CN220407121U - Numerical control edge turning machine for flour stirring pot - Google Patents

Abstract

The utility model provides a numerical control edge turning machine for a flour mixing pot, and belongs to the technical field of food processing. According to the utility model, the rotatable station platform and the pressing mechanism transversely arranged above the station platform are arranged on the frame, so that the barrel body to be processed can be placed on the station platform and pressed by the pressing mechanism, meanwhile, the barrel body to be processed is driven to rotate, the sliding platform is arranged at the side of the station platform, the lifting frame is arranged on the sliding platform, and the turning tool is arranged on the lifting frame, so that the turning tool can move close to or far away from the station platform along the horizontal and vertical directions, the feeding and retracting operation of the turning tool is realized, the edge of the barrel opening of the rotating barrel body is cut by the turning tool, the requirements of the edge turning are met, the cutting precision can be ensured, the processing efficiency can be improved, the product quality can be ensured, the safety risk caused by manual participation can be eliminated, the work load can be lightened, and the edge turning processing of the flour stirring pot is facilitated.

Description

Numerical control edge turning machine for flour stirring pot

Technical Field

The utility model relates to the technical field of food processing, in particular to a numerical control edge turning machine for a flour mixing pot.

Background

The bread stirring pot is used as a core structure of a bread machine and is used as a flour stirring container. The bread agitator kettle on the market is generally in a barrel-shaped structure of a spherical barrel bottom, and when in processing, a plate-shaped material forms a barrel-shaped structure through a pull rope, then the barrel opening is subjected to trimming processing, redundant rim charge of the barrel opening is cut off, and then the subsequent processing such as polishing and grinding is performed.

In the actual processing process, when the stretched barrel body is subjected to trimming treatment, the barrel body is clamped by a clamp, then the barrel opening is marked by means of a gauge and other detection tools manually, and then the barrel opening is trimmed by a manual handheld cutter along the marking, so that the problem of inaccurate marking caused by the problem of reference standard in the marking process is solved, and the follow-up accuracy of marking serving as reference is caused. In addition, when the manual handheld cutting machine cuts, the problem of shaking easily occurs, the cutting precision and efficiency are affected, and the workload and the safety risk caused by rotating the clamp around the barrel body or rotating the clamp by the other hand of the handheld cutting machine are also required, so that the edge cutting processing of the flour stirring pot is not facilitated.

Disclosure of Invention

The numerical control turning edge machine comprises a machine frame, a pressing mechanism, a sliding table, a lifting frame, a turning tool, a cutting mechanism and a turning tool, wherein the machine frame is provided with a rotatable station table arranged on the machine frame, the pressing mechanism is used for clamping a barrel to be processed and driving the barrel to rotate, the sliding table is arranged on the machine frame and is positioned beside the station table and is close to or far away from the station table, the lifting frame is arranged on the sliding table, the turning tool is arranged on the lifting frame, the turning tool is adjusted through the sliding table and the lifting frame, edges of a barrel opening of the barrel to be rotated are cut through the turning tool, cutting precision and efficiency are improved, accuracy can be ensured, meanwhile, the problem of safety risk and heavy work load caused by manual participation can be avoided, and turning edge processing of the flour stirring pot is facilitated.

The specific technical scheme is as follows:

a numerical control hemming machine for a flour-mixing kettle, having the characteristics comprising:

the machine frame is provided with a processing platform;

the station table is rotatably arranged on the processing platform;

the pressing mechanism is arranged on the processing platform and transversely arranged above the station platform, and is provided with a pressing block which is lifted in the vertical direction and is opposite to the station platform in the vertical direction;

the sliding table is arranged on the processing platform and is positioned beside the station table, and the sliding table moves on the processing platform to be close to or far away from the station table;

the lifting frame is arranged at one end of the sliding table, which is close to the station table, and the lifting frame performs lifting movement on the sliding table;

the lathe tool, the lathe tool is installed on the crane and goes up and down in vertical direction along the crane, and the tool bit of lathe tool is arranged towards the station platform.

