CN210880539U - Quantitative automatic gold powder adding device suitable for hot press molding of melamine resin vessel - Google Patents

Abstract

The application discloses be applicable to automatic gold powder device that adds of melamine fat household utensils hot briquetting ration, include: a first material containing part, which is provided with a first discharging groove penetrating in the fifth direction; a second material containing part, which is provided with a second discharging groove communicated in a sixth direction; the first moving device is connected with the first material containing part and used for moving along the seventh direction so that the materials in the first material containing part fall into the second material containing part through the first discharging groove; the second moving device is positioned at the discharge hole of the second discharge groove and used for controlling the material in the second material containing part to fall into the vessel through the second discharge groove; and the controller is used for controlling the movement of the first moving device and the second moving device. The utility model provides an automatic gold powder device that adds suitable for melamine fat household utensils hot briquetting ration can realize that automation, ration and the accuracy of powder add, has guaranteed machining efficiency, and has reduceed the defective percentage greatly.

Description

Quantitative automatic gold powder adding device suitable for hot press molding of melamine resin vessel

Technical Field

The utility model relates to a powder technical field that feeds in raw material especially relates to a be applicable to automatic gold powder device that adds of melamine fat household utensils hot briquetting ration.

Background

In the final step of hot press molding of melamine resin powder into melamine resin vessel, some additive powder, such as colored powder, is added to the vessel for processing the melamine resin to improve the processing effect and the aesthetic property. Use adding the gold powder as an example, generally adopt artifical mode of adding in the prior art, but because artifical pre-estimated volume is inaccurate, the addition in every household utensils is probably inequality, the household utensils are easily glued the difficult drawing of patterns of mould when the gold powder volume has increased the drawing of patterns, the gold powder volume has been reduced, the household utensils quotation can lack the gold, become unqualified substandard product, secondly, the mode of artifical interpolation can make the gold powder position of feeding inaccurate, also can cause and lack the gold phenomenon, there is not little loss volume even to the raw materials, the cost is higher, in addition, the efficiency of interpolation also can greatly influence the efficiency of processing.

SUMMERY OF THE UTILITY MODEL

The utility model aims at the above problem, provide an automatic gold powder device that adds suitable for melamine fat household utensils hot briquetting ration, can realize that automation, ration and the accuracy of powder add, guaranteed machining efficiency, and reduceed the defective percentage greatly.

The utility model adopts the following technical scheme: the utility model provides an automatic gold powder device that adds suitable for melamine fat household utensils hot briquetting ration, include:

a first material containing part, which is provided with a first discharging groove penetrating in the fifth direction;

a second material containing part, which is provided with a second discharging groove communicated in a sixth direction;

the first moving device is connected with the first material containing part and used for moving along a seventh direction so that the material in the first material containing part falls into the second material containing part through the first discharging groove;

the second moving device is positioned at a discharge hole of the second discharge chute and used for controlling the materials in the second material containing part to fall into a vessel through the second discharge chute;

and the controller is used for controlling the motion of the first moving device and the second moving device.

In an example of the present invention, the second moving device completely covers the discharge port of the second discharge chute so that the material can be stored in the second material accommodating portion.

In an example of the present invention, the second moving device moves in an eighth direction so that the material in the second material containing portion falls into the vessel.

In an example of the present invention, the first moving device is along the moving process of the seventh direction, the first material containing bin and the second moving device are made of teflon.

In an example of the present invention, the second moving device rotates around a fixed shaft so that the material in the second material containing portion falls into the vessel.

In an example of the present invention, a sliding guide set is disposed on the inner side wall of the second material containing portion along the seventh direction, and the first material containing portion is slidably disposed on the sliding guide set.

In an example of the present invention, the second material containing portion further includes a sealing plate, the sealing plate is supported and disposed at the discharge port of the first discharge chute, and the first material containing portion is sealed.

In an example of the present invention, the sealing plate is located at the bottom of the second material accommodating portion, the second discharging groove is arranged on the sealing plate in a penetrating manner, and the sealing plate is slidably arranged on the sliding guide rail set; the sealing plate is an aluminum plate.

In an example of the utility model, be applicable to automatic gold powder device that adds of melamine fat household utensils hot briquetting ration still includes cleaning device, cleaning device is just to household utensils setting for the dirt on clean household utensils surface.

In an embodiment of the present invention, the device for quantitatively and automatically adding gold powder for hot press forming of melamine resin vessels further includes a first driving device and a second driving device respectively connected to the controller, the controller respectively controls the respective actions of the first driving device and the second driving device, and the first driving device is connected to the first moving device to control the movement of the first moving device in the seventh direction; the second driving device is connected with the second moving device to control the action of the second moving device.

The utility model has the advantages that: the utility model provides a be applicable to automatic gold powder device that adds of melamine fat household utensils hot briquetting ration, add gold powder in first appearance material portion, when controller control first mobile device drives first appearance material portion and moves to seventh direction, gold powder in first appearance material portion falls into second appearance material portion through first blown down tank, then controller control second mobile device moves to eighth direction, make the discharge gate of second blown down tank open, make gold powder in second appearance material portion can fall into the household utensils through the second blown down tank and carry out hot briquetting, can automatic control the moving speed of first mobile device and the number of times of round trip movement through the controller, and then control the powder volume that falls into second appearance material portion, gold powder after the ration in second appearance material portion falls into the household utensils, and then can realize the automation of powder, ration and add accurately, processing efficiency has been guaranteed, and the defective rate is greatly reduced.

