TWI401101B - The processing method and processing equipment for strengthening the wear resistance of the inner layer of the running belt - Google Patents

Description

Processing method and processing equipment for strengthening anti-wear characteristics of running inner layer of germplasm

The present invention relates to sports equipment, and more particularly to a processing method and processing apparatus for processing the inner layer of a running belt with an inner layer to enhance the anti-wear characteristics of the inner layer of the running belt.

In today's common treadmills, in order to reduce the wear of the running belt and the running board during use, a special wear-resistant material is used in the manufacture of the running belt, so that the inner side of the running belt has anti-wear characteristics, however, the operator still has a treadmill The inner surface of the running board or running belt is then lubricated to extend the life of the treadmill. Most lubrication treatments are prepared by properly programming various lubricants such as liquid wax, lubricating oil or solid wax to adhere to the surface of the running board or the inner surface of the running belt. However, for the manufacturer of the treadmill, how to extend the lubrication aging and reduce the number of times the lubricant is replenished, and how to control the amount of lubricant, so that there is sufficient lubrication between the running board and the running belt without unnecessary The lubricating oil has adverse effects on other mechanisms of the treadmill (such as the treadmills on the treadmill causing abnormal noise during operation and the leakage of lubricating materials), which are problems that have been actively sought to be solved in this field.

One of the processing methods is to coat the surface of the running board with a lubricating layer. When the user moves on the treadmill, the running belt causes the inner surface of the running belt to intermittently contact the upper surface of the running board due to the weight of the user and the impact of the pedaling, thereby breaking the lubricating layer and scraping the lubrication. The powder randomly attaches the lubricating powder to the inner layer of the running belt to produce a lubricating effect. Most running belts are made up of several kinds of materials. The innermost material that is in contact with the running board is woven by a specific material in a warp and weft arrangement, so the surface of the inner layer of the running belt and the running board is in contact with the running board. Although seemingly smooth, microscopically, there are many pores between the fiber and the fiber, which is essentially a rough surface. When the above impact occurs, the inner surface of the running belt blank material will scratch a small amount when it contacts the lubricating layer. Lubricate the powder, and the partially lubricated powder is adhered between the inner fibers of the running belt blank. This lubrication method is used between the running board and the running belt by the micro-lubricating powder attached to the running belt. Produces a lubricating effect. There are two obvious defects in this lubrication method: First, it is impossible to control that the scraped lubricating powder is all attached to the inner layer of the running belt germ, so that as the treadmill continues to operate, some of the free lubricating powder will be everywhere inside the treadmill. Adhesion, especially when the lubricating powder adhering to the front and rear rollers of the treadmill accumulates to a certain amount, the above-mentioned "roller wax" problem arises. Second, a small amount of lubricating powder is sufficient to achieve the lubrication effect, but in order to prolong the lubrication aging and improve the probability of lubricating powder adhering to the inner layer of the running belt, the lubricating layer covering the running board must be thickened to make the lubrication smoothed. The amount of powder deducted can not be successfully attached to the inner layer of the running belt can still reach the predetermined amount, thus increasing the manufacturing cost. For example, it is assumed that three grams of lubricating powder is required to adhere to the inner surface of the running belt. This type of processing may require nine grams of lubricant to be applied to the running board to meet demand.

