JP2010089122A - Method for punching element for cvt belt - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for punching of an element for a CVT belt which can achieve a lower variation in sheet thickness immediately after punching than that in the conventional technique. <P>SOLUTION: In the method, an element 8 for a CVT belt comprising an approximately triangular head part 81, an approximately rectangular body part 82, and a neck part 83 connecting the head part 81 to the body part 82 is punched from a belt-like material 1. The method comprises a preliminary punching step S1 of forming, by punching, a space part 15 on the outer periphery side of an island-shaped part 10 formed of an approximately pentagonal region so that the connection of the island-shaped part 10 to the surrounding belt-like material 1 through only a connection part 11 is maintained and the part other than the connection part 11 is separated from the surrounding part; a finish blanking step S4 of punching the island-like part 10 while remaining the connection part 11 unremoved to regulate the shape of the element 8; and a separation step S5 of cutting the connection part 11 to separate the element 8 from the belt-like material 1. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a method of punching and manufacturing an element used for a CVT belt.

  A belt-type CVT (Continuously Variable Transmission) is composed of a pair of pulleys and a CVT belt that spans the pulleys. The CVT belt is configured by mounting a large number of friction parts called elements on a ring-shaped belt made of a metal strip.

  As shown in FIG. 1 to be described later, the element 8 includes a substantially triangular head portion 81, a substantially rectangular body portion 82, a central portion of the bottom portion of the head portion 81, and a long side portion of the body portion 82. It consists of a neck part 83 that connects the central part of the two. On the left and right sides of the neck portion 83, concave portions 85 formed by a gap between the head portion 81 and the trunk portion 82 are formed. A CVT belt can be obtained by inserting a belt (not shown) made of a metal strip into the recess 85 and disposing the element 8 all around the belt.

The element 8 is manufactured by a process of preparing a strip-shaped material made of a plate-shaped metal, punching it into a desired shape, and then performing a finishing process. The punching process of the element 8 is performed using a die composed of a die and a punch.
Conventional punching methods for CVT elements include those disclosed in Patent Documents 1 and 2, for example.

JP 2005-88025 A Special table 2007-516084 gazette JP 2005-115632 A

  By the way, when the element 8 is punched, stress applied from a punch or the like is influenced around the punched portion of the strip-shaped material, and a difference occurs in the material flow in the portion of the strip-shaped material that has not yet been punched, resulting in a change in thickness. is there. For this reason, in the element 8 after the punching process, for example, there may be a difference in plate thickness on the left and right sides in the width direction in the body portion.

When a CVT belt is formed by laminating a large number of elements having such plate thickness variations, the variations are accumulated, and the CVT belt as a whole may have a large bend. On the other hand, it has been difficult to reduce the variation in the left and right plate thickness in each element as long as the conventional punching process is employed.
Therefore, as described in the above-mentioned Patent Document 3, the thickness variation of each element is investigated, the thickness variation state of the element is classified into a plurality of groups, and the CVT belt is assembled. A technique for combining elements of any group has been proposed.

  However, in such a correspondence, a CVT belt cannot be produced unless a large amount of punched elements are kept in stock. Therefore, it has been desired to review the conventional punching method and develop a punching method that can reduce the variation in the thickness of the right and left elements immediately after the punching.

  The present invention has been made in view of such conventional problems, and an object of the present invention is to provide a method for punching a CVT belt element that can reduce the thickness variation immediately after punching as compared with the conventional punching method.

The present invention provides a CVT composed of a substantially triangular head, a substantially rectangular trunk, and a neck that connects the center of the bottom of the head and the center of the long side of the trunk. A method for punching a belt element from a belt-shaped material,
The island-shaped portion composed of a substantially pentagonal region is maintained in a state where the island-shaped portion is connected to the surrounding band-shaped material only through the connecting portion, and the portions other than the connecting portion are separated from the surroundings. A preliminary punching step of punching and forming a void on the outer peripheral side of the island-shaped portion;
A finish punching process for adjusting the shape of the element by adding a punching process to the island-shaped part in a state where the connecting part is left,
And a separation step of separating the element from the band-shaped material by cutting the connecting portion. A method for punching an element for a CVT belt (Claim 1).

