JP7570682B2 - Microtube opener - Google Patents

Description

The present invention relates to a microtube capping tool that uses the principle of leverage to manually open the caps of small, sealed test tubes (microtubes) used in biochemical tests such as PCR.

Microtubes are small test tubes with a capacity of about 0.2 ml to 2 ml that are used to handle minute amounts of sample (microliters to milliliters) and are widely used in tests and experiments in biochemistry and molecular biology, such as PCR. The opening is made so that it can be sealed with a cap, and they are commercially available as individual tubes or multiple tubes connected together, depending on the application.

In manual testing using microtubes, the caps must be opened when preparing samples, such as when injecting reagents. However, if this is done manually, there is a risk that the sample may become contaminated due to contact between the opening of the tube and the fingers, or that the sample may come into contact with the fingers and cause an infection.

In response to this, a device has been proposed that manually or automatically opens a cap without directly touching the cap with fingers. When handling a large amount of samples, an automatic processing device is recommended and non-contact operation is performed, but when handling a small number of samples, they are often processed manually, one tube at a time. As a capping device for this purpose, for example, a microtube opener device described in Non-Patent Document 1 and a sealed container opener as in Patent Document 1 are known, which use the principle of leverage to open a cap in the manner of a bottle opener by engaging a notch portion consisting of a claw portion and a pressing portion facing the claw portion with a lip protrusion on the cap of a microtube, which is the part where the fingers are placed when opening the cap.

Internet URL: http://www. sarstedt. jp/product/pdctcatleaf. htm General Catalog 2020-2021 Page 139 (Tube Opener) Search date: October 9, 2020

Special Publication No. 2-500265

According to the device described in the above document, the groove (notch) at the tip of the handle, which serves as the holding and operating part, can be hooked onto the lip projection of the cap of the microtube, and the handle can be operated upward in the manner of a bottle opener, allowing the caps to be manually opened one by one without directly touching the microtube with one's fingers.

However, as mentioned above, microtubes come in multiple sizes and shapes depending on the capacity, and with conventional general-purpose devices available on the market, for example, when opening a small-capacity multiple-connected microtube, problems have been pointed out such as the notch interfering with the cap of an adjacent tube, opening the cap of the adjacent tube as well. Thus, conventional devices are not able to address the issue of versatility for a variety of microtubes.

In addition, in tests and experiments using these microtubes, it may be necessary to repeatedly open the cap and inject reagents, etc., with a micropipette for each tube. In such cases, the tester holds the opener between the fingers of the same hand as the micropipette to open the cap and inject reagents, etc., and must keep pressure on the fingers to prevent the tube from dropping during the process.

The present invention aims to provide a cap removal tool for manually removing the caps of microtubes one by one, which can be used for a variety of different sizes and shapes of microtubes, for example, by opening and closing small connected tubes without interfering with adjacent tubes.

Another objective of the present invention is to provide a microtube capping tool that allows users to easily perform processing operations using tools such as micropipettes and open the caps of tubes without having to change tools when manually performing sample preparation and other processing on each microtube.

The microtube opener of the present invention is a device for manually opening the caps of microtubes by utilizing the principle of leverage, and is composed of a notch portion consisting of a claw portion including a point of action for opening the cap that engages with a lip protrusion provided on the edge of the cap and a cap support portion including a fulcrum for opening the cap that abuts on the top surface of the cap, a plate-like or rod-like notch setting portion that serves as a setting portion for the notch portion, and an operation portion extending from the notch setting portion and including a force point for opening the cap, and a plurality of the notches of different sizes and shapes are provided distal to the operation portion of the main body, and the plurality of notches are arranged in series in the axial direction of the notch setting portion .

The claw portion of the cutout portion is formed by protruding from the cutout setting portion in a hook shape, and the gap between the cutout setting portion and the claw portion is formed as a cutout groove. Moreover, the cutout groove is preferably formed as follows.
One side of the gap that forms the notch groove is formed as a wall.
The boundary surface of the claw portion with the notch setting portion on the notch groove side is an inclined surface or an R-formed surface.
The depth of the notch groove is formed shorter than the lip projection of the cap.

It is preferable that the lower surface of the notch setting portion, located on the opposite side of the claw portion across the cap support portion of the notch portion, is formed to protrude downward, and the surface of the protrusion continuing from the cap support portion is formed as an inclined curved surface.