Another processing method, as shown in the Republic of China M257848 patent, applies liquid lubricants such as lubricating oils, liquid waxes, etc. directly to the inner surface of the running belt. The mechanism disclosed in the M257848 patent controls the amount of liquid lubricant to be applied to the running belt by adhering a liquid lubricant to a running belt (using a mechanism having a function similar to a doctor blade) before contacting the inner surface of the running belt. The excess liquid on the drum is scraped off, and then the liquid lubricant is directly applied to the inner surface of the running belt, and is cooled and solidified on the running belt to form a lubricating layer composed purely of lubricating oil. However, there are still some shortcomings in this type of processing. Since the roller is in surface-to-surface contact with the inner surface of the running belt, in practice, it is impossible to control the pores of the liquid lubricating material on the drum that just flow into the inner surface of the running belt. Instead, the liquid lubricant is uniformly covered on the inner surface of the running belt without pores or fibers, and most of the running belts are laminated with several non-absorbent and non-absorbent materials, so that the liquid lubricant cannot be absorbed, microscopically. In other words, the liquid lubricant that does not flow into the pores will accumulate on the surface of the fiber and solidify into a thin layer with a thickness by its own viscosity. During the processing, some liquid lubricant may enter the pores between the fibers and solidify. Around the fiber, but most of the solidified lubricating layer itself and the inner surface of the running belt have no direct contact or a small contact area, so the bonding relationship is weak, once the processed running belt is actually installed on the treadmill, when used When the person starts to exercise, the lubricating layer on the inner surface of the running belt is liable to fall off, causing the aforementioned "roller wax" or "staining". "The question, therefore, of such processing methods even if the amount of liquid lubricant pre-control, still cause the running belt has too much lubricant. In addition, by continuously heating to maintain the lubricant in a liquid state for a long period of time, it is easy to deteriorate the lubricant and affect the lubrication effect.

The main object of the present invention is to provide a processing method for a running belt blank material and a processing device capable of performing the foregoing processing method, which can integrate a powder having a lubricating effect after melting and resolidification into the inner layer of the running belt blank material to strengthen the foregoing The anti-wear property of the inner surface of the running belt with the germ material, and the above method and equipment can make the powder integrated into the inner layer of the running belt blank material not easy to fall off, and more economically process the aforementioned running belt germ material, and shorten the foregoing The time to powder into a liquid reduces the chance of deterioration.

In order to achieve the foregoing main object, in accordance with a preferred embodiment of the present invention, the foregoing processing method includes: providing the aforementioned running belt blank material, and placing the aforementioned running belt blank material with the inner layer surface facing upward, by a frame body An inlet of a processing zone moves toward an outlet of the processing zone; and a powder having a lubricating effect after melting and resolidification is provided, and the powder is stored in a storage portion of the blanking device; and then the cutting device is controlled to The powder is dispersed on the inner surface of the running belt blank through a powder discharging portion located above the processing zone; and a heating device is provided to control the running belt blank through the heating device relative to the cutting device The powder discharging portion is closer to the flat heating space of the outlet of the processing zone, and the flat heating space is heated by a heating portion of the heating device to be raised to a temperature at which the powder can be melted, and the running into the flat heating space is continuously performed. The powder on the surface of the embryonic material is melted, and the powder is maintained in a molten state in the flat heating space. Penetration of the inner layer web running belt embryo; and, cooling the inner running from the embryo flat material is heated with the exit space, such that the melted powder solidified in the inner layer of the web running belt embryos.

In order to achieve the foregoing main object, in accordance with a preferred embodiment of the present invention, the apparatus includes: a frame body and a driving device disposed on the frame body, the frame body having a processing area, the processing area having an inlet And the outlet device, the driving device can drive the running belt blank material to pass through the processing area in such a manner that the inner layer surface faces upward and moves from the inlet to the outlet; the feeding device is disposed on the frame body, and has a storage portion and a In the powder discharging portion, the storage portion may store the powder, the powder discharging portion is located above the processing region of the frame body; and a heating device is disposed on the frame body, having a flat heating space and a heating portion, the flat portion The heated space is closer to the outlet of the processing zone than the powder discharging portion of the feeding device, and the running belt is allowed to pass through, wherein the flat heating space is heated by the heating portion to be raised to melt the powder. temperature.

The structure, operation and effect of the preferred embodiment of the present invention will be described in detail below with reference to the accompanying drawings. In addition, the present invention relates to a processing method and a processing device, and some processing procedures are sequentially divided. Therefore, in this specification, the mechanism for processing the related program or a part thereof is described as "before" and "after" in its position description. "Left", "Right", "Exit", "Entry", etc. correspond to the spatial relationship of the operator in operating the preferred embodiment.

