JP6564697B2 - Weighing container - Google Patents

Description

  The present invention relates to a weighing container.

Conventionally, a container body having a storage chamber in which contents are stored, a passage body through which the contents in the storage chamber pass, a take-out hole in which the content that has passed through the pass-through hole is taken out, and a content that has passed through the pass-through hole An outer wall portion on which a support portion for supporting an object is formed, and an operation portion provided between the container body and the outer wall portion and having a connection passage capable of communicating the passage hole and the extraction hole. Weighing containers are known.
As this type of measuring container, for example, as shown in Patent Document 1 below, the operating portion has a measuring position where the outlet portion on the take-out hole side and the support portion of the both ends of the connecting passage face each other, and the connecting passage. A configuration is known in which the outlet portion and the take-out hole are provided so as to be movable in a direction intersecting the axial direction along the central axis of the pass-through hole.

JP-A-2015-85974

  However, such a measuring container has a problem that the amount of contents that can be taken out cannot be arbitrarily changed.

  This invention is made | formed in view of the said problem, Comprising: It aims at providing the measuring container which can change the quantity of the content which can be taken out arbitrarily.

  In order to solve the above problems, a measuring container according to the present invention has passed through the passage hole, a container body having a storage chamber in which the contents are stored, a passage hole through which the contents in the storage chamber pass. An extraction hole through which the content is taken out, an outer wall portion on which a support portion for supporting the content that has passed through the passage hole is formed, and the passage hole and the outer wall portion. An operation portion formed with a connection passage capable of communicating with the take-out hole, and the operation portion has an outlet portion on the take-out hole side and the support portion of the opening portions at both ends of the connection passage. Between the measuring position to be taken out and the take-out position at which the outlet portion of the connection passage and the take-out hole are opposed to each other in a direction intersecting the axial direction along the central axis of the passage hole. A weighing container, wherein the support part and the operation part are And characterized by being relatively movable along the axial direction.

  According to this invention, when the operation portion is located at the measuring position, the outlet portion of the connection passage faces the support portion, so that the contents in the storage chamber enter the connection passage through the passage hole. And this content will be supported by a support part. In this state, when one content is located over the connection passage, the passage hole, and the storage chamber, when the operation unit is subsequently moved in the intersecting direction toward the take-out position, A shearing force is applied to a portion located between the passage hole and the connection passage, and this portion can be cut. Since the support part and the operation part are provided so as to be relatively movable along the axial direction, the amount of contents to be taken out can be arbitrarily determined by changing the relative position of the support part and the operation part in the axial direction. Can be changed to

  Here, a cover on which the container main body is disposed is provided, the outer wall portion is a part of the cover, and the first formed on the other one of the cover and the container main body A plurality of second engaging portions that can be engaged with the engaging portions may be formed at intervals in the axial direction.

  In this case, since either one of the cover and the container main body is formed with a second engagement portion that can engage the first engagement portion formed on the other, the first engagement portion and the second engagement portion are formed. By engaging the engaging portions with each other, the relative position in the axial direction of the support portion and the operation portion can be stabilized without wobbling, the contents can be cut at an accurate position, and a desired position can be obtained. The amount of contents can be easily removed. In addition, since the plurality of second engaging portions are formed in either one of the cover and the container main body at intervals in the axial direction, the support portion and the operation can be performed according to the desired amount of contents to be taken out. It is possible to selectively change the relative position of the portion in the axial direction, and it is possible to provide excellent operability.

In addition, the said operation part and the said container main body may be formed integrally, and the said operation part and the said container main body may be provided so that a relative movement is possible along the said axial direction with respect to the said outer wall part.
In this case, since the operation part and the container body are integrally formed, the relative movement between the support part and the operation part can be achieved by moving the entire container body and the operation part relative to the outer wall part along the axial direction. Since the position can be changed, the configuration of each part of the weighing container and the operation of the operation part can be simplified.

  According to the present invention, the amount of contents that can be taken out can be arbitrarily changed.