Drawings

FIG. 1 is a schematic view of an integrated mechanism;

FIG. 2 is a schematic perspective view of the feed mechanism;

FIG. 3 is a schematic view of a portion of the structure of FIG. 2;

FIG. 4 is a schematic view of the overall structure of the feeding mechanism and the ingot pressing mechanism;

FIG. 5 is a schematic structural view of the ingot pressing mechanism;

FIG. 6 is a schematic view of the structure of the adjustment member;

FIG. 7 is a schematic structural view of a feeding mechanism and a conveying mechanism;

FIG. 8 is a schematic view of the connecting arm;

FIG. 9 is a schematic view showing the assembly relationship between the automatic gold powder feeding device and the moving module in the hot press molding step;

FIG. 10 is a schematic structural view of an automatic gold powder feeding device in the hot press molding step;

FIG. 11 is a schematic view showing the internal structure of an automatic gold powder feeding apparatus;

FIG. 12 is a sectional view of an automatic gold powder feeding device;

FIG. 13 is a schematic flow diagram of a processing method;

fig. 14 is a schematic flow chart of an ingot pressing method.

The figures are numbered:

100. a feeding mechanism; 200. a pressing mechanism; 300. a grabbing mechanism;

110. a material box; 120. a mold mounting section; 130. a material pushing device; 131. a box body; 132. a pushing part; 133. a discharge port; 134. a material poking module;

22. a first force device; 23. a second force device; 24. a fixed platform; 25. a depth adjustment module;

212. a material containing part; 213. a second force applying member; 211. a first force application member; 241. a limiting module; 251. a connecting member; 252. an adjustment member; 2521. adjusting a rod; 2522. an adjusting block; 2523. a stopper;

310. an array module; 311. a conveying section; 312. a fourth force applying member; 320. a grabbing module; 321. a main board; 322. grasping the part; 330. a trajectory control module; 331. a slide rail module;

400. a gold powder adding device; 401. a mounting frame; 402. a motion module; 410. a first driving device; 411. a sliding guide rail set; 412. a first mobile device; 420. a first material containing part; 421. a second material containing part; 422. a feed box cover; 430. a sealing plate; 431. a second mobile device; 432. a mounting base of the cleaning device; 433. a second driving device; 4201. a first discharge chute; 4211. a second discharge chute;

510. a rotating part; 520. a connecting arm; 530. a first telescoping module; 540. a grasping section; 550. and the second telescopic module.

Detailed Description

The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which embodiments of the invention are shown.

The first direction involved in the technical scheme is a vertical direction, and the forward direction is a vertical downward direction. The second direction is a horizontal direction, the third direction is a horizontal direction, the second direction is perpendicular to the third direction, and the preset plane is a horizontal plane. The fourth direction is a vertical direction, the fifth and sixth directions are vertical directions, the seventh and eighth directions are horizontal directions, and the seventh and eighth directions are opposite directions.

Referring to fig. 1-14, an automatic processing system according to the present invention is illustrated by taking melamine resin powder hot-press molding as an example.

The automatic processing system includes:

the feeding mechanism 100, the ingot pressing mechanism 200, the grabbing mechanism 300 and the hot press forming mechanism are mainly composed of four parts.

Wherein, the feeding mechanism 100 is used for realizing automatic feeding and automatically feeding powder into the die. The mold is placed in a cavity of the pig mechanism 200.

After the required powder is put into the mold, the ingot pressing mechanism 200 performs ingot pressing work to press the powder into an ingot-shaped finished product, and the second acting force device 23 is arranged in the ingot pressing mechanism 200 to eject the powder ingot out of the mold and push the powder ingot out of the material pulling module 134 on the feeding mechanism 100 to the grabbing mechanism 300.

Snatch mechanism 300 mainly used and carry out large batch powder ingot and snatch, for so that use, the powder ingot forms the array in the array module 310 who snatchs mechanism 300, perhaps adopts established mode of arranging also can, as long as can realize snatching when a large amount of powder ingots can, can realize like this that large batch powder ingot snatchs.

In this embodiment, in order to facilitate the transportation of the grabbing mechanism 300 to the hot press forming mechanism, a conveying device is provided on the grabbing mechanism 300, so that the grabbing mechanism 300 can more stably transfer the powder ingot and realize automation in the process of conveying the powder ingot.

Snatch the powder spindle on the mechanism 300 and place in hot briquetting mechanism, the mode through hot pressing carries out hot briquetting with the powder spindle, at this in-process, in order to realize better shaping effect and pleasing to the eye effect, often all can adopt the mode of interpolation batching among the prior art, to this, set up automatic whitewashed device that adds on hot briquetting mechanism for add the batching to the powder spindle ration in the household utensils, in order to realize automatic interpolation, realize the ration interpolation of batching simultaneously.

Through the cooperative work of the above components, the high-efficiency and high-quality automatic processing is realized, the production efficiency can be greatly improved, and almost identical finished products can be obtained.

The processing method corresponding to the processing equipment comprises the following steps:

parameter setting step: the equipment is started and the parameters to be automatically processed are set.

And (3) ingot pressing: after the powder is added according to the capacity in the die, ingot pressing is carried out so that the powder in the die forms a powder ingot.

And the depth of the mold in the mold is automatically adjusted according to the parameters in the parameter setting step.

The feed mechanism 100 effects automatic addition of powder by reciprocating over the die as powder is added to the die.

The powder ingot is automatically ejected out of the die after being formed into a powder ingot.

To improve efficiency, the ejector module pushes the powder ingot out of the processing surface during the feeding process by the reciprocating motion of the feeding mechanism 100 above the die.

In this embodiment, the powder ingots are arranged in an array form while being pushed out.

Hot press molding: and taking out the powder ingot, placing the powder ingot into a vessel in a hot press forming die for hot press forming, starting a plain surface program, performing applique or gold adding operation, finally demolding and taking a piece, and cleaning waste materials in the vessel by using a high-pressure air gun.