As shown in FIG. 1, a processing device (1) according to a preferred embodiment of the present invention mainly includes a frame (10), a control system, and a driving device (20) disposed on the frame body (10). A feeding device (30) provided at a central portion of the frame body (10), and a heating device (40) also disposed at a central portion of the frame body (10) and located to the right of the unloading device (30).

The frame body (10) can be stably erected on the ground, and mainly comprises two support rods (11) which are parallel to each other and horizontally attached to the ground, and a work table (12) fixed to the front part of the two support rods (11), placed and placed The pad body (18) on the table top of the table (12) and the upright frame (13) fixed to the rear portion of the two support bars (11). The upper space of the table (12) is a processing zone (S1) that can be used to accommodate the running belt (50) (as in Figure 4) and to implement the processing methods provided by the present invention. The upper edge of the upright frame (13) is fixed to a support plate (14). The support plate (14) mainly has two guide rails (141), and a left stop block (143) substantially at the middle portion of the support plate (14) and a right stop block (142) at the center of the right end; a pneumatic cylinder (16) is fixed at the top end of the upright frame (13), and the pneumatic cylinder (16) has a movable rod (161) which can be subjected to a pneumatic cylinder (16) The control extends to the right or to the left. In addition, a sliding plate (15) is disposed on the guide rail (141) of the support plate (14) and fixed to the movable rod (161), and the sliding plate (15) has two left and right stop pieces (152) (151). When the movable rod (161) protrudes to the right, the sliding plate (15) can be moved to the right until the right stopping piece (151) abuts against the right stopping block (142) of the supporting plate (14), when the movable rod (161) When retracting to the left side, the sliding plate (15) can be moved to the left until the left stop piece (152) abuts against the left stop block (143) of the support plate. In addition, the upper horizontal portion (171) of the "II"-shaped support frame (17) is fixed to the sliding plate (15), and when the pneumatic cylinder (16) controls the movable rod (161) to expand and contract, it also indirectly drives the support. The frame (17) moves to the left and right with respect to the table (12).

The foregoing control system, such as a conventional electronic control system and an automatic control system, is mounted on the frame (10) for controlling the driving device (20), the unloading device (30), and the heating device of the preferred embodiment ( 40) It is possible to operate automatically, since the control system is not the focus of the present invention and is a conventional technique, and thus is not shown in the drawings.

Referring to FIG. 1 and FIG. 2-a, the driving mechanism (20) mainly includes four rollers located above the table (12) and a motor (25) fixed to the frame body (10). The four rollers are respectively a first roller (21) located on the left side of the processing zone (S1), a second roller (22) on the upper left side of the processing zone (S1), a third roller (23) on the right side of the processing zone (S1), and The fourth roller (24) on the upper right side of the processing zone (S1) is axially arranged before and after, wherein the first roller (21) is disposed on the frame body (10), and the end of the first roller (21) is coaxially fixed. A pulley (27), a pulley (27) and a drive shaft (251) of the motor (25) are wrapped around a belt (26), whereby the first roller (21) can be driven when the motor (25) is activated. Rotating; referring to Fig. 1, the second roller (22) is disposed on the frame body (10), and the third roller (23) and the fourth roller (24) are respectively disposed under the "II"-shaped support frame (17). The horizontal portion (172) and the upper horizontal portion (171) are movable to the left and right with respect to the table (12) with the support frame (17).

