CN112974129B - Automatic temperature control device is used in production of butyronitrile antiskid gloves - Google Patents

Abstract

The invention relates to an automatic temperature control device for butyronitrile antiskid glove production, which comprises a glove transmission mechanism, wherein the glove transmission mechanism comprises a transmission unit, a glove module and a guide assembly; the impregnation tank body is smoothly transitionally connected by a first inclined part, a first horizontal part, a second inclined part, a second horizontal part and a third inclined part along the downward inclined direction; the transmission mechanism comprises a first transmission assembly and a second transmission assembly, and the first transmission assembly and the second transmission assembly synchronously transmit; a chain mechanism; a cleaning mechanism; the first impurity collecting mechanism comprises a first discharging assembly and a first collecting assembly; and a second impurity collecting mechanism including a switching assembly and a second collecting assembly; the invention solves the technical problems that the temperature of the hand membrane is too high, the liquid temperature of the glue to be glued is too high after long-term use, the gluing environment is influenced, the pinholes of the gloves are caused, and the product quality is poor.

Description

Automatic temperature control device is used in production of butyronitrile antiskid gloves

Technical Field

The invention relates to the technical field of butyronitrile anti-skid gloves, in particular to an automatic temperature control device for butyronitrile anti-skid glove production.

Background

The nitrile rubber labor protection gloves have the advantages of excellent oil resistance, excellent wear resistance, comfortable wearing, wide raw material source, moderate price and the like, and the usage amount of the nitrile rubber labor protection gloves tends to be larger and larger in recent years. As the usage of the butyronitrile labor protection gloves becomes larger and larger due to the advantages, the labor protection gloves with various knitted liners dip-coated with butyronitrile coatings are developed and applied to various fields. The surface coating of the glove is subjected to sanding antiskid treatment, is favored by workers and consumers with excellent gripping force and antiskid performance, and the using amount of the surface coating of the glove tends to rise all the time.

Patent document CN201810748355.7 discloses a butyronitrile ultrathin anti-slip skin-care labor protection glove and a manufacturing process thereof, wherein the glove is made of the following substances in parts by mass: 100 parts of carboxylic butyronitrile latex, 0.1-1 part of potassium hydroxide, 0.5-3 parts of zinc oxide, 0.5-1.5 parts of sulfur, 0.5-3 parts of accelerator, 1-2 parts of anti-aging agent, 0.05-0.2 part of dispersing agent, 1-3 parts of titanium dioxide, 1-3 parts of wear-resisting agent, 0.2-1 part of water-based coupling agent, 1-4 parts of wax emulsion, 10-30 parts of deionized water, 1-5 parts of thickening agent and 1-3 parts of foaming agent. The manufacturing process of the gloves comprises a plurality of steps, and the whole process comprises the following steps: the method comprises the steps of die sheathing, preheating, coagulant dipping, gum dipping, salt spraying, drying, water washing, drying and vulcanizing, demoulding, skin care agent treatment, secondary drying and finished product obtaining.

However, in the actual use process, the inventor finds that the temperature of the hand membrane is too high, and the liquid temperature of the glue to be glued is too high after long-term use, so that the gluing environment is influenced, and the problems of needle holes and poor product quality of the gloves are caused.

Disclosure of Invention

Aiming at the defects of the prior art, the invention aims to carry out pre-gluing before formal gluing work when a glove conveying mechanism is matched with flowing glue in the conveying process by arranging a glue dipping groove body and a glove conveying mechanism, so that the glove module is pre-glued in the conveying process of the glued glue with higher temperature, and the technical problems that the temperature difference between the glove module and the glue temperature is too large, the glue quality is influenced in the formal and complete gluing work, the gluing effect is improved, the hand membrane temperature is too high, the liquid temperature of the glue to be glued is too high after long-term use, the gluing environment is influenced, the needle eye problem of the glove is caused, and the product quality is poor are solved.

Aiming at the technical problems, the technical scheme is as follows: the utility model provides a butyronitrile antiskid gloves production is with automatic temperature control device, includes:

the glove conveying mechanism comprises a conveying unit, a plurality of groups of glove modules uniformly arranged on the conveying unit at equal intervals and a guide assembly used for driving the glove modules to lift;

the glue dipping tank body is obliquely and downwards arranged and is positioned below the transmission unit, the glue dipping tank body is of an oval structure, a partition plate is arranged along the middle of the glue dipping tank body and along the length direction of the glue dipping tank body, a glue coating space and an impurity discharging space are formed between the glue dipping tank body and the partition plate, and the glue dipping tank body is in smooth transition connection with a first inclined part, a first horizontal part, a second inclined part, a second horizontal part and a third inclined part along the obliquely and downwards direction;

the transmission mechanism comprises a first transmission assembly arranged at the third inclined part and positioned in the impurity discharging space, and a second transmission assembly arranged at the lower end of the first inclined part and positioned in the impurity gluing space, and the first transmission assembly and the second transmission assembly synchronously transmit;

the chain-driven mechanism is arranged right above the partition plate and synchronously carries out conveying work along the transmission direction of water in the groove body of the impregnation tank, and the chain-driven mechanism is intermittently started;

the cleaning mechanisms are uniformly arranged in a plurality of groups at equal intervals along the transmission direction of the chain mechanism, and are used for cleaning the bottom of the tank body of the impregnation tank;

the first impurity collecting mechanism comprises a first discharging component arranged in the partition plate and a first collecting component for collecting the impurities discharged by the first discharging component; and

and the second impurity collecting mechanism is arranged above the groove body of the impregnation tank and comprises a switching component for driving the cleaning mechanism to automatically switch the decontamination surface and a second collecting component for cleaning the cleaning mechanism in the switching process for the second time.