In the present invention, as described above, after the preliminary punching step is performed, the finish punching step and the separation step are performed. Thereby, the plate | board thickness dispersion | variation immediately after stamping of an element can be reduced rather than before.
That is, in the preliminary punching step, the gap is provided around an island-shaped portion made of a substantially pentagonal region. Since the punching of the contour at this time is not a complicated shape like the final shape of the element but a substantially pentagonal shape, the influence at the time of preliminary punching hardly occurs in the surrounding strip-shaped material. Moreover, there is almost no variation in the plate thickness inside the island portion.

  Further, in the finish punching process, a complicated shape is punched out of the substantially pentagonal island-shaped part, but the influence is blocked by the presence of the gap part, and even around the unpunched part. Not reach. In addition, since there is almost no variation in plate thickness even during preliminary punching as described above in the island-shaped part, variation in plate thickness hardly occurs in the elements after punching, and the elements finally separated in the separation process are Also, the thickness variation is small.

  That is, according to the present invention, it is possible to provide a punching method for an element for a CVT belt capable of reducing the variation in the plate thickness immediately after punching as compared with the prior art. Further, if an element manufactured using the punching method of the present invention is used, a CVT belt can be assembled without sorting, and rationalization of manufacturing such as inventory compression can be promoted.

  In the punching method of the present invention, in the preliminary punching step, it is preferable that the width of the connecting portion is formed to be 20% or less of the overall contour length of the island-shaped portion (Claim 2). In this case, it is possible to more reliably exhibit the above-described operational effects by performing the preliminary removal step. On the other hand, when the width of the connecting portion exceeds 20% of the punching length of the outline of the island-shaped portion, the influence of the finish punching process may be transmitted to the periphery of the island-shaped portion via the connecting portion. come. Therefore, although the width of the connecting portion is preferably as small as possible, a width dimension is required so that the state where the island-like portion is connected to the periphery thereof is stably maintained. In addition, the outline full length of an island-like part can be defined by adding the width dimension of the said connection part to the length of the outline which faces the said space | gap part of the said island-like part.

  Moreover, the said connection part is connected to the position used as the center part of the bottom part of the said trunk | drum in the said island-shaped part so that it may be connected to the position used as the vertex part of the said head in the said island-shaped part. (Claim 3). In this case, in any case, the existence position of the connecting portion is left-right symmetrical, and the plate thickness variation can be further suppressed. In addition, the structure which provides a connection part so that it may be connected to the position used as the vertex part of a head is the most suitable at the point that there is little influence by the cutting | disconnection at the time of isolation | separation.

Further, as the band-shaped material, a material having a uniform thickness in the width direction is used, and a region that becomes a part of the body portion in the island-shaped portion is compressed between the preliminary punching step and the finish punching step. It is preferable to perform a crushing step of reducing the thickness to form a thin portion (claim 4).
As shown in Examples described later, the element has a thin portion having a thickness smaller than that of other portions in a part of the body portion. As a method for forming this thin portion, there are a method of compression molding by press working at the time of punching using a material having a uniform thickness in the width direction as a strip material, and a method of using a stepped strip material having a difference in thickness in the width direction. is there. Among these, it is possible to reduce the cost of the material by providing the thin portion by press working, but the influence at the time of pressing easily extends around the punched portion.

  Here, in the present invention, even if the crushing process is performed after the preliminary punching process is performed, the thickness variation is not affected. On the other hand, it is possible to carry out at the same time as the above finishing punching process, but in that case, it is necessary to set the load of the press device to a high load that can handle both punching and crushing, and it is necessary to enlarge the press device It becomes. Therefore, as described above, it is preferable to provide the crushing step alone between the preliminary punching step and the finishing punching step, and this can increase the number of steps, but can reduce the size of the press device. .

  Moreover, it is preferable to perform the embossing process which performs the embossing for providing a protrusion part in the area | region used as the center part of the said head between the said preliminary punching process and the said finish punching process (Claim 5). As shown also in the Example mentioned later, the said element has the protrusion part which protrudes in one surface in the center part of a head. The formation of the protrusions can be performed at the same time in any step of pressing, but is preferably performed after the preliminary punching step so that the influence during pressing does not reach the periphery of the punched portion. . Similarly to the above, in order to suppress an increase in the size of the press apparatus, it is preferable to provide an embossing step alone between the preliminary punching step and the finishing punching step.

Further, as the band-shaped material, a material having a uniform thickness in the width direction is used, and in the finishing punching step, a region that becomes a part of the body part in the island-shaped part is compressed to reduce the thickness, thereby reducing the thin part The crushing to be formed and the embossing to be applied to the region to be the central part of the head can be performed together by a single press process (Claim 6).
As described above, the crushing molding and the embossing molding are preferably provided as independent processes between the preliminary punching process and the finishing punching process from the viewpoint of downsizing the press device. On the other hand, there may be a case where it is not necessary to reduce the size of the press device, such as using an existing large press device. In this case, the number of processes can be reduced by consolidating into one process in the finish punching process.