Referring to Fig. 1, Fig. 3-a to Fig. 3-e, the unloading device (30) mainly has a compounding group (31) located above the processing zone (S1) and fixed to the frame body (10), left. a right gap adjustment piece (315) (316) and a storage portion (32) connected to the ingredient group (31). The batching group (31) comprises a fixing frame (311), a round rod (314), and a transmission motor (33). The fixing frame (311) has a lap portion (312) fixed to the frame body (10), And a carrying bottom plate (313), the central portion of the carrying bottom plate (313) has an adjustable rectangular hollowed out area (S2), and the long side of the hollowed out area (S2) corresponds to the front and rear direction of the processing device (1); The rod (314) is axially pivoted in the hollow region (S2) of the bearing bottom plate (313) before and after, and further, the circumferential surface of the round rod (314) is covered with axially arranged V-shaped grooves (35); The right gap adjusting piece (315) (316) is respectively disposed on both sides of the long side of the hollow area (S2), and can be adjusted to be respectively displaced left and right with respect to the bearing bottom plate (313), thereby controlling the hollow area (S2) The width, that is, the gap between the boundary of the cutout area (S2) and the circumference of the round rod (314), and the left and right gap adjustment pieces (315) (316) divide the circumference of the round rod (314) into An inner peripheral surface on the upper side of the surface of the second gap adjusting piece (315) (316) and an outer peripheral surface on the lower side of the bottom surface of the two gap adjusting pieces (315) (316); the transmission motor (33) is driven by the output shaft ( 331) Drive a rod (314), wherein when the round rod (314) is rotated, a side of the downward rotation and the boundary of the hollow region (S2) form a powder discharging portion (34), in other words, the inside of the round rod (314) The transition from the circumferential surface to the outer circumferential surface occurs as the aforementioned powder discharging portion (34); in other possible embodiments, the blanking device (30) may also not include the gap adjusting sheet (315) (316), then the circle The boundary between the inner circumferential surface and the outer circumferential surface of the rod (314) is a load bearing bottom plate (313). The storage portion (32) is disposed on the carrying bottom plate (313), and is a container having a storage and a funnel function, and can guide the powder required by the processing method of the present invention to the hollow region of the bearing bottom plate (313) by gravity. S2).

Referring to FIG. 1 and FIGS. 2-a to 2-b, the heating device (40) mainly includes a heating portion (41), a rotating rod (43), and two movable arms (42). In the example, the heating portion (41) is a rectangular parallelepiped metal block, and the long side corresponds to the front and rear direction of the processing device (1), and can be heated by external energy sources (such as electric energy, not shown in the figure) to raise the temperature of the self; The rotating rod (43) is axially disposed on the frame body (10) before and after, and the two movable arms (42) are respectively disposed at one end of the heating portion (41) and the other end is fixed to the rotating rod (43), when the rotating rod (43) When rotating clockwise, the heating portion (41) can be lifted upward, and when the rotating rod (43) rotates counterclockwise, the heating portion (41) can be driven downward toward the table (12); the heating device (40) further comprising a flat heat receiving space (S3). In the processing apparatus (1) of the preferred embodiment, the flat heat receiving space (S3) is located below the bottom surface of the heating portion (41), and the heating portion (41) When the temperature rises, the flat heat receiving space (S3) increases the temperature due to the heat conduction effect.