The numerical control edging machine for the flour-stirring pot further comprises a edging wheel, wherein the edging wheel is arranged on one side, close to the station table, of the sliding table, and the wheel surface of the edging wheel is contacted with or far away from a bunghole of a barrel body to be processed.

The numerical control turning edge machine for the flour-mixing pot comprises a wheel frame and rollers, wherein the wheel frame comprises a fixed plate and protruding arms, one side of the fixed plate is fixed on a sliding table, two protruding arms protruding towards one side of a station table are arranged on the other side of the fixed plate at intervals, and simultaneously, each protruding arm is provided with a roller in a rotating mode.

The numerical control edging machine for the flour-stirring pot is characterized in that two rollers are respectively positioned on two sides of a turning tool in the vertical direction.

The numerical control turning machine for the flour-mixing pot comprises a pressing mechanism, a pressing block, a working platform, a working position table and a transverse plate, wherein the pressing mechanism further comprises a pressing frame and a telescopic driver, the pressing frame comprises a vertical column and the transverse plate, the vertical column is arranged on the working position table and located on two sides of the working position table, two ends of the transverse plate are respectively arranged on the two vertical columns, the telescopic driver is arranged on the transverse plate and the telescopic shaft is vertically arranged towards the working position table, and the pressing block is arranged on the telescopic shaft of the telescopic driver.

The numerical control turning machine for the flour-mixing pot comprises a pressing mechanism, a pressing block, a pressing mechanism and a pressing mechanism, wherein the pressing mechanism further comprises a guide assembly, the guide assembly comprises sliding sleeves and auxiliary frames, each upright post is arranged on the sliding sleeve in a sliding mode, the auxiliary frames are arranged between the two upright posts, two ends of each auxiliary frame are fixedly connected with the two sliding sleeves respectively, meanwhile, a telescopic shaft of the telescopic driver is connected to the auxiliary frames, and the pressing block is arranged at the bottom of each auxiliary frame.

The numerical control turning machine for the flour-mixing pot comprises a sliding rail, a total carrying slide plate, a total carrying screw rod, a total carrying nut and a total carrying driver, wherein the sliding rail is arranged on a processing platform and is arranged along the radial direction of a station table, the total carrying slide plate is arranged on the sliding rail in a sliding manner, the total carrying driver is arranged on the processing platform, the total carrying screw rod is parallel to the sliding rail, one end of the total carrying screw rod is in power connection with the total carrying driver, and the total carrying nut is sleeved outside the total carrying screw rod and is fixed on the total carrying slide plate.

The numerical control turning edge machine for the flour stirring pot further comprises a horizontal sliding frame, the horizontal sliding frame is arranged on the sliding table, the horizontal sliding frame comprises a feeding guide rail, a feeding slide plate, a feeding nut, a feeding screw rod and a feeding driver, the feeding guide rail is arranged on the total carrying slide plate and is arranged along the radial direction of the station table, the feeding guide rail is provided with the feeding slide plate in a sliding manner, the feeding driver is arranged on the total carrying slide plate, the feeding screw rod is parallel to the feeding guide rail, one end of the feeding screw rod is in power connection with the feeding driver, and the feeding nut is sleeved outside the feeding screw rod and is fixedly connected with the feeding slide plate.

The numerical control turning machine for the flour-mixing pot comprises a lifting stand, lifting guide rails, lifting sliding plates, lifting screw rods, lifting nuts and lifting drivers, wherein the lifting stand is arranged on a feeding sliding plate, the lifting guide rails are arranged on the lifting stand along the vertical direction, the lifting sliding plates are arranged on the lifting guide rails in a sliding mode, the lifting drivers are arranged on the lifting stand in parallel, one ends of the lifting screw rods are in power connection with the lifting drivers, the lifting nuts are sleeved outside the lifting screw rods and are fixedly connected with the lifting sliding plates, and turning tools are arranged on the lifting sliding plates.