Further, as the band-shaped material, a step-shaped band-shaped material whose thickness in the width direction is changed is used, and in the preliminary punching process, a portion to be a thin-walled portion in the body portion is straight in the longitudinal direction of the band-shaped material. It is also possible to perform punching in a continuous manner (claim 7).
In this case, the above-described crushing is not necessary, and the number of steps can be easily reduced. Even when such a stepped strip-shaped material is used, it is possible to reduce the variation in the plate thickness of the element obtained by performing the preliminary punching step first.

Example 1
A method for punching a CVT belt element according to an embodiment of the present invention will be described with reference to FIGS.
In this example, as shown in FIG. 1, a substantially triangular head 81, a substantially rectangular trunk 82, a central portion of the bottom of the head 81, and a central portion of the long side of the trunk 82 are provided. This is a method of punching the CVT belt element 8 constituted by the connecting neck portion 83 from the belt-shaped material 1 (FIG. 2). As the strip-shaped material 1, a material having a uniform thickness in the width direction is used.

  In this method, as shown in FIG. 2, the state in which the island-shaped portion 10 formed of a substantially pentagonal region is connected to the surrounding strip-shaped material 1 only through the connecting portion 11 is maintained. A preliminary punching step S1 for punching and forming the gap 15 so that the portion is separated from the surroundings is performed.

  At this time, it forms so that the width | variety a of the said connection part 11 may become sufficiently smaller than the outline full length dimension of the said island-like part 10 (20% or less). Moreover, the connection part 11 is provided so that it may be connected with the position used as the vertex part of the head 81 in the said island-like part 10. FIG. In addition, the island-like portion 10 is arranged so that the vertical direction of the element 8 faces in a direction perpendicular to the longitudinal direction of the strip-shaped material 1. In addition, the plurality of island-like portions 10 that are sequentially formed are all directed in the same direction. At this time, a reference hole 19 for alignment is also provided.

Next, as shown in FIG. 2, after the preliminary punching step S <b> 1, a crushing step S <b> 2 for compressing a region that becomes a part of the body portion 82 in the island-like portion 10 to reduce the thickness to form a thin portion 825. I do.
Next, as shown in the figure, after the crushing step S2, an embossing step S3 for performing embossing for providing the protruding portion 815 in the region that becomes the central portion of the head 81 is performed.

Next, as shown in the figure, a finishing punching step S4 is performed in which the island-like portion 10 is punched to adjust the shape of the element 8 with the connecting portion 11 remaining.
Next, as shown in the figure, a separation step S5 is performed in which the connecting portion 11 is cut at the position of the cutting line 18 to separate the element 8 from the strip-shaped material 1. Thus, the element 8 is obtained, and a finishing process such as polishing may be further added as necessary.

  As described above, in the present example, the preliminary removal step S1 is first performed to form the island-shaped portion 10 formed of a substantially pentagonal region, and the void portion 15 is provided around the island-shaped portion 10. After that, the island-shaped portion 10 separated from the periphery of the strip-shaped material by the gap 15 is processed to the finishing punching step S4, and then the separation step S5 for separating the element 8 from the strip-shaped material 1 is performed. To do. Therefore, even if the processing that applies stress only to the specific portion of the crushing step S2 and the embossing step S3 or the finishing punching step S4 is performed, the influence of the fluctuation of the plate thickness due to the processing is as follows. It is blocked by the presence of the gap 15.

Further, since the punching in the preliminary punching step S1 is not a complicated shape like the final shape of the element but a substantially pentagonal shape, the influence at the time of preliminary punching hardly occurs in the surrounding strip-shaped material, Fluctuation of the plate thickness within the island portion 10 hardly occurs. For this reason, variation in the plate thickness is less likely to occur in the punched element 8 obtained by processing this island-shaped portion 10, and the element 8 finally separated in the separation process has a smaller variation in plate thickness than in the past. Become.
Thus, if the method of this example is used, the plate | board thickness dispersion | variation immediately after stamping of the element for CVT belts can be reduced rather than before.