The plurality of cutouts arranged in series are preferably formed so that the width and length of the cutout on the tip side are smaller than the width and length of the cutout on the operation part side. Also, the plurality of cutouts arranged in series may share a claw part and include a plurality of cap supports.

The notch setting portion may be one whose angle in the horizontal direction relative to the operating portion is freely variable, or may be one that is formed at a specific angle in the horizontal direction relative to the operating portion.

The notch is formed either by directing the notch groove toward the tip and positioning the cap support portion closer to the tip than the claw portion, or by directing the notch groove toward the operating portion and positioning the claw portion closer to the tip than the cap support portion.

The operating section may be formed in a plate shape, and may be formed with a locking means that engages with a finger. In particular, the locking means is preferably formed in the form of a ring that can be inserted into a finger, or a hook that can be hooked onto a finger.

The boundary surface between the claw portion of the cutout portion and the cutout setting portion or the operating portion on the back surface side where there is no cutout groove is preferably formed as an inclined surface that slopes from the cutout setting portion or the operating portion toward the tip of the claw portion, and the back surface on the side where there is no cutout portion of the cutout setting portion is preferably formed as a curved surface that slopes from the back surface of the operating portion toward the back surface.

(Action)
According to this method, one cap removal device is provided with multiple cutout portions, and the sizes and shapes of the cutout portions are set to correspond to different microtubes, so that one device can be used for many different types of microtubes.

By forming one side of the notch groove as a wall, it is possible to prevent disengagement due to shaking of the hand when opening a small microtube. Also, by forming the depth of the notch groove shorter than the lip protrusion, it is possible to prevent the claw portion from contacting the opening of the cap when engaging the lip protrusion. Furthermore, by making the boundary surface between the notch groove and the notch setting portion an inclined surface or an R-shaped surface, the gap space is reduced, preventing the lip protrusion from penetrating too deeply into the gap, and as a result, it is possible to prevent the claw portion from contacting the opening of the cap.

Providing a protrusion on the opposite side of the cap support from the claw portion can prevent the lip protrusion from disengaging from the notch portion backwards when the cap is opened. In addition, making the surface of the protrusion an inclined curved surface allows for smooth attachment and detachment without getting caught when engaging with the lip protrusion and removing the cap.

By providing multiple notches in series on the axis of the notch setting part, it is possible to apply the device to many types of microtubes, and to open multiple types of caps without changing the grip of the operating part. Furthermore, by forming the size of the tip side of the multiple notches smaller than the operating part side, it is possible to reduce interference from other notches when opening caps. Furthermore, by providing the claw part of the notch part at the tip part of the notch setting part with a common claw part and a configuration with multiple cap support parts, and applying the device to one in which the notch groove faces the operating part side, there is no need to provide multiple claw parts, and the length of the device can be shortened.

If the angle of the notch setting part relative to the operating part can be freely changed in the horizontal direction, selective opening can be performed in the axial or lateral direction as needed, and the change in angle makes it possible for both right-handed and left-handed people to use the device. Also, when a specific angle is set, the device can be used for opening in the lateral direction, etc.

If the point of action of the claw is located further forward than the fulcrum of the cap support, the bottle can be opened by pushing the operating part downward relative to the fulcrum. Conversely, if the point of action of the claw is located closer to the operating part than the fulcrum of the cap support, the bottle can be opened by pulling the operating part upward relative to the fulcrum, like a bottle opener.

If the operating part is formed in a plate shape, even if another instrument such as a micropipette is held in the same hand as the cap-opening instrument, the instrument can be easily held between the fingers during processing operations such as cap-opening and reagent injection. Furthermore, by providing a locking means on the operating part to hold it on the fingers, it is possible to reduce concerns about the cap-opening instrument dropping during processing operations, even if a micropipette or the like is held at the same time. If a ring or hook that can be inserted into a finger is provided as the locking means, the instrument can be worn on the finger like a ring, providing a means of preventing the instrument from dropping without requiring force to hold it.

By making the boundary surface between the operating part and the claw part of the notch a sloping curved surface, the shape is free of corners and easy to grip with the fingers, and by making the back surface of the notch setting part a curved surface that slopes backward, even if there are multiple notches, the structure is such that other notches are less likely to interfere with each other when opening the bottle.

The microtube opener of the present invention is provided with a number of cutouts of different sizes and shapes, which means that even small connected microtubes can be opened without interfering with adjacent tubes, and even large microtubes can have a cap and cutout with sufficient width to engage with each other. This makes it possible to provide a highly versatile opener that can be used with multiple types of microtubes regardless of the size or shape of the microtubes.

