CN115307829B - Butyronitrile gloves quality testing device - Google Patents

Abstract

The application provides a butyronitrile gloves quality testing device relates to butyronitrile gloves, including the frame, the surface of frame is equipped with rotary mechanism, locates the sleeve that a plurality of equidistance in the rotary mechanism outside distributed and arch down. This application is through the rotary mechanism that sets up, rotatory mechanism, actuating mechanism, the mechanism of aerifing mutually supporting of bearing and detection mechanism, compare in the operation that traditional simple dependence is manual to carry out the gas tightness to the gloves, greatly simplified staff manual operation's flow step, fine realization mechanical automation's detection operation, improved the detection efficiency of gloves, be favorable to its batch production to detect.

Description

Butyronitrile gloves quality testing device

Technical Field

The invention relates to the field of butyronitrile gloves, in particular to a butyronitrile glove quality inspection detection device.

Background

The nitrile rubber is prepared from butadiene and acrylonitrile by an emulsion polymerization method, has excellent oil resistance, higher wear resistance and better heat resistance, and is prepared by refining and processing high-quality nitrile rubber and other additives; the butyronitrile gloves are free of protein, free of anaphylactic reaction to human skin, non-toxic, harmless, firm, durable and good in adhesion, and can be widely used in industries such as housework, electronics, chemical engineering, aquaculture, glass, food and the like, protection of factories, hospitals, scientific research and the like.

The butyronitrile gloves are products made of nitrile rubber, at present, in order to ensure the glove quality before production and delivery, the butyronitrile gloves need to be detected through a plurality of detection procedures, such as air tightness detection, tensile strength detection and the like, wherein the air tightness detection is mostly manually detected in the air tightness detection process, namely, the interior of each glove is inflated through an inflation tube, and then the inflated gloves are placed in a water tank, and whether bubbles emerge from the interior of the water tank is observed, so that whether leaks exist on the surfaces of the gloves is detected;

although the method can effectively detect whether the surface of the gloves has the leak, the gloves are manually taken, inflated, held, placed into the water tank, observed and taken out one by one, and the like, so that labor is wasted, the detection efficiency of the leak is low for batch production detection of the gloves, and the gloves cannot be well met in modern production;

therefore, the butyronitrile glove quality inspection device is improved.

Disclosure of Invention

The invention aims to provide a butyronitrile glove quality inspection device, which solves the problems that the traditional butyronitrile gloves are labor-wasting, the detection efficiency is low for batch production detection of the butyronitrile gloves, and the traditional butyronitrile gloves cannot be well satisfied with modern production through the mutual matching of a rotating mechanism, a rotating inflating mechanism, a driving mechanism, a bearing mechanism and a detection mechanism.

In order to achieve the above object, the present invention provides the following technical solutions:

a butyronitrile glove quality inspection device aims to solve the problems.

The present application is particularly such that:

including the frame, the surface of frame is equipped with rotary mechanism, locates the sleeve and the lower arch of a plurality of equidistance distributions in the rotary mechanism outside, still includes: an observation mechanism and a drying fan;

the rotary inflating mechanism comprises a rotary column rotatably arranged on the inner wall of the sleeve through a shaft seat, an inflating mechanism arranged on the surface of the rotary column and a contact mechanism communicated with one end of the inflating mechanism;

the inflation mechanism comprises an inflator fixed on the surface of the sleeve, an inflation piston clinging to the inner wall of the inflator is arranged in the inflator in a sliding mode, a push rod is fixedly connected to one side of the inflation piston, a guide push plate is arranged on the surface of the push rod in a propping mode and is fixedly connected with the positioning seat, a return spring is fixedly connected to the surface of the push rod, and the free end of the return spring is fixedly connected with the outer wall of the inflator;

the collision mechanism comprises an inflation hose connected with one end of an inflator, one end of the inflation hose is communicated with a limiting ring, an elastic hollow collision inner ring is arranged on the inner side of the limiting ring, one end of the inflation hose penetrates through the limiting ring and is communicated with the elastic hollow collision inner ring, a lifting frame is fixedly connected to the surface of the limiting ring, a telescopic rod is arranged on the surface of the lifting frame, and an upper bulge is fixedly connected to one end of the telescopic rod;

the bearing mechanism is arranged at one end of the rotating column, which is far away from the sleeve, and the abutting mechanism is arranged on the surface of the bearing mechanism so as to ensure that the sealing of the detection gas is ensured when the glove is inflated by the rotating inflating mechanism;