Wherein, in order to adapt to different powder spindle hot pressing requirements in the hot briquetting step, be provided with a plurality of other contents:

a transmission step: and carrying out integral grabbing and conveying on the powder ingots in the array form to a vessel. During transport, the powder ingots in the form of an array are preheated in a high frequency machine preheater.

In this process, the robot arm is used to transfer the powder to realize an automated production section.

The process can realize a complete set of automatic processing mode of the melamine resin powder.

Referring to fig. 2 and 3, as a specific embodiment, the specific structure of the feeding mechanism 100 includes:

a bin 110 for storing powder;

and the material pushing device 130 is communicated with the bottom of the material box 110 and is used for automatically adding the powder in the material box 110 into the die.

A fixed platform 24 is arranged at the bottom of the pushing device 130 to serve as a carrier of the pushing device 130. Meanwhile, the ingot pressing mechanism 200 is also arranged on the fixed platform 24, an opening is arranged on the fixed platform 24, and the top of the mold in the ingot pressing mechanism 200 is connected with the opening on the fixed platform 24.

The bottom of the material pushing device 130 may be a structure without any baffle, that is, a structure directly connected to the fixed platform 24, or may be a structure of a box 131, and a material outlet 133 is provided at the bottom, so that the powder in the material box 110 can be added into the mold during the movement of the material pushing device 130 on the fixed platform 24.

As a specific embodiment, the fixed platform 24 is provided with a limiting module 241 for limiting a moving track of the pushing device 130, and a related structure of a sliding rail may be adopted, the fixed platform 24 is provided with a sliding rail, the pushing device 130 is provided with a connecting member 251, and the pushing device 130 slides on the sliding rail through the connecting member 251. In this embodiment, two slide rails are adopted.

As a specific example, the bin 110 may be made of a transparent material, so that during the whole processing process, the worker can observe the remaining amount of powder in the bin 110 in real time to add the powder in time.

As a specific example, the inside of the bin 110 may be provided with a monitoring element for monitoring the powder content in the box 131, and a display module or an alarm device or the like may be matched to the monitoring element to play a role of a prompt.

In this embodiment, the monitoring element may be an infrared device, since the box 131 is filled with powder, the powder may automatically move downward during use, and an appropriate position inside the box 131 is provided with an infrared emitter and an infrared receiver on a set of opposite surfaces, respectively, when the powder falls below the infrared emitter, the infrared receiver may receive a signal, and at this time, a prompt of the display module or a prompt of the alarm device may be triggered, thereby realizing an automatic operation of adding powder in the hopper 110.

As a specific embodiment, the pushing device 130 may be provided with a pushing portion 132 located outside the box 131 for providing power to move the pushing device 130 on the limiting module 241. The pushing unit 132 is provided with a control module therein to set the pushing distance and the pushing period of the pushing device 130.

As a specific embodiment, the material containing mold is installed in the mold installation portion 120, and in order to more quickly fill the mold with powder during the material pushing process of the material pushing device 130, if the material pushing device 130 adopts a box 131 structure, the cross section of the material outlet 133 at the bottom of the material pushing device completely covers the material inlet of the material containing mold, or in the direction perpendicular to the pushing direction of the pushing device, the cross section of the material outlet 133 can completely cover the maximum width of the material inlet of the material containing mold during the pushing process of the material outlet 133. Therefore, when the pushing device 130 pushes, the cross section of the die can be covered by the powder, and rapid high-quality feeding is realized.

As a specific example, after the ingot pressing mechanism 200 presses the powder ingot in the material holding mold, the second force applying device 23 in the ingot pressing mechanism 200 may push the powder ingot out to the fixing platform 24, and at this time, an independent third force applying member may be disposed on the fixing platform 24 to push the powder ingot away from the position of the mold. At this time, the feeding mechanism 100 feeds again to realize a linked feeding-ingot pressing-pushing process.

As a specific example, the third force applying member can make full use of the movement of the pushing device 130, and the third force applying member is disposed on the pushing device 130. The end of the third force applying member in contact with the powder ingot is marked as the kick-out block 134. The kick-off modules 134 are shaped to match the powder ingot to reduce the impact on the powder ingot.

The material pulling module 134 can work independently, and as long as the second acting force device 23 pushes out the powder ingot, the material pulling module 134 can push the powder ingot to the lower part of the grabbing mechanism 300.

Or, the material pushing device 130 may not be provided with a separate driving component, and is directly installed at the front end of the box 131 of the material pushing device 130, and by setting the motion trajectory of the pushing device, when the material pushing module 134 pushes the powder ingot to the lower side of the grabbing mechanism 300, the pushing device can feed the mold at the same time, so that the simultaneous work of powder adding and powder ingot pushing is realized, the work cycle can be greatly reduced, and the processing efficiency is improved.

As a specific example, a cleaning part may be provided on the feeding mechanism 100 to blow out the powder remaining on the fixed platform 24 by blowing air to improve the cleanliness of the whole processing table.

As a specific example, the powder ingot is shaped as a cylinder, and the material pushing module 134 is shaped as an arc, which is consistent with the powder ingot.

Referring to fig. 4 and 5, as a specific embodiment, the ingot pressing mechanism 200 structurally includes a material accommodating member 212 for accommodating melamine resin powder; the first acting force device 22 is used for pressing an ingot on one surface of the material containing part 212; and the second force device 23 is connected with the material containing part 212 and is used for ejecting the pressed product out of the material containing part 212. Wherein the material containing part 212 can be replaced and comprises the ingot pressing end of the first force device 22, so that the production of powder ingots with different scales can be realized.

When the powder storage device is used specifically, powder is stored in the material storage part 212, then the powder is pressed and molded by the first acting force device 22, and finally the pressed and molded block is ejected by the second acting force device 23. The process can realize the automatic ingot pressing and molding of the powder.