In addition, when preparing samples for tests or experiments using microtubes, it is possible to provide a user-friendly cap removal device that allows easy operation of a test device such as a micropipette and cap removal with the cap removal device, even when both devices are held in the same hand at the same time.

1 is an overall configuration diagram (perspective view) of a microtube cap remover showing a first embodiment of the present invention; 3A and 3B are side and bottom views of the embodiment; FIG. 4 is an enlarged view showing a cutout portion of the embodiment. 5A to 5C are schematic diagrams showing a method of opening a cap using the opener of the embodiment. FIG. 11 is an overall configuration diagram (perspective view) of a microtube cap removal device according to a second embodiment of the present invention. 3A and 3B are side and bottom views of the embodiment; 5A to 5C are schematic diagrams showing a method of opening a cap using the opener of the embodiment. FIG. 13 is an overall configuration diagram (perspective view) of a microtube cap removal device according to a third embodiment of the present invention. 3A and 3B are side and bottom views of the embodiment; FIG. 4 is an enlarged view showing a cutout portion of the embodiment. 5A to 5C are schematic diagrams showing a method of opening a cap using the opener of the embodiment. FIG. 2 is a configuration diagram showing an example of a microtube used in the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a microtube opener according to the present invention will be described in detail with reference to the drawings.
Figure 12 shows examples of microtubes that can be used with the cap removal device of the present invention, with A being a small-sized tube with a protrusion on the top surface of the cap, and B being a relatively large-sized lock-type tube with a flat top surface of the cap, showing the capping and uncapping states.
As described above, the microtube 90 is a small test tube container for handling minute or small amounts of samples with a volume of about 0.2 ml (for PCR) to 2 ml, which is widely used in biochemistry and molecular biology tests and experiments such as PCR, and the container opening 96 is closed with a cap 91 to seal the sample and prevent it from being easily opened. The cap 91 may be of a screw type, but the cap 91 to which the cap opening tool of this embodiment is applied is inserted into the opening 96 of the tube 90 and fitted in place to seal, and the opening edge 97 of the tube 90 and the flange 98 of the cap are connected and integrated by a hinge 95. A lip projection 92 is provided on the edge of the cap opposite the position where the hinge 95 of the flange 98 is provided, which serves as a portion for hooking a finger or a cap opening tool when opening the cap.

The microtube 90 is available in several sizes within the above-mentioned capacity range and in the following shapes.
- A type in which each tube 90 is independent, and a multi-type tube in which multiple tubes 90 are connected together.
- A tube in which the upper surface of the cap 90 is flush with the upper surface of the lip projection 92, and a tube in which the central portion of the cap protrudes 93 beyond the lip projection 92.
- A type in which the lip projection 92 is relatively thin and flat, and the opening 96 of the tube is kept closed only by the fitting force of the fitting portion 911 of the cap 91, and a locking type tube in which the underside of the lip projection 92 is inclined 94 so that it becomes thicker toward the opening side, and which is equipped with a locking portion (hanging portion) 912 that holds the edge portion 97 of the opening 96 closed by clamping it with the fitting portion 911 of the cap 90.
While there are various configurations, the cap remover of the present invention is proposed as a bottle opener type cap remover that utilizes the principle of leverage to manually open the caps 91 one by one for any type of tube 90.

Figure 1 is a perspective view of the overall configuration of a first embodiment of the present invention, Figure 2 shows A as a side view, Figure 2 shows B as a bottom view, and Figure 3 shows an enlarged view of the notch portion of this embodiment. The microtube opener of this embodiment is composed of a notch setting portion 10 formed in a plate shape, two notch portions 20A and 20B provided on one side of the notch setting portion 10, and an operating portion 30 that serves as the gripping portion of this device and extends from the notch setting portion 10. The two notch portions 20A and 20B are formed in series on the tip side (distal side) 20A and the operating portion side (proximal side) 20B, with the notch grooves 24A and 24B facing the distal side.

This instrument is formed in a plate shape as a whole, with the distal side being the notch setting portion 10 to which the notch portion 20 is attached as described above, and the proximal side being formed as the operating portion 30 for holding and operating the instrument. The size of this instrument in this embodiment is set to match the size of the notch portion 20 described below, but the width is set to be narrow for the distal notch setting portion 10 and wide for the proximal operating portion 30 for ease of gripping, and the length is set to be the length of the two notch portions 20A and 20B described below plus 50 mm (85 mm in this example) to make it easy to grip and operate as the operating portion 30. In addition, the thickness of the operating portion 30 is formed to be 3 mm for easy gripping, since it is always held by the fingers during processing. In addition, the part that comes into contact with the fingers may be treated with an anti-slip coating.