It is (a) longitudinal cross-sectional view of the measuring container shown as one Embodiment which concerns on this invention, (b) It is a V direction arrow view in (a) figure. It is the longitudinal cross-sectional view in the (a) measurement position of the measurement container shown in FIG. 1, (b) The longitudinal cross-sectional view in the taking-out position. FIG. 2A is a longitudinal sectional view at a measuring position and FIG. 2B is a longitudinal sectional view at an extraction position in a state where the container main body and the operation portion of the measuring container shown in FIG. 1 are relatively moved in the axial direction with respect to an outer wall portion.

Hereinafter, embodiments of a measuring container according to the present invention will be described with reference to FIGS.
First, the overall structure of the weighing container 1 according to the present embodiment will be described. As shown in FIG. 1, the weighing container 1 has a storage chamber R1 in which the content A is stored and a content A in the storage chamber R1. A container body 2 having a passage hole 28, a cover 3 in which a take-out hole 34 for taking out the contents that have passed through the passage hole 28 is formed, and a ceiling wall portion 32C (outer wall portion) of the passage hole 28 and the cover 3 described later. And an operation unit 4 provided between the two.

  In the present embodiment, the direction along the central axis O1 of the passage hole 28 is referred to as the axial direction, and the container body 2 and the cover 3 are formed in a rectangular parallelepiped shape that is long in the axial direction, and are orthogonal to the central axis O1 when viewed from the axial direction. The size of one direction among the directions to be performed is larger than the size of the other direction orthogonal to the one direction. Hereinafter, the one direction is referred to as a width direction S1, and the other direction is referred to as a thickness direction S2. In FIG. 1, the direction from the storage chamber R1 toward the passage hole 28 along the axial direction is referred to as “upward”, and the opposite is referred to as “downward”.

  Further, in the present embodiment, the contents A extend in the axial direction in the storage chamber R1, and are arranged in the width direction S1 so as to be accommodated in a plurality of shapes, which are rod-shaped bodies or tubular bodies. However, the shape of the content A is not limited to a rod-shaped body or a tubular body. Examples of this type of content A include processed foods such as refreshing confectionery and supplements, and drugs such as fertilizers and fragrances.

The cover 3 is erected toward the container main body 2 along the first main plate portion 31 formed in a rectangular shape that is long in the axial direction when viewed from the thickness direction S2 and along the outer peripheral edge of the first main plate portion 31. And an outer peripheral wall portion 32.
The outer peripheral wall portion 32 extends in the axial direction, and has a short wall portion 32A and a long wall portion 32B arranged at intervals in the width direction S1, and a ceiling wall extending from the upper end of the long wall portion 32B toward the short wall portion 32A. Part (outer wall part) 32C. The short wall portion 32A is shorter in the axial direction than the long wall portion 32B, and the upper end of the short wall portion 32A is positioned below the upper end of the long wall portion 32B. The tip of the top wall portion 32C on the short wall portion 32A side is located closer to the long wall portion 32B than the short wall portion 32A.

In the outer peripheral wall portion 32, an opening portion 33 that opens in the axial direction is formed over the entire region in the width direction S1 at a portion facing the top wall portion 32C in the axial direction. Further, an extraction hole 34 is formed in an intermediate portion of the top wall portion 32C in the width direction S1. In the illustrated example, the take-out hole 34 is located at the approximate center in the width direction of the cover 3 and is formed in a square shape in plan view. However, the shape of the take-out hole 34 is not limited to this shape, and may be formed to be larger than the diameter of the content A. For example, the shape may be a circular shape in plan view, an elliptical shape, or a polygonal shape. .
A support portion 32D that protrudes downward is formed at the tip of the top wall portion 32C. The support portion 32D is formed at the opening edge of the take-out hole 34 at the tip of the top wall portion 32C. The support portion 32D is continuous with the take-out hole 34 and the width direction S1.

A container body 2 is disposed inside the cover 3. The container body 2 includes a second main plate portion 21 formed in a rectangular shape that is long in the axial direction when viewed from the thickness direction S2, and the first main plate portion 31 side of the cover 3 along the outer peripheral edge of the second main plate portion 21. And an inner peripheral wall portion 22 erected toward the front.
The second main plate portion 21 is arranged at an interval in the thickness direction S2 with respect to the first main plate portion 31 of the cover 3, and the outer shape substantially coincides with the outer shape of the first main plate portion 31. However, the second main plate portion 21 is formed to be slightly smaller so as to fit inside the outer peripheral wall portion 32 of the cover 3.

