JP5709421B2 - Loose belt looseness detection method and detection device - Google Patents

Description

  The present invention relates to a rotation belt looseness detection method and a detection device capable of detecting an increase in looseness of a rotation belt wound around two pulleys and notifying an operator of the increase.

  In various manufacturing processes for manufacturing various products, a motor is often used as a power source, and a large number of rotating belts wrapped around two pulleys are used to transmit the rotational force from the motor. ing.

  When the rotating belt is wound around two pulleys, a certain slack is generated even in the initial state. This is because if the rotating belt is too tight, the life of the rotating belt and various machine parts is shortened, and the safety of the manufacturing process is also lowered.

  The main material of the rotating belt is generally rubber having a certain elasticity. Therefore, when the rotating belt is used for a long time, loosening of the rotating belt increases due to stretching of the rotating belt and the like. Using a rotating belt with increased looseness causes a reduction in the transmission efficiency of the rotational force. In addition, when the degree of stretching of the rotating belt increases, the thickness of the rotating belt decreases and the rotating belt may be divided.

  For this reason, the operator needs to regularly check the looseness of the rotating belt and perform maintenance and inspection work such as replacing the rotating belt when the looseness increases. A technique for checking the loose state of the rotating belt is disclosed in Patent Document 1, for example.

  Japanese Patent Application Laid-Open No. 2004-133620 discloses a rotating belt deflection determination tool. This bending determination tool holds the two belt portions facing each other in the rotating belt with the pulley stopped, and sets the distance between the belt portions when a predetermined load is applied in the direction in which the belt portions are close to each other. Based on this, the propriety of the bending of the rotating belt is determined.

JP-A-9-257466 (FIG. 1)

  The pulley and the rotating belt are generally covered with a protective cover in consideration of safety. Therefore, when carrying out maintenance and inspection work using the above-described deflection determination tool, the protective cover must be removed after the pulleys and the rotation belt are stopped in order to determine whether or not the rotation belt is loose (deflection). Therefore, there are problems that the work is troublesome and the work time becomes long.

  By the way, when the rotating belt is run in a loose state, a so-called fluttering phenomenon occurs in the belt portion between the two pulleys. This phenomenon is a phenomenon similar to vibration. As the looseness of the rotating belt increases, the vibration of the belt portion also increases. Therefore, even if the rotating belt is not stopped, the operator can visually check the loose state of the rotating belt, that is, how much the looseness has increased (the degree of increase in looseness).

  However, when the protective cover is attached as described above, the operator cannot visually confirm. Although it is possible to confirm by removing the protective cover, it is not preferable to remove the protective cover with the pulley rotated in consideration of safety.

  Therefore, for example, if a protective cover formed of a punching plate (a plate on which a large number of through holes having a predetermined shape are formed) is used, the operator can visually check the loosening of the rotating belt without removing the protective cover. It is possible to confirm the degree of increase. However, if the through-hole is enlarged, the inside becomes easy to see, but the safety is lowered, so the through-hole cannot be made too large. Therefore, the operator needs to check the degree of increase in looseness of the rotating belt by bringing his face close to the protective cover.

  In addition, when the rotating belt is disposed near a manufacturing apparatus that is at a high temperature, it is difficult for an operator to approach the protective cover, so that maintenance and inspection work is still difficult.

  The problem to be solved by the present invention is to provide a rotation belt slack detection method and a detection device capable of easily confirming the degree of increase in rotation belt slack.

  In order to solve the above problems, the present inventor has conceived of using a thread-like detection element that is cut by sliding contact with the surface of a rotating belt for a certain period of time, and has completed the present invention.

That is, according to the first aspect of the present invention, in the method of detecting looseness of the rotating belt that detects looseness of the rotating belt that is wound around two pulleys, the surface of the rotating belt is cut when the surface of the rotating belt is in sliding contact for a certain period of time. A sensing element and a weight connected to one end of the sensing element and suspended are prepared, the sensing element is arranged in a direction intersecting the traveling direction of the rotating belt, and the rotating belt When the rotation of the rotating belt is increased, the loosened surface of the rotating belt is in sliding contact with the detecting element, and the detecting element is cut after being in sliding contact for a certain period of time. The weight is dropped.

According to a second aspect of the present invention, in the method for detecting looseness of the rotating belt according to the first aspect , the plurality of detecting elements are arranged so that the distances from the rotating belt are different from each other, and one end of each detecting element is arranged It is characterized by connecting a weight to each and hanging.