Please refer to the 3-e diagram. The processing procedure of the preferred embodiment is: firstly, a powder (such as wax powder) having a lubricating effect after melting and resolidifying is processed until each powder particle has substantially the same size. The particle size is placed in the storage portion (32) of the blanking device (30). Preferably, the particle size of the powder particles can be accommodated in the V-shaped concave surface of the circumference of the round rod (314) of the cutting device (30). The groove (35), the reason is detailed later; then, as shown in Fig. 4, a running belt (50) is wrapped around the first (21) and the second (22) with the inner layer surface facing the processing zone (S1). ), the third (23), and the fourth roller (24), and the pneumatic cylinder (16) controls the movable rod (161) to protrude to the right, and drives the support frame (17) to move to the right relative to the table (12). The first (21), the second (22), the third (23), and the fourth roller (24) are capable of holding the running belt (50) in a tight state to facilitate the work; controlling the heating device (40), raising the temperature of the heating portion (41), raising the heating portion (41) itself and the flat heating space (S3) to a temperature of a meltable powder; opening the control system, starting the transmission motor (33), and cutting the material The round rod (314) of the device (30) is open Rotating, the powder is spread on the surface of the inner layer of the running belt (50), while the motor (25) is activated and the driving shaft (251) is rotated counterclockwise, thereby driving the first roller (21) to rotate counterclockwise. The running belt (50) is rotated counterclockwise, when the running belt (50) passes under the first roller (21), that is, from the entrance of the processing zone (S1), and when the running belt (50) passes through the flat When the heated space (S3) advances to the lower side of the third roller (23), it is equivalent to the running belt (50) having been processed to exit from the exit of the processing zone (S1), wherein the inlet and outlet of the processing zone (S1) Depending on the relative position of the unloading device (30) and the flat heated space (S3), for example, if the position of the unloading device (30) and the heating device (40) of the present embodiment are reversed, the running belt ( 50) It must also be turned clockwise. In contrast, the area below the third roller (23) is the inlet of the processing zone (S1), and the area below the first roller (21) is the exit of the processing zone (S1).

It should be noted that although the present embodiment uses the finished product of the running belt which has been subjected to the front stacking and cutting for further processing, the processing method of the present invention is not limited to being applied only to the finished running belt, but can be used as The running belt embryo material of the innermost part of the running belt is the object of the processing method of the present invention. In other words, the running belt blank material itself has considerable anti-wear characteristics, and one of the planes of the running belt germ material can become running. The inner peripheral surface of the finished product. In addition, the running belt blank material is substantially a flat material having a thickness. For convenience of description, the surface of the running belt blank material which can be used as the inner circumferential surface of the running belt finished product in this specification is called the inside of the running belt blank material. Layer surface, further, the conventional running belt embryo material is substantially interwoven with fibers. Microscopically, the inner surface of the running belt germ material is relative to the space between the plurality of fibers and fibers, in other words, The staggered fibers and the pores between the fibers are referred to herein as the inner layer of the running belt.

Referring to Figures 3-d and 3-e, the round rod (314) in the figure can be rotated by the drive motor (33) in the clockwise direction, and the left gap adjusting piece (315) and the round rod (314) The circumferential surface contact, the right gap adjusting piece (316) leaves a gap with the circumferential surface of the round rod (314), and when the storage portion (32) of the feeding device (30) is filled with powder, the powder (not shown) It will fall into the V-shaped groove (35) due to the action of gravity and the rotation of the round rod (314), and the V-shaped groove (35) containing the powder rotates to the low side with the circumferential surface of the round rod (314). When the inner peripheral surface of the round rod (314) is turned to the outer peripheral surface at a certain angle to the boundary of the right side gap adjusting piece (316), the powder in the V-shaped groove (35) is turned to Dropping down, that is, the powder is dropped through the powder discharging portion (34) of the blanking device (30), and conversely, when the circumferential surface of the round rod (314) is rotated to the right side regulating piece (316), the powder is stopped. That is, the boundary of the hollow region (S2) and the circumferential surface of the corresponding round bar (314) at this time are substantially in a state of conformity, in other words, the boundary of the hollow region (S2) and the circumferential surface of the round bar (314). The gap between the gaps is smaller than the particle size of the powder; The degree of density of the V-shaped groove (35) and the rotation speed of the round rod (314) can directly affect the powdering frequency of the powder portion (34), such as the speed of rotation of the running belt (50), which can be controlled. The degree of density of the powder scattered on the inner surface of the running belt embryo; if the particle size of the powder is small enough to fully enter the V-shaped groove (35), the right gap adjusting piece (316) can also be directed to the round rod (314). The circumferential surface is adjusted to approximate contact. In short, the left and right gap adjusting pieces (315) (316) can be adjusted according to actual needs, so that the powder discharging portion (34) is intermittently opened or closed. For example, the blanking device (30) of the preferred embodiment can control the powder to be scattered one by one on the inner surface of the running belt blank, and can correctly control the inner surface of the running belt blank within a certain unit area. The degree of density of the powder; assuming that the length of the V-shaped groove (35) is 30 cm, a V-shaped groove (35) can accommodate approximately 300 powders arranged in a line with respect to the operator, and the right gap adjustment piece ( 316) The gap between the circumferential surface of the round rod (314) does not allow the passage of powder particles, and when the round rod is rotated such that the V-shaped grooves (35) pass one by one through the powder discharging portion (34), the powder is substantially Each time 300 pieces are dropped line by line on the inner surface of the running belt, and the speed of the running belt (50) is controlled to control the powder (34) to the inner layer of the running belt (50). The distance of the surface controls the line spacing of each row of powder on the inner surface of the running belt (50), and the number of powders per row is approximately the same, in other words, the amount of powder actually required is effectively quantified. In other possible embodiments, a single gap adjusting piece and a round bar having no groove may be used, and the gap between the boundary of the hollow region and the circumferential surface of the round bar may be adjusted in advance according to the particle diameter of the powder, and only The rotation of the round rod takes the powder out of the powder section.