The inner peripheral wall portion 22 extends in the axial direction, and extends from the upper end of the long inner wall portion 22B toward the short inner wall portion 22A side, from the short inner wall portion 22A and the long inner wall portion 22B arranged at intervals in the width direction S1. An upper wall portion 22C and a bottom wall portion 22D for connecting lower ends of the short inner wall portion 22A and the long inner wall portion 22B are provided.
The short inner wall portion 22A is shorter in the axial direction than the long inner wall portion 22B, and the upper end of the short inner wall portion 22A is positioned below the upper end of the long inner wall portion 22B. The tip of the upper wall portion 22C on the short inner wall portion 22A side is located closer to the long inner wall portion 22B than the short inner wall portion 22A. Further, the front end portion of the upper wall portion 22 </ b> C is located immediately below the take-out hole 34 of the cover 3.

Further, the short inner wall portion 22A and the long inner wall portion 22B are close to or in contact with the short wall portion 32A and the long wall portion 32B of the cover 3 in the width direction S1, respectively. The upper wall portion 22C is close to or in contact with the top wall portion 32C of the outer peripheral wall portion 32 in the axial direction.
Further, an engaging convex portion (first engaging portion) 23 that protrudes outward in the width direction S1 is formed on the upper portion of the short inner wall portion 22A, and on the inner surface of the upper portion of the short wall portion 32A of the cover 3. A plurality (two in the illustrated example) of engaging recesses (second engaging portions) 35 that can engage with the engaging protrusions 23 are formed in the axial direction.

As shown in FIG. 1, the internal space of the container body 2 is disposed above the container body 2, and is positioned below the partition wall 24 by a partition wall 24 formed integrally with the inner peripheral wall portion 22. The chamber is divided into two chambers, a communication chamber R2 positioned above the storage chamber R1 and the partition wall 24. The partition wall 24 protrudes from the second main plate portion 21 of the container main body 2 toward the first main plate portion 31 side of the cover 3, and a bulging portion 25 that protrudes upward and has a center axis O1. An orthogonal flat wall portion 26 and a stopper wall portion 27 located above the flat wall portion 26 are provided.
Among these, the bulging portion 25 and the flat wall portion 26 connect the short inner wall portion 22A and the long inner wall portion 22B in the width direction.

The bulging portion 25 of the partition wall 24 has an upright wall 25a positioned on the short inner wall portion 22A side along the width direction S1 and an inclined wall 25b positioned on the long inner wall portion 22B side in the longitudinal sectional view along the axial direction. It is formed in the taper shape provided with. Accordingly, the upper end portion of the bulging portion 25 is located above the flat wall portion 26 and is disposed at a position away from the central portion in the width direction S1 of the container body 2 toward the short inner wall portion 22A. Yes.
The stopper wall portion 27 forms a part of the partition wall of the communication chamber R2, and includes an upper step portion 27a connected to the long inner wall portion 22B, a lower step portion 27b connected to the inclined wall 25b, an upper step portion 27a, and a lower step. And an inclined connecting portion 27c for connecting the portion 27b.

Here, the passage hole 28 is formed in the upper end portion of the bulging portion 25. Further, the passage hole 28 faces the support portion 32D of the cover 3 in the axial direction.
In this embodiment, the passage hole 28 is formed in a square shape in plan view. However, the shape of the passage hole 28 is not limited to this shape, and may be larger than the diameter of the contents A. For example, the shape may be a circular shape in plan view, an elliptical shape, a polygonal shape, or the like. I do not care.

  In addition, a plurality of step portions that protrude downward on the lower surface of the inclined wall 25b facing the accommodation chamber R1 and provide resistance to the contents A that move toward the passage hole 28 along the inclined wall 25b. 25c is formed.