As a specific example, if there is a relatively fine requirement for the size of the powder lump, a weighing module may be disposed on the top of the second force application member 213, and during the process of continuously injecting the powder into the material accommodating member 212, the weighing module performs weighing to make the powder amount reach the requirement, so that the cake weight after each processing is the same. After feeding, the pushing device 130 moves from the fixed platform 24 to trowel the redundant powder, the weight of the weighing module is the weight of the final powder ingot at the moment, and records are formed, and as the powder ingots are arranged in an array, as long as the several groups of the powder ingots grabbed by the grabbing mechanism 300 can be recorded, rapid positioning can be realized.

If need remind in time, can be provided with the threshold value in weighing module, when the result of weighing not in reasonable scope, report to the police promptly, need artifical intervention in order to adjust.

In order to adapt to different material containing modules, for example, in the case of the same cross section, powder ingots of different heights need to be produced, and at this time, the second force application member 213 of the material containing member 212 needs to be adjusted in height.

As a specific example, the height of the cake product can be changed by adjusting the depth adjusting module 25, which can be manually or automatically.

By way of example, the adjustment member 252 is configured to:

an adjustment rod 2521 for defining a sliding trajectory of the connection 251;

an adjustment block 2522 on the adjustment rod 2521 for defining a movement range of the connection member 251;

a stop 2523 on the connection 251 for movement between the adjustment blocks 2522;

wherein the position of the adjustment block 2522 on the adjustment rod 2521 is movable.

The moving range of the stopper 2523 is changed by manually changing the position of the adjusting block 2522, namely, the moving range of the position of the connecting member 251 is changed, and after the cake-shaped product is pushed out, the connecting member 251 is descended to the position of the adjusting block 2522, so that the cake-shaped product can quickly reach the specified position.

Taking an automatic mode as an example, the structure of the adjusting block 2522 is added to the structure of the electronic ruler, so that the height of the electronic ruler can be remotely controlled according to actual needs, and the size can be controlled.

The mode of in time modifying can also be selected, namely, the real-time weighing is carried out in the process of continuously injecting the powder, each height of the electronic ruler can correspond to the weight of the powder in the material containing part 212 under the current height, and when the weighing module detects that the current weight exceeds the weight of the powder at the current height, an adjusting signal is sent to the electronic ruler for adjusting, so that an automatic correcting mode can be realized.

As a specific embodiment, the power sources of the first acting force device 22 and the second acting force device 23 adopt hydraulic cylinders, and a hydraulic frame is arranged to fix each component.

The hydraulic frame adopts the design of four columns and five layers, the fixed platform 24 is used for fixing the powder channel and building the automatic powder feeding mechanism 100, and is connected with the array transmission mechanism, the second force application part 213 has the main function of changing the volume in the cavity of the material containing channel by using the depth adjusting module 25 to carry out powder weighing and metering, an electronic ruler is installed to automatically adjust the volume according to the requirement of the weight of a powder ingot by a program, and the lifting is responsible for lifting and ejecting the pressed powder ingot upwards to eject the cavity of the material containing channel to be demolded. The upper hydraulic cylinder is connected with the first force application piece 211 through a first force application piece 211 installation sliding block, and mainly has the main function of applying pressure to powder in the material containing channel cavity and pressing the powder into powder ingots, wherein the pressure can be set; the material containing channel is filled with powder through an automatic powder feeding mechanism 100 arranged on the die fixing platform 24, and ingots are pressed circularly.

As a specific embodiment, the ingot pressing process is divided into several steps:

a feeding step: and automatically adding the powder to be processed into the die, and pushing the removed powder ingot away from the upper part of the die before adding the powder into the die.

If the adjustment rod 2521 is adjusted manually, the weight of the powder ingot processed this time is set before the feeding step. And manually or remotely adjusting the depth of the die according to the set weight of the powder ingot.

If an automatic adjustment mode is adopted, taking the above embodiment as an example, the electronic ruler is adopted and the weighing module is arranged, then the weighing module is used for weighing the powder in real time in the process of adding the powder into the die, and the electronic ruler automatically adjusts the depth of the die according to the weight in the process of adding the powder.

And (3) ingot pressing: and carrying out ingot pressing and molding on the powder in the mold to obtain a powder ingot.

And (3) an ejection step: the powder ingot is ejected from the mold, and the powder is ingot-pressed from above the mold by the ingot pressing mechanism 200. In the ejection process, the ejection mechanism and the ingot pressing mechanism 200 are kept relatively static, in the process of ejecting the powder ingot, the ingot pressing mechanism 200 applies acting force to the powder ingot so that the upper part and the lower part of the powder ingot have acting force, and after the powder ingot is moved out of the die, the ingot pressing mechanism 200 continues to move so as to be separated from the powder ingot.

Referring to fig. 6, after the powder ingot is pressed into an ingot shape by the ingot pressing mechanism 200, the powder ingot is pushed out from the fixed platform 24 to the conveying part 311 by the material pushing module 134, and then the powder ingot is grabbed and transported by the grabbing module 320.

As a specific example, the conveying part 311 conveys the powder ingots at a fixed period, so that at least one row of the powder ingots is distributed on the conveying part 311 and the powder ingots are uniformly distributed.

In order to be able to increase the distribution density of the powder ingots even further, not only a row of powder ingots is realized, but also the powder ingots are formed into an array. The powder ingot is subjected to position change by the fourth force application member 312, taking the array as n × m as an example, the specific process is as follows: when the powder ingot is just pushed onto the conveying portion 311, the position is recorded as [1,1], and if the fourth force application member 312 is not operated, the conveying portion 311 performs a conveying operation to the position [1,2] for a distance period, which is a distance between two adjacent conveying positions, and so on, thereby forming a row array of 1 × m.

