CN211043270U - Air reactivity device for continuously measuring carbon material - Google Patents

Abstract

The utility model discloses an air reactivity device for continuous measurement carbon material, including backup pad, base, sample ejector pin, shock absorption mechanism, rapping mechanism, motor and guide rail, base top welding guide rail bottom, guide rail fixed connection backup pad, backup pad top fixed connection motor, the motor cup joints with shock absorption mechanism, the base top is close to guide rail left side fixed connection rapping mechanism bottom. This an air reactivity device for continuous measurement carbon material is through air pump and the extension spring that sets up, can realize drawing down fast upwards at a slow speed, shake the rapping rod simultaneously and be close to first connecting block left side and be longer than second connecting block right side, can know to push down according to lever principle and shake the power that rapping rod right side is greater than the power that shakes the rapping rod left side and pull back, further realization that can be better is drawn down fast upwards at a slow speed, and the cooperation through piston and air pump, when the extension spring will shake the rapping rod and pull back fast, the piston can not cause any hindrance to pulling back.

Description

Air reactivity device for continuously measuring carbon material

Technical Field

The utility model relates to a reactive device technical field specifically is an air reactivity device for continuous measurement carbon material.

Background

In the field of carbon material operation manufacturing, such as the field of carbon electrode operation manufacturing, a carbon material is used as a raw material or a consumable material, and the size of the residual electrode rate, the shedding rate and the reaction loss ratio of the carbon electrode directly influences the quality and the efficiency of the electrolysis process, so that the air reactivity detection of the carbon material belongs to a daily necessity item. A device for measuring the reactivity of carbon material with air, which is disclosed in patent No. CN202837132U, comprises a device shell part, a heating furnace part arranged on the device shell part, a lifting part and a rapping part, wherein the heating furnace part is positioned above the lifting part, and the lifting part is positioned above the rapping part. There is, however, a place where the rapping component thereof needs to be improved and the patent does not describe in detail how the vibrations of the motor itself are eliminated.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an air reactivity device for continuous measurement carbon material to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: an air reactivity device for continuously measuring a carbon material comprises a supporting plate, a base, a sample ejector rod, a vibration absorption mechanism, a motor and a guide rail, wherein the bottom of the guide rail is welded on the top of the base;

The vibration absorption mechanism comprises a vibration absorption shell, a first reinforcing ring, a first rubber ring, a second reinforcing ring, a second rubber ring, a first rubber pad and a second rubber pad, wherein the second rubber pad is arranged at the bottom of the motor, the motor is fixedly connected with the supporting plate through the second rubber pad, the second rubber pad is sleeved with the first rubber pad, the vibration absorption shell is arranged at the top of the first rubber pad and is sleeved with the motor, the vibration absorption shell is fixedly connected with the supporting plate through the first rubber pad, the first reinforcing ring and the second reinforcing ring are welded in the vibration absorption shell, and the first reinforcing ring and the second reinforcing ring are sleeved with the first rubber ring and the second rubber ring;

The rapping mechanism comprises a rapping rod, a first connecting block, a contact block, an air pump, an air pipe, an air cylinder, a piston rod, a second connecting block, a tension spring, a first clamping block and a second clamping block, the top of the base is close to one side of the supporting plate and is fixedly connected with the bottom of the air pump, the air pump is fixedly connected with one end of the air pipe, the other end of the air pipe is fixedly connected with the air cylinder, the air cylinder is fixedly connected with one side of the supporting rod, the other side of the supporting rod is welded with a guide rail, the air cylinder is provided with the piston, the piston is fixedly connected with one side of the piston rod, the piston rod is sleeved with the air cylinder, the other end of the piston rod is hinged with one side of the first connecting block, the other side of the rapping rod is welded with one side of the rapping rod, the rapping rod is close to the contact block and is welded with a first clamping block, the first clamping block is clamped on one side of a tension spring, the other side of the tension spring is clamped with a second clamping block, and the second clamping block is welded with the base.

Preferably, the first rubber pad and the second rubber pad are both in a ring shape and are arranged between the motor and the support plate and between the vibration absorption shell and the support plate.

Preferably, the first rubber ring and the second rubber ring are sleeved on and contacted with the motor, and the first reinforcing ring and the second reinforcing ring are distributed at the top and the bottom close to the motor.

Preferably, the air reactivity apparatus for continuously measuring carbon material is characterized in that: the piston is sleeved with the cylinder and is in clearance fit with the cylinder.

Preferably, the length of the rapping rod close to the left side of the second connecting block is larger than that of the rapping rod close to the right side of the second connecting block, and the first clamping block and the second connecting block are arranged at the bottom of the rapping rod.

