a collection chamber 6 with the bottom surface as the collection surface 4. The upper space is defined as a storage chamber 7, and the boundary between the pickup chamber 6 and the storage chamber 7 is partitioned by a funnel-shaped partition wall 9, and the passage 8 has an inner diameter through which the beads 1 </ b> B pass. As shown in FIG. 12B, the container 15 has a configuration in which a take-out port 21 for the beads 1 </ b> B provided with a movable lid 20 is provided.

What is shown in FIG. 12C is a pick-up surface 4 for picking up beads 1B. For example, when collecting beads 1B having a minimum diameter S of about 1 mm. The linear body 3 uses Tegus No. 0.6 (standard diameter of about 0.128 mm) used for fishing, and the gap H is 0.3 to 0.8 mm narrower than the minimum diameter S of the beads 1B. As described in detail in the first embodiment, the pickup surface 4 is configured in parallel.

In FIG. 13, a process in which various types of beads 1 </ b> B bend the linear bodies 3 to widen the gaps H between the linear bodies 3 and collect them will be described. As shown in FIG. 13A, a bead 1B having a shape close to a sphere like an icosahedron is placed downward by placing the bead 1B downward and pressing the linear body 3 forming the collecting surface 4 from above. A certain bead 1B passes through the gap H as shown in FIG. 13B and moves upward above the linear body 3 as shown in FIG. 13C.

The star-shaped beads 1B protruded by sliding the pick-up surface 4 as shown in FIG. 13E while pressing the linear body 3 forming the pick-up surface 4 from above (FIG. 13D). It passes easily between the gaps H without the linear body getting caught in the part (FIG. 13F), and it is collected.

The dice-shaped beads 1B and the like as shown in FIG. 13G pass through as shown in FIG. 13H by pressing one side or corner from the angle entering the gap H between the linear bodies 3 (FIG. 13H). It will be collected as shown in 13I).

A bead 1B having a difference in length between the minimum diameter S and the maximum diameter L, such as a cylindrical shape or an ellipse as shown in FIG. 13J, has an arrangement direction of the linear bodies 3 forming the pickup surface 4. By sliding the pick-up surface 4 while pressing the pick-up surface 4 against the surface of the bead 1B in the direction of the maximum diameter L of the bead 1B, an operation such as rolling the bead 1B by the linear body 3 is added (Fig. 13K), the beads 1B pass between the gaps H of the linear bodies 3, and are collected as shown in FIG. 13L.

In the case of the beads 1B having a diameter of about 1 mm which is difficult to pick up with fingers, which is one of the objects of the present invention, since it is a very small object, few are processed into complicated shapes, and many of them are circular. It is easy to collect because it is a polyhedron close to a circle or a cylindrical granular material.

The beads 1B that are generally sold are often contained in a small transparent bag, and may be spilled on the table or floor when transferred to a container after purchase or by handling by work. Since the beads 1B spilled and scattered in this way are small in size, a very troublesome work is required to pick them up with fingers and return them to the bag or container. In particular, beads 1B with a size of about 1 mm spilled on carpets etc. are buried in carpets and are difficult to pick up. Conventionally, they are stuck on adhesive tapes and collected, or needle-like tips are inserted into the holes of beads 1B. Such as picking up and picking up with tweezers.

What is shown in FIG. 14 is a process of collecting the beads 1B that have entered the carpet eyes M with the storage container 15 having the pickup mechanism of the present invention. As shown in (FIG. 14A), as shown in (FIG. 14C), the pickup surface 4 is pressed against the beads 1B in the carpet eyes M from above as shown in (FIG. 14B). When the bottom opening frame 2 and the linear body 3 push down the soft carpet, the hard beads 1B come into contact with the linear body 3. At this time, as shown in (FIG. 14C) to (FIG. 14D) and (FIG. 14E), the beads 1B are scraped from the carpet eyes M by the linear bodies 3 by repeating the operation of rubbing on the collecting surface 4. It is taken out and passed through the gap H between the linear bodies 3 and collected in the container 15 as shown in FIG. 14E.

(FIG. 15) shows the process from picking up beads 1B to storage. As shown in FIG. 15A, the beads 1B pass through the gaps H between the linear bodies 3 as shown in FIG. 15B by pressing the collecting surface 4 of the container 15 from above the scattered beads 1B. Then enter the pick-up room 6. As shown in FIG. 15C, when the container 15 is tilted, the beads 1 </ b> B move to the storage chamber 7 through the passage 8. After that, when the container 15 is erected as shown in FIG. 15D, the trap 15 described in the first embodiment is moved to the concave space (valley) Y formed from the partition wall 9 and the container wall 5 and accumulated below the storage chamber 7. It is housed stably by the return preventing means that is a structure.

As mentioned above, scraping from the carpet eyes and picking up various shapes of beads 1B, etc. with a particularly small inclination angle, when rubber is used, the elastic deformation and friction are smoothly collected. It is difficult to do. Therefore, the linear body 3 is preferably a thread-like material such as Tegs, and the rod-shaped linear body 3 is not suitable because a small object is a target.

Example 5 is a game to which the storage container with a pickup mechanism in the present invention described in the above example is applied.

In the game, the object of collection is the other object 1C. The other object 1C is a false mole 1C ′. In this game, the fake mole 1C 'is captured by a storage container with a pickup mechanism formed in a hammer shape. The game will be described below (FIG. 16).