the bearing mechanism comprises a bearing seat communicated with one end of the rotating column, an inflation valve head is arranged on the upper surface of the bearing seat, the bearing seat is communicated with a palm die through the inflation valve head, and a plurality of gas injection grooves for discharging gas input by the inflation valve head are formed in the surface of the palm die;

the detection mechanism is arranged on one side of the base and is used for carrying out inflation detection on the butyronitrile gloves sleeved on the bearing mechanism;

the driving mechanism is arranged on the surface of the sleeve and connected with the rotating column for driving the inflating mechanism to enable the butyronitrile gloves to synchronously rotate in the observation mechanism;

the rotary mechanism comprises a rotary servo motor fixedly arranged at the center of the upper surface of the base, the output end of the rotary servo motor is fixedly connected with a top seat, a plurality of sleeves are fixedly connected with the outer side of the top seat, the rotary mechanism also comprises a plurality of side frames which are fixed on the upper surface of the base and are arranged at equal intervals and close to the rotary servo motor, the top ends of the side frames are fixedly connected with positioning seats together, and a toothed ring part is sleeved on the outer side of each positioning seat;

the tooth ring part comprises a rotating ring sleeved on the surface of the positioning seat, and a first tooth area and a second tooth area are respectively arranged on two sides of the surface of the rotating ring;

the driving mechanism comprises an inner gear sleeved on the surface of the rotary column, an outer gear is meshed on the surface of the inner gear, a suspension bracket is rotatably installed at the center of the outer gear through a bearing, a first bevel gear is coaxially arranged on the suspension bracket and the outer gear, a second bevel gear is meshed on the surface of the first bevel gear, a side gear is fixedly arranged on the surface of the second bevel gear, the bottom of the side gear is movably connected with the suspension bracket through a shaft seat, and the suspension bracket is fixedly connected with the sleeve.

As the preferred technical scheme of this application, aerify the mechanism and still include spacing subassembly, the positioning disk on push rod surface is located including the cover to spacing subassembly, the inside slip of positioning disk is equipped with the arc stopper, the one end fixedly connected with spring of arc stopper, and the one end and the positioning disk fixed connection of spring, the spacing groove of multiunit linear arrangement and with arc stopper looks adaptation is seted up to the surface equidistance of push rod, positioning disk and sleeve fixed connection.

As the preferred technical scheme of this application, detection mechanism is including being fixed in the frame surface examine test table, the last surface mounting who examines test table has the detection air pump, the output fixedly connected with air transmission corrugated hose who detects the air pump, and air transmission corrugated hose's surface is equipped with the holder, the surface mounting of holder has pneumatic push rod, and pneumatic push rod fixed mounting in the surface of examining test table, air transmission corrugated hose's top is equipped with aerifys public head, and detection mechanism still includes the female head of aerifing that is linked together with the column spinner.

As the preferred technical scheme of this application, observation mechanism is including the fixed cistern of locating frame edge, the inside of cistern is equipped with the baffle and is used for separating the inside both sides of cistern for water storage chamber and waterlogging caused by excessive rainfall chamber, the back of cistern is equipped with electric putter, electric putter and frame fixed connection.

Compared with the prior art, the invention has the following beneficial effects:

in the scheme of the application:

1. the gloves are sleeved in the bearing seat through the arranged bearing mechanism and the rotary inflating mechanism, the lower bulges and the upper bulges are matched with each other in the process that the rotary mechanism rotates at a constant speed, and the bottom of the gloves is extruded and sealed through the abutting mechanism, so that the gas in the gloves is prevented from leaking easily in the inflating process, and the problem that the bottom of the butyronitrile gloves needs to be held by hands to realize sealed inflation in manual detection in the prior art is solved;

2. through the arranged driving mechanism and the detection mechanism, the gloves which are inflated and positioned above are placed in the corresponding observation mechanisms below in the process that the rotating mechanism rotates at a constant speed, and can realize rotation reset after observation, and the problems that the gloves need to be manually placed in a water tank for observation after being inflated and water drops easily exist on the surfaces of the gloves after detection in the prior art are solved by matching the water draining cavity and the drying fan;

3. through the mutual matching of the rotating mechanism, the rotating inflation mechanism, the driving mechanism, the bearing mechanism and the detection mechanism, compared with the traditional simple manual operation of detecting the air tightness of the gloves by relying on hands, the manual operation process of workers is greatly simplified, the mechanical automatic detection operation is well realized, the detection efficiency of the leaks of the gloves is improved, and the batch production detection is facilitated.