Next, the operation unit 4 includes an operation unit main body 40 in which a connection passage 42 capable of communicating the passage hole 28 and the take-out hole 34 is formed, and an elastic piece 41 formed integrally with the operation unit main body 40. I have. The operation unit 4 is connected to the container main body 2 via a hinge 44. The hinge 44 connects the lower end portion of the operation unit main body 40 and the upright wall 25 a of the container main body 2, and is formed integrally with the operation unit main body 40 and the container main body 2.
The operation portion main body 40 is disposed between the bulging portion 25 of the partition wall 24 and the top wall portion 32 </ b> C of the cover 3, and is rotatably supported by the cover 3 via the rotation shaft portion 43. Further, the operation portion main body 40 is formed to have a thickness close to the first main plate portion 31 of the cover 3 and the second main plate portion 21 of the container main body 2. Further, the operation unit main body 40 is formed in such a size that its upper end is in contact with or close to the support portion 32D with its lower end in contact with or close to the bulging portion 25.
As shown in FIG. 1, the upper end portion of the operation unit main body 40 is in contact with or close to the support portion 32D, and the upper surface of the upper wall portion 22C of the container main body 2 is on the lower surface of the top wall portion 32C of the cover 3. The engaging convex part 23 of the short inner wall part 22A is engaged with the upper end edge 32E of the short wall part 32A in the state of contact or proximity.

The rotation shaft portion 43 projects from the lower end portion of the operation portion main body 40 toward the first main plate portion 31 side of the cover 3 and is formed in a circular shape when viewed from the thickness direction S2 side. The rotation shaft 43 is fitted and supported in a circular recess 45 formed in the first main plate portion 31. In the illustrated example, the rotation axis M of the rotation shaft portion 43 extends in the thickness direction S2 and is orthogonal to the center axis O1. Therefore, the operation unit 4 is swingable in the width direction S1 about the rotation axis M.
In addition, although the case where only one rotation shaft portion 43 is formed is described, two rotation shaft portions 43 may be formed so as to protrude toward the first main plate portion 31 and the second main plate portion 21, respectively.

The connection passage 42 penetrates the operation unit main body 40 in the axial direction. The connection passage 42 is formed in, for example, a square shape in plan view. Of the opening portions at both ends of the connecting passage 42, the lower opening portion that is opposed to the passage hole 28 of the bulging portion 25 in the axial direction and into which the content A that has passed through the passage hole 28 enters is an inlet portion 42a and is supported. The upper opening that guides the content A that opens to the side of the portion 32D and enters the inlet portion 42a to the outlet hole 34 at an outlet position to be described later is an outlet portion 42b (see FIG. 2B).
In addition, the shape of the connection channel | path 42 is not limited to this shape, What is necessary is just to be formed larger than the diameter of the content A, for example, planar view circular shape, elliptical shape, and polygonal shape may be sufficient. Absent.

Here, the connection passage 42 is arranged coaxially with the central axis O1 of the passage hole 28, and the operation portion 4 in a state where the passage hole 28, the connection passage 42, and the support portion 32D are located on the central axis O1. Hereinafter, the position is referred to as a measurement position P1 (see FIG. 2A).
Further, when the operation unit 4 rotates from the measuring position P1 around the rotation axis M, the operation unit 4 moves in a direction intersecting the axial direction, and the outlet portion 42b of the connection passage 42 and the extraction hole are moved. 34 is in a state of facing. Hereinafter, the position of the operation unit 4 at which the connection passage 42 is in such a state is referred to as an extraction position P2 (see FIG. 2B).

That is, the operation unit 4 rotates around the rotation axis M, and moves between the measurement position P1 and the take-out position P2 shown in FIG. 2 in a direction intersecting the axial direction.
An operation protrusion 46 is formed on the upper end portion side of the operation portion main body 40 so as to protrude toward the outside in the width direction S1 and exposed to the outside of the container main body 2. Accordingly, for example, the operation unit 4 can be easily rotated by pushing the operation unit 4 using the fingertip while holding the cover 3.

In addition, a positioning projection 47 is formed at the lower end of the operation unit main body 40 so as to protrude downward and come into contact with the upright wall 25a of the bulging portion 25 from the outside in the width direction S1 of the upright wall 25a. Thereby, the amount of rotation from the take-out position P2 of the operation unit 4 to the measurement position P1 can be restricted, and the operation unit 4 can be positioned at the measurement position P1.
Further, a restriction convex portion 48 that protrudes toward the first main plate portion 31 side of the cover 3 is formed on the second main plate portion 21 of the container body 2. The restricting convex portion 48 is disposed so as to come into contact with the operation portion main body 40 when the operation portion 4 moves to the take-out position P2. As a result, the amount of rotation of the operation unit 4 from the measuring position P1 to the take-out position P2 can be restricted, and the operation unit 4 can be positioned at the take-out position P2.

