CN114803979A - Non-destructive laboratory glass container cork pulling device - Google Patents

Abstract

The invention discloses a non-destructive laboratory glass container cork pulling device which comprises a shell, wherein a through groove is formed in the middle of the shell, a plurality of clamping blocks used for clamping a volumetric flask are arranged at the lower end inside the through groove, the clamping blocks are driven by a rotating frame arranged on the lower end face of the shell, two observation grooves and two ascending grooves are symmetrically formed in the upper end groove wall of the through groove respectively, a first clamping plate and a second clamping plate are respectively connected inside the two ascending grooves in a sliding mode, the inner end faces of the first clamping plate and the second clamping plate are respectively and fixedly connected with a first clamping frame and a second clamping frame used for clamping a bottle cork, the first clamping plate and the second clamping plate are respectively connected with a sliding block in a sliding mode through sliding grooves formed in the first clamping plate and the second clamping plate, the sliding blocks are connected with a screw rod in a meshing mode, and the screw rod is driven by a rotating rod arranged on the outer side wall of the upper end of the shell.

Description

Non-destructive laboratory glass container cork pulling device

Technical Field

The invention relates to the technical field of experimental articles, in particular to a non-destructive laboratory glass container cork pulling device.

Background

The volumetric flask is the flat container of thin neck pear shape, has ground glass stopper, has the marking on the neck, and the volumetric flask is the accurate utensil for preparing the solution of the volume concentration of accurate certain material, all adopts the glass material generally, is common experimental apparatus in laboratories such as chemistry, biology.

However, sometimes the solution in the bottle is weak alkaline or is left for a long time after preparation, so that the plug is difficult to pull out, which is often very painful for the laboratory staff.

At present, manual cork pulling is generally adopted, but the shape of the cork and the shape of the volumetric flask cause that the manual cork pulling is not good in force application and poor in effect; and the glass material is also inconvenient to implement by excessive vibration or knocking. If the solution in the volumetric flask has low value, the volumetric flask can be immersed in hot water for a certain period of time and then subjected to cork removal, but the method easily causes the solution in the volumetric flask to be polluted; in addition, if the solution has high value, such as some drug intermediate standards, the solution can be taken out by destroying the volumetric flask, but the risk of broken glass pollution still exists. The invention provides a non-destructive laboratory glass container cork pulling device for solving the problems.

Disclosure of Invention

The invention aims to provide a nondestructive laboratory glass container cork pulling device to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a non-destructive formula laboratory glass container cork pulling device, includes the shell, open at the middle part of shell has the groove of lining up, it is equipped with a plurality of clamp splices that are used for the centre gripping volumetric flask to link up inslot portion lower extreme, the clamp splice is by the commentaries on classics frame drive that the terminal surface was equipped with under the shell, it has two observation tanks and ascending groove to link up to open respectively the symmetry on the upper end cell wall in groove, and the inside difference sliding connection in two ascending grooves has first splint and second splint, respectively fixedly connected with is used for the first double-layered frame and the second double-layered frame of centre gripping bottle plug on the interior terminal surface of first splint and second splint, first splint and second splint all have the slider through the spout sliding connection that has opened on it, the slider is connected with the screw rod meshing, the screw rod is driven by the bull stick that is equipped with on the lateral wall of shell upper end.

Preferably, the outer side wall of the clamping block is fixedly connected with a mandril, the outer end of the mandril penetrates through the groove wall of the through groove and extends into a hollow groove formed in the shell, and is movably connected with a chute formed in the inner side surface of the rotating ring, the rotating ring is rotatably connected in the hollow groove, the lower side groove wall of the hollow groove is meshed with the rotating frame, and the rotating frame is connected with a fixing rod and a rotating ring in a sliding manner through the upper end of the rotating frame.

Preferably, a circular plate is fixedly sleeved on the side wall of one end, located inside the empty groove, of the ejector rod, and a spring is connected between the circular plate and the wall of the empty groove.

Preferably, the inside of clamp splice is equipped with the heating block that is used for heating the volumetric flask bottle, and the heating block is connected with the external power electricity of conducting rod through fixedly connected with on its lateral wall and is connected.

Preferably, the upper end of screw rod extends to the inside and the fixedly connected with gear of the annular that has on the shell upper end lateral wall, and the gear is connected with the ring gear meshing with the inside rotation of annular and is connected, fixed connection bull stick on the lateral wall of ring gear.