Preferably, the glove module comprises:

the base b is arranged on any chain link of the transmission unit;

the telescopic unit c is fixedly arranged on the base b and vertically arranged downwards; and

and the hand membrane is rotatably arranged at the lower end of the telescopic unit c.

Preferably, the guide assembly comprises a guide rail for driving the glove module to move downwards in the vertical direction twice and a guide member for driving the glove module to rotate circularly;

when the glove module is transmitted to the first horizontal part, the guide rail drives the control rod on the telescopic unit c to be pulled down into the first horizontal part, and when the glove module is transmitted to the second horizontal part, the guide rail drives the control rod on the telescopic unit c to be pulled down into the second horizontal part;

the guide piece comprises a driving gear and a driving rack, the driving gear is coaxial and in synchronous transmission with the upper end of the hand membrane, the driving rack is arranged on the transmission unit and meshed with the driving gear, and the driving rack is located right above the second horizontal part.

Preferably, the first transmission assembly comprises a bracket a arranged on the body of the glue dipping tank, a driving shaft a rotatably arranged on the bracket a, and a turbine a which is coaxial with and fixedly connected with the lower end of the driving shaft a, the turbine a is used for driving water at the lower end of the body of the glue dipping tank to flow back to the gluing space from the impurity discharge space, and the driving shaft a is driven by a first motor to rotate continuously.

Preferably, the second transmission assembly comprises a bracket b arranged on the body of the glue dipping tank, a driving shaft b rotatably arranged on the bracket b and a turbine b coaxial with and fixedly connected with the lower end of the driving shaft b, and the driving shaft b and the driving shaft a are in synchronous transmission connection through a plurality of groups of synchronous belts;

and the upper end of the driving shaft b is provided with a radiating blade, and the radiating blade is used for physically cooling the hand membrane in transmission.

Preferably, the cleaning mechanism includes:

the base a is arranged on any chain link of the linkage mechanism;

the telescopic shaft is arranged on the base a along the vertical direction, a base is arranged at the lower end of the telescopic shaft, and the telescopic shaft completes lifting work along the vertical direction under the action of the limiting rail;

the rotating rod is rotatably arranged in a guide groove which is formed in the base and is in an L-shaped structure through a circular ring;

the limiting ring is fixedly arranged at the lower end of the rotating rod;

the one-way bearing is arranged in the limiting ring in a matching and rotating mode;

the hairbrush is arranged at the lower end of the limiting ring;

the brush roll is sleeved outside the one-way bearing; and

the screens piece, the screens piece includes that a plurality of groups circumference sets up the elasticity dog and the setting of spacing ring inner wall are at one-way bearing outer wall and with the briquetting that the elasticity dog matching corresponds the setting.

Preferably, the first discharging assembly comprises:

the telescopic end of the horizontal pushing cylinder is vertically arranged downwards, and the lower end of the horizontal pushing cylinder is fixedly provided with a telescopic unit a;

the limiting plate is fixedly connected with the lower end of the telescopic unit a and is matched with the width of the impurity discharging space, and the limiting plate is of a filter screen structure;

the pushing cylinder is made of elastic rubber materials, is arranged on an outlet a formed in the partition plate in a matched sliding mode and is horizontally arranged in the partition plate through a telescopic unit b, and is used for discharging sediments in front of the brush roller; and

the translation piece, the translation piece include with telescopic unit b fixed connection's drive rack a, with drive gear a that drive rack a meshed, with drive gear a is coaxial and synchronous transmission's drive gear b and with drive gear b meshes and vertical setting and is in drive rack b on the telescopic unit a.

Preferably, the first collecting assembly includes:

the protruding platform is arranged in the glue dipping tank body and protrudes outwards, and the protruding platform is matched with the push-out barrel structure;

the control door is driven by an electric signal to automatically open and close; and

the first collecting box, the inside filter that is provided with of first collecting box, the upper end retrieval and utilization of steeping vat cell body is beaten to the liquid of filter below through pump body circulation.

Preferably, the switching component includes:

the driving gear is coaxial with the horizontal part of the rotating rod and synchronously transmits;

the driven rack is fixedly connected with the telescopic unit a and meshed with the driving gear; and

and the friction roller is driven by a transmission part to synchronously rotate clockwise with the transmission mechanism, and is in intermittent contact with the brush roller.

As still further preferred, the second collection assembly comprises:

the impurity removing plate is positioned below the friction roller, a chamfer is arranged at the contact end part of the impurity removing plate, and the impurity removing plate is arranged on the rack through an obliquely arranged tension spring; and

and the second collecting box is arranged below the impurity removing plate and is used for collecting impurities on the impurity removing plate.