According to a third aspect of the present invention, in the method for detecting loosening of the rotating belt according to the second aspect , the colors of the surfaces of the plurality of weights are different from each other.

According to a fourth aspect of the invention, in the rotating belt looseness detecting device for detecting the loosening of the rotating belt wound around the two pulleys, the surface of the rotating belt is cut when the surface is in sliding contact for a certain period of time. A detection element; and a notification unit that operates when the detection element is disconnected. The detection element is disposed in a direction intersecting a traveling direction of the rotating belt, and has a predetermined distance from the surface of the rotating belt. When the rotating belt is loosened, the loosened surface of the rotating belt is in sliding contact with the detecting element, and the detecting element is disconnected after being in sliding contact for a certain period of time, the notification means is activated. And an attachment portion that is disposed on one side of the direction intersecting the traveling direction of the rotating belt and to which one end of the detection element is attached, and intersects the traveling direction of the rotating belt. While being arranged on the other side of direction, the a transparent plate having an insertion hole in which the other end is pulled out of the sensing element, and integrally formed by connecting the transparent plate and the mounting portion with the connection member It is characterized by that.

The notification means is not particularly limited as long as it operates when the detection element is cut and appeals to the human senses, particularly vision and hearing, and includes, for example, a weight, a light emitting element, and a buzzer. In particular, weight is used because it is economical.

According to a fifth aspect of the present invention, in the rotating belt slack detection device according to the fourth aspect , the notification means is a weight that is attached to the other end of the detection element and is also suspended. A guide member having a guide surface that smoothly guides the detection element drawn out from the insertion hole toward the weight is provided on the transparent plate.

According to the first aspect of the present invention, when the rotating belt runs for a long time, the loosening of the rotating belt increases and the amplitude of vibration of the rotating belt between the pulleys increases. It comes into sliding contact with the thread-like detection element. Then, when the surface of the rotating belt is in sliding contact for a certain period, the thread-like detecting element is cut and the weight is dropped. The operator can easily recognize that the looseness of the rotating belt has increased by recognizing that the weight is falling. Therefore, it is not necessary for the operator to periodically stop and inspect the rotating belt as in the past, or to visually inspect the rotating belt and approach the rotating belt. It becomes possible to shorten.

According to the second aspect of the present invention, as the looseness of the rotating belt increases, the plurality of detecting elements are cut in order from the closest distance to the rotating belt, so that the plurality of weights also drop in order. To go. Therefore, the operator can easily grasp the degree of increase in the looseness of the rotating belt by recognizing the falling state of the plurality of weights. This eliminates the need for the operator to pay much attention to the looseness of the rotating belt when no weight is dropped, and can eliminate the inspection work. Since it is only necessary to pay attention to the looseness of the rotating belt after the first weight has dropped, it is possible to perform maintenance and inspection work on the rotating belt at an appropriate timing.

According to the invention described in claim 3 , since the colors of the surfaces of the plurality of weights are different, the degree of increase in the looseness of the rotating belt can be easily grasped by looking at the color of the falling weight. For example, three weights of blue, yellow, and red may be used so that the weights fall in the order of blue, yellow, and red.

According to the fourth aspect of the present invention, when the rotating belt runs for a long time, the rotation of the rotating belt increases and the amplitude of vibration of the rotating belt between the pulleys increases. It comes into sliding contact with the thread-like detection element. Then, when the surface of the rotating belt is in sliding contact for a certain period, the thread-like detection element is cut and the notification means is activated. The operator can easily recognize that the loosening of the rotating belt has increased by recognizing that the notification means is operating. Therefore, it is not necessary for the operator to periodically stop and inspect the rotating belt as in the past, or to visually inspect the rotating belt and approach the rotating belt. It becomes possible to shorten.
Moreover, since the attachment part and the transparent plate were comprised integrally, if a transparent plate is removed, an attachment part can also be removed collectively. Therefore, the mounting operation of the detection element to the mounting portion is facilitated, and the operation of mounting the detection element in a predetermined manner is facilitated. The predetermined mode is a mode in which the detection element is parallel to the surface of the rotating belt when the transparent plate is attached. Further, even when a plurality of rotating belts are used, it becomes possible to easily arrange the detecting elements so as to be parallel to the surface of each rotating belt. Since there is no variation in distance, it is possible to prevent detection failure.