As described above, two notch portions 20A and 20B are provided in series in the notch setting portion 10, and each notch portion 20 forms a claw portion 21A or 21B that protrudes in a hook shape from the lower surface of the notch setting portion 10, and the gap formed by the claw portion 21 is a cut groove 24A or 24B that serves as an engagement portion for accommodating the lip protrusion 92 of the cap 91 of the microtube 90. The lower surface of the notch setting portion 10 facing the upper surface of the claw portions 21A and 21B, and the portions that abut against the upper surface of the cap 90 when the cut groove 24A or 24B is engaged with the lip protrusion 92 are cap support portions 22A and 22B, and are defined as the notch portions 20A and 20B together with the claw portions 21A and 21B. In addition, the definitions of up and down described in this specification are used by defining the cap 91 side of the microtube 90 as the top and the bottom 99 side of the cap as the bottom when the lip protrusion 92 of the cap 91 of the microtube 90 is engaged with the notch portion 20. Therefore, the top surface of the notch setting portion refers to the back side of the device on the side without the notch portion, and the bottom surface refers to the surface on which the notch portion 20 is provided.

In addition, the underside of the notch setting portion 10 is formed by sandwiching the cap support portions 22A, 22B and forming the inclined curved surfaces 23A, 23B that are inclined downward on the surface located opposite the claw portions 21A, 21B. As a result, during the opening operation, the cap 91 engaged with the notch portions 20A, 20B is positioned between the claw portions 21A, 21B and the inclined curved surfaces 23A, 23B, and the inclined curved surfaces 23A, 23B prevent it from coming off backward. In addition, the inclined curved surfaces 23A, 23B have no catches when engaging with and removing the cap 91, allowing for smooth attachment and removal operations. In this embodiment, the tip of the notch setting section 10 is the inclined curved surface 23A of the tip-side notch section 20A, and the back surface (the surface without the notch groove) of the claw section 21A of the tip-side notch section 20A is the inclined curved surface 33B of the notch section 20B on the operating section side, so that the two notches 20A and 20bB are continuous.

Here, the two notches 20A and 20B are formed in different sizes and shapes so as to be widely compatible with different types of microtubes 90. In this example, the notch 20A on the tip side is small in size (capacity) and is formed to be suitable for a type of microtube 90 commonly found in multiple tubes, in which the upper surface of the cap 91 protrudes 93 from the upper surface of the lip protrusion 92. The widths of the claw portion 21A and the cap support portion 22A are formed small at 5 mm so as not to interfere with the adjacent cap 91 of the multiple tube when opening the cap, and the height of the notch groove 24A is set to 3 mm so that the protrusion 93 on the upper surface of the cap can be accommodated in the gap between the upper surface of the claw portion 21A and the surface that becomes the cap support portion 22A. In addition, the length of the notch formed by the notch 20A and the inclined curved surface 23A, that is, the length from the rising part of the claw portion 21A, including the cap support portion 22A, to the end point of the inclined curved surface 23A, is made to be about 10 mm to fit small-sized microtubes 90.

On the other hand, the notch 20B on the operating part side is relatively large in size (capacity), and is suitable for locking type microtubes with a flat upper surface of the cap 91 and an inclined lower surface of the lip projection 92. To ensure reliable engagement with the lip projection 92 when opening the cap, the width of the claw 21B is formed to be as large as 15 mm, the same as the width of the operating part 30, and the height of the notch groove 24B (the distance between the upper surface of the claw 21B and the surface that becomes the cap support part 22B) is set to 2 mm, which is narrower than the notch groove 24A on the tip side, since there is no projection on the upper surface of the cap. The length of the cap support part 22B is also formed to be 21 mm, which is suitable for microtubes that are larger in size than the tip side. The width and length of the notch 20B also correspond to the width and length of the notch setting portion 10, and the tip side of the notch setting portion 10 is formed to be narrower than the operation side, and is formed as a symmetrical fan shape 25 with a gradually increasing diameter from the claw portion 21A of the notch 20A on the tip side to the claw portion 21B of the notch 20B on the operation side. In this way, the tip side notch 20A is formed to be narrow and short, and the operation side 20B is formed to be wide and long, so that the tip side notch 20A is less likely to interfere when opening the cap with the notch 20B on the operation side.