The invention has the beneficial effects that:

(1) according to the invention, the glue dipping groove body is matched with the glove conveying mechanism, so that when the glove conveying mechanism is matched with flowing glue in the conveying process, pre-gluing work is carried out before formal gluing work, and the glove module is pre-glued in the conveying process of the glued glue with higher temperature, so that the phenomenon that the temperature difference between the glove module and the glue is too large, the quality of the glue is influenced in the formal and complete gluing work is avoided, and the gluing effect is improved;

(2) if the dip tank body adopts a flat layer inclined upward structure, the force of flowing fluid acting on the glove modules in continuous transmission is different due to the fact that the gravity does work at the changed moment, so that the plane structure is changed into a multi-section structure, the second horizontal part is of a horizontal structure, the adhesive force between the glove modules and the glue conveyed in the state is constant, the force of gluing the glove modules is uniform, and the effect of uniform gluing is improved;

(3) according to the invention, the guide component is matched with the glove module, so that the pre-gluing work of the first horizontal part and the gluing work of the second horizontal part of the glove module are sequentially completed in the transmission process along the groove body of the dipping groove, the pre-gluing work of the glove module adopts a material dipping mode, the phenomenon that the gloves are too thick due to two gluing works is avoided, and the guide component 132 drives the glove module to perform rotary gluing work during formal gluing work;

(4) according to the invention, by arranging the second transmission assembly, on one hand, the colloid in an upstream state is pumped by the second transmission assembly, so that the problem of insufficient power for conveying the colloid passing through the two horizontal parts to the upper end of the groove body of the impregnation tank is avoided, and on the other hand, the heat dissipation blades are used for synchronous transmission, so that the physical cooling work of the hand membrane in transmission is completed, the overhigh temperature of the hand membrane is avoided, and the product quality is further improved; the structure is simple, additional power is saved, production is reduced, cooling is completed, and pumping work of the upflow colloid is promoted.

In conclusion, the equipment has the advantages of simple structure and automatic temperature control, and is particularly suitable for the technical field of butyronitrile anti-skid gloves.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings described below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an automatic temperature control device for producing butyronitrile anti-skid gloves.

FIG. 2 is a schematic structural diagram of a body of a dip tank.

Fig. 3 is a schematic view of the driving state of the cleaning mechanism.

Fig. 4 is a first structural diagram of the guide assembly.

Fig. 5 is a schematic structural diagram of a guide assembly.

Fig. 6 is a schematic diagram of the transmission operation of the guide assembly.

Fig. 7 is a schematic structural diagram of the first transmission assembly.

Fig. 8 is a schematic structural diagram of the second transmission assembly.

Fig. 9 is a first structural schematic diagram of the cleaning mechanism.

Fig. 10 is a second schematic structural diagram of the cleaning mechanism.

Fig. 11 is a first schematic sectional view of the cleaning mechanism.

FIG. 12 is a second schematic cross-sectional view of the cleaning mechanism.

Fig. 13 is a third schematic cross-sectional view of the cleaning mechanism.

Fig. 14 is a fourth schematic cross-sectional view of the cleaning mechanism.

Fig. 15 is a first schematic structural view of the second impurity collecting mechanism.

Fig. 16 is a second schematic structural view of the second impurity collecting mechanism.

Fig. 17 is a first schematic structural diagram of the first impurity collecting mechanism.

Fig. 18 is a second schematic structural view of the first impurity collecting mechanism.

Fig. 19 is a third schematic structural view of the first impurity collecting mechanism.

Fig. 20 is a fourth schematic structural view of the first impurity collecting mechanism.

Fig. 21 is a schematic structural view five of the first impurity collecting mechanism.

Detailed Description

The technical scheme in the embodiment of the invention is clearly and completely explained by combining the attached drawings.

Example one

As shown in fig. 1, an automatic temperature control device for producing butyronitrile antiskid gloves comprises:

the glove conveying mechanism 1 comprises a conveying unit 11, a plurality of groups of glove modules 12 uniformly arranged on the conveying unit 11 at equal intervals and a guide component 13 for driving the glove modules 12 to lift;

the glue dipping tank body 2 is obliquely and downwards arranged and is positioned below the transmission unit 11, the glue dipping tank body 2 is of an oval structure, a partition plate 201 is arranged along the middle of the glue dipping tank body 2 and along the length direction of the glue dipping tank body 2, a gluing space 202 and an impurity discharging space 203 are formed between the glue dipping tank body 2 and the partition plate 201, and the glue dipping tank body 2 is smoothly and transitionally connected by a first inclined part 20a, a first horizontal part 20b, a second inclined part 20c, a second horizontal part 20d and a third inclined part 20e along the obliquely and downwards direction;

a first transmission assembly 31, wherein the first transmission assembly 31 comprises a first transmission assembly 31 arranged at the third inclined part 20e and positioned in the impurity discharging space 203, a second transmission assembly 32 arranged at the lower end of the first inclined part 20a and positioned in the impurity gluing space 202, and the first transmission assembly 31 and the second transmission assembly 32 synchronously transmit;

the chain-driven mechanism 205 is arranged right above the partition plate 201 and synchronously carries out conveying work along the transmission direction of water in the dip tank body 2, and the chain-driven mechanism 205 is intermittently started;

the cleaning mechanisms 4 are arranged in a plurality of groups at equal intervals and uniformly along the transmission direction of the chain mechanism 205, and the cleaning mechanisms 4 are used for cleaning the bottom of the impregnation tank body 2;

the first impurity collecting mechanism 5, the first impurity collecting mechanism 5 includes a first discharging component 51 arranged in the partition plate 201 and a first collecting component 52 for collecting the impurities discharged from the first discharging component 51; and

and the second impurity collecting mechanism 6 is arranged above the dip tank body 2, and comprises a switching component 61 for driving the cleaning mechanism 4 to automatically switch the decontamination surface and a second collecting component 62 for cleaning the cleaning mechanism 4 in the switching process for the second time.