The one shown in FIG. 16A represents the false mole 1C ′ viewed from the front, back, left, and top and bottom. The structure is made of a synthetic resin material having a hollow structure with a dimension of about 1 to 2 cm formed in a substantially ellipsoidal shape.

What is shown in FIG. 16B is a storage container 16 with a pickup mechanism configured in a hammer shape to strike the false mole 1C ′. The structure is a cylindrical container with an outer diameter of 5 to 7 cm and a length of about 12 cm with a handle R that can be held by a child, and has a soft outer surface made of a vinyl material for safety reasons. It is. The lower part of the container hitting the false mole 1C ′ is the collecting surface 4, and the upper part of the container is a take-out port 21 and includes a movable lid 20.

The pickup surface 4 will be described with reference to FIG. 16C. The pick-up surface 4 is obtained by arranging linear bodies 3 on the bottom opening frame 2 in a grid pattern extending vertically and horizontally. The vertically extending linear bodies 3 are installed so that the gap H between the linear bodies 3 is narrower than the minimum diameter of the false mole 1C ′.
The gaps H between the linear bodies 3 that are stretched horizontally are arranged in a lattice shape with an interval narrower than the maximum diameter.

The linear body 3 constituting the pickup surface 4 is a Tegus 10 (standard diameter 0,520 mm). The material of the linear body 3 is preferably selected in consideration of durability by hitting the false mole 1C ′.

A game using the game shown in FIG. 16 will be described with reference to FIG. As shown in FIG. 17A, the pseudo mole 1C ′ is scattered and placed on the tabletop or the floor. As shown in FIG. 17B, the fake mole 1C ′ is aimed at the pick-up surface 4 of the storage container 16 with the pick-up mechanism of the hammer type. As shown in FIG. 17C, by hitting the false mole 1C ′ placed on the table and passing the false mole 1C ′ through the pickup surface 4, as shown in FIG. 17D, the hammer type This is a mole hitting game in which a fake mole 1C ′ is captured in the storage container 16 with a pickup mechanism.

At this time, by changing the dimensions of the false mole 1C ′, it is possible to increase the probability that the large false mole 1C ′ cannot pass due to the resistance of the linear bodies 3 arranged in a lattice shape. For this reason, if it does not just meet in the gap H between the linear bodies 3 stretched vertically and horizontally, it will be missed. This makes it a game for competing to catch the false mole 1C ′ that has been caught. It can be said that it is preferable for the game to be unable to pass through the collecting surface 4 in a straightforward manner.

1 object, 1A, 1B, 1C, object, 2 bottom opening frame, 3 linear body, 4 pickup surface, 5 walls, 6 pickup room, 7 storage room, 8 passage, 9 bulkhead, 10 valve, 11 pickup Storage container with mechanism, 12 storage container with pick-up mechanism, 13 storage container with pick-up mechanism, 14 storage container with pick-up mechanism, 15 storage container with pick-up mechanism, 16 tip, 17 passage opening, 18 passage exit, 19 Sweep section, 20 lids, 21 outlet.

Claims (8)

In a container equipped with a pick-up mechanism for picking up a three-dimensional object, the bottom opening of the container is stretched by a plurality of linear bodies, and the bottom opening is smaller than the minimum diameter of the object picked up by the linear body. A pick-up surface arranged in parallel with a narrow interval to form a gap, and the linear body forming the pick-up surface bends along the object surface and the gap is pushed and the object is placed in the container. A storage container with a pick-up mechanism, wherein when the wire enters, the gap is returned to less than the minimum diameter of the object by bending back the linear body, and the object is retained in the container. The storage container with a pick-up mechanism is divided into a pick-up room for temporarily detaining the object collected inside the two rooms and a storage room for stable storage, and the boundary between the two rooms is stored from the pick-up room. 2. The storage container with a pickup mechanism according to claim 1, further comprising a return prevention means that prevents the object from moving from the storage chamber to the pickup chamber, although the object moves into the chamber. The return blocking means is a passage configured such that a partition wall that forms a boundary between the pickup chamber and the storage chamber narrows from the pickup chamber toward the storage chamber, and the passage extends from the pickup chamber to the storage chamber. The storage container with a pickup mechanism according to claim 1, wherein the storage container has a structure that allows movement of an object to the pickup chamber and prevents movement of the object in the storage chamber to the pickup chamber. The storage container with the pickup mechanism has a trap structure in which the pickup chamber side surface excluding the opening of the passage outlet as viewed from the storage chamber side takes a reverse form, and the object once entering the storage chamber is 4. A storage container with a pickup mechanism according to claim 1, wherein the container is configured to prevent returning to the pickup room. The said storage container with a pick-up mechanism consists of a raw material in which the Young's modulus of the said linear body which comprises the said pick-up surface has a value larger than 0.1 (GPa). A storage container with a pick-up mechanism. In the storage container with a pick-up mechanism, the linear body forming the pick-up surface is a rod-like one made of metal, synthetic resin, or wood containing bamboo, or a yarn-like piece made of natural fiber or chemical fiber. The storage container with a pickup mechanism according to claim 1, wherein the storage container has a string shape. The storage container with a pickup mechanism is provided with a pickup mechanism by a bamboo craft characterized in that the linear body and the storage container are made of bamboo, and the collected sphere hits the container and emits a sound. Item 6. A storage container with a pickup mechanism according to Item 1. 7. The storage container with a pick-up mechanism according to claim 1, wherein the object to be picked up is a bead or a bullet of a playgun.

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