The numerical control turning machine for the flour-mixing pot comprises a lifting slide plate, wherein a cutter mounting groove is formed in the lower end of the lifting slide plate and close to one side of a station table, a plurality of locking holes communicated with the cutter mounting groove are formed in the side portion of the lifting slide plate, a cutter handle of a turning tool is embedded in the cutter mounting groove, and locking bolts are connected in the locking holes in a threaded mode and extend into the cutter mounting groove to press the cutter handle.

The technical scheme has the positive effects that:

according to the numerical control turning machine for the flour-mixing pot, the rotatable station table and the pressing mechanism arranged above the station table are arranged on the processing platform of the machine frame, stable clamping of the barrel to be processed is achieved, the barrel is driven to rotate, meanwhile, the sliding table which is close to or far away from the station table is arranged on the processing platform and is arranged on the side of the station table, the lifting frame which is arranged on the sliding table is arranged on the lifting frame, a turning tool is arranged on the lifting frame, adjustment of the position of the turning tool is achieved through the sliding table and the lifting frame, the feeding and withdrawal requirements of the turning tool are met, the edge of a barrel opening of the rotating barrel is cut through the turning tool, the turning operation is completed, the cutting precision is ensured, the processing efficiency is improved, the product quality is higher, manual participation is not needed, the safety guarantee is higher, the work burden is smaller, and turning edge processing of the flour-mixing pot is facilitated.

Drawings

FIG. 1 is a block diagram of an embodiment of a numerical control hemming machine for a flour-mixing kettle in accordance with the present utility model;

FIG. 2 is a block diagram of a crimping wheel according to a preferred embodiment of the present utility model;

FIG. 3 is a block diagram of a skid platform according to a preferred embodiment of the present utility model;

FIG. 4 is a block diagram of a horizontal carriage according to a preferred embodiment of the present utility model;

fig. 5 is a block diagram of a lifting frame according to a preferred embodiment of the present utility model.

In the accompanying drawings: 1. a frame; 11. a processing platform; 2. a station table; 3. a pressing mechanism; 31. pressing the block; 32. a pressing frame is pressed down; 33. a telescopic drive; 34. a guide assembly; 321. a column; 322. a transverse plate; 341. a sliding sleeve; 342. an auxiliary frame; 4. a sliding table; 41. a slide rail; 42. a total load slide plate; 43. a total load screw rod; 44. a total load driver; 5. a lifting frame; 51. lifting the vertical frame; 52. lifting the guide rail; 53. a lifting slide plate; 54. a lifting driver; 55. lifting the screw rod; 531. a cutter mounting groove; 532. a locking hole; 6. turning tools; 7. edge pressing wheels; 71. a wheel carrier; 72. a roller; 711. a fixing plate; 712. a protruding arm; 8. a horizontal carriage; 81. a feed rail; 82. a feed slide plate; 83. and a feed driver.

Detailed Description

In order to make the technical means, the creation features, the achievement of the purposes and the effects of the present utility model easy to understand, the following embodiments specifically describe the technical solution provided by the present utility model with reference to fig. 1 to 5, but the following disclosure is not limited to the present utility model.

Fig. 1 is a block diagram of an embodiment of a numerical control hemming machine for a flour-mixing kettle in accordance with the present utility model. As shown in fig. 1, the numerical control edging machine for flour-mixing pot provided in this embodiment includes: the device comprises a frame 1, a station table 2, a pressing mechanism 3, a sliding table 4, a lifting frame 5 and a turning tool 6.

Specifically, the frame 1 is placed on the ground, the frame 1 is provided with a horizontally arranged processing platform 11, and an installation carrier is provided for the arrangement of the subsequent station platform 2, the pushing mechanism 3, the sliding platform 4 and the like through the processing platform 11.

Specifically, install station platform 2 rotation on processing platform 11, the upper end of station platform 2 is the plummer, place the staving of waiting to process through the plummer, the middle section of station platform 2 is installed on processing platform 11 through the bearing rotation, the lower extreme of station platform 2 extends to the below of processing platform 11, at this moment, frame 1 is last and be located the bottom of processing platform 11 and be provided with the drive main shaft, the drive main shaft passes through gear train power with the lower extreme of station platform 2 and is connected, drive station platform 2 through the drive main shaft promptly and rotate on processing platform 11, thereby can drive the staving of waiting to process and rotate when processing for the follow-up car limit.

