CN109719878B - Automatic change gum dipping gloves curing time adjustment structure - Google Patents

Abstract

The invention relates to an automatic dipped glove curing time adjusting structure, which comprises a pair of chain conveying lines as conveying systems, wherein the chain conveying lines are used for driving all mold rods to sequentially pass through dipping stations on the automatic dipped glove lines; a reversible mold bar disposed across the pair of chain conveyor lines by a rotatable structure; the clutch mechanism is used for disengaging or connecting torque transmission between the die rod and the chain conveying line; the overturning driving mechanism is used for driving the mold rod to overturn around the rotatable structure; the method is characterized in that: the two dip stations are at least two, and the overturning driving mechanism comprises gears arranged on the mold rods and rack groups matched with the gears, and the relative distance between the two rack groups between the adjacent dip stations is adjustable. The invention has the advantages that: the distance between the rack groups of two turnover driving mechanisms in different dipping stations is adjustable, so that the distance between the rack groups of two turnover driving mechanisms can change the turnover time interval of the mold rods between adjacent dipping stations, the moving speed of the whole chain conveying line is not required to be changed, and the regulation is convenient.

Description

Automatic change gum dipping gloves curing time adjustment structure

Technical Field

The invention relates to glove production equipment, in particular to an automatic gum dipping glove curing time adjusting structure.

Background

The labor protection articles are individual protection equipment for protecting workers from casualty accidents and occupational hazards in the re-labor process, and the labor protection articles are one of important measures for protecting the safety and health of the workers. Labor protection equipment is therefore also an important item in safety production supervision and management.

At present, the labor protection articles in China are complete in variety and sufficient in quantity, basically meet the requirements of domestic economic development, and form the labor protection article industry for protecting the safety and health of workers.

The process for producing the labor protection glove mainly comprises the working procedures of preheating, dipping, primary drying, desalting, dipping, secondary drying and vulcanizing, wherein the dipping working procedure is divided into impermeable agent dipping, rubber dipping and anti-slip salt dipping treatment.

However, in the currently known continuous production line of labor protection gloves, a passive impregnation scheme is mainly adopted, for example: erecting a plurality of mould rods fixed on a conveying line on a pair of chain conveying lines, installing a plurality of hand moulds on the mould rods, sequentially passing the hand moulds and gloves on the hand moulds through the chain conveying lines and temporarily staying at corresponding sections of an impregnation process, namely an anti-seepage agent tank and a rubber tank in the impregnation process, and actively lifting the anti-seepage agent tank and the rubber tank to ensure that the gloves are contacted with materials in the anti-seepage agent tank and the rubber tank, and actively descending the gloves after impregnation is finished so as to ensure that the gloves smoothly pass through the anti-seepage agent tank and the rubber tank; in the mode, the anti-seepage agent tank and the rubber tank are large in volume and heavy in mass, so that the energy consumption is high due to frequent lifting, the failure rate is high, and certain potential safety hazards exist.

In addition, after the anti-seepage agent pool is immersed, the time before the glove moves to the rubber pool is the curing time, the quality of the glove is directly influenced by the control of the curing time, the curing time is determined by the distance between the anti-seepage agent pool and the rubber pool and the moving speed of the chain conveying line, and the adjustment of the curing time can be realized only by controlling the moving speed of the chain conveying line due to the fixed distance between the anti-seepage agent pool and the rubber pool.

Disclosure of Invention

The invention aims to solve the technical problem of providing an automatic gum dipping glove curing time adjusting structure which can ensure gum dipping quality of gloves and has high production efficiency.