If the fourth force applying member 312 is activated, when the powder ingot is located at the position [1,1], the fourth force applying member 312 may push the powder ingot to the position [2,1] along a direction perpendicular to the conveying direction of the conveying portion 311 on the surface where the conveying portion 311 is located, the next powder ingot is placed at the position [1,1], and then the conveying portion 311 conveys the powder ingot again, and so on, so as to realize a 2 × m matrix distribution.

By analogy, for the first n powder ingots, the fourth force application member 312 is sequentially pushed to the positions [ n,1], [ n,1], …, [1,1], so as to obtain a column matrix of n × 1, and the conveying portion 311 conveys again, so that by analogy, a matrix of n × m can be obtained.

Of course, the driving control of the fourth force application member 312 is matched with a control module, the pushing distance is set every time according to the size of the matrix actually required, the distance between the matrixes to be formed is not necessarily equal, as long as the pushing at every time can realize the distinguishing of the positions, and the distance can be ensured as long as the adjacent powder ingots cannot be crossed.

As a specific example, the fourth force application member 312 may be matched with a sliding rail, a plurality of track points are disposed on the sliding rail, and the distribution of the track points corresponds to the n-row array, so that the fourth force application member 312 can be directly controlled to push the predetermined track points, thereby improving the pushing precision of the fourth force application member 312.

As a specific example, the fourth force-applying member 312 can move at a fixed distance, and a sliding rail is provided at the bottom of the conveying portion 311, and the relative movement between the fourth force-applying member 312 and the conveying portion 311 is realized by moving the conveying portion 311 in a direction perpendicular to the pushing direction of the pushing mechanism.

In the present embodiment, the conveying direction of the conveying portion 311 coincides with the pushing direction of the pushing mechanism.

As a specific example, the gripping members 322 of the gripping module 320 are distributed in the same array at the maximum array on the conveying part 311, which is generally the array of powder ingots on each conveying part 311. If the array distribution is not as dense as required due to the processing requirements of different powder ingots, the operation distance and the operation period of the conveying part 311 and the fourth force application member 312 can be adjusted, in this case, due to the distribution mode of the gripping members 322 in the embodiment, all the powder ingots on the conveying part 311 can be gripped simultaneously, and only if the utilization rate is not hundreds, there will be idle gripping members 322.

As a specific example, the grabbing mechanism 300 is provided with a positioning member for accurately positioning the grabbing member 322 to the powder ingot, and may be generally disposed on the grabbing member 322 or disposed on the main plate 321.

As a specific example, the grabbing mechanism 300 is matched with a track control module 330, so as to directly control the position of the grabbing member 322, replace the function of the positioning member, or make the positioning member used as an alternative, and improve the grabbing precision of the whole device.

In this embodiment, adopt the triaxial sliding structure that relatively commonly uses in the industrial production, namely, x axle slide rail, y axle slide rail and z axle slide rail, adopt sliding cylinder or sliding block to be connected between the adjacent slide rail. The position of the grabbing mechanism 300 is accurately positioned through cooperation of the x-axis slide rail and the y-axis slide rail, and finally accurate grabbing action is realized through the z-axis slide rail.

As a specific example, the z-axis slide rail and the gripping mechanism 300 are interconnected to achieve the up-and-down gripping action of the gripping mechanism 300.

As a specific example, the gripping member 322 employs a vacuum chuck structure to achieve gripping of the powder ingot without any damage to the surface of the powder ingot.

After the powder ingot is processed and formed, the next procedure is to carry out hot pressing final forming. In this process, the gripping mechanism 300 is provided with a conveying device for transferring the gripping mechanism 300 to the upper side of the hot press mechanism and placing the powder ingot into the vessel for hot press molding.

As a specific embodiment, the conveying device is in the form of a mechanical arm, more than one connecting arm 520 is arranged, the connecting arm 520 is connected with the grabbing mechanism 300, no acting force is generated between the connecting arm 520 and the grabbing mechanism 300 during the grabbing action of the grabbing mechanism 300, including the accurate positioning process realized by the three-axis sliding rail, after the grabbing mechanism 300 grabs all the powder ingots with the array structure, the grabbing mechanism 300 moves up and down through the z-axis sliding rail, so that the top of the grabbing mechanism 300 is connected with the connecting arm 520, and then the grabbing mechanism 300 is separated from the z-axis sliding rail. A telescoping structure may be provided on the connecting arm 520 to enable the gripping mechanism 300 to perform a downward action when gripping the powder ingot over the vessel.

As another embodiment, the powder ingots are conveyed to a transfer platform by the grabbing mechanism 300, the end of the conveying device is provided with the grabbing part 540, so that when the grabbing mechanism 300 grabs the powder ingots onto the transfer platform, the conveying device can convey the powder ingots in time, the efficiency can be improved by the structure with a plurality of mechanical arms, on one hand, one part of the grabbing mechanism 300 continuously transfers the powder ingots to the transfer platform, on the other hand, the grabbing part 540 on the other part of the conveying device continuously transfers the powder ingots, on the other hand, the work of conveying the powder ingots is divided into two grabbing parts 540, so that the mechanical movement distance of each grabbing part 540 is relatively short, the error of the movement is relatively small, and the precision of grabbing operation and the like of the whole device is realized.

As a specific example, the rotating part 510 may be provided such that more than one connecting arm 520 is provided when a form of a robot arm is employed, and the connecting arms 520 are transferred around the rotating part 510, thereby achieving simultaneous working of a plurality of stations to achieve an improvement in production efficiency.

As a specific example, a moving module is provided on the connecting arm 520 for changing the position of the gripping part 540 on the connecting arm 520, mainly to realize the vertical movement and the horizontal movement of the gripping part 540 relative to the connecting arm 520.