Specifically, the pushing mechanism 3 is mounted on the processing platform 11, and the middle part of the pushing mechanism 3 is transversely arranged above the station platform 2, so that the interference of the pushing mechanism 3 to the action of the station platform 2 is avoided. And, the pushing down mechanism 3 has the briquetting 31 that goes up and down in vertical direction, simultaneously, briquetting 31 is just right with station platform 2 down in vertical direction for when briquetting 31 descends down, can push down the staving of waiting to process of placing on station platform 2 through briquetting 31 down, ensured the stability of staving of waiting to process in the course of working, ensured machining precision. It is worth noting that the lower pressing block 31 is of a rotatable structure, so that when the lower pressing block 31 presses the barrel to be processed on the station table 2, the lower pressing block 31 can synchronously rotate along with the barrel to be processed, and processing requirements are met.

Specifically, the sliding table 4 is arranged on the processing platform 11, and the sliding table 4 is positioned beside the station table 2, meanwhile, the sliding table 4 moves on the processing platform 11 to be close to or far away from the station table 2, so that the follow-up conditions can be provided for the sliding table 4 to drive the structures such as the turning tool 6, the blank holder 7 and the like to be close to or far away from the station table 2.

Specifically, the lifting frame 5 is arranged at one end of the sliding table 4, which is close to the station table 2, so that the sliding table 4 can drive the lifting frame 5 to be close to or far away from the station table 2, and the lifting frame 5 can do lifting motion on the sliding table 4, so that the lifting frame 5 can do motion close to or far away from the station table 2 in a horizontal plane under the action of the sliding table 4, and can do motion close to or far away from the station table 2 in a vertical direction under the action of the lifting frame, thereby providing conditions for adjusting the position of a turning tool 6 arranged on the lifting frame 5 subsequently so as to realize feeding or retracting.

Specifically, the lathe tool 6 is installed on the crane 5 and goes up and down in the vertical direction along with the crane 5 to, arrange the tool bit of lathe tool 6 towards station platform 2, when crane 5 descends promptly, the tool bit of lathe tool 6 is close to station platform 2 gradually, thereby realize carrying out the car limit processing to the bung hole of the staving of waiting to process of placing on station platform 2, simultaneously, make the tool bit of lathe tool 6 keep away from station platform 2 gradually through the rise of crane 5 after the processing is accomplished, realize the operation of moving back of lathe tool 6, satisfy car limit processing demand.

Fig. 2 is a block diagram of a crimping wheel according to a preferred embodiment of the present utility model. As shown in fig. 1 and 2, the processing platform 11 is further provided with a blank holder 7, at this time, the blank holder 7 is disposed on one side of the sliding table 4 close to the station table 2, so that the blank holder 7 can move along with the sliding table 4 close to or away from the station table 2, and when the blank holder 7 is close to the station table 2, the wheel surface of the blank holder 7 contacts with the bung hole of the barrel to be processed on the station table 2, so that the bung hole of the barrel to be processed is pressed on the station table 2, the inner wall of the bung hole of the barrel can be tightly attached to the bearing table, and the problem of size deviation caused by non-compaction of the inner wall of the bung hole of the barrel is avoided, and the processing precision is ensured. And when the edge pressing wheel 7 is far away from the station table 2, the wheel surface of the edge pressing wheel 7 is far away from the barrel mouth of the barrel body to be processed, so that the feeding and discharging operations of the barrel body to be processed on the station table 2 are facilitated.