Drawings

Fig. 1 is a schematic structural diagram of a butyronitrile glove quality inspection device provided in the present application;

fig. 2 is a schematic structural diagram of a base of the butyronitrile glove quality inspection device provided by the present application;

fig. 3 is a schematic structural view of a rotating mechanism of the butyronitrile glove quality inspection device provided by the present application;

fig. 4 is a schematic structural view of a rotary inflation mechanism of the butyronitrile glove quality inspection device provided by the present application;

fig. 5 is a schematic structural view of an inflation mechanism of the butyronitrile glove quality inspection device provided by the present application;

fig. 6 is a partial structural schematic view of a rotary inflation mechanism of the butyronitrile glove quality inspection detection device provided by the present application;

fig. 7 is an enlarged structural schematic view of a point a in fig. 6 of the butyronitrile glove quality inspection device provided by the present application;

fig. 8 is a schematic structural view of a collision mechanism of the butyronitrile glove quality inspection device provided by the present application;

fig. 9 is a schematic structural view of a driving mechanism of the butyronitrile glove quality inspection device provided in the present application;

fig. 10 is a schematic structural view of a first form and a second form of a carrying mechanism of a butyronitrile glove quality inspection device provided by the present application;

fig. 11 is a schematic top view of an observation mechanism of the butyronitrile glove quality inspection device provided in the present application;

fig. 12 is an enlarged schematic structural diagram of a portion B in fig. 1 of the butyronitrile glove quality inspection device provided by the present application;

fig. 13 is an enlarged schematic structural diagram of a portion C in fig. 1 of the butyronitrile glove quality inspection device provided by the present application.

The following are marked in the figure:

1. a machine base;

2. a rotation mechanism; 201. rotating the servo motor; 202. a top seat; 203. a side frame; 204. positioning seats; 205. a rotating ring; 206. a first tooth area; 207. a second dental area;

3. a sleeve;

4. a rotary inflation mechanism; 401. rotating the column;

402. an inflation mechanism; 4021. an inflator; 4022. an inflation piston; 4023. a push rod; 4024. a guide push plate; 4025. a return spring; 4026. positioning a plate; 4027. an arc-shaped limiting block; 4028. a spring; 4029. a limiting groove;

403. a collision mechanism; 4031. an inflation hose; 4032. a confinement ring; 4033. the elastic hollow is abutted against the inner ring; 4034. a lifting frame; 4035. a telescopic rod; 4036. an upper bulge;

5. a drive mechanism; 501. an inner gear; 502. an outer gear; 503. a suspension bracket; 504. a first bevel gear; 505. a second bevel gear; 506. a side gear;

6. a carrying mechanism; 601. a bearing seat; 602. an inflation valve head; 603. palm molding; 604. an air injection groove;

7. a detection mechanism; 701. a detection table; 702. detecting the air pump; 703. a gas transmission corrugated hose; 704. a holder; 705. a pneumatic push rod;

8. an observation mechanism; 801. a reservoir; 802. a partition plate; 803. a water storage cavity; 804. a draining cavity; 805. electric push rod

9. A drying fan;

10. and a lower bulge.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings. It is to be understood that the embodiments described are only a few embodiments of the present invention, and not all embodiments.

Thus, the following detailed description of the embodiments of the invention is not intended to limit the scope of the invention as claimed, but is merely representative of some embodiments of the invention. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

It should be noted that the embodiments of the present invention and the features and technical solutions in the embodiments may be combined with each other without conflict.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present invention, it should be noted that the terms "upper", "lower", and the like refer to orientations or positional relationships based on those shown in the drawings, or orientations or positional relationships that are conventionally arranged when the products of the present invention are used, or orientations or positional relationships that are conventionally understood by those skilled in the art, and such terms are used for convenience of description and simplification of the description, and do not refer to or imply that the devices or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