The elastic piece 41 provided in the operation unit main body 40 is a leaf spring extending in a band shape from the base end part 41 a toward the front end part 41 b, and the base end part 41 a is connected to the upper end part side of the operation unit main body 40. Has been. More specifically, the base end portion 41a of the elastic piece 41 is connected to a portion of the upper end portion of the operation portion main body 40 that is located on the opposite side of the width direction S1 from the operation protrusion 46 with the connection passage 42 interposed therebetween. Yes. The distal end portion 41 b of the elastic piece 41 is locked to the inclined connection portion 27 c of the stopper wall portion 27.
At this time, the elastic piece 41 is elastically deformed in advance so as to be curved in an arc shape from the base end portion 41a toward the tip end portion 41b, and the operation portion main body 40 is moved to the measuring position by using the elastic force due to this elastic deformation. Pressing toward the P1 side.
That is, the operation unit 4 is elastically deformed between the measuring position P1 and the take-out position P2 by the elastic piece 41, and naturally returns to the measuring position P1 by receiving the elastic force from the elastic piece 41. Is configured to do.

Next, the operation of the weighing container 1 according to the present embodiment will be described with reference to FIG. 2 in the case where the content A is weighed and taken out with the shortest length.
The weighing container 1 in the upright posture state shown in FIG. 1 is turned upside down, for example, so that it passes through one of the contents A stored in the storage chamber R1 as shown in FIG. Guide to hole 28. Then, the content A passes through the inlet 42 a from the passage hole 28 and enters the connection passage 42 of the operation unit 4. Note that the weighing container 1 does not necessarily need to be in an inverted posture. For example, the contents A may enter the connection passage 42 by tilting the weighing container 1.

At this time, since the operation unit 4 is located at the measuring position P1 and the outlet portion 42b of the connection passage 42 is opposed to the support portion 32D, the content A that has entered the connection passage 42 is discharged from the connection passage 42. It does not advance to the outside from the portion 42b and is supported by the support portion 32D. In the case shown in FIG. 2, since the content A is longer than the length of the connection passage 42, a part of the content A enters the connection passage 42 and the remaining portion protrudes into the storage chamber R1. .
Here, since the plurality of step portions 25c are formed in the inclined wall 25b of the partition wall 24, the contents other than the contents A that have passed through the passage hole 28 are prevented from gathering toward the passage hole 28 side. be able to. Accordingly, it is possible to prevent the plurality of contents A from being densely packed around the passage hole 28 and the contents A from being difficult to pass through the passage hole 28 due to frictional resistance or the like due to the denseness.

  Next, as shown in FIG. 2B, the operation unit 4 is pushed into the container body 2 via the operation protrusion 46, the operation unit 4 is rotated around the rotation axis M, and the operation unit 4 is moved from the measuring position P1. Move to take-out position P2. At this time, the operation unit 4 is pushed in with a force against the elastic force of the elastic piece 41, and the operation unit 4 is rotated in a direction intersecting the axial direction. As a result, the elastic piece 41 is further elastically deformed and bent. At this time, since the distal end portion 41b of the elastic piece 41 is locked to the inclined connection portion 27c of the stopper wall portion 27, the distal end portion 41b is difficult to move. Therefore, the elastic piece 41 can be elastically deformed smoothly.

Then, in the process of rotating the operation part 4 from the measuring position P1 toward the take-out position P2, the gap between the opening edge of the inlet part 42a in the operation part body 40 and the opening edge of the passage hole 28 in the container body 2 Thus, it is possible to sandwich the contents A that have entered the connection passage 42 and apply a shearing force in the radial direction.
Thereby, in the case of the hard contents A, for example, it can be divided (divided) into two parts and divided.
In this way, the contents A can be subdivided, and the length of the subdivided contents A is defined by the axial distance between the support portion 32D and the opening edge of the passage hole 28 in the container body 2 (measurement). )can do. At the take-out position P2, the outlet portion 42b faces the take-out hole 34, and the outlet portion 42b and the take-out hole 34 are in communication with each other. And can be taken out from the connection passage 42 through the take-out hole 34.