More specifically, the edge pressing wheel 7 further includes a wheel frame 71 and a roller 72, at this time, the wheel frame 71 includes a fixing plate 711 and a protruding arm 712, and one side of the fixing plate 711 is fixed on the sliding table 4 through a threaded fastener, so that stable installation of the fixing plate 711 on the sliding table 4 is realized, and the fixing plate 711 can move along with the sliding table 4 toward or away from the station table 2. In addition, two protruding arms 712 protruding toward one side of the station 2 are disposed at intervals on the other side of the fixing plate 711, and preferably, the two protruding arms 712 are respectively located at two ends of the fixing plate 711, so that a gap is formed between the two protruding arms 712, and an avoidance space is provided for lifting of the subsequent turning tool 6. Meanwhile, a roller 72 is rotatably installed on each protruding arm 712, namely, the roller 72 is installed through the protruding arms 712, and the roller 72 can be arranged protruding from the sliding table 4, so that the sliding table 4 can still keep a distance from the station table 2 when the barrel to be processed is pressed by the roller 72 in the following process is avoided, the problem of structural interference is avoided, and the safety and the security are higher.

More specifically, in the vertical direction, two gyro wheels 72 are located the both sides of lathe tool 6 respectively, promptly when crane 5 drives lathe tool 6 decline and carry out the edging processing at the border of the bung hole of the staving of treating the processing, and two gyro wheels 72 can compress tightly the staving of bung hole department of the staving of treating the processing of lathe tool 6 both sides respectively, have further guaranteed the staving of substituting the processing and have been at the stability of edging in-process, structural design is more reasonable.

More specifically, as shown in fig. 1, the pressing mechanism 3 includes, in addition to the pressing block 31, the pressing frame 32 and the telescopic driving device 33, at this time, the pressing frame 32 includes a stand 321 and a transverse plate 322, an upright 321 is disposed on the processing platform 11 and located on two sides of the station platform 2, the lower ends of the stand 321 are fixed on the processing platform 11, and at the same time, two ends of the transverse plate 322 are respectively mounted on the two upright 321 to form an approximately n-shaped structure, so that the transverse plate 322 can be stably and transversely placed above the station platform 2, at the same time, the telescopic driving device 33 is mounted on the transverse plate 322 along the vertical direction, and the telescopic shaft of the telescopic driving device 33 is vertically arranged towards the station platform 2, and the pressing block 31 is mounted on the telescopic shaft of the telescopic driving device 33, so that when the telescopic shaft of the telescopic driving device 33 extends downwards, the pressing block 31 can be close to the station platform 2 to compress the barrel to be processed placed on the station platform 2.

More specifically, in order to promote the stability of pushing down the mechanism 3 when pushing down, the mechanism 3 still has the direction subassembly 34, at this moment, the direction subassembly 34 includes sliding sleeve 341 and auxiliary frame 342 again, use each stand 321 as the guide post, all slide on each stand 321 and locate a sliding sleeve 341 for sliding sleeve 341 can slide in vertical direction along the axial of stand 321, simultaneously, install auxiliary frame 342 between two stands 321 and both ends respectively with two sliding sleeve 341 fixed connection, make auxiliary frame 342 can do elevating movement on stand 321, simultaneously can guide through stand 321 in the elevating process, stability when auxiliary frame 342 goes up and down has been improved. Meanwhile, the telescopic shaft of the telescopic driver 33 is connected to the auxiliary frame 342, and the lower pressing block 31 is mounted at the bottom of the auxiliary frame 342, so that the lower pressing block 31 can be lifted and lowered in the vertical direction along with the auxiliary frame 342 when the telescopic driver 33 drives the auxiliary frame 342 to perform lifting and lowering motion in the vertical direction. It is worth noting that the lower pressing block 31 is mounted on the auxiliary frame 342 through a bearing, so that the lower pressing block 31 can maintain self rotation while lifting along with the auxiliary frame 342, thereby meeting the use requirement of following the rotation of the barrel to be processed.