Preferably, the contact block and the first connecting block are arranged at the top of the rapping rod, and the contact block is arranged at the position corresponding to the first clamping block.

Compared with the prior art, the beneficial effects of the utility model are that:

1. This an air reactivity device for continuous measurement carbon material is through air pump and the extension spring that sets up, can realize drawing down fast upwards at a slow speed, shake the rapping bar simultaneously and be close to first connecting block left side and be longer than second connecting block right side, can know according to lever principle and press down the power that shakes the rapping bar right side and be greater than the power that shakes the rapping bar left side and pull back, further realization that can be better is drawn down fast upwards at a slow speed, and the cooperation through piston and air pump, can stably provide the power of upwards shaking, when the extension spring will shake the rapping bar and pull back fast, the piston can not cause any hindrance to pulling back.

2. This an air reactivity device for continuous measurement carbon material is through the first back up collar that sets up, the second back up collar, first rubber circle and second rubber circle, can be when self produces the vibration when the motor uses, further fastening through first back up collar and second back up collar can greatly offset the motor vibration, the first rubber circle and the second rubber circle that set up simultaneously can be when motor self produces the vibration and first back up collar and second back up collar contact each other, can effectively offset the vibration of motor self each other, thereby guarantee the precision, the first rubber pad and the second rubber pad that set up simultaneously, can offset the vibration of motor and damping shell, do not conduct to the backup pad, thereby further guarantee the precision.

Drawings

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

Fig. 2 is a schematic view of the structure of the rapping mechanism, taken out;

FIG. 3 is an enlarged view of the structure at A in FIG. 1;

FIG. 4 is an enlarged view of the structure at B in FIG. 1;

Fig. 5 is an enlarged view of the structure at C in fig. 2.

In the figure: 1 supporting plate, 2 bases, 3 sample ejector rods, 4 vibration elimination mechanisms, 41 vibration elimination shells, 42 first reinforcing rings, 421 first rubber rings, 43 second reinforcing rings, 431 second rubber rings, 44 first rubber pads, 45 second rubber pads, 5 vibration beating mechanisms, 51 vibration beating rods, 511 first connecting blocks, 512 contact blocks, 52 air pumps, 53 air pipes, 54 air cylinders, 541 pistons, 542 piston rods, 55 second connecting blocks, 56 tension springs, 561 first clamping blocks, 562 second clamping blocks, 57 supporting rods, 6 motors, 7 guide rails

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: an air reactivity device for continuously measuring a carbon material comprises a supporting plate 1, a base 2, a sample ejector rod 3, a vibration absorption mechanism 4, a vibration absorption mechanism 5, a motor 6 and a guide rail 7, wherein the top of the base 2 is welded to the bottom of the guide rail 7, the guide rail 7 is fixedly connected with the supporting plate 1, the top of the supporting plate 1 is fixedly connected with the motor 6, the motor 6 is sleeved with the vibration absorption mechanism 4, the top of the base 2, close to the left side of the guide rail 7, is fixedly connected with the bottom of the vibration mechanism 5, and the top of the vibration absorption mechanism 5 is;

The vibration damping mechanism 4 comprises a vibration damping shell 41, a first reinforcing ring 42, a first rubber ring 421, a second reinforcing ring 43, a second rubber ring 431, a first rubber pad 44 and a second rubber pad 45, the bottom of the motor 6 is provided with the second rubber pad 45, the motor 6 is fixedly connected with the support plate 1 through the second rubber pad 45, the second rubber pad 45 is sleeved with the first rubber pad 44, the top of the first rubber pad 44 is provided with the vibration damping shell 41, the vibration damping shell 41 is sleeved with the motor 6, the vibration damping shell 41 is fixedly connected with the support plate 1 through the first rubber pad 44, the first rubber pad 44 and the second rubber pad 45 are both ring-shaped and are arranged between the motor 6 and the support plate 1 as well as between the vibration damping shell 41 and the support plate 1, the first reinforcing ring 42 and the second reinforcing ring 43 are welded in the vibration damping shell 41, the first reinforcing ring 42 and the second reinforcing ring 43 are sleeved with the first rubber ring 421 and the second rubber ring 431, the first rubber ring 421 and the second rubber ring 431 are in contact with the motor, first reinforcing ring 42 and second reinforcing ring 43 distribute at the top and the bottom that are close to motor 6, through the first reinforcing ring 42 that sets up, second reinforcing ring 43, first rubber circle 421 and second rubber circle 431, can be when motor 6 self produces the vibration when using, further fastening through first reinforcing ring 42 and second reinforcing ring 43 can greatly offset motor 6 vibration, the first rubber circle 421 and the second rubber circle 431 that set up simultaneously can be when motor 6 self produces the vibration and first reinforcing ring 42 and second reinforcing ring 43 contact each other, can effectively offset the vibration of motor 6 self each other, thereby guarantee the precision, first rubber pad 44 and second rubber pad 45 that set up simultaneously, can offset the vibration of motor 6 and damping shell 41, do not conduct to backup pad 1, thereby further guarantee the precision.