(Example 2)
In this example, as illustrated in FIG. 3, the formation position of the connecting portion 12 is changed to a position different from that in the first embodiment. Others are almost the same as in the first embodiment.
That is, as shown in FIG. 3, the state in which the island-shaped portion 10 made of a substantially pentagonal region is connected to the surrounding strip-shaped material 1 only through the connecting portion 12 is maintained, and the portions other than the connecting portion 12 are A preliminary punching step S201 for punching and forming the gap 16 so as to be separated from the surroundings is performed.

  At this time, it forms so that the width | variety b of the said connection part 12 may become sufficiently smaller than the outline full length dimension of the said island-like part 10 (20% or less). Moreover, the connection part 12 of this example is provided so that it may be connected with the position used as the center part of the base part of the trunk | drum 82 in the said island-like part 10. FIG.

Next, as shown in FIG. 3, after the preliminary punching step S <b> 1, a crushing step S <b> 202 for compressing a region that becomes a part of the body portion 82 in the island-like portion 10 to reduce the thickness to form a thin portion 825. I do.
Next, as shown in the figure, after the crushing step S202, an embossing step S203 for performing an embossing process for providing the protruding portion 815 in the region that becomes the central portion of the head 81 is performed.

Next, as shown in the drawing, a finishing punching step S204 is performed in which the shape of the element 8 is adjusted by punching the island-like portion 10 with the connecting portion 12 left.
Next, as shown in the figure, a separation step S205 is performed in which the connecting portion 12 is cut at the position of the cutting line 17 to separate the element 8 from the strip-shaped material 1.
Others are the same as in the first embodiment.
Also in the case of this example, the same effects as those of the first embodiment can be obtained.

FIG. 3 is a perspective view showing the shape of an element in Example 1. FIG. 3 is an explanatory diagram showing an element punching process in Example 1. Explanatory drawing which shows the punching process of the element in Example 2. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Band-shaped material 10 Island-shaped part 11,12 Connection part 15,16 Cavity part 8 Element S1, S201 Preliminary extraction process S2, S202 Crushing process S3, S203 Embossing process S4, S204 Finishing extraction process S5, S205 Separation process

Claims (7)

An element for a CVT belt comprising a substantially triangular head, a substantially rectangular trunk, and a neck connecting the central part of the bottom of the head and the central part of the long side of the trunk. A method of punching from a strip material,
The island-shaped portion composed of a substantially pentagonal region is maintained in a state where the island-shaped portion is connected to the surrounding band-shaped material only through the connecting portion, and the portions other than the connecting portion are separated from the surroundings. A preliminary punching step of punching and forming a void on the outer peripheral side of the island-shaped portion;
A finish punching process for adjusting the shape of the element by adding a punching process to the island-shaped part in a state where the connecting part is left,
And a separation step of separating the element from the strip material by cutting the connecting portion.   2. The punching method for an element for a CVT belt according to claim 1, wherein, in the preliminary punching step, the width of the connecting portion is formed to be 20% or less of the total contour length of the island-shaped portion.   3. The connecting portion according to claim 1, wherein the connecting portion is connected to a position that is a top portion of the head portion in the island-shaped portion, or is a central portion of a bottom portion of the trunk portion in the island-shaped portion. A punching method for an element for a CVT belt, which is provided so as to be connected to a position.   4. The body portion of the island-shaped portion according to claim 1, wherein the strip-shaped material has a uniform thickness in the width direction, and the body portion of the island-shaped portion is interposed between the preliminary punching step and the finishing punching step. A punching method for an element for a CVT belt, wherein a crushing step of compressing a region that becomes a part of the belt to reduce a thickness to form a thin portion is performed.   5. The embossing step of performing embossing for providing a protruding portion in a region to be a central portion of the head between the preliminary punching step and the finish punching step according to claim 1. A method for punching a CVT belt element.   In any 1 item | term of Claims 1-3, as the said strip | belt-shaped raw material, the thing of the thickness of the width direction is used uniformly, and the area | region used as a part of the said trunk | drum in the said island-shaped part is compressed in the said finish extraction process. CVT belt element characterized in that crushing forming to reduce the thickness to form a thin portion and embossing forming to the central portion of the head are performed together by a single press process. Punching method.   In any 1 item | term of Claims 1-3, the site | part which should become the thin part in the said trunk | drum in the said preliminary | backup removal process using the stepped strip | belt-shaped material from which the thickness of the width direction is changing as said strip | belt-shaped material. A stamping method for an element for a CVT belt, wherein punching is performed so as to be continuous in a straight line in the longitudinal direction of the strip-shaped material.

Images