It should be noted that if the nitrile latex is left to stand for exhausting after the completion of the compounding, the used mold is unglazed, if the mold film using the glazed mold is excessively shrunk, the temperature of the mold does not exceed 70 ℃ after the coagulant is dried, because the temperature is exceeded, the film is not formed well, the film starts to gel after the dipping of the eight-size, and the pH value of the right compounding ensures that the process is completed before the leaching stage. Leaching the gloves, wherein the sirloin latex is stable, a large amount of surfactant is present in the wet gel, and the leaching water removes the excessive surfactant and residues of calcium chloride and soluble impurities, wherein the leaching temperature does not exceed 45 ℃; above this temperature the film will shrink. The final stage of the process is vulcanization, the vulcanization temperature is high because the nitrile latex has no pre-vulcanization, the oven temperature must exceed 110 ℃ in the vulcanization cycle, the optimal vulcanization condition is that 8-9 ℃ is started, then the temperature is increased to 110-120 ℃, finally 80-9 ℃ is started, the nitrile gloves which are not vulcanized sufficiently will generate wrinkles, stickiness and damage durability, and after demoulding, the semi-finished gloves are required to be chloridized to remove surface stickiness, so the temperature of the hand mould cannot be too high, the temperature of the rubber material is below 24 ℃, and the pinhole phenomenon of the finished products can be reduced to the maximum extent.

In this embodiment, by arranging the dipping groove body 2 and matching the glove conveying mechanism 1, when the glove conveying mechanism 1 matches the flowing colloid in the conveying process, the pre-gluing operation is performed before the formal gluing operation, so that the glove module 12 is pre-glued in the conveying process of the colloid at a higher temperature after the gluing operation, and the problem that the quality of the colloid is affected in the formal and complete gluing operation due to the overlarge temperature difference between the glove module 12 and the colloid is avoided, and the gluing effect is improved.

Meanwhile, the cleaning mechanism 4 is driven by the chain mechanism 205, so that in the process that the colloid flows along the impregnation tank body 2 for a circle, the cleaning mechanism 4 finishes the automatic cleaning work on the side wall and the bottom of the impregnation tank body 2, the impregnation tank body 2 is guaranteed to be kept in a cleaning state constantly in the gluing working process, on the other hand, the traditional machine needs to be stopped to discharge the colloid, the automatic cleaning work on the impregnation tank body 2 is manually carried out, the timeliness is high, extra labor force output is replaced, and the production cost is reduced.

Secondly, the glue dipping tank body 2 is obliquely and upwards arranged and is arranged in a single-layer structure, on one hand, the single-layer opening is upwards arranged to replace the traditional upper and lower rail type connection, so that the glue dipping tank is not required to be disassembled for cleaning, the operation is simple and rapid, and meanwhile, the glue can be ensured to always keep a flowing state in the inclination process of the glue dipping tank body 2, the glue is not easy to precipitate, the uniform degree of gluing is facilitated, and the product quality is improved; on the other hand, the processing is convenient, and the production cost is reduced.

It should be noted that, if the dipping tank body 2 adopts a flat-layer inclined upward structure, the force of the flowing fluid acting on the glove modules 12 in continuous transmission is different due to the fact that the gravity does work at the changed edge, and the gluing force of the entering products is not uniform, in order to solve the technical problem, the inventor changes the flat structure of the dipping tank body 2 into a multi-section structure, the second horizontal part 20d is a horizontal structure, the adhesive force between the glove modules 12 and the glue conveyed in the state is constant, and further, the gluing force of the glove modules 12 is uniform, so that the effect of uniform gluing is improved.

Thirdly, through setting up first impurity collection mechanism 5 and second impurity collection mechanism 6, after clean mechanism 4 accomplished the cleaning work to 2 a week of steeping vat cell body, first impurity collection mechanism 5 carries out automatic discharge collection with the colloid that deposits, recycle first impurity collection mechanism 5 and carry out row sediment work in, second impurity collection mechanism 6 drive clean mechanism 4 clears away row sediment work to the cleaning surface, switch the cleaning surface simultaneously and adjust into a new cleaning surface, improve the life of clean effect and cleaning surface.

Further, as shown in fig. 5 to 6, the glove module 12 includes:

a base b121, the base b121 being disposed on any one of the links of the transfer unit 11;

the telescopic unit c122 is fixedly arranged on the base b121 and is vertically arranged downwards; and

and a hand film 123, wherein the hand film 123 is rotatably arranged at the lower end of the telescopic unit c 122.

Further, as shown in fig. 4 to 6, the guide assembly 13 includes a guide rail 131 for driving the glove module 12 to perform two downward movements in the vertical direction and a guide 132 for driving the glove module 12 to perform a circular rotation;

when the glove module 12 is driven to the first horizontal portion 20b, the guide rail 131 drives the control rod on the telescopic unit c122 to be pulled down into the first horizontal portion 20b, and when the glove module 12 is driven to the second horizontal portion 20d, the guide rail 131 drives the control rod on the telescopic unit c122 to be pulled down into the second horizontal portion 20 d;

the guide member 132 includes a driven gear 133 coaxial with and synchronously driving the upper end of the hand membrane 123, and a driving rack 134 provided on the transmission unit 11 and engaged with the driven gear 133, wherein the driving rack 134 is located right above the second horizontal portion 20 d.

In this embodiment, by arranging the guide component 13 in cooperation with the glove module 12, the glove module 12 sequentially completes the pre-gluing operation at the first horizontal portion 20b and the gluing operation at the second horizontal portion 20d during the transmission process along the dipping tank body 2, the pre-gluing operation of the glove module 12 adopts a material dipping mode, thereby avoiding the phenomenon that the glove is too thick due to two gluing operations, and during the formal gluing operation, the guide component 132 drives the glove module 12 to perform the rotary gluing operation, because the water flow direction is opposite to the transmission direction of the glove module 12, the part of the glove module 12 facing the glue body has the effect of promoting the gluing, and on the contrary, the part facing away from the glue body has the effect of squeezing out the glue body of the glove module 12, so that the part needs the glove module 12 to adopt a structure of rotationally cooperating with the horizontal glue body, and the effect of improving the gluing is good.