In addition, if the depth of the notch grooves 24A, 24B of each notch portion 20A, 20B is too long, there is a possibility that it may come into contact with the opening fitting portion 911 of the cap 90 or other parts that may come into contact with the sample when engaged, causing contamination. Therefore, the depth was set to 2 mm so that it does not come into contact with the opening fitting portion 911, i.e., so that it engages halfway with the lip protrusion 92, but is not so short that it causes problems when opening the cap.

One side of the gap that becomes the notch groove 24A of the notch portion 20A on the tip side is formed as a wall 211. This wall 211 is provided as a stopper to prevent the lip protrusion 92, which is small in size, from coming off this notch groove 24A due to hand vibration or the like when engaging with it. On the other hand, the notch groove 24B of the notch portion 20B on the operating part side is wide enough for engagement, so this wall 211 is not necessary.

In addition, the boundary surface (the surface of the notch groove 24A side of the attachment part of the claw part 21A) of the gap that becomes the notch groove 24A on the tip side with the notch setting part 10 is formed as an R-forming surface 212. This allows the volume of the groove 24A to be made small and the depth to be made shallow, and prevents the lip protrusion 92 of the cap 90 from entering the notch groove 24A at an angle or otherwise entering too deeply into the groove when or after the cap 90 is opened, thereby reducing the possibility that the tip of the claw part 21A will come into contact with the periphery of the opening 96 of the microtube. On the other hand, the notch groove 24B of the notch part 20B on the operation part side does not require such an R-forming surface 212 because the height of the groove 24B is set small, and the lip protrusion 92 does not enter too deeply into the groove.

Furthermore, the boundary surface between the side of each claw portion 21A, 21B without the notch groove 24A, 24B and the underside of the notch setting portion 10 or the operation portion 30 is formed as a slope 26 that slopes from the notch setting portion 10 or the operation portion 30 toward the tip of the claw portion 21A, 21B. By forming it as a slope in this way, the back surface of the claw portion 21A on the tip side becomes an inclined curved surface 23B including the fulcrum of the notch portion 20B on the operation portion side as described above, while the slope 26 from the back surface of the claw portion 21B on the operation portion side to the underside of the operation portion 30 becomes an easy-to-hold gripping surface that does not get caught on fingers when gripping. In addition, the back surface of the notch setting portion 10 is formed as a curved surface 27 that curves gently from the back surface of the operation portion 30 toward the back side. By forming it in this way, it is ensured that the notch 20A on the tip side does not interfere when opening the cap using the notch 20B on the operating part side.

Figure 4 shows how the cap 91 of a microtube 90 is opened using this embodiment of the cap removal tool, where A shows how the cap of a small-sized microtube, such as a multiple-type, with a protrusion on the top surface of the cap is opened using the notch 20A on the tip side, and B shows how the cap of a relatively large-sized, lock-type microtube with a flat top surface is opened using the notch 20B on the operating part side.

When using this device to open the cap 91 of a microtube 90, it is preferably used together with a micropipette and is used when manually opening each tube one by one. Usually, the operating part 30 of this device is held between two fingers of the dominant hand, which has the least effect on the gripping operation of the micropipette, and while holding the micropipette in the same hand, the cap 91 of the microtube 90 held in the opposite hand is opened. That is, the lip projection 92 of the cap 90 is engaged with the notch 20 of this device, and either the notch 20 on the tip side 20A (Figure A) or the ring side 20B (Figure B) is selected depending on the shape of the tube.

When the notches 20A and 20B engage with the lip projection 92, the upper surfaces of the claws 21A and 21B enter halfway into the lower surface of the lip projection 92, and the contact surface becomes the point of action for opening the cap, the part of the cap support parts 22A and 22B that contacts the upper surface of the cap becomes the fulcrum for opening, and the operating part 30 held between the fingers becomes the force point for opening. In this case, since the fulcrum is located toward the tip side of the point of action, the cap 91 is opened by pulling the operating part 30 upward relative to the fulcrum like a bottle opener.