Three possible schemes are proposed in this example:

as a specific example of the implementation of the method,

the first moving portion includes: a first expansion module 530 disposed on the connecting arm 520;

a connection block for connecting the first expansion module 530 and the second moving part;

wherein the first telescopic module 530 is used for changing the position of the second moving part relative to the connecting arm 520.

The second moving portion includes:

and a second expansion module 550 for connecting the block and the grip part 540, for changing a distance between the grip part 540 and the block.

During specific use, the horizontal position of the second moving part is realized through the extension and retraction of the first telescopic module 530, and the distance between the grabbing mechanism 300 and the powder ingot in the vertical direction is realized by the second telescopic module 550.

When the powder ingot is located the transfer platform, the connecting arm 520 uses the rotating part 510 as the axle center, rotate to the established position, namely the top of transfer platform, first flexible module 530 stretches out and draws back so that snatch mechanism 300 and be located the powder ingot directly over, the flexible module 550 of second stretches out and draws back so that snatch mechanism 300 and can realize snatching the action, snatch the powder ingot, later the connecting arm 520 continues to rotate, make and snatch the module 320 and can be located the top of household utensils, later the flexible module 550 of second continues to stretch out and draw back so that the powder ingot can fall into the household utensils, finally, snatch mechanism 300 and open the powder ingot, the flexible module 550 of second will snatch mechanism 300 and upwards rise, leave the household utensils.

As a specific example, the first moving part includes:

a first slide rail module 331 disposed on the connecting arm 520;

a sliding block for connecting the first slide rail module 331 and the second moving part;

the sliding block slides on the first sliding rail module 331 to change the position of the second moving part on the connecting arm 520.

The second moving portion includes: and a second expansion module 550 for connecting the sliding block and the grasping part 540 and for changing the distance between the grasping part 540 and the sliding block.

When the powder ingot is located on the transfer platform, the connecting arm 520 rotates to a predetermined position, namely above the transfer platform, by using the rotating part 510 as an axis, the sliding block slides on the first sliding rail module 331 so that the grabbing part 540 is located right above the powder ingot, the second telescopic module 550 stretches and retracts so that the grabbing mechanism 300 can realize grabbing actions, the powder ingot is grabbed, then the connecting arm 520 continues to rotate, so that the grabbing module 320 can be located above a vessel, then the second telescopic module 550 continues to stretch and retract so that the powder ingot can fall into the vessel, finally, the powder ingot is released by the grabbing part 540, and the grabbing part 540 is lifted upwards by the second telescopic module 550 to leave the vessel.

As a specific embodiment, the second moving unit in the above two embodiments is disposed on the rotating unit 510, and at this time, the second moving unit has a function of extending and retracting up and down, and the horizontal height of the connecting arm 520 is adjusted directly by adjusting the height of the rotating unit 510, so as to adjust the horizontal height of the capturing module 320.

After powder ingots are placed in a vessel, in order to match different products, some ingredients, such as powder materials with different colors or powder materials with different functions, are often required to be added, and since the powder ingots are placed in the vessel in an array form, an automatic powder adding device is matched in order to ensure that the adding amount of the powder ingots in the same batch is constant.

In this embodiment with add gold powder as an example, all adopt artifical mode of adding among the prior art basically, but because artifical pre-estimated volume is inaccurate, the gold powder volume adds when the drawing of patterns the household utensils and glues the mould easily and be difficult for the drawing of patterns, the gold powder volume adds fewly, the household utensils quotation can lack gold, becomes unqualified substandard product, secondly the mode of artifical interpolation can make gold powder reinforced position inaccurate, also can cause and lack the gold phenomenon, even to the raw materials have not little loss, the cost is higher.

Referring to fig. 9-12, as an embodiment, an apparatus 400 for quantitatively and automatically adding gold powder for hot press molding of melamine resin vessels comprises: a first receiving portion 420 in which a first chute 4201 penetrating in a fifth direction is formed; a second receiving portion 421 having a second chute 4211 formed to penetrate in a sixth direction; the first moving device 412 is connected to the first material containing part 420, and the first moving device 412 is configured to move in the seventh direction so that the material in the first material containing part 420 falls into the second material containing part 421 through the first discharging slot 4201; the second moving device 431 is positioned at the discharge hole 133 of the second discharge chute 4211, and the second moving device 431 is used for controlling the material in the second material containing part 421 to fall into a vessel through the second discharge chute 4211; and a controller for controlling the movement of the first and second moving devices 412 and 431. During operation, gold powder is added into the first material containing portion 420, when the controller controls the first moving device 412 to drive the first material containing portion 420 to move towards the seventh direction, the gold powder in the first material containing portion 420 falls into the second material containing portion 421 through the first discharging groove 4201, then the controller controls the second moving device 431 to move towards the eighth direction, the discharging hole 133 of the second discharging groove 4211 is opened, the gold powder in the second material containing portion 421 can fall into a utensil through the second discharging groove 4211 for hot press molding, the moving speed and the number of times of back and forth movement of the first moving device 412 can be automatically controlled through the controller, the amount of the powder falling into the second material containing portion 421 is further controlled, the gold powder quantified in the second material containing portion 421 falls into the utensil, automatic, quantitative and accurate addition of the powder can be further achieved, the processing efficiency is guaranteed, and the defective rate is greatly reduced.

As a specific embodiment, the amount of powder discharged from the second material containing portion 421 is controlled by the moving speed and the number of times of the first material containing portion 420, and the amount of powder falling into the vessel at each time is controlled by providing a plurality of second discharge grooves 4211 with different specifications on the bottom of the second material containing portion 421 and controlling the moving distance of the second moving device 431. The plurality of second discharge grooves 4211 may be provided in a specification to change the amount of powder that each second discharge groove 4211 can contain, which is the amount of powder that needs to be dropped, by the size of the height and diameter of the second discharge groove 4211, and the simultaneous opening and closing of all the second discharge grooves 4211 can be achieved by simultaneously controlling the moving distance of the second moving device 431 in the eighth direction.