According to the fifth aspect of the present invention, the detection element having one end attached to the attachment portion is arranged in a state where the other end is drawn out from the insertion hole of the transparent plate and a weight is attached to the other end. At this time, since the other end side of the detection element pulled out from the insertion hole is smoothly guided by the guide surface of the guide member, it can be prevented from coming into contact with the acute edge of the insertion hole. Accordingly, it is possible to prevent the detection element from being slid in contact with the edge of the insertion hole during the detection operation, thereby preventing detection failure.

It is a front view which notches and shows a part of structure which concerns on one Embodiment of this invention. It is a top view which notches and shows a part of structure which concerns on one Embodiment of this invention. It is sectional drawing which expands and shows the principal part of this invention. It is a conceptual diagram which shows a motion of a rotating belt. It is a front view which shows other embodiment of this invention. It is a front view for demonstrating 1st Example of this invention. FIG. 6 is a perspective view schematically showing a second embodiment of the present invention. It is the schematic for demonstrating 2nd Example of this invention, (a) is a horizontal sectional view of the insertion hole 12 vicinity, (b) is a vertical sectional view of the insertion hole 12 vicinity. It is the schematic for demonstrating a comparative example, (a) is a perspective view, (b) is a horizontal sectional view of the insertion hole 12 vicinity.

  FIG. 1 is a front view showing a part of the configuration according to an embodiment of the present invention, with a part thereof cut away, FIG. 2 is a plan view showing a part of the configuration with a part cut out, and FIG. It is sectional drawing which expands and shows a principal part.

  The rotating belt 1 is wound around two pulleys 2 and 3 arranged side by side in the horizontal direction. The pulley 2 is attached to a rotating shaft 4 a of the motor 4, and the pulley 3 is attached to a power input shaft 5 a of a predetermined manufacturing apparatus 5. The pulley 2 is rotationally driven by the motor 4 in the direction of the arrow R1. Therefore, the rotational force of the motor 4 is transmitted to the manufacturing apparatus 5 via the pulley 2, the rotating belt 1, and the pulley 3. The manufacturing apparatus 5 executes a predetermined manufacturing process using the transmitted rotational force as power.

  The two pulleys 2 and 3 around which the rotating belt 1 is wound are disposed in the storage unit 6. This is in consideration of safety, and prevents foreign objects such as workers' hands and clothes from being caught, and the part of the belt that has been divided when the rotating belt 1 is divided for some reason. This is to prevent it from splashing around.

  The storage unit 6 includes a back plate 7, a side plate 8, and a front plate 9. The back plate 7 and the side plate 8 are integrally formed, and the front plate 9 is detachably attached to the side plate 8. The operator removes the front plate 9 and replaces the rotating belt 1 and performs maintenance and inspection.

  The front plate 9 is formed of a transparent plate 13 having a predetermined rectangular area made of a transparent material (for example, polyvinyl chloride (PVC)). The rectangular region in which the transparent plate 13 is disposed is a rectangular region including a part facing the rotating belt 1 and a part where an insertion hole 12 described later is formed. An operator can visually check the rotating belt 1 through the transparent plate 13.

  In the present embodiment, three thread-like detection elements 10B, 10Y, and 10R (referred to collectively as reference numerals) are configured to detect the degree of increase in looseness of the rotating belt 1 wound around the pulleys 2 and 3. 10) and weights 11B, 11Y, and 11R attached to the sensing elements 10B, 10Y, and 10R (reference numeral 11 is used collectively).

  The detection element 10 is formed of a material that is cut when the surface of the rotating belt 1 is in sliding contact with the surface for a certain period. The material of the detection element 10 is preferably a material having a relatively low strength so as not to be affected even if it is wound around the rotating belt 1 after cutting. Note that a weight 11 is attached to the detection element 10, and most of the weight 11 comes out of the storage unit 6 after being cut, so that the possibility of being caught in the rotating belt 1 is low. The detection element 10 is a belt portion between the pulleys 2 and 3 and is disposed in the vicinity of a so-called loose belt portion.

  Here, the loose belt portion is a belt portion on the side where the rotating belt 1 is fed from the driven pulley 2. In FIG. 1, since the pulley 2 is rotationally driven in the direction of the arrow R1 (counterclockwise), the upper belt portion becomes the loose belt portion. Note that the belt portion on the side where the rotating belt 1 is drawn into the driven pulley 2, that is, the lower belt portion in FIG. 1, becomes the tension-side belt portion.