Referring to fig. 1 to 13, the present invention provides a technical solution: the utility model provides a butyronitrile gloves quality testing detection device, includes frame 1, and the surface of frame 1 is equipped with rotary mechanism 2, locates sleeve 3 and lower protruding 10 that a plurality of equidistance in the 2 outsides of rotary mechanism distribute, still includes: an observation mechanism 8 and a drying fan 9;

the rotary inflating mechanism 4 comprises a rotary column 401 which is rotatably arranged on the inner wall of the sleeve 3 through a shaft seat, an inflating mechanism 402 arranged on the surface of the rotary column 401 and a propping mechanism 403 communicated with one end of the inflating mechanism 402;

the bearing mechanism 6 is arranged at one end, far away from the sleeve 3, of the rotary column 401, and the abutting mechanism 403 is arranged on the surface of the bearing mechanism 6 so that the sealing of the detection gas is ensured when the rotary inflating mechanism 4 inflates the glove;

the detection mechanism 7 is arranged on one side of the base 1, and is used for carrying out inflation detection on the butyronitrile gloves sleeved on the bearing mechanism 6;

and the driving mechanism 5 is arranged on the surface of the sleeve 3, and is connected with the rotating column 401 and used for driving the inflating mechanism 402 so as to enable the butyronitrile gloves to synchronously rotate in the observation mechanism 8.

As shown in fig. 1, 3 and 11, the rotating mechanism 2 includes a rotating servo motor 201 fixedly installed at the center of the upper surface of the base 1, and when the rotating servo motor 201 is adjusted to drive the gloves sleeved on the carrying mechanism 6 to rotate in the observation mechanism 8 at a constant speed, the worker can see the rotating track of the gloves, and can avoid that the gloves rotate too fast to stir the water surface to generate large ripples which are not beneficial to observing bubbles, the output end of the rotating servo motor 201 is fixedly connected with a top seat 202, and a plurality of sleeves 3 are fixedly connected with the outer side of the top seat 202, the rotating mechanism 2 further includes a plurality of side frames 203 which are fixed on the upper surface of the base 1 and are close to the rotating servo motor 201, and the top ends of the plurality of side frames 203 are fixedly connected with a positioning seat 204 together, so that the positioning seat 204 can be effectively supported and can be more stable in the using process, the top seat 202 is slidably installed at the top of the positioning seat 204 to facilitate the more stable rotation of the top seat 202, and a toothed ring component is sleeved on the outer side of the positioning seat 204;

the tooth ring component includes a rotating ring 205 sleeved on the surface of the positioning seat 204, and two sides of the surface of the rotating ring 205 are respectively provided with a first tooth area 206 and a second tooth area 207.

As shown in fig. 1, 4, 5, 6, and 7, the inflation mechanism 402 includes an inflator 4021 fixed on the surface of the sleeve 3, an inflation piston 4022 closely attached to the inner wall of the inflator 4021 is slidably disposed inside the inflator 4021, one side of the inflation piston 4022 is fixedly connected to a push rod 4023, the push rod 4023, after being stressed, can drive the inflation piston 4022 to horizontally slide inside the inflator 4021 to a end far away from the push rod 4023, so as to squeeze the air therein to achieve an inflation operation, the surface of the push rod 4023 is abutted to a guide push plate 4024, the guide push plate 4024 is fixedly connected to the positioning seat 204, the surface of the push rod 4023 is fixedly connected to a return spring 4025, the free end of the return spring 4025 is fixedly connected to the outer wall of the inflator 4021, the return spring 4025 is naturally extended in an initial natural state, and the inflation piston 4022 is disposed in the middle of the inside of the inflator 4021.

As shown in fig. 4, 5, 6 and 7, as a further optimization of the present embodiment: the inflation mechanism 402 further comprises a limiting assembly, the limiting assembly comprises a positioning disc 4026 sleeved on the surface of the push rod 4023, an arc-shaped limiting block 4027 is arranged in the positioning disc 4026 in a sliding mode, one end of the arc-shaped limiting block 4027 is fixedly connected with a spring 4028, one end of the spring 4028 is fixedly connected with the positioning disc 4026, a plurality of groups of limiting grooves 4029 which are linearly arranged and matched with the arc-shaped limiting block 4027 are formed in the surface of the push rod 4023 in an equidistant mode, the positioning disc 4026 is fixedly connected with the sleeve 3, the top end of the push rod 4023 penetrates through the positioning disc 4026 to extend to the outside, the arc-shaped limiting block 4027 is pulled outwards to enable the bottom end of the arc-shaped limiting block 4027 to move upwards and break away from the corresponding limiting groove 4029, free sliding between the positioning disc 4026 and the push rod 4023 can be achieved, and under the natural state, the arc-shaped limiting block 4027 can be clamped in the corresponding limiting groove 4029 through the abutting force of the spring 4028, and the arc-shaped limiting block 4027, and the push rod 4023 can only slide in the direction far away from the inflator 4021.