FIG. 3 is a block diagram of a skid platform according to a preferred embodiment of the present utility model. As shown in fig. 1 and 3, the sliding table 4 disposed on the processing platform 11 further includes a sliding rail 41, a total load sliding plate 42, a total load screw 43, a total load nut and a total load driver 44, at this time, the sliding rail 41 is mounted on the processing platform 11 and is disposed along a radial direction of the station platform 2, the total load sliding plate 42 is slidably disposed on the sliding rail 41, so that the total load sliding plate 42 can move along an arrangement direction of the sliding rail 41 toward or away from the station platform 2, meanwhile, the total load driver 44 is mounted on the processing platform 11, and the total load screw 43 is disposed parallel to the sliding rail 41, two ends of the total load screw 43 are rotatably mounted on the processing platform 11, and one end of the total load screw 43 is in power connection with the total load driver 44, so that the total load driver 44 can drive the total load screw 43 to rotate, and at the same time, the total load nut is sleeved outside the total load screw 43 and is fixed on the total load sliding plate 42, so that when the total load driver 44 drives the total load screw 43 to rotate, the total load nut can reciprocate along an axial direction of the total load screw 43, thereby providing power for the sliding of the total load screw 43 on the sliding rail 41. It is worth noting that the pinch roller 7 is mounted on the load slide 42 such that the load slide 42 can drive the pinch roller 7 toward or away from the station table 2.

Fig. 4 is a block diagram of a horizontal carriage according to a preferred embodiment of the present utility model. As shown in fig. 1 and 4, a horizontal carriage 8 is further provided on the sliding table 4, and the horizontal carriage 8 is used as a driving structure for horizontally feeding or retracting the turning tool 6. At this time, the horizontal carriage 8 further includes a feeding guide rail 81, a feeding slide plate 82, a feeding nut, a feeding screw rod, and a feeding driver 83, and the feeding guide rail 81 is mounted on the total load slide plate 42 and is arranged along the radial direction of the station platform 2, that is, the edge pressing wheel 7 is pressed on the barrel mouth of the barrel body to be processed by the sliding table 4, and then the turning tool 6 is controlled to move in the horizontal direction by the horizontal carriage 8 under the condition that the sliding table 4 does not act, so as to meet the feeding and retracting requirements. Meanwhile, a feeding slide plate 82 is slidably arranged on the feeding guide rail 81, so that the feeding slide plate 82 can slide along the feeding guide rail 81, a feeding driver 83 is arranged on the total load slide plate 42, a feeding screw rod is arranged parallel to the feeding guide rail 81, two ends of the feeding screw rod are rotatably mounted on the total load slide plate 42, one end of the feeding screw rod is in power connection with the feeding driver 83, so that the feeding driver 83 can drive the feeding screw rod to rotate, a feeding nut is sleeved outside the feeding screw rod and fixedly connected with the feeding slide plate 82, and when the feeding driver 83 drives the feeding screw rod to rotate, the feeding nut can reciprocate along the axial direction of the feeding screw rod, so that power is provided for sliding of the feeding slide plate 82 on the feeding guide rail 81.

Fig. 5 is a block diagram of a lifting frame according to a preferred embodiment of the present utility model. As shown in fig. 1 and 5, the lifting frame 5 arranged on the sliding table 4 is arranged on the horizontal sliding frame 8 at this time, that is, when the sliding table 4 does not act, the lifting frame 5 can be driven by the horizontal sliding frame 8 to move continuously, so that the use requirement of feeding or retracting the turning tool 6 is met. At this time, the lifting frame 5 further includes a lifting stand 51, a lifting guide rail 52, a lifting slide plate 53, a lifting screw rod 55, lifting nuts and a lifting driver 54, the lifting stand 51 is mounted on the feeding slide plate 82, so that the lifting stand 51 can move along with the feeding slide plate 82, meanwhile, the lifting guide rail 52 is mounted on the lifting stand 51 along the vertical direction, the lifting slide plate 53 is slidingly arranged on the lifting guide rail 52, the lifting driver 54 is mounted on the lifting stand 51, the lifting screw rod 55 is parallel to the lifting guide rail 52, both ends of the lifting screw rod 55 are rotatably mounted on the lifting stand 51, one end of the lifting screw rod 55 is in power connection with the lifting driver 54, so that the lifting driver 54 can drive the lifting screw rod 55 to rotate, meanwhile, the lifting nuts are sleeved outside the lifting screw rod 55 and are fixedly connected with the lifting slide plate 53, namely, when the lifting screw rod 55 is driven to rotate by the lifting driver 54, the lifting nut can do lifting movement along the axial direction of the lifting screw rod 55, and accordingly a driving force is provided for the lifting slide plate 53 in the vertical direction. In addition, the turning tool 6 is arranged on the lifting sliding plate 53, so that the height of the turning tool 6 in the vertical direction is adjusted, the use requirement that the turning tool 6 is close to or far away from a barrel body to be processed is met, and the feeding or retracting operation of the turning tool 6 is realized.