  Further, the detection element 10 is disposed substantially below the intermediate position of the belt portion on the loose side. The detection element 10 is arranged in a direction orthogonal to the traveling direction of the rotating belt 1 and is arranged at a predetermined interval from the surface of the rotating belt 1. Further, the distance between the detection element 10 and the rotating belt 1 is the distance LB between the first detecting element 10B and the rotating belt 1, the distance LY between the second detecting element 10Y and the rotating belt 1, and the third detecting element 10R and the rotating belt. 1 is set to be longer in the order of the interval LR with respect to 1 (see FIG. 3).

  One end of the detection element 10 is attached to a stopper (for example, a thread stopper ring) provided on the back plate 7 of the storage unit 6, and the other end passes through the insertion hole 12 of the front plate 9 and is outside the storage unit 6. Has been drawn to.

  The weight 11 is attached to the other end of the detection element 10 drawn out of the storage unit 6 and is disposed so as to hang down. The surface of the weight 11B is colored blue, the surface of the weight 11Y is colored yellow, and the surface of the weight 11R is colored red.

  FIG. 4 is a conceptual diagram showing the movement of the rotating belt 1. When the rotating belt 1 is wound around the two pulleys 2 and 3, a certain slack is generated even in the initial state. This is because if the rotating belt 1 is too tight, the life of the rotating belt 1 and various machine parts is shortened, and the safety of the manufacturing process of the manufacturing apparatus 5 is also reduced.

  It is known that when the rotating belt 1 having such looseness is caused to travel, the belt portion between the pulleys 2 and 3 flutters (vibrates) as shown in FIG. This vibration is centered on the travel locus L of the rotating belt 1 when there is no looseness, and the amplitude is W1. Therefore, it is necessary to arrange the detection element 10 at a position that does not contact the surface of the rotating belt 1 in the initial state of the rotating belt 1. Further, since the vibration amplitude is considered to be greatest at the intermediate position M of the rotating belt 1, it is preferable that the detecting element 10 be disposed near the intermediate position M of the rotating belt 1 (see FIG. 4C).

  When the running time of the rotating belt 1 becomes long, loosening of the rotating belt 1 increases. Therefore, as shown in FIG. 4B, the vibration amplitude W2 of the belt portion is larger than the amplitude W1 in the initial state.

  In the present embodiment, three sensing elements 10B, 10Y, 10R are arranged. Therefore, when the running time of the rotating belt 1 becomes long, the loosening of the rotating belt 1 increases, and the amplitude of vibration of the belt portion between the pulleys 2 and 3 increases, first, the position closest to the rotating belt 1 is reached. The surface of the rotary belt 1 comes into sliding contact with the arranged first detection element 10B. When the surface of the rotating belt 1 is in sliding contact for a certain period, the first detection element 10B is cut and the blue weight 11B falls.

  Thereafter, when the vibration amplitude of the belt portion increases, the surface of the rotating belt 1 comes into sliding contact with the second detection element 10Y, and when the second detection element 10Y is cut, the yellow weight 11Y falls. Furthermore, when the amplitude of the vibration of the belt portion increases, the surface of the rotating belt 1 comes into sliding contact with the third detection element 10R, and when the third detection element 10R is cut, the red weight 11R falls. As described above, as the looseness of the rotating belt 1 increases, the blue weight 11B, the yellow weight 11Y, and the red weight 11R are sequentially dropped.

  As described above, according to the present embodiment, the operator can easily recognize that the looseness of the rotating belt 1 has increased by recognizing that the weight 11 is falling. As a result, it is not necessary to periodically stop and inspect the rotating belt 1 as in the prior art, or to visually inspect the rotating belt 1 and to save time and effort required for maintenance and inspection of the rotating belt 1. It becomes possible to shorten. Further, even when the rotating belt 1 is disposed at a place where the temperature becomes high, the operator can easily know that the rotating belt 1 has become loose without approaching the rotating belt 1. For example, it is suitable for the inspection of the rotating belt 1 used in an air conditioner-related device that is used in an environment where heat is generated and the inspection is difficult as in a drying process.