Here, since the operation part 4 is positioned at the take-out position P2 by the restricting convex part 48, the outlet part 42b of the connection passage 42 and the take-out hole 34 can be reliably opposed to each other. Therefore, the subdivided contents A can be taken out without being caught.
When the operation portion 4 is located at the take-out position P2, a part of the opening edge of the inlet portion 42a of the operation portion main body 40 blocks a part of the passage hole 28. The longitudinal direction of the contents A left on the R1 side is different from the extending direction of the connection passage 42, and they are not located on the same axis. Therefore, these things prevent the contents A in the storage chamber R1 from continuously passing through the connection passage 42 and the take-out hole 34 and jumping outside.

Furthermore, even if the container body 2 is returned to the upright posture while the operation unit 4 is located at the take-out position P2, as described above, the extending direction of the connection passage 42 is inclined with respect to the axial direction. . For this reason, a part of the opening edge of the passage hole 28 in the container body 2 blocks a part of the inlet portion 42 a of the connection passage 42, so that the subdivided contents A can be removed from the connection passage 42. It does not return to the storage room R1 side.
When the length of the content A that has entered the connection passage 42 is shorter than the connection passage 42, the content A is taken out without being cut. Therefore, in this case, the content A defined to be equal to or shorter than the length of the connection passage 42 can be obtained.

Next, a case where the amount of content A taken out is changed will be described with reference to FIG.
As shown in FIG. 3, the container body 2, the operation unit 4, and the cover 3 are moved relative to each other in the axial direction to support the cover 3 and the operation unit 4 formed integrally with the container body 2. The distance in the axial direction of the portion 32D is increased by the dimension δ. When the cover 3 and the container body 2 are separated from each other in the axial direction from the state shown in FIGS. 1 and 2, the short wall portion 32A of the cover 3 is outside the width direction S1, and the short inner wall portion 22A of the container body 2 is wide. Each bends slightly in the direction S1.
As a result, the engagement state between the engagement convex portion 23 and the upper end edge 32E of the short wall portion 32A is released, and the engagement concave portion 35 formed on the inner surface of the short wall portion 32A and the engagement convex portion 23 are formed. By engaging, the relative positions in the axial direction of the cover 3, the container main body 2, and the operation unit 4 are determined.
This operation is performed, for example, by sliding and moving along the axial direction while pressing the second main plate portion 21 of the container body 2 against the cover 3 side while holding the cover 3.

And since the content A falls to the support part 32D side to the position contact | abutted with the support part 32D, the length of the content A which has come out of the storage chamber R1 becomes long by dimension (delta). In this state, the operation portion 4 is rotated around the rotation axis M by operating the operation protrusion 46, and the operation portion 4 is pushed in with a force against the elastic force of the elastic piece 41, so that the operation portion 4 is moved to the axis of the passage hole 28. Rotate in a direction that intersects the direction. Thereby, when the operation part 4 is moved from the measurement position P1 to the take-out position P2, as in the case described above, between the opening edge of the inlet part 42a of the connection passage 42 and the opening edge of the passage hole 28, The shearing force can be applied in the radial direction by sandwiching the content A that has entered the connection passage 42. Thereby, the content A is cut | disconnected.
Compared with the case where the container main body 2 and the cover 3 are not separated in the axial direction, the length of the content A to be subdivided is longer by the dimension δ of the container main body 2 and the cover 3 separated in the axial direction. It has become. That is, the amount by which the content A is weighed can be changed by the distance separating the container body 2 and the cover 3 in the axial direction.

  As shown in FIGS. 1 and 2, the upper end portion of the operation portion main body 40 is in contact with or close to the support portion 32D before the cover 3, the container main body 2 and the operation portion 4 are separated in the axial direction. In the state where the upper surface of the upper wall portion 22C of the container body 2 is in contact with or close to the lower surface of the top wall portion 32C of the cover 3, as described above, the engagement convex portion 23 of the container body 2 and the cover 3 are short. The upper end edge 32E of the wall portion 32A is engaged with each other. For this reason, the container body 2 does not fall from the cover 3 through the opening 33 even in the upright posture as shown in FIG.