(1) In order to solve the technical problems, the technical scheme of the invention is as follows: the automatic dipped glove curing time adjusting structure comprises a conveying system, a pair of chain conveying lines and a control system, wherein the conveying system is arranged on an automatic dipped glove line with a dipping station and is used for driving all mold rods to sequentially pass through the dipping station on the automatic dipped glove line; the die rods can be turned over and used for installing a plurality of hand dies capable of sleeving the gloves to be impregnated, and the die rods are transversely arranged between the pair of chain conveying lines through a rotatable structure; the clutch mechanism is used for disengaging or connecting torque transmission between the die rod and the chain conveying line; the turnover driving mechanism is used for driving the mold rod to turn around the rotatable structure, and is a through type turnover driving mechanism arranged on the dipping station and the mold rod; (1) At least two dipping stations are arranged and distributed on an automatic dipping glove line along the moving direction of the chain conveying line; (2) The overturning driving mechanism comprises gears which are arranged on each mold rod and connected with the clutch, and rack groups which are arranged on each dipping station and can be matched with the gears, and the relative distance between the two rack groups between the adjacent dipping stations is adjustable; (3) The clutch mechanism comprises clutches arranged on the rotatable structures of the mold rods and clutch actuating devices arranged on the dipping stations, and the relative distance between the two clutch actuating devices between the adjacent dipping stations is adjustable.

The rack set comprises at least one upper rack arranged on the dipping station, the upper rack is horizontally arranged, the tooth surface of the upper rack faces downwards, and the extending direction of the upper rack is consistent with the moving direction of the chain conveying line; the lower rack is arranged on the dipping station, the tooth surface of the lower rack faces upwards, and the extending direction of the lower rack is consistent with the moving direction of the chain conveying line; the upper rack and the lower rack are arranged in a staggered mode in the front-back direction along the moving direction of the chain conveying line, the upper rack and the lower rack are respectively located at the upper part and the lower part of a gear path when the gear moves along the chain conveying line in the height direction, the gear is meshed with the upper rack when passing through the upper rack, and the gear is meshed with the lower rack when passing through the lower rack.

The flip drive mechanism further includes: the follow-up driving mechanism is matched with the upper rack or the lower rack, and is connected with the upper rack or the lower rack, and the follow-up driving mechanism can drive the upper rack and the lower rack to move along the self extending direction.

The rack of the dipping station is provided with a mounting bracket capable of moving along the moving direction of the chain conveying line, and the rack group and the follow-up driving mechanism are arranged on the mounting bracket.

In the clutch mechanism, the clutch comprises a clutch shaft, a clutch first module, a clutch second module and a clutch third module, and the clutch action device comprises a clutch switching guide rail and a clutch driver;

the clutch mechanism comprises a clutch shaft, a chain conveying line, a clutch third module, a clutch driving mechanism and a clutch driving mechanism, wherein the two ends of the clutch shaft are defined to be a first end and a second end; a first torque transmission structure is arranged between the clutch third module and the clutch first module, and a second torque transmission structure is arranged between the clutch third module and the clutch second module; the clutch switching guide rail is arranged at the dipping station, and is provided with a through clutch groove extending along the moving direction of the chain conveying line, wherein the through clutch groove can accommodate the embedding of a shifting block of the clutch third module and is driven by a clutch driver to move between a first position and a second position on the dipping station along the vertical direction of the through clutch groove; in the first state, the clutch switching guide rail is positioned at a first position, the clutch third module is embedded with the clutch second module, the first torque transmission structure and the second torque transmission structure keep the torque transmission state, the clutch second module cannot rotate, and the shifting block of the clutch second module can move along the extending direction of the through clutch groove; in the second state, the clutch switching guide rail is located at a second position, the clutch third module is separated from the clutch second module, the first torque transmission structure keeps the torque transmission state, the second torque transmission structure cannot transmit torque, the clutch second module can rotate on the clutch shaft, and the shifting block of the clutch second module can move along the extending direction of the through clutch groove.

The invention has the advantages that:

according to the invention, the clutch mechanism and the turnover driving mechanism for realizing turnover and impregnation of the mold rods adopt a split structure, and the distance between the rack groups of the two turnover driving mechanisms in different impregnation stations is adjustable, so that the separation time of turnover of the mold rods between adjacent impregnation stations can be changed, and the curing time is adjusted. The moving speed of the whole chain conveying line is not required to be changed to realize, the adjustment is convenient, and the production efficiency is improved.