  In addition, the operator can easily grasp how much the rotating belt 1 is loosened by recognizing the falling state of the three types of weights 11B, 11Y, and 11R. This eliminates the need for the operator to pay much attention to the looseness of the rotating belt 1 when no weight 11 has fallen, and the inspection work can be omitted. Then, it is only necessary to pay attention to the looseness of the rotating belt 1 after the first weight 11B is dropped, and maintenance and inspection work such as replacement of the rotating belt 1 may be performed immediately after all the weights 11 are dropped. Therefore, it is possible to perform maintenance and inspection work of the rotating belt 1 at an appropriate timing.

  Further, since the colors of the three types of weights 11B, 11Y, and 11R are different, it is possible to easily grasp how much the rotating belt 1 is loosened by looking at the color of the falling weight 11. .

  In the above embodiment, the detection element 10 is disposed below the rotating belt 1, but may be disposed above. Moreover, in the said embodiment, although the detection element 10 was arrange | positioned in the direction orthogonal to the running direction of the rotating belt 1, you may make it arrange | position in the diagonal direction with respect to a running direction.

  Further, in the above-described embodiment, the plurality of detection elements 10 are arranged so as to be shifted along the traveling direction of the rotating belt 1, but may be arranged in a line perpendicular to the surface of the rotating belt 1. Of course.

  Moreover, as shown in FIG. 5, even when the pulleys 2 and 3 are arranged side by side in the vertical direction, the same operation can be performed. In this case, the detection element 10 may be arranged on the right side with respect to the rotating belt 1 as shown in FIG. 5, or may be arranged on the left side. Furthermore, even when the pulleys 2 and 3 are arranged side by side in the oblique direction, the same can be implemented.

  In the above embodiment, the weight 11 is used as the notification unit. However, another notification unit can be used instead of the weight 11 or together with the weight 11. For example, if a sensing element with conductivity is used and a current is passed through the sensing element before disconnection, the current is interrupted when the sensing element is disconnected. Or a buzzer sound may be output. In addition, a weight 11 may be attached to a conductive sensing element, and a notification by dropping the weight 11 may be added to the notification by turning on the light emitting element or outputting a buzzer sound.

  EXAMPLES Hereinafter, although an Example is given and this invention is demonstrated further more concretely, this invention is not limited to a following example, unless the summary is exceeded.

  FIG. 6 is a front view for explaining the first embodiment of the present invention, in which a part of the front plate 9 is cut away. In this embodiment, the pulleys 2 and 3 are arranged side by side in the vertical direction. A punching plate was used as the front plate 9.

  As the rotating belt 1, two V belts (JIS code: 3V-310) were used. The pulley 2 (JIS code: 200-3V-2) attached to the rotating shaft 4a of the motor 4 has a diameter of 200 mm, and the pulley 3 (JIS code: 224-3V-2) has a diameter of 224 mm. The length La of the belt portion between the pulleys 2 and 3 is 580 mm, and therefore the length Lb to the intermediate position M is 290 mm.

  The number of revolutions of the pulley 2 is 1600 revolutions / minute, whereby the speed of the rotating belt 1 is 1112 m / minutes.

  As the detection element 10, a fishing line made of nylon having a diameter of 0.15 mm was used. Further, as the weight 11, a stainless steel cylinder (weight: about 20 g) having a diameter of 10 mm and a length of 30 mm was used.

  Since the pulley 2 is rotationally driven in the direction of the arrow R1, the left belt portion in FIG. 6 becomes the loose belt portion. And the detection element 10 was arrange | positioned on the outer side (left side in FIG. 6) of the belt part of a loose side.

  The first detection element 10 </ b> B is disposed at a distance from the intermediate position M of the belt portion between the pulleys 2 and 3 in the vertical direction on the surface of the rotating belt 1. Further, the second and third detection elements 10Y and 10R are arranged so as to be shifted in the traveling direction of the rotating belt 1.

  The distance LB between the first detecting element 10B and the rotating belt 1 is 7 mm, the distance LY between the second detecting element 10Y and the rotating belt 1 is 12 mm, and the distance LR between the third detecting element 10R and the rotating belt 1 is 17 mm. The distance Wa between the first sensing element 10B and the second sensing element 10Y and the distance Wb between the second sensing element 10Y and the third sensing element 10R were each 10 mm. The diameter of the insertion hole 12 was 5 mm. The transparent plate 13 was made of PVC.