  As described above, according to the measuring container 1 of the present embodiment, when the operation unit 4 is located at the measuring position, the outlet portion 42b of the connection passage 42 faces the support portion 32D. When the content A in the chamber R1 enters the connection passage 42 through the passage hole 28, the content A is supported by the support portion 32D. In this state, when one content is located over the connection passage 42, the passage hole 28, and the storage chamber R1, the operation unit 4 is then crossed with respect to the axial direction along the central axis O1 of the passage hole 28. When moving toward the take-out position P <b> 1 in the direction, the shearing force is applied to the portion of the contents A located between the passage hole 28 and the connection passage 42, and this portion can be cut. And since support part 32D and the operation part 4 are provided so that relative movement is possible along an axial direction, changing the relative position of the support part 32D and the operation part 4 in the axial direction changes the content A to be taken out. The amount can be changed arbitrarily.

  Moreover, since the engagement convex part 23 is formed in the container main body 2, and the engagement recessed part 35 is formed in the cover 3, the axial direction of support part 32D and the operation part 4 is made by engaging these mutually. The relative position can be stabilized without wobbling, the content A can be cut at an accurate position, and a desired amount of the content A can be easily taken out. In addition, since a plurality of engaging convex portions 23 and engaging concave portions 35 are formed in the container body 2 and the cover 3 in the axial direction, the shafts of the container body 2 and the cover 3 are adjusted in accordance with a desired amount of the content A to be taken out. The relative position in the direction can be selectively changed.

  Moreover, since the operation part 4 and the container main body 2 are integrally formed, the support formed in the cover 3 can be obtained by moving the entire container main body 2 and the operation part 4 in the axial direction relative to the cover 3. The relative position between the unit 32D and the operation unit 4 can be changed. For this reason, the structure of each part of the measurement container 1 and the operation of the operation part 4 in the axial direction can be simplified.

  The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.

For example, in the above embodiment, since the cover 3 includes the opening 33, the container main body 2 and the cover 3 can be moved relative to each other in the axial direction. The container main body and the outer wall portion may be configured to be relatively movable in the axial direction by providing a portion shorter than the dimension to be moved in the axial direction with respect to the portion.
Moreover, although the aspect in which the operation part 4 is formed integrally with the container body 2 has been described, the present invention is not limited to such an aspect, and the operation part and the container body are formed separately, and in the axial direction, the outer wall You may provide the clearance gap between which an operation part can move between an operation part and an operation part, and between an operation part and a container main body.

  Moreover, in the said embodiment, although the engagement convex part 23 was provided in the container main body 2, and the two engagement recessed parts 35 were provided in the cover 3, it is not restricted to such an aspect, An engagement convex part May be provided, or the relationship between the projections and depressions may be provided in reverse, and the number of engagement recesses or engagement projections may be three or more, and can be arbitrarily selected.

  In addition, it is possible to appropriately replace the constituent elements in the embodiment with known constituent elements without departing from the spirit of the present invention, and the above-described modified examples may be appropriately combined.

DESCRIPTION OF SYMBOLS 1 Measuring container 2 Container main body 3 Cover 4 Operation part 23 Engaging convex part (1st engaging part)
28 Passing hole 32C Top wall (outer wall)
32D Support part 34 Extraction hole 35 Engaging recess (second engaging part)
42 Connection passage 42b Outlet A Contents R1 Storage chamber P1 Weighing position P2 Extraction position

Claims (2)

A container body having a storage chamber in which the contents are stored, and a passage hole through which the contents in the storage chamber pass;
An outer wall portion formed with a take-out hole from which the content that has passed through the passage hole is taken out, and a support portion that supports the content that has passed through the passage hole;
An operation portion provided between the passage hole and the outer wall portion, wherein a connection passage capable of communicating the passage hole and the extraction hole is formed;
With
The operation unit is
Among the opening portions at both ends of the connection passage, a measuring position where the outlet portion on the extraction hole side and the support portion face each other,
The measuring container is provided between the outlet portion of the connection passage and the take-out position where the take-out hole is opposed to be movable in a direction intersecting the axial direction along the central axis of the passage hole. And
The measuring container, wherein the support part and the operation part are provided so as to be relatively movable along the axial direction. It includes a cover on which the container body is disposed, and the outer wall portion is a part of the cover.
A plurality of second engaging portions engageable with the first engaging portion formed on the other of the cover and the container main body are formed at intervals in the axial direction. The measuring container according to claim 1.

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