As a specific example, the moving distance of the second moving device 431 in the eighth direction is such that the material in the second material containing part 421 can fall into the vessel through the second discharging groove 4211. The second moving device 431 has a plate-like structure in this embodiment. But not limited to this, the second mobile device 431 rotates around a fixed axle so that the material in the second material containing part 421 falls into the vessel, and the discharge hole 133 of the second discharge chute 4211 can also be opened, so that the material in the second material containing part 421 can fall into the vessel through the second discharge chute 4211, and the utility model discloses do not limit this.

As a specific embodiment, the second moving device 431 completely covers the discharge port 133 of the second discharge chute 4211, when the second material containing portion 421 is provided with a plurality of second discharge chutes 4211, the distribution of the second discharge chutes 4211 is consistent with that of the vessels, and the discharge ports 133 of part of the second discharge chutes 4211 can be opened to fall into the corresponding vessels through the moving distance of the second moving device 431, so that different powder additions under the same batch of powder ingots can be realized, which is adopted according to needs in this embodiment.

As a specific embodiment, the first material containing bin and the second moving device 431 are both made of teflon, and the teflon material has the characteristics of small friction resistance and self-lubrication, so that the first material containing bin and the second moving device 431 can move smoothly, and the powder cannot be adhered to the side wall of the first material containing portion 420 and the second moving device 431.

As a specific example, the second discharging grooves 4211 may be provided as one, and a quantitative device is provided in the second discharging groove 4211, so that the powder can be quantitatively added into the vessel by adding the powder into one second discharging groove 4211 and quantifying by the quantitative device during discharging.

As a specific example, a monitoring element may be disposed in the first material containing portion 420 for monitoring the remaining amount of the powder, and a display module or an alarm device may be matched with the monitoring element to play a role of prompting.

As a specific embodiment, a sliding guide set 411 is disposed on the inner sidewall of the second material containing portion 421 along the seventh direction, the first material containing portion 420 is slidably disposed on the sliding guide set 411, and the first material containing portion 420 is disposed in the second material containing portion 421, so as to reduce the size of the overall structure of the automatic gold powder adding device 400.

As a specific embodiment, the second material containing portion 421 further includes a sealing plate 430, and the sealing plate 430 is abutted against the discharge port 133 of the first discharge groove 4201, and is used for sealing the first material containing portion 420; the sealing plate 430 is located at the bottom of the second material containing portion 421, and serves as a bottom plate of the second material containing portion 421, the second discharging groove 4211 is disposed through the sealing plate 430, and when the first material containing portion 420 moves in the seventh direction, the discharging hole 133 of the first discharging groove 4201 is tightly attached to the sealing plate 430, so that the powder only enters the second discharging groove 4211 and does not remain at other positions of the second material containing portion 421 during the movement of the first material containing portion 420 in the second material containing portion 421 in the seventh direction. The sealing plate 430 is slidably arranged on the sliding guide rail group 411, and the sealing plate 430 provided with the second discharging grooves 4211 of different specifications can be replaced according to the powder discharging requirements under different conditions. The sealing plate 430 is an aluminum plate, which is light in weight, low in cost, and easy to machine.

As a specific embodiment, the gold powder adding device 400 further comprises a cleaning device, which is disposed opposite to the vessel and is used for cleaning dirt on the surface of the vessel and ensuring the quality of the vessel. The cleaning device comprises an installation seat 432 arranged outside the second material containing part 421 and an air blowing pipe arranged on the installation seat 432, wherein the air blowing pipe can be connected with an electromagnetic valve, and the on-off of compressed air in the air blowing pipe is controlled by the electromagnetic valve.

As a specific example, the gold powder adding device 400 further includes a first driving device 410 and a second driving device 433 respectively connected to the controller, the controller respectively controls the respective actions of the first driving device 410 and the second driving device 433, the first driving device 410 is connected to the first moving device 412 to control the movement of the first moving device 412 in the seventh direction; the second driving device 433 is connected to the second moving device 431 to control the operation of the second moving device 431.

As a specific example, the bin cover 422 may be made of a transparent material, so that during the whole processing process, a worker can observe the remaining amount of the powder in the second material containing portion 421 in real time to add the powder in time.

As a specific embodiment, the gold powder adding apparatus 400 includes a first material containing part 420, a second material containing part 421, a first moving device 412, a second moving device 431, and a sealing plate 430, a sliding guide rail set 411 is disposed on an inner sidewall of the second material containing part 421, the first material containing part 420, the sealing plate 430, and the second moving device 431 are slidably disposed on the sliding guide rail set, the first material containing part 420 is made of teflon material, and the bottom has no bottom plate, a first discharging groove 4201 penetrating along the fifth direction is formed, the opening of the first discharging groove 4201 is attached to the sealing plate 430 to block the leakage, a second discharging groove 4211 penetrating along the sixth direction is provided on the sealing plate 430, the first material containing part 420 is installed in the upper layer chute of the sliding guide rail group 411 to slide back and forth, the first driving device 410 pushes the material to advance to cover the second discharging groove 4211 for feeding, and the material is retreated to be attached to the sealing plate 430 to block bottom leakage; the second moving device 431 is of a plate-shaped structure, is arranged in a chute at the lower layer of the sliding guide rail group 411 and is attached to the lower surface of the second discharging groove 4211, and can slide back and forth under the pushing of the second driving device 433, so that the opening of the second discharging groove 4211 is moved forward to close for waiting for charging, and the opening of the second discharging groove 4211 is moved backward to open for discharging; the cleaning air pipe mounting frame 401 is provided with a compressed air pipe controlled by an electromagnetic valve, and before the gold powder is added, the surface of a vessel to be added with the gold powder is cleaned. The first driving device 410 and the second driving device 433 are both air cylinders.