Preferably, the shape of slider is "worker" font, and a plurality of archs of fixedly connected with on its lower extreme inside wall, just the both sides that are located the spout on the lower lateral wall of first splint and second splint all open a plurality of draw-in grooves that correspond each other with the arch.

Compared with the prior art, the invention has the beneficial effects that: the bottle stopper is characterized in that the rotating frame is arranged on the bottle stopper, the clamping blocks are arranged on the rotating frame, the rotating frame is matched with the clamping blocks, the clamping blocks can move towards the middle of the through groove simultaneously by rotating the rotating frame, so that the bottle stopper can be clamped by clamping the bottle stopper, the first clamping frame and the second clamping frame can clamp the upper part of the bottle stopper by pushing the first clamping plate and the second clamping plate, and then the rotating rod can be rotated, so that the first clamping frame and the second clamping frame are driven by the first clamping plate and the second clamping plate to ascend respectively, and the purpose of pulling out the bottle stopper is achieved.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a cross-sectional view of the present invention;

FIG. 3 is an exploded view of the tooth ring and ring groove of the present invention;

FIG. 4 is an exploded view of the first and second clamping frames of the present invention;

FIG. 5 is a schematic view of the connection of the first clamping frame and the second clamping frame according to the present invention;

FIG. 6 is a schematic view of the underside of the first and second clamping plates of the present invention;

FIG. 7 is a schematic view of the inner structure of the camera obscura of the present invention;

FIG. 8 is a schematic view of the connection of the chute and the ejector pin of the present invention;

FIG. 9 is an exploded view of the bezel and swivel of the present invention;

FIG. 10 is a schematic view of the first and second clamping frames of the present invention in use;

FIG. 11 is an enlarged view taken at A of FIG. 2 according to the present invention.

In the figure: 1. the device comprises a shell, 2, a through groove, 3, a clamping block, 4, a rotating frame, 5, an observation groove, 6, a lifting groove, 7, a first clamping plate, 8, a second clamping plate, 9, a first clamping frame, 10, a second clamping frame, 11, a sliding groove, 12, a sliding block, 13, a screw rod, 14, a rotating rod, 15, a push rod, 16, an empty groove, 17, a rotating ring, 18, a chute, 19, a fixing rod, 20, a circular plate, 21, a spring, 22, a heating block, 23, a conductive rod, 24, a ring groove, 25, a gear, 26, a toothed ring, 27, a protrusion, 28, a clamping groove, 29, a conductive ring, 30, a communication groove, 31, a through hole, 32, a hidden groove, 33, an abdicating groove, 34, a plug handle, 35 and a bottle plug.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-11, the present invention provides a technical solution: a non-destructive laboratory glass container cork pulling device comprises a shell 1, wherein a through groove 2 is formed in the middle of the shell 1, the bottleneck of a volumetric flask can be inserted into the through groove 2, a plurality of clamping blocks 3 used for clamping the volumetric flask are arranged at the lower end inside the through groove 2, the inner side surfaces of the clamping blocks 3 are cambered surfaces and can well clamp the bottleneck of the volumetric flask, the clamping blocks 3 are made of hard materials, the outer parts of the clamping blocks are coated with a layer of soft rubber, the volumetric flask can be prevented from being damaged when the clamping blocks 3 stably clamp the volumetric flask, the clamping blocks 3 are driven by a rotating frame 4 arranged on the lower end surface of the shell 1, the plurality of clamping blocks 3 can simultaneously move towards the middle of the through groove 2 by rotating the rotating frame 4, so that the clamping blocks 3 clamp the volumetric flask, two observation grooves 5 and two ascending grooves 6 are respectively and symmetrically formed in the upper groove wall of the through groove 2, and the two observation grooves 5 and the two ascending grooves 6 are sequentially and crossly distributed on the groove wall of the through groove 2, the insides of the two ascending grooves 6 are respectively connected with a first clamping plate 7 and a second clamping plate 8 in a sliding manner, the inner end faces of the first clamping plate 7 and the second clamping plate 8 are respectively fixedly connected with a first clamping frame 9 and a second clamping frame 10 which are used for clamping a bottle stopper 35, the first clamping frame 9 and the second clamping frame 10 are both in a U shape, the thickness of the vertical rod of the first clamping frame 9 is larger than that of the vertical rod of the second clamping frame 10, the thickness of the closed end of the first clamping frame 9 is equal to that of the closed end of the second clamping frame 10, the two vertical rods of the second clamping frame 10 can be inserted into a communicating groove 30 arranged in the two vertical rods on the first clamping frame 9 (as shown in figure 5), one side groove wall and one end groove wall of the communicating groove 30 are communicated with the outside, after the second clamping frame 10 is inserted into the first clamping frame 9, the transverse rod on the second clamping frame 10 and the transverse rod on the first clamping frame 9 can be matched with each other to clamp the upper half part of the bottle stopper 35, open on the second splint 8 and have the groove of stepping down 33, can let first splint 9 move on the second splint 8 smoothly (as shown in fig. 5), first splint 7 and second splint 8 all have slider 12 through the 11 sliding connection of spout that have opened on it, slider 12 is connected with the meshing of screw rod 13, screw rod 13 is driven by bull stick 14 that is equipped with on the shell 1 upper end lateral wall, and bull stick 14 can make screw rod 13 rotate when rotating around shell 1 pivoted, and screw rod 13 rotates and to make corresponding slider 12 drive first splint 7 and second splint 8 simultaneously and rise.