According to the invention, the turnover driving mechanism adopts a through type turnover driving mechanism which is of a unpowered driving structure, and the turnover of the mold rods is realized by utilizing the movement of the chain conveying line and the relative displacement of the through type turnover driving mechanism, so that a power device is not required to be arranged between the chain conveying line and each mold rod, and the manufacturing cost and the manufacturing difficulty are greatly reduced.

The follow-up driving mechanism is arranged on the overturning driving mechanism, and in the moving process of the chain conveying line, the relative displacement between the overturning driving mechanism and the chain conveying line is dynamically adjusted by the follow-up driving mechanism, so that the overturning posture of the mould rod during overturning is controlled, and the glove dipping quality is improved.

Drawings

FIG. 1 is a schematic diagram of a curing time adjustment structure of an automated dipped glove of the invention.

Fig. 2 is a front view of the curing time adjustment of the automated dipped glove of the invention.

Fig. 3 is a partial enlarged view C in fig. 2.

Fig. 4 is a partial cross-sectional view of fig. 3.

FIG. 5 is a schematic view of the connection of a mold bar to a hand mold mounted on the mold bar in the present invention.

Description of the embodiments

As shown in fig. 1 and 2, the curing time adjusting structure of the automated dipped glove of the invention comprises:

the conveying system is arranged on an automatic dipped glove line with a dipping station and is used for driving each mold rod 2 to sequentially pass through the dipping station on the automatic dipped glove line, and the conveying system adopts a pair of chain conveying lines 1.

And the die rods 2 can be turned over and are used for installing a plurality of hand dies capable of sleeving gloves to be impregnated, and the die rods 2 are transversely arranged between the pair of chain conveying lines 1 through a rotatable structure.

A clutch mechanism 3 for disengaging or connecting the torque transmission between the die rod 2 and the chain conveyor line 1;

and the overturning driving mechanism 4 is used for driving the die rod 2 to overturn around the rotatable structure, and the overturning driving mechanism 4 is a through type overturning driving mechanism arranged on the dipping station and the die rod 2.

The core of the invention is that:

(1) The dipping stations are two or more than two and distributed on an automatic dipping glove line along the moving direction of the chain conveying line 1. In this embodiment, there are two dipping stations, each labeled A, B.

(2) The overturning driving mechanism 4 comprises a gear 41 which is arranged on each mold rod and connected with the clutch, and a rack group which is arranged on each dipping station and can be matched with the gear 41, and the relative distance between two rack groups between adjacent dipping stations is adjustable; the trigger interval of the overturning of the die rods between adjacent dipping stations can be changed, and the time of the dipping interval can be adjusted.

(3) The clutch mechanism 3 comprises a clutch arranged on the rotatable structure of each mold rod and a clutch action device arranged on each dipping station, and the relative distance between two clutch action devices between adjacent dipping stations is adjustable.

As a more specific embodiment of the present invention: as shown in the figure 3 of the drawings,

the rack set in the turnover driving mechanism 4 comprises

An upper rack 42 arranged on the dipping station, wherein the upper rack 42 is horizontally arranged and the tooth surface faces downwards, and the extending direction of the upper rack 42 is consistent with the moving direction of the chain conveying line 1;

the lower rack 43 is arranged on the dipping station, the lower rack 43 is horizontally arranged, the tooth surface faces upwards, and the extending direction of the lower rack 43 is consistent with the moving direction of the chain conveying line 1;

the upper rack 42 and the lower rack 43 are staggered back and forth in the moving direction along the chain conveyor line, the upper rack 42 and the lower rack 43 are respectively located above and below the gear 41 in the gear path when moving along with the chain conveyor line 1 in the height direction, and the gear 41 is meshed with the upper rack 42 when passing the upper rack 42, and the gear 41 is meshed with the lower rack 43 when passing the lower rack 43.

Of course, it should be understood by those skilled in the art that the number of upper or lower racks in a rack set need not be fixed in the same dipping station, and that different numbers and lengths of upper and lower racks may be selected as required by the flipped posture.

The flip drive mechanism further includes: a follow-up driving mechanism (not shown) which is matched with the upper rack 42 or the lower rack 43 and is connected with the upper rack 42 or the lower rack 43, and the follow-up driving mechanism can drive the upper rack 42 and the lower rack 43 to move along the self extending direction. In this embodiment, the follow-up driving mechanism employs a screw nut pair, a ball screw, or the like.