More specifically, the cutter mounting groove 531 has still been seted up in the lower extreme of lift slide 53 and one side that is close to station platform 2, simultaneously, a plurality of locking holes 532 that communicate cutter mounting groove 531 have been seted up to the lateral part of lift slide 53, equal threaded connection has the lock bolt in each locking hole 532, and in the one end of lock bolt extends to cutter mounting groove 531, install lathe tool 6 on lift slide 53, when the handle of a knife of lathe tool 6 inlays in cutter mounting groove 531, locking hole 532 threaded connection's lock bolt's tip and stretch into the handle of a knife of compressing tightly lathe tool 6 in cutter mounting groove 531, not only can stably install lathe tool 6 on lift slide 53, can also make things convenient for the dismouting of lathe tool 6 on lift slide 53, follow-up maintenance is more convenient.

The numerical control edging machine for the flour-mixing pot comprises a frame 1, a station table 2, a pushing mechanism 3, a sliding table 4, a lifting frame 5 and a turning tool 6; the rotatable station platform 2 and the pushing mechanism 3 transversely arranged above the station platform 2 are arranged on the frame 1, so that a barrel to be processed can be placed on the station platform 2 and is compressed through the pushing mechanism 3, meanwhile, the barrel to be processed is driven to rotate, a sliding platform 4 is arranged at the side of the station platform 2, a lifting frame 5 is arranged on the sliding platform 4, a turning tool 6 is arranged on the lifting frame 5, the turning tool 6 can simultaneously follow the sliding platform 4 and the lifting frame 5 to move in the horizontal and vertical directions to be close to or far away from the station platform 2, feeding and retracting operations of the turning tool 6 are realized, the edge of a barrel opening of the rotary barrel body is cut through the turning tool 6, the requirement of a rim is met, the cutting precision can be ensured, the processing efficiency is improved, the product quality is ensured, the safety risk caused by manual participation can be eliminated, the work burden is lightened, and the rim processing of a flour stirring pot is facilitated.

The foregoing is merely illustrative of the preferred embodiments of the present utility model and is not intended to limit the embodiments and scope of the present utility model, and it should be appreciated by those skilled in the art that equivalent substitutions and obvious variations may be made using the description and illustrations of the present utility model, and are intended to be included in the scope of the present utility model.

Claims (10)

1. The utility model provides a flour is numerical control edging machine for agitated kettle which characterized in that includes:

the machine frame is provided with a processing platform;

the station table is rotatably arranged on the processing platform;

the pressing mechanism is arranged on the processing platform and transversely arranged above the station platform, and is provided with a pressing block which is lifted in the vertical direction and is opposite to the station platform in the vertical direction;

the sliding table is arranged on the processing platform and is positioned beside the station table, and the sliding table moves on the processing platform to be close to or far away from the station table;

the lifting frame is arranged at one end, close to the station platform, of the sliding table, and the lifting frame performs lifting movement on the sliding table;

the lathe tool, the lathe tool install in on the crane and follow the crane goes up and down in vertical direction, the tool bit of lathe tool orientation station platform is arranged.

2. The numerical control hemming machine for a flour-mixing pot according to claim 1, further comprising a hemming wheel, wherein the hemming wheel is arranged on one side of the sliding table close to the station table, and the wheel surface of the hemming wheel contacts or is far away from the bunghole of the barrel body to be processed.