Specifically, the outer side wall of the clamping block 3 is fixedly connected with a push rod 15, the outer end of the push rod 15 penetrates through the wall of the through groove 2 and extends into an empty groove 16 formed in the shell 1, and is movably connected with a chute 18 formed on the inner side surface of a rotating ring 17, the rotating ring 17 is rotatably connected in the empty groove 16, the number of the chute 18 is the same as that of the clamping blocks 3, the rotating ring 17 is rotated clockwise as shown in fig. 8, the chute wall of the chute 18 can extrude the push rod 15, so that the push rod 15 drives the clamping block 3 to move towards the middle part of the through groove 2, so that the clamping block 3 clamps the bottleneck of the volumetric flask, the rotating ring 17 is rotatably connected in the empty groove 16, the lower side wall of the empty groove 16 is engaged with the rotating frame 4, as shown in fig. 3, a through circular groove is formed on the lower side wall of the empty groove 16, an internal thread is formed on the inner side wall of the rotating frame 4 and is engaged with the circular groove wall of the lower side wall of the empty groove 16, the rotating frame 4 is connected with the rotating ring 17 in a sliding mode through a fixing rod 19 fixedly connected with the upper end of the rotating frame 4, the upper end of the fixing rod 19 extends into a through hole 31 formed in the rotating ring 17, and the rotating frame 4 can drive the rotating ring 17 to rotate through the fixing rod 19 when rotating (when the rotating frame 4 rises, the fixing rod 19 only can rise in the through hole 31 and cannot contact with and drive the rotating ring 17 to rise).

Because the rotating frame 4 is meshed with the circular groove, the angle of the rotating frame 4 can be kept unchanged without external force after the rotating frame rotates to any angle, so that the rotating ring 17 can not rotate randomly after rotating to any angle, the inclined groove 18 can stably drive the clamping block 3 to move inwards, and the volumetric flask bottle body can be clamped.

In order to be able to take the device off the volumetric flask better after the use, a spring 21 is provided, specifically, a circular plate 20 is fixedly sleeved on a side wall of one end of the push rod 15 positioned inside the empty groove 16, and a spring 21 is connected between the circular plate 20 and a groove wall of the empty groove 16, one end of the spring 21 is fixedly connected with the circular plate 20, and the other end is fixedly connected with a groove wall of the empty groove 16, the spring 21 can give a certain elastic force to the push rod 15 to make it move towards the inside of the empty groove 16, when the push rod 15 is not extruded by the inclined groove 18 any more, the push rod 15 can drive the clamping block 3 to move towards a central position far away from the through groove 2 under the elastic force of the spring 21, so that the device can be taken off the volumetric flask well after the use.