  7 and 8 are schematic views for explaining a second embodiment of the present invention. 7 is a perspective view, FIG. 8A is a horizontal sectional view in the vicinity of the insertion hole 12, and FIG. 8B is a vertical sectional view in the vicinity of the insertion hole 12. FIG. 9 is a schematic diagram for explaining a comparative example, (a) is a perspective view, and (b) is a horizontal sectional view in the vicinity of the insertion hole 12.

  A feature of the present embodiment is that it is arranged and detected on one side of a direction (direction orthogonal in the present embodiment) that intersects the traveling direction of the rotating belts 1a, 1b, and 1c (generally, reference numeral 1 is used). An attachment portion 14 to which one end of the element 10 is attached, a transparent plate 13 that is disposed on the other direction side in the direction orthogonal to the traveling direction of the rotating belt 1 and has an insertion hole 12 through which the other end side of the detection element 10 is drawn out. Are connected by the connecting member 15 and integrally configured.

  A rectangular window 9 a is formed on the front plate 9 of the storage unit 6. The rectangular transparent plate 13 is formed larger than the window 9a and is attached at a position covering the window 9a. In the four corners of the transparent plate 13, elongated holes 13a extending in the horizontal direction are formed, and as shown in FIG. The face plate 9 is detachably attached. Moreover, the transparent plate 13 can adjust an attachment position to a horizontal direction (arrow 20 direction) using the long hole 13a.

  The connection member 15 is a substantially U-shaped member, an attachment portion 15a arranged on the transparent plate 13 side, a support portion 15b arranged in parallel to the attachment portion 15a, an attachment portion 15a, and a support portion. It is comprised with the connection part 15c which connects 15b. The connecting portion 15c is disposed orthogonal to the mounting portion 15a and the support portion 15b, and is connected to one end of the mounting portion 15a and the support portion 15b. In addition, it is desirable to form the connection member 15 with transparent materials, such as an acrylic, from a viewpoint of making it easy to confirm the state of the rotating belt 1 visually.

  An attachment portion 14 for attaching the detection element 10 is provided on the upper portion of the support portion 15b. The attachment portion 14 is a substantially C-shaped member, and is attached by, for example, binding the detection element 10. The mounting portion 15a is fixed to one surface (the surface facing the window 9a) of the transparent plate 13 by a bolt 16 and a nut 17 below the insertion hole 12. At this time, the connecting member 15 is positioned so that the insertion hole 12 and the attachment portion 14 face each other.

  A guide member 18 is fixed to the other surface of the transparent plate 13 (a surface opposite to the surface on which the connection member 15 is fixed, hereinafter referred to as an outer surface). The guide member 18 is a columnar member having a fan-shaped cross section, and includes two rectangular side surfaces 18a and 18b corresponding to a fan-shaped straight portion, and a guide surface 18c that is one arc-shaped side surface corresponding to a fan-shaped curved portion. Have In the present embodiment, the central angle of the sector is 90 degrees. In addition, it is desirable to form the guide member 18 with transparent materials, such as an acrylic, from a viewpoint of making it easy to confirm the state of the rotating belt 1 visually.

  The guide member 18 is fixed by joining the rectangular side surface 18 a to the outer surface of the transparent plate 13. At this time, as shown in FIG. 8 (b), one end of the guide surface 18 c is fixed so as to be connected to the drawing position of the detection element 10 in the insertion hole 12. That is, the detection element 10 pulled out from the insertion hole 12 is fixed at a position where it can be smoothly guided to the guide surface 18c without a step.

  As described above, according to the present embodiment, the attachment portion 14 and the transparent plate 13 are integrally formed. Therefore, if the transparent plate 13 is removed, the attachment portion 14 can also be removed. Therefore, the mounting operation of the detection element 10 to the mounting portion 13 is facilitated, and the operation of mounting the detection element 10 in a predetermined manner is facilitated. The predetermined mode is a mode in which the ground detection element 10 is parallel to the surface of the rotating belt 1 when the transparent plate 13 is attached.

  For example, as shown in FIG. 9, when the transparent plate 13 and the attachment portion 14 are separately arranged, the attachment portion 14 needs to be fixed to the back plate 7. At this time, it is necessary to fix the attachment portion 14 at a position facing the insertion hole 12 of the transparent plate 13, and the positioning operation of the attachment portion 14 becomes complicated, and further, the positioning operation and the fixing operation are performed from the window 9 a of the front plate 9. Since this is necessary, the work is complicated in this respect as well. On the other hand, in the present embodiment, since it is manufactured as one component in advance, the manufacturing becomes easy.