The sealing plate 430 is made of an aluminum plate with a certain thickness, the gram number of gold powder is calculated according to the surface area of a vessel added with the gold powder, the second discharging groove 4211 with a corresponding volume is dug according to the volume of the gram number, and templates are made according to the output modulus, the distance and the gram number of different melamine resin vessels according to the output modulus, the distance and the gram number, so that the sealing plate is plug and play and is convenient to replace.

Add gold powder device 400 and the head mounting flange of motion module 402 and pass through screw fixed connection, move module 402 and fix on mounting bracket 401, move module 402 and add gold powder device 400 and hang through mounting bracket 401 and install on the press top layer.

During filling operation, the second driving device 433 is at an opening extending position and is attached to the lower surface of the sealing plate 430 to seal the discharge hole 133 of the second discharge groove 4211, the first material containing part 420 filled with gold powder moves to the position above the second discharge groove 4211 of the sealing plate 430 under the pushing of the first driving device 410 to perform filling twice, the first material containing part 420 is pulled to retract and reset under the pushing of the first driving device 410 pushing cylinder and scrapes the upper opening of the second discharge groove 4211, and the first material containing part 420 and the sealing plate 430 are attached to each other, so that the gold powder in the first material containing part 420 cannot diffuse outwards to leak, and the gold powder is filled in the second discharge groove 4211 and waits for gold adding to a vessel after the filling is completed; at this moment, when the hot press finishes plain surface operation and descends to the height of the initial table top, the motion module 402 is instructed to move to the gold powder feeding position, the motion module 402 opens the electromagnetic valve for cleaning the air pipe in the motion process, pollutants attached to the surface of a vessel to be fed with gold powder are cleaned, when the motion module 402 moves in place, the electromagnetic valve is closed, meanwhile, the second driving device 433 is closed, the second moving device 431 is withdrawn to open the discharge port 133 of the second discharge tank 4211, the gold powder falls to the gold powder feeding position of the vessel, the second driving device 433 is opened to push the second moving device 431 to the discharge port 133 of the second discharge tank 4211, the discharge port 133 of the second discharge tank 4211 is closed, the motion module 402 resets, and the hot press starts gold feeding operation.

The above only is the preferred embodiment of the present invention, not therefore the limit the patent protection scope of the present invention, all applications the equivalent structure transformation made by the contents of the specification and the drawings of the present invention is directly or indirectly applied to other related technical fields, and all the same principles are included in the protection scope of the present invention.

Claims (10)

1. The utility model provides an automatic gold powder device that adds of ration suitable for melamine fat household utensils hot briquetting which characterized in that includes:

a first material containing part, which is provided with a first discharging groove penetrating in the fifth direction;

a second material containing part, which is provided with a second discharging groove communicated in a sixth direction;

the first moving device is connected with the first material containing part and used for moving along a seventh direction so that the material in the first material containing part falls into the second material containing part through the first discharging groove;

the second moving device is positioned at a discharge hole of the second discharge chute and used for controlling the materials in the second material containing part to fall into a vessel through the second discharge chute;

and the controller is used for controlling the motion of the first moving device and the second moving device.

2. The apparatus for quantitatively and automatically adding gold powder for hot press forming of melamine resin vessels as claimed in claim 1, wherein said second moving means completely covers the discharge port of the second discharge chute to enable the storage of the material in the second containing portion.

3. The apparatus for quantitatively and automatically adding gold powder suitable for hot press forming of melamine resin vessels as claimed in claim 1, wherein the second moving means moves in an eighth direction to cause the material in the second material containing portion to fall into the vessel.

4. The apparatus according to claim 1, wherein the second moving means rotates around a fixed axis to let the material in the second material container drop into the vessel.

5. The device for quantitatively and automatically adding gold powder for hot press forming of melamine resin vessels as claimed in claim 1, wherein the first holding bin and the second moving device are both made of teflon.

6. The automatic quantitative gold powder adding device suitable for hot press forming of melamine resin vessels as claimed in claim 1, wherein a sliding guide rail set is arranged on the inner side wall of the second material containing part along the seventh direction, and the first material containing part is slidably arranged on the sliding guide rail set.

7. The automatic quantitative gold powder adding device suitable for hot press molding of melamine resin vessels as claimed in claim 6, wherein the second material containing portion further comprises a sealing plate abutting against the discharge port of the first discharge chute for sealing the first material containing portion.

8. The automatic quantitative gold powder adding device suitable for hot press molding of melamine resin vessels as claimed in claim 7, wherein the sealing plate is located at the bottom of the second material containing part, the second discharging groove is arranged on the sealing plate in a penetrating manner, and the sealing plate is arranged on the sliding guide rail set in a sliding manner; the sealing plate is an aluminum plate.

9. The apparatus for quantitatively and automatically adding gold powder suitable for hot press forming of melamine resin vessels as claimed in claim 1, further comprising a cleaning means disposed opposite to the vessel for cleaning the surface of the vessel from dirt.

10. The apparatus for quantitatively and automatically adding gold powder suitable for hot press forming of melamine resin vessels according to claim 1, further comprising a first driving device and a second driving device respectively connected to the controller, wherein the controller respectively controls the respective actions of the first driving device and the second driving device, and the first driving device is connected to the first moving device to control the movement of the first moving device in the seventh direction; the second driving device is connected with the second moving device to control the action of the second moving device.

Images