When the gear 41 is meshed with the upper rack 42 or the lower rack 43, the relative displacement speed of the gear 41 and the gear set can be changed by controlling the movement of the upper rack 42 or the lower rack 43, so that the control of the overturning speed and the gesture of the die rod 2 can be realized.

In the invention, the rack of the dipping station is provided with the mounting bracket which can move along the moving direction of the chain conveying line, and the rack group and the follow-up driving mechanism are both arranged on the mounting bracket. Of course, for more convenient adjustment, the mounting bracket may be divided into an upper bracket 51 and a lower bracket 52 so as to independently mount the upper rack and the lower rack.

As a more specific embodiment of the present invention: in the clutch mechanism, the clutch includes a clutch shaft 34, a clutch first module 31, a clutch second module 32, and a clutch third module 33, and the clutch actuation device includes a clutch switching rail 35 and a clutch driver 36.

The two ends of the clutch shaft 34 are defined as a first end and a second end, a clutch first module 31 which is directly or indirectly connected and fixed with the chain conveyor line 1 is fixed at the first end of the clutch shaft 34, a clutch second module 32 which is connected and fixed with the die rod 2 and can rotate relative to the clutch shaft 34 is movably sleeved at the second end of the clutch shaft 34, a clutch third module 33 which can axially move along the clutch shaft 34 is sleeved between the first end and the second end of the clutch shaft 34, and a shifting block which can be matched with a clutch switching guide rail 35 is arranged on the clutch third module 33;

a first torque transmission structure is arranged between the clutch third module 33 and the clutch first module 31, and a second torque transmission structure is arranged between the clutch third module 33 and the clutch second module 32;

the clutch switch guide rail 35 is arranged at the dipping station, the clutch switch guide rail 35 is provided with a through clutch groove extending along the moving direction of the chain conveying line 1, the through clutch groove can accommodate the embedding of a shifting block of the clutch third module 33, and the clutch switch guide rail 35 is driven by the clutch driver 35 to move between a first position and a second position on the dipping station along the vertical direction of the through clutch groove;

in the first state, the clutch switch rail 35 is located at a first position, the clutch third module 33 is embedded with the clutch second module 32, the first torque transmission structure and the second torque transmission structure keep the torque transmission state, the clutch second module 32 cannot rotate, and the shifting block of the clutch second module 32 can move along the extending direction of the through clutch groove;

in the second state, the clutch switch rail 35 is located at the second position, the clutch third module 33 is separated from the clutch second module 32, the first torque transmission structure maintains the torque transmission state, the second torque transmission structure cannot transmit torque, the clutch second module 32 can rotate on the clutch shaft 34, and the shifting block of the clutch second module 32 can move along the extending direction of the through clutch groove.

In the present embodiment, the clutch actuation means including the clutch switch rail 35 and the clutch driver 36 are also mounted on the lower bracket 52.

In this embodiment, as shown in fig. 4, the specific structure of the clutch mechanism is: the clutch shaft 34 is sequentially divided into a chain seat connecting section, a main mounting section and a gear seat mounting section from a first end to a second end along the axis direction of the clutch shaft, and the diameter of the main mounting section is larger than that of the chain seat connecting section and the gear seat mounting section;

the clutch first module 31 comprises a chain seat 311 and a sliding sleeve seat 312, the chain seat 311 is arranged on the chain conveying line 1, and the center of the chain seat 311 is provided with a shaft hole for being connected with a connecting section of the clutch shaft chain seat in a key way; the center of the sliding sleeve seat 312 is provided with a first through hole which can be used for allowing the clutch shaft to pass through; in the axial direction of the clutch shaft, the chain seat 311 and the sliding sleeve seat 312 are sleeved on the clutch shaft 34 in sequence from the first end to the second end, and the chain seat 311 is sleeved on a chain seat connecting section of the clutch shaft 34 through a shaft hole and is connected with the chain seat connecting section in a key or threaded manner; the sliding sleeve seat 312 is sleeved on the main mounting section of the clutch shaft 34 through a first through hole, and the sliding sleeve seat 312 is fixedly connected with the chain seat 311;