In order to make the bottle plug 35 more easily pulled up, the heating block 22 is arranged to heat the bottle neck, specifically, the heating block 22 for heating the bottle body of the volumetric bottle is arranged inside the clamping block 3, and the heating block 22 is electrically connected with the external power supply of the conducting rod 23 through being fixedly connected on the outer side wall thereof, the heating block 22 can heat the bottle neck part of the volumetric bottle to generate slight thermal expansion and cold contraction on the bottle neck part, so that the bottle plug 35 can be more easily pulled out, each heating block 22 is connected with two conducting rods 23, the two conducting rods 23 extend into the shell 1 through the wall of the through groove 2 to be provided with the hidden groove 32 and are respectively movably connected with the two conducting rings 29 inside the hidden groove 32, the two conducting rings 29 are respectively connected with the positive and negative poles of the external power supply, and form a form with the conducting rings 29 when the conducting rod 23 moves along with the heating brush block 22 (clamping block 3), the heating block 22 can keep the circuit smooth, the heating block 22 is the prior art, and the structure and the working principle are not the technical characteristics of the invention, so the description is not needed, for example, the electric warmer which is widely used at present,

specifically, the piece 22 that generates heat is metallic texture, and its inside heater strip circular telegram back of being equipped with produces heat, and the soft rubber of the outer parcel of the piece 22 that generates heat, metallic texture's the piece 22 that generates heat play certain intensity and can let the bottleneck that outer rubber can closely laminate the volumetric flask to the bottleneck that the piece 22 that generates heat can transmit for the volumetric flask fast through its outer rubber film of cladding of metal possesses dual function.

Specifically, the upper end of the screw 13 extends to the inside of the annular groove 24 formed in the outer side wall of the upper end of the housing 1, the gear 25 is fixedly connected with the gear 25, the gear 25 is connected with the annular groove 24 in a rotating manner in a meshing manner, a plurality of teeth are arranged on the inner side wall of the gear 26, the two gears 25 can synchronously rotate by rotating the gear 26, so that the two screws 13 rotate, the two rotating rods 14 are symmetrically connected to the outer side wall of the gear 26, and the gear 26 can rotate by rotating the rotating rods 14.

In order to make the first splint 7 and the second splint 8 rise more stably, be equipped with arch 27 on slider 12, specifically speaking, slider 12's shape is "worker" font, and a plurality of archs 27 of fixedly connected with on its lower extreme inside wall, just the both sides that are located spout 11 on the lower lateral wall of first splint 7 and second splint 8 all open a plurality of draw-in grooves 28 that correspond each other with arch 27, and slider 12 can drive first splint 7 and second splint 8 and rise when rotating screw 13, and the lower extreme lateral wall of slider 12 will exert certain pressure to first splint 7 and second splint 8 this moment to can make protruding 27 and the inseparable joint of draw-in groove 28 together, can make first splint 7 and second splint 8 can not random slip when rising like this.

The 3-piece stopper 35 of fig. 10 is the stopper 35 of most commercial volumetric flasks.

The working principle is as follows: when the device is used, the shell 1 is sleeved on the bottleneck of a volumetric flask, the positions of the first clamping frame 9 and the second clamping frame 10 are determined by observing the groove 5, the first clamping frame 9 and the second clamping frame 10 are positioned below the stopper handle 34 of the flask, then the rotating frame 4 is rotated clockwise while the shell 1 is held, so that the clamping block 3 clamps the bottleneck of the volumetric flask (at the moment, the heating block 22 in the clamping block 3 is electrified to heat the bottleneck), then the first clamping plate 7 and the second clamping plate 8 are pushed towards the middle part of the groove 2 at the same time, the plug handle 34 is clamped by the first clamping frame 9 and the second clamping frame 10 through the first clamping frame 9 and the second clamping frame 10, then the rotating rod 14 can be rotated clockwise, the toothed ring 26 drives the gear 25 to rotate clockwise, so that the screw 13 also rotates clockwise, then the first clamping plate 7 and the second clamping plate 8 drive the first clamping frame 9 and the second clamping frame 10 to ascend respectively, and the upward pulling force is improved through the transmission between teeth and the meshing of the screw 13, realizing plug pulling; after the cork is removed, the rotating frame 4 is rotated anticlockwise to enable the clamping block 3 not to clamp the bottleneck of the volumetric flask, and at the moment, the device can be taken down from the volumetric flask.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a non-destructive formula laboratory glass container cork pulling device, includes through groove (2) in shell (1), shell (1) middle part, its characterized in that: a plurality of clamping blocks (3) used for clamping the volumetric flask are arranged in the through groove (2), the clamping blocks (3) are driven by the rotating frame (4) to move simultaneously, two observation grooves (5) and two ascending grooves (6) are symmetrically arranged on the groove wall of the through groove (2) respectively, the two observation grooves (5) and the two ascending grooves (6) are sequentially distributed on the groove wall of the through groove (2) in a crossed manner, a first clamping plate (7) and a second clamping plate (8) which are U-shaped are respectively connected inside the two ascending grooves (6) in a sliding manner, the inner end surfaces of the first clamping plate (7) and the second clamping plate (8) are respectively and fixedly connected with a first clamping frame (9) and a second clamping frame (10) which are used for clamping the bottle stopper, and two vertical rods of the second clamping frame (10) can be inserted into communication grooves (30) formed in the two vertical rods on the first clamping frame (9) to be matched with each other to clamp the upper half part of the bottle stopper (35);