The rapping mechanism 5 comprises a rapping rod 51, a first connecting block 511, a contact block 512, an air pump 52, an air pipe 53, an air cylinder 54, a piston 541, a piston rod 542, a second connecting block 55, a tension spring 56, a first clamping block 561 and a second clamping block 562, wherein one side of the top of the base 2, which is close to the supporting plate 1, is fixedly connected with the bottom of the air pump 52, the air pump 52 is fixedly connected with one end of the air pipe 53, the other end of the air pipe 53 is fixedly connected with the air cylinder 54, the air cylinder 54 is fixedly connected with one side of a supporting rod 57, the other side of the supporting rod 57 is welded with a guide rail 7, the air cylinder 54 is provided with the piston 541, the piston 541 is sleeved with the air cylinder 54 and is in clearance fit with the air cylinder 54, the piston rod 541 is fixedly connected with one side of the piston rod 542, the other end of the piston rod 542 is hinged with, the other side of the second connecting block 55 is welded with the base 2, the other side of the rapping rod 51 is welded with the bottom of the contact block 512, the rapping rod 51 is close to the contact block 512 and is welded with a first clamping block 561, the first clamping block 561 is clamped on one side of a tension spring 56, the other side of the tension spring 56 is clamped with a second clamping block 562, the second clamping block 562 is welded with the base 2, the length of the rapping rod 51 close to the left side of the second connecting block 55 is larger than that of the second connecting block 55, the first clamping block 561 and the second connecting block 55 are arranged at the bottom of the rapping rod 51, the contact block 512 and the first connecting block 511 are arranged at the top of the rapping rod 51, the contact block 512 is arranged at the corresponding position of the first clamping block 561, slow and upward quick pull-down can be realized through the air pump 52 and the tension spring 56, meanwhile, the left side of the rapping rod 51 close to the first connecting block 511 is longer than the right side of the second connecting block 55, the further realization that can be better is drawn down fast upwards slowly, and through the cooperation of piston 541 and air pump 52, can stably provide the power of upwards shaking, when extension spring 56 will shake pole 51 and draw back fast, piston 541 can not cause any hindrance to pulling back.

When the vibration damping device is used, air is rapidly conveyed into the air cylinder 54 through the air pipe 53 by the air pump 52, the piston 541 moves downwards through the piston 541, so that the piston rod 542 is driven to move downwards, the piston rod 542 and the first connecting block 511 move, the second connecting block 55 and the rapping rod 51 move, so that the contact block 512 raps the sample ejector rod 3, when the air in the air cylinder 54 disappears, the rapping rod 51 is rapidly pulled back under the action of the tension spring 56, and meanwhile, the motor 6 counteracts the self vibration of the motor 6 under the first reinforcing ring 42, the second reinforcing ring 43, the first rubber ring 421, the second rubber ring 431, the first rubber pad 44 and the second rubber pad 45.

In summary, the air reactivity device for continuously measuring the carbon material can realize slow upward and fast pull-down through the air pump 52 and the tension spring 56, meanwhile, the left side of the rapping rod 51 close to the first connecting block 511 is longer than the right side of the second connecting block 55, the force for pressing down the right side of the rapping rod 51 is known to be larger than the force for pulling back the left side of the rapping rod 51 according to the lever principle, slow upward and fast pull-down can be better realized, the upward and fast shaking force can be stably provided through the cooperation of the piston 541 and the air pump 52, when the rapping rod 51 is pulled back fast through the tension spring 56, the piston 541 cannot cause any obstruction to pull back, through the arrangement of the first reinforcing ring 42, the second reinforcing ring 43, the first rubber ring 421 and the second rubber ring 431, when the motor 6 vibrates in use, the vibration of the motor 6 can be greatly counteracted through the further fastening of the first reinforcing ring 42 and the second reinforcing ring 43, first rubber circle 421 and the second rubber circle 431 that set up simultaneously can effectively offset the vibration of motor 6 self each other when motor 6 self produces vibration and first reinforcing ring 42 and the mutual contact of second reinforcing ring 43 to guarantee the precision, first rubber pad 44 and the second rubber pad 45 that set up simultaneously can offset the vibration of motor 6 and damping shell 41, do not conduct to backup pad 1, thereby further guarantee the precision.