Figure 5 shows a perspective view of the overall configuration of the second embodiment of the present invention, and Figure 6 shows a side view and a bottom view. The microtube opener of this embodiment is composed of a notch setting part 10 formed in a plate or rod shape, two notches 20A, 20B provided on one side of the notch setting part 10, and a ring-shaped ring 40 that serves as a gripping part of the device and an operating part extending from the notch setting part 10 and a locking means for the fingers. The two notches 20A, 20B are formed in series on the tip side (distal side) 20A and the operating part side (proximal side) 20B with the notch grooves 24A, 24B facing the distal side. Note that the configuration of the notch part 20 of this embodiment is almost the same as that of the notch part 20 of the first embodiment, so a description of the common parts will be omitted.

The notch setting portion 10 in this embodiment is a plate-like or rod-like portion that protrudes from the circumferential surface of the ring 40 to one side and serves as an axis for opening the cap 91 of the microtube 90, and serves as an axis connecting the notch portion 20 including the point of action and the fulcrum and the ring 40 including the point of force. The size of the notch setting portion 10 is not specified, but the width of the notch portion 20A on the tip side is 5 mm, which is a width that does not interfere with the adjacent cap 91 when opening the multiple-type microtube 90 and does not cause inconvenience in operation, and the width of the notch portion 20B on the ring side is 10 mm, which is sufficient for engagement with the lip protrusion 92, and the transition portion 28 is formed in a tapered shape that gradually decreases in width from the ring side to the tip side. In addition, the length is formed to 35 mm, which is a length that allows two notches to be arranged in series.

The ring 40, which serves as the means for fastening the device to the fingers, is the holding part of the device and the operating part at hand, and is formed as a ring 40 of a size that is inserted on the finger like a ring and does not easily come off. In this example, a circular ring 40 is exemplified, but it does not have to be circular as long as it can be worn on the finger, and it may be a ring with a missing part. In addition, instead of one ring, two rings formed in a wing shape with respect to the notch setting part 10 may be worn on two adjacent fingers and the device is held between the two fingers. In this example, the width of the ring 40 is 10 mm, the same as the notch setting part 10 on the ring side, the thickness is 2 mm for easy gripping, and the inner diameter of the ring is 22 mm, which is sufficiently applicable to the fingers of an average adult male. In addition, if the ring with a missing part is made flexible so that the diameter can be changed by inserting it, it will be more versatile.

In addition, the means for fastening to the finger does not have to be a ring 40, but may be a hook-like device that can be hooked onto the finger and secured in place, or it may have a recess that conforms to the shape of the finger so that it does not easily come off the finger.

The notches 20A and 20B that engage with the lip projection 92 are omitted because they are the same as in the first embodiment, as described above.

Figure 7 shows how the cap 91 of a microtube 90 is opened using the cap removal device of this embodiment. As in the first embodiment, A shows how the cap 91 of a small-sized microtube 90 is opened using the notch 20A on the tip side, and B shows how the cap 91 of a relatively large, lock-type microtube 90 is opened using the notch 20B on the ring side.

As with the first embodiment, the cap 91 of the microtube 90 can be opened manually one tube at a time using this embodiment. Normally, the micropipette is held in the dominant hand, and the ring 40 of this capping tool is inserted on the finger of the same hand, while the microtube 90 held in the opposite hand is opened. In this case, the ring 40 is attached to a finger that has minimal effect on the holding and operation of the micropipette. Then, the lip projection 92 of the cap 91 is engaged with the notches 20A and 20B of this tool, and either the notch 20 on the tip side (Figure A) or the ring side (Figure B) is selected depending on the shape of the tube 90.

When the lip protrusion 92 engages with the notch grooves 24A, 24B of the notches 20A, 20B, the contact points between the lip protrusions 92 on the upper surfaces of the claws 21A, 21B become the point of action for opening the bottle, a part of the contact points on the upper surface of the cap of the cap support parts 22A, 22B becomes the fulcrum for opening the bottle, and the ring 40 worn on the finger becomes the force point for opening the bottle. In this case, since the fulcrum is located toward the tip side of the point of action, the ring 40 is pulled upward relative to the fulcrum like a bottle opener to open the bottle.

Figure 8 is a perspective view of the overall configuration of a third embodiment of this embodiment, Figure 9 shows a side view and a bottom view, and Figure 10 shows an enlarged view of the notch of this embodiment. The microtube capping device of this embodiment is composed of a notch setting part 50 formed in a plate or rod shape, a ring 40 that is inserted into the finger and serves as the holding and operating part of the device, and a connecting movable part 70 that can freely change the horizontal angle of the notch setting part 50 relative to the ring 40. The notch setting part 50 is formed with a claw part 61 that forms a notch groove 64 at the tip part toward the ring side as the notch part 60, and cap support parts 62A and 62B that are provided at two different lengths from the claw part 61.