Please refer to Figure 2-b, Figure 3-e, and Figure 4, in which the running belt (50) is as described above with the inner surface of the inner running belt blank facing up from the processing zone (S1) The inlet (left side of the figure) moves toward the exit of the processing zone (S1) (on the right side of the figure), and when the running belt (50) is driven through the unloading device (30), the powder is evenly dispersed through the powder discharging section (34). Running with the inner surface of the embryo material, as the running belt (50) continues to advance, the powder also enters the heating portion (41) with the running belt (50), that is, enters the flat heating space (S3), and each powder particle In the flat heated space (S3), it is heated and melted into lubricating droplets, and due to the control of the feeding device (30), only a small amount of lubricating droplets can be controlled in a certain unit area of the inner surface of the running belt, thereby lubricating The droplets can flow into the pores of the fiber near the location, reducing the probability of excessive lubrication droplets at the same location, preventing partial lubrication droplets from entering the pores of the fibers, and cooling when the running belt (50) exits the flat heated space (S3) Solidified on the inner surface of the running belt. Further, since the flat heat receiving space (S3) has a certain range, the powder is continuously heated in a short time when it enters, thereby increasing the probability that the powder melts into lubricating pores into the fiber pores.

In detail, if only a small amount of powder is required to be integrated into the inner surface of the running belt, the height of the flat heating space (S3) can be controlled to be substantially the same as the thickness of the article to be processed, as in the preferred embodiment (this embodiment). For the running belt, the heating part (41) is adjusted so that the bottom surface of the heating part (41) can be flatly attached to the inner surface of the running belt, so that when the running belt (50) moves to the flat heated space ( At S3), the powder begins to melt upon contact with the leading edge of the bottom surface of the heating portion (41), and the melted lubricating droplets not only naturally flow into the pores of the fiber, but also because the bottom surface of the heating portion (41) and the inner surface of the running belt. Closely fit and further forced into the vicinity of the fiber pores, and the bottom surface of the heating portion (41) also has a certain width, which can force the lubrication droplets to flow into the pores of the fibers, thereby preventing the lubricating droplets from solidifying in the running belt. Inner surface. In other possible embodiments, the bottom surface of the heating portion may be designed to be slightly inclined with respect to the portion near the entrance of the processing region, that is, when the heating portion is attached to the inner surface of the running belt, the flat heat is applied. The space is a space that is wide and narrow, and gradually converges to the inner surface of the running belt. When the powder enters the flat heating space of the front section, it can be melted first, and then the bottom of the heating part gradually forces the lubricating fluid into the pores of the fiber.