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 an air reactivity device for continuous measurement carbon material, includes backup pad (1), base (2), sample ejector pin (3), damping mechanism (4), rapping mechanism (5), motor (6) and guide rail (7), its characterized in that: the bottom of a guide rail (7) is welded on the top of the base (2), the guide rail (7) is fixedly connected with the support plate (1), the top of the support plate (1) is fixedly connected with a motor (6), the motor (6) is sleeved with the vibration absorption mechanism (4), the top of the base (2) close to the left side of the guide rail (7) is fixedly connected with the bottom of a vibration beating mechanism (5), and the top of the vibration beating mechanism (5) is provided with a sample-ejector rod (3);

The vibration absorption mechanism (4) comprises a vibration absorption shell (41), a first reinforcing ring (42), a first rubber ring (421), a second reinforcing ring (43), a second rubber ring (431), a first rubber pad (44) and a second rubber pad (45), a second rubber pad (45) is arranged at the bottom of the motor (6), the motor (6) is fixedly connected with the support plate (1) through the second rubber pad (45), the second rubber pad (45) is sleeved with the first rubber pad (44), the top of the first rubber pad (44) is provided with a vibration absorption shell (41), the vibration absorption shell (41) is sleeved with the motor (6), the vibration absorption shell (41) is fixedly connected with the support plate (1) through a first rubber pad (44), a first reinforcing ring (42) and a second reinforcing ring (43) are welded in the vibration eliminating shell (41), the first reinforcing ring (42) and the second reinforcing ring (43) are sleeved with the first rubber ring (421) and the second rubber ring (431);

The rapping mechanism (5) comprises a rapping rod (51), a first connecting block (511), a contact block (512), an air pump (52), an air pipe (53), an air cylinder (54), a piston (541), a piston rod (542), a second connecting block (55), a tension spring (56), a first clamping block (561) and a second clamping block (562), wherein the top of the base (2) is close to the bottom of the air pump (52) on one side of the supporting plate (1), one end of the air pump (52) is fixedly connected with the air pipe (53), the other end of the air pipe (53) is fixedly connected with the air cylinder (54), one side of a supporting rod (57) is fixedly connected with the air cylinder (54), a guide rail (7) is welded on the other side of the supporting rod (57), the air cylinder (54) is provided with the piston (541), one side of the piston (541) is fixedly connected with the piston rod (542), the other end of the piston rod (542) is hinged to one side of a first connecting block (511) in a hinged mode, the other side of the first connecting block (511) is welded to one side of a rapping rod (51), the rapping rod (51) is close to one side of a second connecting block (55) hinged to the first connecting block (511) in a hinged mode, the other side of the second connecting block (55) is welded to the base (2), the other side of the rapping rod (51) is welded to the bottom of a contact block (512), the rapping rod (51) is close to the contact block (512) and is welded to a first clamping block (561), the first clamping block (561) is clamped to one side of a tension spring (56), the other side of the tension spring (56) is clamped to a second clamping block (562), and the second clamping block (562) is.

2. An air reactivity device for continuous measurement of carbon material according to claim 1, wherein: the first rubber pad (44) and the second rubber pad (45) are both ring-shaped and are arranged between the motor (6) and the support plate (1) and between the vibration absorption shell (41) and the support plate (1).

3. An air reactivity device for continuous measurement of carbon material according to claim 1, wherein: the first rubber ring (421) and the second rubber ring (431) are sleeved on the motor (6) and are in contact with the motor, and the first reinforcing ring (42) and the second reinforcing ring (43) are distributed at the top and the bottom of the motor (6).

4. An air reactivity device for continuous measurement of carbon material according to claim 1, wherein: the piston (541) is sleeved with the cylinder (54) and is in clearance fit with the cylinder (54).

5. An air reactivity device for continuous measurement of carbon material according to claim 1, wherein: the length of the rapping rod (51) close to the left side of the second connecting block (55) is larger than that of the rapping rod close to the right side of the second connecting block (55), and the first clamping block (561) and the second connecting block (55) are arranged at the bottom of the rapping rod (51).

6. An air reactivity device for continuous measurement of carbon material according to claim 1, wherein: the contact block (512) and the first connecting block (511) are arranged at the top of the rapping rod (51), and the contact block (512) is arranged at the corresponding position of the first clamping block (561).

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