The notch setting portion 50 is a plate-like or rod-like axial rod for opening the cap, which extends outward from the peripheral surface of the ring 40, which serves as the operating portion, so that the surface including the tangent to the ring 40 forms the back surface 52. The size of the notch setting portion 50 is not specified, but the narrow diameter portion is formed to a width of 5 mm so as not to interfere with the adjacent cap 91 when opening the multiple-type microtube 90 and to provide a width that does not cause inconvenience in operation, and the length is formed to about 25 mm (from the tip to the end point of the inclined curved surface 63B) so that it can be adapted to the length of the cap 91 of a relatively large microtube 90.

The ring 40, which serves as the means for fastening to the finger, is formed as a ring 40 that is worn on the finger like a finger ring, similar to the second embodiment, and has a width of 5 mm, a thickness of 2 mm, and an inner diameter of 22 mm, similar to the second embodiment. In this example, a circular ring 40 is exemplified, but it may have a shape other than this, or may be one as described in the second embodiment.

The notch portion 60 is formed in such a manner that the claw portion 61 protrudes in a hook shape toward the ring at the tip of the notch setting portion 50, forming a notch groove 64. The lower surface of the notch setting portion 50, which abuts against the upper surface of the cap 90 when the notch groove 64 engages with the lip protrusion 92 of the cap 90, is the cap support portion 62A, 62B, and is defined together with the claw portion 61 as the notch portion 60.

The lower surface of the notch setting portion 50 is formed by protruding an inclined curved surface 63 that slopes downward on the surface located opposite the claw portion 61 between the cap support portions 62A and 62B. In this embodiment, the inclined curved surface 63 is formed at two positions at different lengths from the claw portion 61 so that it can be widely adapted to different types of microtubes 90. This allows one claw portion 61 to be shared by multiple microtubes 90 of different sizes (cap widths).

The two inclined curved surfaces 63A and 63B are the first inclined curved surface 63A on the side closer to the claw portion 61, and the length from the claw portion 61 is set to 10 mm to fit the small-sized cap 91 found in the multi-type microtube 90. The height of the notch groove 94 is set to 3 mm to fit a cap with a protrusion 93 on the upper surface. On the other hand, the second inclined curved surface 63B on the side farther from the claw portion 61 is set to 25 mm in length from the claw portion 61 to fit a relatively large-sized microtube 90. In addition, the inclination width of the first inclined curved surface 63A is set to a step, the cap support portion 62B is formed, and the step difference and the notch setting portion 50 are formed thick so that the height between the upper surface of the claw portion 61 and the cap support portion 62B is set smaller by the inclination of the first inclined curved surface 63A so that it can fit a cap with a flat upper surface. This allows microtubes 90 of different sizes and shapes to be used with a single common claw portion 61.

As in the first and second embodiments, the depth of the claw portion 61 of the notch portion 60 is set to 2 mm so that it does not come into contact with the opening fitting portion 911 and does not cause any problems when opening the cap, since if it is too long, contamination may occur.

As described above, the movable connection part 70 is a movable connection part that allows the horizontal angle of the notch setting part 50 relative to the ring 40, which serves as the operating part, to be freely set. In this embodiment, the extension parts 41, 51 are respectively extended from the notch setting part 50 and the ring 40 (both 5 mm wide) in a manner that gradually increases in width to form circular connection surfaces 70A, 70B with a diameter of approximately 15 mm. The circular connection surfaces 70A, 70B are overlapped with each other, and the central axis of the overlapped circles is tightened or loosened with tightening means 71 such as a bolt and nut, allowing the desired angle to be set and fixed at the set angle.

In this embodiment, the notch setting part 50 and the operating part 40 can be freely adjusted to any desired mounting angle, but a specific angle may be preset, in which case it is preferable that they are molded integrally without the movable connecting part 70. If the mounting angle is set to 90°, the device can open the cap 91 by operating it horizontally, rather than axially. If the angle is set in reverse, the device can be used by both right-handed and left-handed people.

Figure 11 shows a method of opening a cap using the cap opener of this embodiment, where A shows how to open a small microtube cap with a protruding top surface, and B shows how to open a large lock-type cap with a flat top surface.