In detail, the guide rail 131 drives the glove module 12 to move downwards along the inclined planes of the first inclined part 20a, the second inclined part 20c and the third inclined part 20e, and simultaneously, the guide rail 131 drives the glove module 12 to move downwards along the horizontal parts of the first horizontal part 20b and the second horizontal part 20d to the inside of the dipping tank body 2 to complete the pre-gluing work and the gluing work; meanwhile, after the driven gear 133 moves to the driving rack 134, the driven gear rotates under the driving of the driving rack 134, and the gluing operation is uniform in the gluing process; while the glove molding 12 is pre-glued as a dip when located in the first horizontal portion 20 b.

Further, as shown in fig. 7, the first transmission assembly 31 includes a bracket a21 disposed on the body 2 of the dip tank, a driving shaft a22 rotatably disposed on the bracket a21, and a turbine a23 coaxially and fixedly connected with the lower end of the driving shaft a22, the turbine a23 is used for driving water at the lower end of the body 2 of the dip tank to flow back into the glue applying space 202 from the impurity discharging space 203, and the driving shaft a22 is driven by the first motor 24 to rotate continuously.

In this embodiment, through setting up first transmission assembly 31 for turbine 23 is rotating the in-process, can be with the colloid transmission that is located the steeping vat cell body 2 bottom to the upper end of steeping vat cell body 2, and the colloid that is located the upper end flows to from impurity discharge space 203 under the action of gravity in, and then accomplishes the work of backward flow of whole colloid at steeping vat cell body 2.

Further, as shown in fig. 8, the second transmission assembly 32 includes a bracket b321 disposed on the dip tank body 2, a driving shaft b322 rotatably disposed on the bracket b321, and a turbine b coaxially and fixedly connected with the lower end of the driving shaft b322, and the driving shaft b322 and the driving shaft a22 are in synchronous transmission connection through a plurality of sets of synchronous belts;

the upper end of the driving shaft b322 is provided with a heat radiating blade, and the heat radiating blade performs physical cooling work on the hand membrane 123 in transmission.

In the embodiment, by arranging the second transmission assembly 32, on one hand, the second transmission assembly 32 is used for pumping the colloid in the upstream state, so that the problem of insufficient power for conveying the colloid passing through the two horizontal parts to the upper end of the glue dipping groove body 2 is avoided, and in addition, the heat dissipation blades are used for synchronous transmission, so that the physical cooling work for the hand membrane 123 in transmission is completed, the overhigh temperature of the hand membrane 123 is avoided, and the product quality is further improved; the structure is simple, additional power is saved, production is reduced, cooling is completed, and pumping work of the upflow colloid is promoted.

In detail, the driving shaft b322 is in synchronous transmission with the driving shaft a22 through a synchronous belt, the driving shaft b322 drives the turbine b to perform synchronous transmission, the power supply effect on the upward flowing colloid pumping is completed, and meanwhile, the heat dissipation blades rotating on the driving shaft b complete the hand membrane cooling work in the transmission process.

Further, as shown in fig. 17 to 21, the first discharging assembly 51 includes:

the horizontal pushing cylinder 511 is provided with a telescopic end which is vertically arranged downwards, and a telescopic unit a512 is fixedly arranged at the lower end of the horizontal pushing cylinder 511;

a limiting plate 513, wherein the limiting plate 513 is fixedly connected with the lower end of the telescopic unit a512 and is arranged in a manner of being matched with the width of the impurity discharging space 203, and the limiting plate 513 is of a filter screen structure;

the pushing cylinder 514 is made of elastic rubber materials, the pushing cylinder 514 is arranged on an outlet a510 formed in the partition plate 201 in a matching sliding mode and is horizontally arranged in the partition plate 201 through a telescopic unit b516, and the pushing cylinder 514 is used for discharging sediments in front of the brush roller 48; and

and the translation piece 517 comprises a driving rack a5171 fixedly connected with the telescopic unit b516, a driving gear a5172 meshed with the driving rack a5171, a driving gear b5173 coaxial and synchronously driven with the driving gear a5172, and a driving rack b5174 meshed with the driving gear b5173 and vertically arranged on the telescopic unit a 512.

Further, as shown in fig. 17 to 21, the first collecting assembly 52 includes:

the protruding platform 521 is arranged in the dip tank body 2 and protrudes outwards, and the protruding platform 521 is matched with the push-out cylinder 514 in structure;

a control gate 522, wherein the control gate 522 is driven by an electric signal to be automatically opened and closed; and

the first collecting box 523 is provided with a filter plate 524 inside, and liquid below the filter plate 524 is circularly pumped to the upper end of the glue dipping tank body 2 for recycling through the pump body.

In this embodiment, through setting up first collection subassembly 52 cooperation first ejection of compact subassembly 51 for accomplish a week impurity discharge during operation, accomplish earlier by limiting plate 513 and arrange the regional restriction of sediment work, treat impurity and fall behind, translation piece 517 redrives and pushes out a section of thick bamboo 514 and accomplish the complete discharge work to impurity, and waste material automatic discharge when clean thorough.