As shown in fig. 1, 4, 8 and 10, the abutting mechanism 403 includes an inflation hose 4031 connected to one end of an inflator 4021, the inflation hose 4031 is a hose having good flexibility and capable of meeting bending requirements to a certain extent, one end of the inflation hose 4031 is communicated with a limit ring 4032, an elastic hollow abutting inner ring 4033 is disposed inside the limit ring 4032, one end of the inflation hose 4031 penetrates through the limit ring 4032 and is communicated with the elastic hollow abutting inner ring 4033, a lifting frame 4034 is fixedly connected to the surface of the limit ring 4032, a telescopic rod 4035 is disposed on the surface of the lifting frame 4034, one end of the telescopic rod 4035 is fixedly connected with an upper protrusion 4036, and the lifting frame 4034 and the telescopic rod 4035 are used in cooperation, so that the limit ring 4032 can only slide up and down, and the movement stability of the limit ring 4032 is ensured.

As shown in fig. 1, 9 and 10, the support mechanism 6 includes a support base 601 communicated with one end of the rotating column 401, an inflation valve head 602 is disposed on an upper surface of the support base 601, the support base 601 is provided with a palm die 603 through the inflation valve head 602, a plurality of air injection grooves 604 for discharging air input by the inflation valve head 602 are disposed on a surface of the palm die 603, and an interior of the rotating column 401 is communicated with the support base 601, so that air thereof can be sequentially input to a surface of the palm die 603 through the rotating column 401, the support base 601 and the inflation valve head 602 and discharged through the air injection grooves 604, when a glove is sleeved on the surface of the palm die 603, air discharged from the air injection grooves 604 can support the glove, thereby facilitating a subsequent detection of tightness of the detection mechanism 7, a top end of the telescopic rod 4035 is fixedly connected with a bottom of the support base 601, the support base 601 and the palm die 603 are detachably connected, an air cylinder 4021 in the inflation mechanism 402 is communicated with an elastic inner ring 4033 through an inflation hose 4031, and an inner ring 4033 in a natural state is fixedly connected with the bottom of the glove, and a gap between the support base 4033, so that the glove and the glove can be sealed in a hollow state, and the glove can form a hollow cavity, and the glove can facilitate a gap between the glove 601, and the glove when the glove is sealed and the glove 601.

As shown in fig. 1 and 4, the detection mechanism 7 includes a detection platform 701 fixed on the surface of the base 1, a detection air pump 702 is installed on the upper surface of the detection platform 701, an output end of the detection air pump 702 is fixedly connected with an air transmission corrugated hose 703, a retainer 704 is arranged on the surface of the air transmission corrugated hose 703, a pneumatic push rod 705 is installed on the surface of the retainer 704, the pneumatic push rod 705 is fixedly installed on the surface of the detection platform 701, an inflation male head is arranged at the top end of the air transmission corrugated hose 703, the detection mechanism 7 further includes an inflation female head communicated with the rotary column 401, the air transmission corrugated hose 703 can be extended and retracted to a certain height, so that the requirement that the inflation male head at the top end can contact the inflation female head when the pneumatic push rod 705 is started to drive the air transmission corrugated hose 703 on the retainer 704 to move upwards can be met, and mutual matching can be completed, so that the detection air pump 702 is inflated to realize air delivery.

As shown in fig. 1, 4 and 9, the driving mechanism 5 includes an inner gear 501 sleeved on the surface of the rotary column 401, the surface of the inner gear 501 is engaged with an outer gear 502, a suspension bracket 503 is rotatably installed at the center of the outer gear 502 through a bearing, the suspension bracket 503 and the outer gear 502 are coaxially provided with a first bevel gear 504, the surface of the first bevel gear 504 is engaged with a second bevel gear 505, the surface of the second bevel gear 505 is fixedly provided with a side gear 506, the bottom of the side gear 506 is movably connected with the suspension bracket 503 through a shaft seat, the suspension bracket 503 and the sleeve 3 are fixedly connected, when the sleeve 3 is driven to rotate by the rotating mechanism 2, the first tooth area 206 first contacts the side gear 506, the side gear 506 drives the second bevel gear 505 and the first bevel gear 504 thereon to rotate, so that the outer gear 502 drives the inner gear 501 to rotate, and the rotary column 401 is synchronously rotated, so that the glove on the glove mold 603 can be rotated to enable the glove to be placed inside the observation mechanism 8, and when the second tooth area 207 contacts the side gear 506, the mold 603 is rotated again, so that the glove can be recovered, and the glove can be used for drying and detection of the glove can be performed after drying, thereby being beneficial to be used for detection and detection of the dry glove being used;