As with the first and second embodiments, the cap 91 of this embodiment is preferably used when manually operating each micropipette used together. When the ring 40 of this device is inserted on the finger and the claw portion 61 at the tip of this device is engaged with the lip protrusion 92 of the cap 91, depending on the size of the microtube 90, the top surface of the cap comes into contact with either the first cap support portion 62A (Figure A) located on the tip side or the second cap support portion 62B (Figure B) located on the ring side, which serves as a fulcrum when opening the cap.

When the lip projection 92 engages with the notch 60, the contact point between the upper surface of the claw portion 61 and the lower surface of the lip projection 92 becomes the point of action for opening the cap, the contact surface of the cap support portions 62A and 62B with the cap 91 becomes the fulcrum for opening the cap, and the ring 40 worn on the finger becomes the force point for opening the cap. In this case, since the point of action is located toward the tip side of the fulcrum, the ring 40 is pressed downward against the fulcrum to open the cap.

10. 50. Cutout setting portion 20. 60. Cutout portion 21. 61. Claw portion 211. Wall 212. R-forming surface 22. 62. Cap holding portion 23. 63. Inclined curved surface 24. 64. Cutout groove 26. Slope 30. Operation portion (plate)
40. (Operation part) Ring 70. Movable connection part 90. Microtube 91. Cap 92. Lip protrusion 93. (Cap upper surface) Protrusion 96. Opening

Claims (17)

A capping tool for manually opening caps of microtubes using the principle of leverage.
a claw portion that is an engagement portion with a lip protrusion provided on the edge portion of the cap and includes a point of application for opening the cap, and a notch portion that is an abutment surface with the upper surface of the cap and includes a fulcrum for opening the cap;
A plate-shaped or rod-shaped notch setting portion that serves as a setting portion for the notch portion;
and an operation portion including a force point for opening the cap, the force point extending from the notch setting portion,
A microtube cap removal device characterized in that the notch portions are provided in multiple locations distal to the operating portion and have different sizes and shapes, and the multiple notch portions are arranged in series in the axial direction of the notch setting portion . The microtube opener of claim 1, in which the claw of the notch protrudes from the notch setting portion in a hook shape, and the gap between the notch setting portion and the claw protrudes from the notch setting portion is formed as a notch groove. The microtube opener of claim 2, in which one side of the gap that forms the notch groove of the claw portion is formed as a wall. A microtube opener according to any one of claims 2 to 3, in which the boundary surface between the claw portion and the notch setting portion and the boundary surface on the notch groove side is an inclined surface or an R-shaped surface. A microtube opener according to any one of claims 2 to 4, in which the depth of the notch groove of the claw is shorter than the lip projection of the cap. A microtube opener according to any one of claims 1 to 5, in which the lower surface of the notch setting part, located on the opposite side of the claw part, sandwiching the cap support part of the notch part, is formed to protrude downward, and the surface of the protrusion continuing from the cap support part is formed as an inclined curved surface. 7. The microtube opener according to claim 1, wherein the width and length of the notch on the tip side of said plurality of cutouts arranged in series are smaller than the width and length of the notch on the operation portion side. 7. The microtube opener according to claim 1, wherein the plurality of cutout portions arranged in series share a common tab and are provided with a plurality of cap supports. 9. The microtube opener according to claim 1 , wherein the angle of said notch setting portion in the horizontal direction with respect to said operation portion is freely variable. 9. The microtube opener according to claim 1, wherein said notch setting portion is formed at a specific angle in the horizontal direction with respect to said operation portion. 11. The microtube opener according to claim 1, wherein the notch groove of the notch portion faces the tip side, and the cap support portion is positioned on the tip side of the claw portion. 11. The microtube opener according to claim 1, wherein the notch portion has a notch groove facing the operation portion and a claw portion positioned further forward than the cap support portion. 13. The microtube opener according to claim 1, wherein said operating portion is formed in a plate shape. 13. The microtube opener according to claim 1, wherein said operating portion is provided with a locking means for engaging with a finger. 15. The microtube cap remover according to claim 14 , wherein said fastening means for engaging with a finger comprises a ring which can be inserted onto a finger, or a hook which can be hung on a finger. A microtube capping device according to any one of claims 1 to 15, wherein the boundary surface between the claw portion of the notch portion and the notch setting portion or operating portion, which is a boundary surface on the back side without a notch groove, is formed as an inclined surface that slopes from the notch setting portion or operating portion toward the tip of the claw portion . 17. The microtube opener according to claim 1, wherein a rear surface of said notch setting portion, on which said notch is not provided, is formed as a curved surface that is curved and inclined from the rear surface of the operation portion toward the rear surface.

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