In detail, when the brush roll 48 moves to the first discharging assembly 51, at this time, the link mechanism 205 stops working, the distance sensor drives the horizontal pushing cylinder 511 to automatically start, the limiting plate 513 moves to the bottom of the gum dipping tank body 2, impurities are blocked by the limiting plate 513, colloid is output through the filter screen part of the limiting plate 513, then the telescopic unit a512 continues to extrude, the telescopic unit a512 drives the driving gear a5172 to rotate through the driving rack a5171, the rotating driving gear a5172 drives the driving rack b5174 to act on the telescopic unit a512, the pushing cylinder 514 discharges sediment in front of the brush roll 48, after the pushing cylinder 514 enters the protruding platform 521 together, the control door 522 automatically opens, the colloid and the impurities enter the first collecting box 523 together, the glue under the filter plate 524 is collected, and the impurities on the filter plate 524 are collected.

Further, as shown in fig. 15 to 16, the switching member 61 includes:

a driving gear 611, the driving gear 611 being coaxial with the horizontal portion of the rotating lever 42 and being synchronously driven;

a driven rack 612, wherein the driven rack 612 is fixedly connected with the telescopic unit a512 and is meshed with the driving gear 611; and

a friction roller 613, wherein the friction roller 613 is driven by a transmission member to rotate clockwise synchronously with the first transmission assembly 31, and the friction roller 613 is arranged in intermittent contact with the brush roller 48.

Further, as shown in fig. 16, the second collecting unit 62 includes:

a impurity removing plate 621, wherein the impurity removing plate 621 is positioned below the friction roller 613, a contact end part of the impurity removing plate 621 is provided with a chamfer, and the impurity removing plate 621 is installed on a frame 623 through an obliquely arranged tension spring 622; and

a second collection box 624, wherein the second collection box 624 is disposed below the impurity removing plate 621 and is used for collecting impurities on the impurity removing plate 621.

In this embodiment, through setting up 4 cooperation switching module 61 of clean mechanism, make clean mechanism 4 accomplish once cleaning work back every time, in first ejection of compact subassembly 51 automatic discharge material in-process, switching module 61 is to its automatic switch-over work of face of wasing after clean, make the brush roll 48 who washs the work at every turn remain the face of wasing all the time, improve clean effect, utilize simultaneously and utilize second collection subassembly 62, accomplish the self-cleaning work to the brush roll 48 face of wasing, and then guarantee the cleaning all the time of brush roll 48, improve the life and the high-usage of brush roll 48, brush roll 48 need not change often.

In detail, in the downward moving process of the driven rack 612, the driven rack 612 drives the driving gear 611 to rotate, the rotating driving gear 611 drives the rotating rod 42 to rotate, after the rotating rod 42 rotates to the impurity removing plate 621, the brush roller 48 and the brush 47 complete scraping of the cleaned bottom surface under the action of the impurity removing plate 621, and then the impurities drop into the second collection box 624 to be collected under the shaking of the tension spring 622; after the brush roller 48 on the rotating rod 42 moves to the friction roller 613, the friction roller 613 drives the brush roller 48 to rotate circumferentially by a distance between the elastic stop 49a and the pressing block 49b, so that the switching operation is completed, and finally the rotating rod 42 is reset to the glue dipping tank body 2 to wait for the next cleaning operation.

Example two

As shown in fig. 9 to 13, in which the same or corresponding components as those in the first embodiment are denoted by the same reference numerals as those in the first embodiment, only the points of difference from the first embodiment will be described below for the sake of convenience. The second embodiment is different from the first embodiment in that:

further, as shown in fig. 9 to 13, the cleaning mechanism 4 includes:

a base a41, the base a41 being disposed on any link of the linkage 205;

the telescopic shaft 41a is arranged on the base a41 along the vertical direction, the lower end of the telescopic shaft 41a is provided with a base 41b, and the telescopic shaft 41a completes lifting work along the vertical direction under the action of a limiting rail 41 c;

the rotating rod 42 is rotatably arranged in a guide groove 44 which is arranged on the base 41b and is in an L-shaped structure through a circular ring 43;

the limiting ring 45 is fixedly arranged at the lower end of the rotating rod 42;

the one-way bearing 46 is arranged in the limiting ring 45 in a matching and rotating mode;

the hairbrush 47 is arranged at the lower end of the limiting ring 45;

the brush roller 48 is sleeved outside the one-way bearing 46; and

the clamping piece 49 comprises a plurality of groups of elastic stoppers 49a arranged on the inner wall of the limit ring 45 and pressing blocks 49b arranged on the outer wall of the one-way bearing 46 and matched with the elastic stoppers 49a and correspondingly arranged.

In the present embodiment, the cleaning mechanism 4 is arranged such that the brush roller 48 and the brush 47 complete the cleaning of the bottom of the dip tank body 2 under the driving of the chain mechanism 205.

It is worth mentioning that the limiting rail 41c is matched with the control rod arranged on the telescopic shaft 41a, the driving brush roller 48 and the brush 47 are driven to transmit along the bottom of the impregnation tank body 2 all the time, and the impregnation tank body 2 plays a role in supporting and guiding.

It should be noted that the one-way bearing 46 is arranged to prevent the one-way bearing 46 from rotating clockwise during the process of flowing the colloid and the process of rubbing the bottom of the dip tank body 2, whereas when the brush roller 48 switches the brushing work surface, the brush roller 48 can rotate in the opposite direction by a certain angle to ensure the cleanness of the brush roller 48.

In addition, the limiting operation of the brush roller 48 for each rotation is completed by arranging the clamping piece 49, so that the rotation angle is switched to be fixed for each rotation.