3. The numerical control hemming machine for a flour-mixing pot according to claim 2, wherein the hemming wheel comprises a wheel frame and a roller, the wheel frame comprises a fixing plate and protruding arms, one side of the fixing plate is fixed on the sliding table, two protruding arms protruding towards one side of the station table are arranged on the other side of the fixing plate at intervals, and meanwhile, one roller is rotatably mounted on each protruding arm.

4. A numerical control hemming machine for a flour-mixing kettle according to claim 3 wherein, in the vertical direction, the two rollers are located on either side of the turning tool.

5. The numerical control turning edge machine for flour-mixing pans according to claim 1, wherein the pressing mechanism further comprises a pressing frame and a telescopic driver, the pressing frame comprises a vertical column and a transverse plate, the two sides of the processing platform, which are positioned on the station platform, are respectively provided with one vertical column, two ends of the transverse plate are respectively arranged on the two vertical columns, the telescopic driver is arranged on the transverse plate, the telescopic shaft is vertically arranged towards the station platform, and the pressing block is arranged on the telescopic shaft of the telescopic driver.

6. The numerical control turning machine for flour-mixing pans according to claim 5, wherein the pressing mechanism further comprises a guide assembly, the guide assembly comprises a sliding sleeve and an auxiliary frame, each upright is slidably arranged on one sliding sleeve, the auxiliary frame is arranged between two uprights, two ends of the auxiliary frame are respectively fixedly connected with the two sliding sleeves, simultaneously, a telescopic shaft of the telescopic driver is connected to the auxiliary frame, and the pressing block is arranged at the bottom of the auxiliary frame.

7. The numerical control hemming machine for a flour-mixing kettle according to claim 1, wherein the sliding table comprises a sliding rail, a total carrying slide plate, a total carrying screw rod, a total carrying nut and a total carrying driver, the sliding rail is mounted on the processing platform and is arranged along the radial direction of the station table, the total carrying slide plate is slidably arranged on the sliding rail, the total carrying driver is mounted on the processing platform, the total carrying screw rod is arranged parallel to the sliding rail, one end of the total carrying screw rod is in power connection with the total carrying driver, and the total carrying nut is sleeved outside the total carrying screw rod and is fixed on the total carrying slide plate.

8. The numerical control hemming machine for a flour-mixing kettle according to claim 7, further comprising a horizontal carriage, wherein the horizontal carriage is arranged on the sliding table, the horizontal carriage comprises a feeding guide rail, a feeding slide plate, a feeding nut, a feeding screw rod and a feeding driver, the feeding guide rail is arranged on the total carrying slide plate and is arranged along the radial direction of the station table, the feeding slide plate is arranged on the feeding guide rail in a sliding manner, the feeding driver is arranged on the total carrying slide plate, the feeding screw rod is arranged parallel to the feeding guide rail, one end of the feeding screw rod is in power connection with the feeding driver, and the feeding nut is sleeved outside the feeding screw rod and is fixedly connected with the feeding slide plate.

9. The numerical control turning machine for flour-mixing pans according to claim 8 wherein the lifting frame comprises a lifting vertical frame, a lifting guide rail, a lifting slide plate, a lifting screw rod, a lifting nut and a lifting driver, wherein the lifting vertical frame is arranged on the feeding slide plate, the lifting guide rail is arranged on the lifting vertical frame along the vertical direction, the lifting slide plate is slidingly arranged on the lifting guide rail, the lifting driver is arranged on the lifting vertical frame, the lifting screw rod is parallel to the lifting guide rail, one end of the lifting screw rod is in power connection with the lifting driver, the lifting nut is sleeved outside the lifting screw rod and is fixedly connected with the lifting slide plate, and the turning tool is arranged on the lifting slide plate.

10. The numerical control turning machine for flour-mixing pans according to claim 9, wherein a cutter mounting groove is formed in the lower end of the lifting slide plate and close to one side of the station table, a plurality of locking holes communicated with the cutter mounting groove are formed in the side portion of the lifting slide plate, a cutter handle of the turning tool is embedded in the cutter mounting groove, and locking bolts are connected in the locking holes in a threaded mode and extend into the cutter mounting groove to tightly press the cutter handle.