In general, with the efficacy of the powder which can be used as a lubricating function and the actual demand of the treadmill, only a small amount of powder is sufficient to function. Therefore, it can be seen from the above description that the powder can be processed according to the processing method and processing equipment of the present invention. Quantitatively controlled and reshaped to bond with the inner layer of the running belt; and the heating time for the powder is short during the processing; when the finished running belt is set on the treadmill, the instant running belt is actually running and running When the plate is in contact, the lubricating effect is not easily degraded, and the occurrence of other undesirable problems may be effectively reduced by leaving excess powder on the surface of the running belt.

1. . . Processing Equipment

10. . . Frame

11. . . Support rod

12. . . Workbench

13. . . Upright frame

14. . . Support plate

141. . . guide

142. . . Right stop

143. . . Left stop

15. . . Sliding plate

151. . . Right stop

152. . . Left stop

16. . . Pneumatic cylinder

161. . . Movable rod

17. . . Support frame

171. . . Upper horizontal part

172. . . Lower horizontal part

20. . . Drive unit

twenty one. . . First wheel

twenty two. . . Second wheel

twenty three. . . Third wheel

twenty four. . . Fourth wheel

25. . . motor

251. . . Drive shaft

26. . . Belt

27. . . Pulley

30. . . Cutting device

31. . . Ingredient group

311. . . Fixing frame

312. . . Lap

313. . . Carrying floor

314. . . Round rod

315. . . Left gap adjuster

316. . . Right gap adjuster

32. . . Storage department

33. . . Drive motor

34. . . Powdering department

35. . . V-shaped groove

40. . . heating equipment

41. . . Heating department

42. . . Moving arm

43. . . Rotating lever

S1. . . Processing Zone

S2. . . Hollow area

S3. . . Flat heated space

Figure 1 is a perspective view of a preferred embodiment of the present invention;

Figure 2-a is a front elevational view of a preferred embodiment of the present invention corresponding to the state of Figure 1;

Figure 2-b is an enlarged view of a detail corresponding to the range A in Figure 2 in a preferred embodiment of the present invention;

Figure 3-a is a perspective view of the blanking device in a preferred embodiment of the present invention;

Figure 3-b is a top view of the storage portion corresponding to Figure 3-a and removing the upper storage portion in accordance with a preferred embodiment of the present invention;

Figure 3-c is a left side view corresponding to the state of Figure 3-a in a preferred embodiment of the present invention;

Figure 3-d is a cross-sectional view corresponding to the E-E hatching in Figure 3-c in a preferred embodiment of the present invention;

Figure 3-e is an enlarged view of a detail corresponding to the range of B in Figure 3-d in a preferred embodiment of the present invention;

Figure 4 is a perspective view of a running belt in accordance with a preferred embodiment of the present invention.

1. . . Processing Equipment

10. . . Frame

20. . . Drive unit

30. . . Cutting device

40. . . heating equipment

Claims (12)