The working process is as follows:

the chain-driven mechanism 205 drives the cleaning mechanism 4, so that the cleaning mechanism 4 finishes the automatic cleaning work on the side wall and the bottom of the impregnation tank body 2 in the process that the colloid flows along the impregnation tank body 2 for a circle;

when the brush roll 48 moves to the first discharging assembly 51, the chain mechanism 205 stops working at the moment, the distance sensor drives the horizontal pushing cylinder 511 to automatically start, the limiting plate 513 moves to the bottom of the gum dipping groove body 2, impurities are blocked by the limiting plate 513, colloid is output through a filter screen part of the limiting plate 513, then the telescopic unit a512 continuously extrudes, the telescopic unit a512 drives the driving gear a5172 to rotate through the driving rack a5171, the rotating driving gear a5172 drives the driving rack b5174 to act on the telescopic unit a512, the pushing cylinder 514 discharges sediment in front of the brush roll 48, after the pushing cylinder 514 enters the protruding platform 521, the control door 522 automatically opens, the colloid and the impurities enter the first collecting box 523 together, the glue under the filter plate 524 is collected, and the impurities on the filter plate 524 are collected;

the guide rail 131 drives the glove module 12 to downwards drive along the inclined planes of the first inclined part 20a, the second inclined part 20c and the third inclined part 20e, and simultaneously, the guide rail 131 drives the glove module 12 to downwards move along the horizontal parts of the first horizontal part 20b and the second horizontal part 20d into the dipping groove body 2 to complete pre-gluing work and gluing work; meanwhile, after the driven gear 133 moves to the driving rack 134, the driven gear rotates under the driving of the driving rack 134, and the gluing operation is uniform in the gluing process; when the glove module 12 is located in the first horizontal portion 20b, the glue applicator is used as a material dipping mode, the driving shaft b322 is synchronously driven with the driving shaft a22 through the synchronous belt, the driving shaft b322 drives the turbine b to synchronously drive, the power supply effect on the upward flow colloid pumping is completed, and meanwhile, the heat dissipation blades rotating on the driving shaft b complete the hand film cooling work in the transmission process.

In the description of the present invention, it is to be understood that the terms "front-back", "left-right", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referred device or component must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the invention.

Of course, in this disclosure, those skilled in the art will understand that the terms "a" and "an" should be interpreted as "at least one" or "one or more," i.e., in one embodiment, a number of an element may be one, and in another embodiment, a number of the element may be plural, and the terms "a" and "an" should not be interpreted as limiting the number.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily made by those skilled in the art in light of the technical teaching of the present invention should be included within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. The utility model provides a butyronitrile antiskid gloves production is with automatic temperature control device which characterized in that includes:

the glove conveying mechanism (1) comprises a conveying unit (11), a plurality of groups of glove modules (12) which are uniformly arranged on the conveying unit (11) at equal intervals and a guide assembly (13) for driving the glove modules (12) to lift;

the glue dipping tank body (2) is obliquely and downwards arranged and is positioned below the conveying unit (11), the glue dipping tank body (2) is of an oval structure, a partition plate (201) is arranged along the middle of the glue dipping tank body (2) and along the length direction of the glue dipping tank body (2), a glue applying space (202) and an impurity discharging space (203) are formed between the glue dipping tank body (2) and the partition plate (201), and the glue dipping tank body (2) is in smooth transition connection with a first inclined part (20a), a first horizontal part (20b), a second inclined part (20c), a second horizontal part (20d) and a third inclined part (20e) along the oblique downward direction;

the transmission mechanism (204) comprises a first transmission assembly (31) arranged at the third inclined part (20e) and positioned in the impurity discharging space (203), and a second transmission assembly (32) arranged at the lower end of the first inclined part (20a) and positioned in the impurity gluing space (202), wherein the first transmission assembly (31) and the second transmission assembly (32) synchronously transmit;

the chain-driven mechanism (205) is arranged right above the partition plate (201) and synchronously carries out transmission work along the transmission direction of water in the glue dipping tank body (2), and the chain-driven mechanism (205) is intermittently started;

the cleaning mechanisms (4) are arranged in groups at equal intervals along the transmission direction of the chain mechanism (205), and the cleaning mechanisms (4) are used for cleaning the bottom of the glue dipping tank body (2);

the first impurity collecting mechanism (5), the first impurity collecting mechanism (5) comprises a first discharging component (51) arranged in the partition plate (201) and a first collecting component (52) for collecting the impurities discharged by the first discharging component (51); and

the second impurity collecting mechanism (6) is arranged above the dip tank body (2), and comprises a switching component (61) for driving the cleaning mechanism (4) to automatically switch the decontamination surface and a second collecting component (62) for cleaning the cleaning mechanism (4) in the switching process for the second time.

2. An automatic temperature control device for the production of nitrile non-slip gloves according to claim 1, characterized in that the glove module (12) comprises:

a base b (121), the base b (121) being disposed on any one of the links of the transport unit (11);

the telescopic unit c (122) is fixedly arranged on the base b (121) and vertically arranged downwards; and

the hand membrane (123) is rotatably arranged at the lower end of the telescopic unit c (122).

3. The automatic temperature control device for butyronitrile antiskid glove production according to claim 2, wherein the guide assembly (13) comprises a guide rail (131) for driving the glove module (12) to move downwards twice in the vertical direction and a guide member (132) for driving the glove module (12) to rotate circumferentially;

when the glove module (12) is transmitted to the first horizontal part (20b), the guide rail (131) drives the control rod on the telescopic unit c (122) to be pulled down into the first horizontal part (20b), and when the glove module (12) is transmitted to the second horizontal part (20d), the guide rail (131) drives the control rod on the telescopic unit c (122) to be pulled down into the second horizontal part (20 d);

the guide piece (132) comprises a driven gear (133) which is coaxial with and synchronously drives the upper end of the hand membrane (123) and a driving rack (134) which is arranged on the transmission unit (11) and meshed with the driven gear (133), and the driving rack (134) is positioned right above the second horizontal part (20 d).