as shown in fig. 1, 10 and 11, the observation mechanism 8 includes a reservoir 801 fixedly disposed at an edge of the base 1, a partition plate 802 is disposed inside the reservoir 801 and is used for dividing two sides inside the reservoir 801 into a water storage chamber 803 and a draining chamber 804, deionized water is disposed inside the water storage chamber 803, when the palm mold 603 is turned inside the reservoir 801, it is possible to observe whether air bubbles exist inside the glove to determine whether the glove has a leak, and the draining chamber 804 can collect water drops dropping from the surface of the glove after detection, so as to avoid the influence of overflow of sewage on the detection environment, an electric push rod 805 is disposed on the back side of the reservoir 801, the electric push rod 805 is fixedly connected with the base 1, and the height of the reservoir 801 can be adjusted by the arrangement of the electric push rod 805, so that the water entry depth of the palm mold 603 can be adjusted, and detection use under different conditions can be satisfied.

The rotary servo motor 201, the pneumatic push rod 705 and the electric push rod 805 are all regulated and controlled by an external PLC controller through wires to realize the mutual cooperative operation, and the PLC controller is a conventional technical means in the art, and therefore is not shown in the figures and is not described herein again.

The present solution is further introduced below with reference to specific working modes, which are described in detail below:

specifically, this butyronitrile gloves quality testing detection device is at the during operation:

1. as shown in fig. 1, a nitrile glove is sleeved on a bearing seat 601 on a bearing mechanism 6 on the right side of a lower protrusion 10, then a rotary servo motor 201 is started to drive a top seat 202 to rotate, so that the top seat drives a sleeve 3 to rotate, when an upper protrusion 4036 rotates on the lower protrusion 10 and is abutted against the lower protrusion 10, a telescopic rod 4035 drives a lifting frame 4034 and a limiting ring 4032 on the lifting frame 4034 to move upwards, so that an elastic hollow abutting inner ring 4033 moves at the bottom of the nitrile glove, and at the moment, a push rod 4023 is in contact with a guide push plate 4024 and slides at the edge (the push rod 4023 is about to be separated from the guide push plate 4024), in the sliding process of the push rod 4023, the push rod 4023 drives an inflation piston 4022 to slide in an inflation barrel 4021, so that gas in the inflation barrel is input into an inflation hose 4031 and is input into the elastic hollow abutting inner ring 4033, the elastic abutting inner ring 4033 is inflated to expand the outer side of the elastic hollow abutting inner ring 4033 to contact the surface of the nitrile glove, so that the bottom of the nitrile glove can be abutted against the bottom of the nitrile glove, and the glove can form an effective sealing state inside of the nitrile glove;

2. after the elastic hollow abutting inner ring 4033 is inflated, the rotary servo motor 201 stops rotating, the inflation male head is just positioned under the inflation female head, the pneumatic push rod 705 is started to enable the retainer 704 on the pneumatic push rod to drive the inflation male head at the top end of the air transmission corrugated hose 703 to be inserted into the surface of the female inflation male head, the detection air pump 702 is started to enable air to be input into the rotary column 401 through the air transmission corrugated hose 703, the air in the rotary column 401 is input into the interior of the nitrile glove through the bearing seat 601, the inflation valve head 602, the palm mold 603 and the air injection groove 604, and after the nitrile glove is expanded in a proper shape, the detection air pump 702 stops working;