the clutch second module 32 comprises a gear seat 321, the gear seat 321 is directly or indirectly connected and fixed with the mold rod 2, a second through hole is arranged in the center of the gear seat 321, the second through hole is a step through hole, the gear seat 321 is arranged on a gear seat mounting section of the clutch shaft 34 through the second through hole, and a bearing group 322 is arranged between the gear seat 321 and the gear seat mounting section; the gear seat 321 is externally provided with a gear 41, and the gear 41 and the gear seat 321 can be integrally formed or connected by keys.

The clutch third module 33 comprises a sliding sleeve 331 and a shifting block 332, a third through hole which can be used for allowing a clutch shaft to pass through is formed in the center of the sliding sleeve 331, the third through hole is a step through hole, the third through hole comprises a large-diameter spring hole and a small-diameter shaft body matching hole which are coaxially arranged, the sliding sleeve 331 is arranged on a main installation section of the clutch shaft 34 through the third through hole, the large-diameter spring hole is close to a first end of the clutch shaft, and the small-diameter shaft body matching hole is close to a second end of the clutch shaft; and the sliding sleeve 331 is slidably engaged with the main mounting section of the clutch shaft 34 through the small diameter shaft body engagement hole.

A compression spring 37 is disposed between the clutch first module 31 and the clutch third module 33, and the compression spring 37 is mounted in an annular cavity formed by the cooperation of the clutch shaft 34, the sliding sleeve seat 312, the sliding sleeve 331 and the chain seat 311.

It should be appreciated by those skilled in the art that the first and second torque transmission structures may be known torque transmission structures such as pins and pin holes, and the first and second torque transmission structures may maintain the torque transmission state when the third clutch module 33 is engaged with the second clutch module 32 as long as the lengths of the pins and pin holes are controlled; when the clutch third module 33 is separated from the clutch second module 32, the first torque transmission structure maintains a torque transmission state, and the second torque transmission structure cannot transmit torque, which will not be described herein. Of course, the second torque transmission structure may also be a friction type clutch or the like.

In order to better control the dipping operation of the hand mold 6, as shown in fig. 5, the hand mold 6 is attached to the mold bar 2 in such a manner that: the hand mould 6 is provided with a finger section 61 and a palm section 62 which are sequentially arranged, wherein one end of the palm section 62 far away from the finger section 61 is directly or indirectly connected and fixed with the mould rod 2, and the end is indirectly connected with the mould rod through a connecting section 63 in the embodiment.

Defining the entirety of the finger section 61 and the palm section 62 as a reference plane D, defining a plane passing through the rotational axis of the rotatable structure and perpendicular to the reference plane as a reference plane E, the finger section 61, the palm section 62 and the reference plane E satisfying the following relationship:

with reference surface E as boundary, the back part of palm section 62 and finger section 61 is located on the same side of reference surface, the front part of finger section 61 is located on the other side of reference surface, and the distance H between the forefront part of finger section 61 and reference surface is no more than 2 times of average thickness of finger section of hand mould.

Working principle:

normal impregnation state:

in an initial state, the chain conveying line drives the mold rod to move on the automatic gum dipping glove line through the clutch; the clutch switching guide rail of the clutch action module is positioned at a first position, and the clutch is kept in a connection state capable of transmitting torque;

in the process that the mold rod moves forward in the dipping station, a shifting block of the clutch passes through a clutch switching guide rail of the clutch action module, and the clutch switching guide rail moves to a second position to drive the shifting block in a groove to move, so that the clutch is in a disengaging state; at the moment, the gear on the die rod just starts to be meshed with the rack group, and under the cooperation of the forward moving gear and the upper rack or the lower rack in the rack group, the die rod is driven to overturn to realize overturn impregnation;

immersion interval adjustment state:

and (3) independently moving the mounting bracket on the dipping station A or B, or simultaneously adjusting the mounting bracket on the adjacent dipping stations, and changing the distance between the two rack groups between the adjacent dipping stations, so as to realize the interval time of two times of overturning dipping actions.