the first clamping plate (7) and the second clamping plate (8) are both connected with a sliding block (12) in a sliding way through a sliding groove (11) formed on the first clamping plate and the second clamping plate, the slide block (12) is meshed with the screw rod (13), the screw rod (13) is driven by a rotating rod (14) arranged on the outer side wall of the upper end of the shell (1) to drive the first clamping frame (9) and the second clamping frame (10) to clamp the bottle stopper to be upwards separated from the volumetric flask, the outer side wall of the clamping block (3) is fixedly connected with a mandril (15), the outer end of the mandril (15) penetrates through the wall of the through groove (2) and extends into a hollow groove (16) formed in the shell (1), and is movably connected with a chute (18) arranged on the inner side surface of the rotating ring (17), the rotating ring (17) is rotatably connected inside the empty groove (16), the lower side groove wall of the empty groove (16) is meshed with the rotating frame (4), and the rotating frame (4) is connected with the rotating ring (17) in a sliding manner through a fixed rod (19) fixedly connected with the upper end of the rotating frame;

the heating block (22) used for heating the bottle body of the volumetric flask is arranged inside the clamping block (3), the heating block (22) is electrically connected with an external power supply through a conducting rod (23) fixedly connected to the outer side wall of the heating block (22), two conducting rods (23) are connected to each heating block (22), the two conducting rods (23) penetrate through the wall of the through groove (2) and extend into a dark groove (32) formed inside the shell (1), the two conducting rods are movably connected with the two conducting rings (29) inside the dark groove (32), the two conducting rings (29) are respectively connected with the positive pole and the negative pole of the external power supply, and when the conducting rod (23) moves along with the heating block (22), the conducting rings (29) form an electric brush, so that the heating block (22) keeps the circuit smooth.

2. A non-destructive laboratory glass container cork-pulling apparatus according to claim 1, characterized in that: the side wall of one end, positioned inside the empty groove (16), of the ejector rod (15) is fixedly sleeved with a circular plate (20), and a spring (21) is connected between the circular plate (20) and the wall of the empty groove (16).

3. A non-destructive laboratory glass container cork-pulling apparatus according to claim 1, characterized in that: open on the downside cell wall of dead slot (16) and have a circular slot that runs through, the upper end of dead lever (19) extends to and opens some through-hole (31) on swivel (17) to let swivel (4) drive swivel (17) through dead lever (19) and rotate in the pivoted, just it has internal thread and circular slot cell wall intermeshing on dead slot (16) downside cell wall to open on the inside wall of swivel (4), so that swivel (17) can not rotate at will after rotating arbitrary angle.

4. A non-destructive laboratory glass container cork-pulling apparatus according to claim 1, characterized in that: the heating block (22) is made of metal, and soft rubber is wrapped outside the heating block (22).

5. A non-destructive laboratory glass container cork-pulling apparatus according to claim 1, characterized in that: the upper end of screw rod (13) extends to inside and fixedly connected with gear (25) of the annular (24) that open on shell (1) upper end lateral wall, and gear (25) and annular (24) internal rotation are connected with ring gear (26) meshing connection, fixed connection bull stick (14) on the lateral wall of ring gear (26).

6. A non-destructive laboratory glass container cork-pulling apparatus according to claim 1, characterized in that: the shape of slider (12) is "worker" font, and fixedly connected with a plurality of archs (27) on its lower extreme inside wall, just be located both sides of spout (11) and all opened a plurality of draw-in grooves (28) that correspond each other with arch (27) on the lower lateral wall of first splint (7) and second splint (8).

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