3. at the moment, the rotary servo motor 201 rotates, when the side gear 506 rotates in the first tooth area 206 and continuously rotates, the side gear 506 drives the second bevel gear 505, the first bevel gear 504, the outer gear 502 and the rotary column 401 on the inner gear 501 to rotate, the rotary column 401 drives the palm mould 603 on the bearing seat 601 to rotate by one hundred and eighty degrees, the first tooth area 206 is separated from the side gear 506, the inverted gloves are placed in the water storage tank 801 in the observation mechanism 8, the electric push rod 805 is started to adjust the height of the water immersed gloves by adjusting the height of the water storage tank 801, whether bubbles are generated near the surfaces of the gloves is observed, detection is not cooperated if bubbles are generated, if no obvious bubbles are generated, no large leaks are generated on the surfaces of the gloves, and preliminary detection is qualified;

4. when the rotary servo motor 201 drives the nitrile gloves to rotate to a position close to the partition plate 802, the second tooth area 207 is meshed with the side gear 506, the rotation column 401 drives the nitrile gloves to rotate for one hundred eighty degrees again and then reset, the second tooth area 207 is disengaged at the moment, the nitrile gloves are placed inside the draining cavity 804, and in the process that the rotary servo motor 201 drives the top seat 202 to rotate at a constant speed, water drops on the surfaces of the nitrile gloves drop inside the draining cavity 804 and are collected;

5. after the rotary servo motor 201 drives the nitrile gloves to rotate outside the observation mechanism 8, the drying fan 9 can dry the nitrile gloves, then workers pull the arc limiting blocks 4027 upwards to enable the nitrile gloves to be separated from the corresponding limiting grooves 4029, at the moment, the inflating pistons 4022 can move to reset through the arrangement of the reset springs 4025, the elastic hollow collision inner rings 4033 do not collide with the surfaces of the nitrile gloves any more, the elastic hollow collision inner rings 4033 fall to the initial position under the action of gravity, at the moment, the nitrile gloves are manually picked down, and collection after detection is achieved.

The above embodiments are only used for illustrating the invention and not for limiting the technical solutions described in the invention, and although the present invention has been described in detail in the present specification with reference to the above embodiments, the present invention is not limited to the above embodiments, and therefore, any modification or equivalent replacement of the present invention is made; all such modifications and variations are intended to be included herein within the scope of this disclosure and the appended claims.

Claims (4)

1. The utility model provides a butyronitrile gloves quality testing detection device, includes frame (1), its characterized in that, the surface of frame (1) is equipped with rotary mechanism (2), locates sleeve (3) and lower arch (10) that a plurality of equidistance in the rotary mechanism (2) outside distributed, still includes: an observation mechanism (8) and a drying fan (9); the rotary inflating mechanism (4) comprises a rotary column (401) rotatably mounted on the inner wall of the sleeve (3) through a shaft seat, an inflating mechanism (402) arranged on the surface of the rotary column (401) and a propping mechanism (403) communicated with one end of the inflating mechanism (402);

the inflation mechanism (402) comprises an inflator (4021) fixed on the surface of the sleeve (3), an inflation piston (4022) tightly attached to the inner wall of the inflator (4021) is arranged in the inflator (4021) in a sliding mode, a push rod (4023) is fixedly connected to one side of the inflation piston (4022), a guide push plate (4024) is arranged on the surface of the push rod (4023) in an abutting mode, the guide push plate (4024) is fixedly connected with the positioning seat (204), a reset spring (4025) is fixedly connected to the surface of the push rod (4023), and the free end of the reset spring (4025) is fixedly connected with the outer wall of the inflator (4021);

the collision mechanism (403) comprises an air hose (4031) connected with one end of an air inflator (4021), one end of the air hose (4031) is communicated with a limiting ring (4032), an elastic hollow collision inner ring (4033) is arranged on the inner side of the limiting ring (4032), one end of the air hose (4031) penetrates through the limiting ring (4032) and is communicated with the elastic hollow collision inner ring (4033), a lifting frame (4034) is fixedly connected to the surface of the limiting ring (4032), a telescopic rod (4035) is arranged on the surface of the lifting frame (4034), and an upper protrusion (4036) is fixedly connected to one end of the telescopic rod (4035);

the bearing mechanism (6) is arranged at one end, far away from the sleeve (3), of the rotary column (401), and the abutting mechanism (403) is arranged on the surface of the bearing mechanism (6) so that the sealing of the detection gas is ensured when the rotary inflating mechanism (4) inflates the gloves;