The invention relates to a processing device for enhancing the anti-wear property of the inner layer of the running belt, wherein the processing device can integrate the powder into the inner layer of the running belt blank, the processing device comprises: a frame body having a processing area, the processing area Having an inlet and an outlet; a driving device disposed on the frame body to drive the running belt blank material to pass through the processing zone in such a manner that the surface of the inner layer faces upward and moves from the inlet to the outlet; Provided in the frame body, having a storage portion and a powder discharging portion, wherein the storage portion can store the powder, the powder discharging portion is located above the processing region of the frame body, and the powder can be dropped through the powder discharging portion; a heating device is disposed on the frame body, and has a flat heat receiving space and a heating portion, wherein the heating portion is a metal block, and the flat heat receiving space is located below the bottom surface of the metal block, and the height of the flat heat receiving space is substantially equal to The thickness of the running belt blank material, and the flat heating space is closer to the outlet of the processing area than the powder discharging portion of the cutting device. Material for the embryo by the running belt, and, the space may be heated by the flat piece of metal may be heated up to the melting temperature of the powder. The processing device for enhancing the anti-wear property of the inner layer of the running belt blank according to the first aspect of the invention, wherein the cutting device further comprises a batching group, wherein the batching group can control the powdering of the powder discharging portion. rate. The processing apparatus for enhancing the anti-wear property of the inner layer of the running belt with the raw material according to the second aspect of the invention, wherein the batching group comprises a round rod, a transmission motor, and a hollowing area, wherein the round rod is pivoted The foregoing In the hollow area, the aforementioned transmission motor can drive the aforementioned round rod to rotate. The processing apparatus for enhancing the anti-wear property of the inner layer of the running belt blank according to the third aspect of the invention, wherein the circumferential surface of the round rod is provided with at least one groove, and the circumferential surface of the round rod and the foregoing The boundaries of the hollowed out area are roughly fitted. A processing apparatus for enhancing the wear resistance of an inner layer of a running belt blank according to the fourth aspect of the invention, wherein the groove extends substantially axially. The processing apparatus for enhancing the anti-wear property of the inner layer of the running belt blank according to the first aspect of the invention, wherein the cutting device further comprises at least one gap adjusting piece disposed around the powder discharging portion and controllable The particle diameter of the powder passing through the aforementioned powder discharging portion. The processing apparatus for enhancing the anti-wear property of the inner layer of the running belt blank according to the first aspect of the invention, wherein the height of the flat heat receiving space is adjustable. The processing apparatus for enhancing the anti-wear property of the inner layer of the running belt blank according to the first aspect of the invention, wherein the metal block is forced downward toward a working table such that the height of the flat heating space is substantially equal to the foregoing Running with the thickness of the embryo material. A processing method for enhancing the anti-wear property of an inner layer of a running belt, the method comprising the steps of: causing the running belt to have an inner layer facing upward, from an inlet of a processing area of a frame Moving the outlet of the processing zone; controlling the material discharge device to pre-store a powder having a lubricating effect after being melted and solidified in a storage portion of the cutting device a powder discharging portion of the cutting device above the processing zone is disposed on a surface of the inner layer of the running belt blank; and a heating portion of a heating device is controlled to perform a powder discharging with respect to the cutting device The height of the flat heat receiving space closer to the outlet of the processing zone is substantially equal to the thickness of the running belt blank, wherein the heating portion is a metal block, and the flat heat receiving space is located below the bottom surface of the metal block, and the metal block pair The flat heated space is heated to a temperature at which the powder can be melted. When the running belt blank enters the flat heating space, the bottom surface of the metal block is flatly attached to the inner surface of the running belt blank, and continuously enters the flat surface. The powder on the surface of the inner layer of the running belt blank of the heated space is melted, so that the powder is maintained in a melted state in the flat heat receiving space to penetrate into the inner layer of the running belt blank; and the running belt is made of the aforementioned The flat heat receiving space is withdrawn, so that the melted powder is solidified in the inner layer of the aforementioned running belt. The processing method for enhancing the anti-wear property of the inner layer of the running belt blank according to claim 9, wherein the cutting device is controlled such that the unloading device is disposed in a hollow region and is subjected to a transmission motor. The driven round rod discharges the aforementioned powder through the aforementioned powder discharging portion. The processing method for enhancing the anti-wear property of the inner layer of the running belt blank according to claim 10, wherein the peripheral surface of the round rod is controlled to substantially conform to the boundary of the hollow region, when the round rod is When the opening of the groove provided in the circumferential surface of the round bar is substantially aligned with the boundary of the hollowed portion, the powder discharging portion is opened. A method for processing an anti-wear property of an inner layer of a running belt with an embryo according to claim 9 of the patent application, wherein the metal is first controlled The block is approached downward toward a table until the height of the aforementioned flat heated space is substantially equal to the thickness of the aforementioned running belt blank.