Claims (2)

1. An automatic change gum dipping gloves curing time adjustment structure, include

The conveying system is arranged on an automatic dipped glove line with a dipping station and is used for driving each mold rod to sequentially pass through the dipping station on the automatic dipped glove line, and the conveying system adopts a pair of chain conveying lines;

the die rods can be turned over and used for installing a plurality of hand dies capable of sleeving the gloves to be impregnated, and the die rods are transversely arranged between the pair of chain conveying lines through a rotatable structure;

the clutch mechanism is used for disengaging or connecting torque transmission between the die rod and the chain conveying line;

the turnover driving mechanism is used for driving the mold rod to turn around the rotatable structure, and is a through type turnover driving mechanism arranged on the dipping station and the mold rod;

the method is characterized in that:

at least two dipping stations are arranged and distributed on an automatic dipping glove line along the moving direction of the chain conveying line;

the overturning driving mechanism comprises gears which are arranged on the mold rods and connected with the clutches, and rack groups which are arranged on the dipping stations and can be matched with the gears, and the relative distance between the two rack groups between the adjacent dipping stations is adjustable;

the clutch mechanism comprises clutches arranged on the rotatable structures of the mold rods and clutch action devices arranged on the dipping stations, and the relative distance between two clutch action devices between adjacent dipping stations is adjustable;

the rack set comprises

The upper rack is arranged on the dipping station, the upper rack is horizontally arranged, the tooth surface of the upper rack faces downwards, and the extending direction of the upper rack is consistent with the moving direction of the chain conveying line;

the lower rack is arranged on the dipping station, the tooth surface of the lower rack faces upwards, and the extending direction of the lower rack is consistent with the moving direction of the chain conveying line;

the upper rack and the lower rack are staggered back and forth along the moving direction of the chain conveying line, the upper rack and the lower rack are respectively positioned above and below a gear path when the gear moves along the chain conveying line in the height direction, the gear is meshed with the upper rack when passing through the upper rack, and the gear is meshed with the lower rack when passing through the lower rack;

the flip drive mechanism further includes:

the follow-up driving mechanism is matched with the upper rack or the lower rack and is connected with the upper rack or the lower rack, and the follow-up driving mechanism can drive the upper rack and the lower rack to move along the self extending direction;

in the above-mentioned clutch mechanism, the clutch mechanism is formed from a first clutch plate and a second clutch plate,

the clutch comprises a clutch shaft, a clutch first module, a clutch second module and a clutch third module, and the clutch action device comprises a clutch switching guide rail and a clutch driver;

the clutch mechanism comprises a clutch shaft, a chain conveying line, a clutch third module, a clutch driving mechanism and a clutch driving mechanism, wherein the two ends of the clutch shaft are defined to be a first end and a second end;

a first torque transmission structure is arranged between the clutch third module and the clutch first module, and a second torque transmission structure is arranged between the clutch third module and the clutch second module;

the clutch switching guide rail is arranged at the dipping station, and is provided with a through clutch groove extending along the moving direction of the chain conveying line, wherein the through clutch groove can accommodate the embedding of a shifting block of the clutch third module and is driven by a clutch driver to move between a first position and a second position on the dipping station along the vertical direction of the through clutch groove;

in the first state, the clutch switching guide rail is positioned at a first position, the clutch third module is embedded with the clutch second module, the first torque transmission structure and the second torque transmission structure keep the torque transmission state, the clutch second module cannot rotate, and the shifting block of the clutch second module can move along the extending direction of the through clutch groove;

in the second state, the clutch switching guide rail is located at a second position, the clutch third module is separated from the clutch second module, the first torque transmission structure keeps the torque transmission state, the second torque transmission structure cannot transmit torque, the clutch second module can rotate on the clutch shaft, and the shifting block of the clutch second module can move along the extending direction of the through clutch groove.

2. The automated dipped glove cure time adjustment structure of claim 1, wherein: the rack of the dipping station is provided with a mounting bracket capable of moving along the moving direction of the chain conveying line, and the rack group and the follow-up driving mechanism are arranged on the mounting bracket.