the bearing mechanism (6) comprises a bearing seat (601) communicated with one end of the rotary column (401), an inflation valve head (602) is arranged on the upper surface of the bearing seat (601), the bearing seat (601) is communicated with a palm die (603) through the inflation valve head (602), and a plurality of gas injection grooves (604) for discharging gas input by the inflation valve head (602) are formed in the surface of the palm die (603);

the detection mechanism (7) is arranged on one side of the base (1) and is used for carrying out inflation detection on the butyronitrile gloves sleeved on the bearing mechanism (6);

the driving mechanism (5) is arranged on the surface of the sleeve (3) and is connected with the rotary column (401) and used for driving the inflating mechanism (402) to enable the butyronitrile gloves to rotate synchronously in the observation mechanism (8);

the rotary mechanism (2) comprises a rotary servo motor (201) fixedly mounted at the center of the upper surface of the base (1), the output end of the rotary servo motor (201) is fixedly connected with a top seat (202), a plurality of sleeves (3) are fixedly connected with the outer side of the top seat (202), the rotary mechanism (2) further comprises a plurality of side frames (203) which are fixed on the upper surface of the base (1) and are close to the rotary servo motor (201) and are arranged at equal intervals, the top ends of the side frames (203) are fixedly connected with positioning seats (204) together, and a toothed ring component is sleeved on the outer side of the positioning seat (204);

the gear ring component comprises a rotating ring (205) sleeved on the surface of the positioning seat (204), and a first gear area (206) and a second gear area (207) are respectively arranged on two sides of the surface of the rotating ring (205);

the driving mechanism (5) comprises an internal gear (501) sleeved on the surface of the rotary column (401), an outer gear (502) is meshed with the surface of the inner gear (501), a suspension bracket (503) is rotatably mounted at the center of the outer gear (502) through a bearing, and the suspension bracket (503) and the external gear (502) are coaxially provided with a first bevel gear (504), the surface of the first bevel gear (504) is engaged with a second bevel gear (505), a side gear (506) is fixedly arranged on the surface of the second bevel gear (505), the bottom of the side gear (506) is movably connected with a suspension bracket (503) through a shaft seat, the suspension bracket (503) is fixedly connected with the sleeve (3), when the rotating mechanism (2) drives the sleeve (3) to rotate, the first tooth area (206) contacts with a side gear (506), the side gear (506) drives a second bevel gear (505) and a first bevel gear (504) thereon to rotate, so that an external gear (502) drives an internal gear (501) to rotate and synchronously rotates the rotating column (401) to rotate, the gloves on the palm model (603) can be rotated to be inverted inside the observation mechanism (8), when the second tooth area (207) contacts the side gear (506), the palm die (603) rotates again and returns.

2. The butyronitrile glove quality inspection device according to claim 1, wherein the inflation mechanism (402) further comprises a limiting assembly, the limiting assembly comprises a positioning disk (4026) sleeved on the surface of the push rod (4023), an arc limiting block (4027) is slidably arranged inside the positioning disk (4026), one end of the arc limiting block (4027) is fixedly connected with a spring (4028), one end of the spring (4028) is fixedly connected with the positioning disk (4026), a plurality of sets of limiting grooves (4029) which are linearly arranged and matched with the arc limiting block (4027) are equidistantly arranged on the surface of the push rod (4023), and the positioning disk (4026) is fixedly connected with the sleeve (3).

3. The butyronitrile glove quality inspection device according to claim 1, wherein the detection mechanism (7) comprises a detection table (701) fixed on the surface of the base (1), the upper surface of the detection table (701) is provided with a detection air pump (702), the output end of the detection air pump (702) is fixedly connected with an air transmission corrugated hose (703), the surface of the air transmission corrugated hose (703) is provided with a retainer (704), the surface of the retainer (704) is provided with a pneumatic push rod (705), the pneumatic push rod (705) is fixedly arranged on the surface of the detection table (701), the top end of the air transmission corrugated hose (703) is provided with an inflation male head, and the detection mechanism (7) further comprises an inflation female head communicated with the rotary column (401).

4. A butyronitrile glove quality inspection device according to claim 1, wherein the observation mechanism (8) comprises a reservoir (801) fixedly arranged at the edge of the base (1), a partition (802) is arranged inside the reservoir (801) to divide two sides inside the reservoir (801) into a water storage cavity (803) and a water draining cavity (804), an electric push rod (805) is arranged on the back side of the reservoir (801), and the electric push rod (805) is fixedly connected with the base (1).

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