4. The automatic temperature control device for producing butyronitrile anti-slip gloves as claimed in claim 1, wherein the first transmission assembly (31) comprises a bracket a (21) arranged on the dipping tank body (2), a driving shaft a (22) rotatably arranged on the bracket a (21), and a turbine a (23) which is coaxial with and fixedly connected with the lower end of the driving shaft a (22), the turbine a (23) is used for driving water at the lower end of the dipping tank body (2) to flow back into the gluing space (202) from the impurity discharge space (203), and the driving shaft a (22) is driven by the first motor (24) to rotate continuously.

5. The automatic temperature control device for butyronitrile antiskid glove production according to claim 4, wherein the second transmission assembly (32) comprises a bracket b (321) arranged on the dip tank body (2), a driving shaft b (322) rotatably arranged on the bracket b (321), and a turbine b (323) coaxial with and fixedly connected with the lower end of the driving shaft b (322), wherein the driving shaft b (322) and the driving shaft a (22) are synchronously connected through a plurality of groups of synchronous belts in a transmission manner;

and the upper end of the driving shaft b (322) is provided with a radiating blade, and the radiating blade performs physical cooling work on the hand membrane (123) in transmission.

6. The automatic temperature control device for the production of butyronitrile anti-slip gloves according to claim 1, characterized in that the cleaning mechanism (4) comprises:

a base a (41), wherein the base a (41) is arranged on any chain link of the linkage mechanism (205);

the telescopic shaft (41a) is arranged on the base a (41) along the vertical direction, a base (41b) is arranged at the lower end of the telescopic shaft (41a), and the telescopic shaft (41a) completes lifting work along the vertical direction under the action of a limiting rail (41 c);

the rotating rod (42) is rotatably arranged in a guide groove (44) which is formed in the base (41b) and is in an L-shaped structure through a circular ring (43);

the limiting ring (45) is fixedly arranged at the lower end of the rotating rod (42);

the one-way bearing (46), the one-way bearing (46) is matched and rotatably arranged in the limiting ring (45);

the hairbrush (47), the said hairbrush (47) is set up in the lower end of the said spacing ring (45);

the brush roll (48), the brush roll (48) is sleeved outside the one-way bearing (46); and

screens piece (49), screens piece (49) include that a plurality of groups circumference sets up elastic stop (49a) and setting of spacing ring (45) inner wall are in one-way bearing (46) outer wall and with elastic stop (49a) match briquetting (49b) that corresponds the setting.

7. The automatic temperature control device for the production of butyronitrile anti-slip gloves according to claim 6, characterized in that, the first discharging component (51) comprises:

the horizontal pushing cylinder (511), the telescopic end of the horizontal pushing cylinder (511) is vertically arranged downwards, and the lower end of the horizontal pushing cylinder is fixedly provided with a telescopic unit a (512);

the limiting plate (513) is fixedly connected with the lower end of the telescopic unit a (512) and is matched with the width of the impurity discharging space (203), and the limiting plate (513) is of a filter screen structure;

the pushing cylinder (514) is made of elastic rubber materials, the pushing cylinder (514) is arranged on an outlet a (510) formed in the partition plate (201) in a matching sliding mode and is horizontally arranged in the partition plate (201) through a telescopic unit b (516), and the pushing cylinder (514) is used for discharging sediments in front of the brush roller (48); and

the translation piece (517) comprises a driving rack a (5171) fixedly connected with the telescopic unit b (516), a driving gear a (5172) meshed with the driving rack a (5171), a driving gear b (5173) coaxial and synchronously driven with the driving gear a (5172), and a driving rack b (5174) meshed with the driving gear b (5173) and vertically arranged on the telescopic unit a (512).

8. An automatic temperature control device for the production of nitrile gloves according to claim 7, characterized in that said first collection assembly (52) comprises:

the protruding platform (521) is arranged in the glue dipping tank body (2) and protrudes outwards, and the protruding platform (521) is matched with the push-out cylinder (514) in structure;

a control gate (522), the control gate (522) being automatically opened and closed by an electric signal; and

the device comprises a first collecting box (523), wherein a filter plate (524) is arranged inside the first collecting box (523), and liquid below the filter plate (524) is circularly pumped to the upper end of a glue dipping tank body (2) for recycling through a pump body.

9. An automatic temperature control device for the production of nitrile gloves according to claim 7, characterized in that said switching assembly (61) comprises:

a driving gear (611), the driving gear (611) being coaxial with and synchronously transmitting with the horizontal portion of the rotating lever (42);

the driven rack (612) is fixedly connected with the telescopic unit a (512) and meshed with the driving gear (611); and

a friction roller (613), wherein the friction roller (613) is driven by a transmission piece to rotate clockwise synchronously with the transmission mechanism (204), and the friction roller (613) is arranged in intermittent contact with the brush roller (48).

10. An automatic temperature control device for the production of nitrile gloves according to claim 9, characterized in that said second collection assembly (62) comprises:

the impurity removing plate (621) is positioned below the friction roller (613), a chamfer is arranged at the contact end part of the impurity removing plate (621), and the impurity removing plate (621) is arranged on a rack (623) through an obliquely arranged tension spring (622); and

a second collection tank (624), the second collection tank (624) being disposed below the impurity removing plate (621) and used for collecting impurities on the impurity removing plate (621).

Images