  Further, when the transparent plate 13 and the mounting portion 14 are separately arranged, the mounting operation of the detection element 10 becomes complicated. This is because when one end of the detection element 10 is attached to the attachment portion 14, it is necessary to insert the hand from the window 9 a and perform the attachment work. Further, the detection element 10 is parallel to the surface of the rotating belt 1. This is because it is necessary to adjust the mounting position of the detection element 10 with respect to the mounting portion 14 and the mounting position of the transparent plate 13 in order to be installed. On the other hand, in this embodiment, since the detection element 10 is attached in a state where the transparent plate 13 and the attachment portion 14 are removed from the storage portion 6, the attachment work is facilitated.

  Here, the arrangement of the detection element 10 in parallel with the rotating belt 1 is particularly important when a plurality of rotating belts 1 are used. For example, as shown in FIG. 9B, if the detection operation is performed in a state where the detection element 10 is not arranged in parallel with the three rotating belts 1a, 1b, and 1c, a detection failure occurs. . That is, if the distance between the rotating belt 1 and the detecting element 10 varies, the rotating belt 1a close to the detecting element 10 contacts the detecting element 10 at a stage where the degree of looseness is smaller than the other rotating belts 1b and 1c. On the contrary, the rotating belt 10c far from the detecting element 10 is not in contact unless the degree of looseness is larger than that of the other rotating belts 1a and 1b. On the other hand, in the present embodiment, since the detection element 10 can be easily arranged in parallel to the rotating belt 1, it is possible to prevent occurrence of detection failure.

  Further, the detection element 10 having one end attached to the attachment portion 14 is arranged in a state where the other end is drawn out from the insertion hole 12 of the transparent plate 13 and the weight 11 is attached to the other end. At this time, the other end side of the detection element 10 drawn out from the insertion hole 12 is smoothly guided by the guide surface 18c of the guide member 18, so that it can be prevented from contacting the acute edge of the insertion hole 12.

  For example, as shown in FIG. 9A, when the detection operation is performed in a state where the detection element 10 is in contact with the acute edge of the insertion hole 12, a detection failure may occur. This is because when the rotating belt 1 is loosened and comes into sliding contact with the detection element 10, the detection element 10 vibrates finely, and the detection element 10 may be slid into contact with the edge of the insertion hole 12 and cut. Because there is. On the other hand, in the present embodiment, it is possible to avoid the detection element 10 from being slid in contact with the edge of the insertion hole 12 during the detection operation, and thus it is possible to prevent the occurrence of detection failure.

DESCRIPTION OF SYMBOLS 1,1a, 1b, 1c Rotating belt 2,3 Pulley 4 Motor 4a Rotating shaft 5 Manufacturing apparatus 5a Power input shaft 6 Storage part 7 Back surface plate 8 Side surface plate 9 Front surface plate 9a Window 10 Detection element 10B 1st detection element 10Y 2nd Detection element 10R Third detection element 11 Weight 11B Blue weight 11Y Yellow weight 11R Red weight 12 Insertion hole 13 Transparent plate 14 Attachment portion 15 Connection member 15a Attachment portion 15b Support portion 15c Connection portion 18 Guide member 18c Guide surface

Claims (5)

In a method for detecting looseness of a rotating belt that detects looseness of a rotating belt that is wound around two pulleys,
A thread-like sensing element that is cut by sliding the surface of the rotating belt for a certain period;
A weight connected to one end of the sensing element and arranged to hang down is prepared,
The detection element is disposed in a direction intersecting the traveling direction of the rotating belt, and is disposed at a predetermined interval from the surface of the rotating belt,
The rotation is characterized in that the rotation of the rotating belt increases, the loose surface of the rotating belt is in sliding contact with the sensing element, and the weight is dropped when the sensing element is cut after sliding for a certain period of time. Belt looseness detection method. The loosening detection method of the rotating belt according to claim 1 ,
A method for detecting looseness of a rotating belt, wherein the plurality of detecting elements are arranged such that the distances from the rotating belt are different from each other, and a weight is connected to one end of each detecting element and suspended. In the loosening detection method of the rotating belt according to claim 2 ,
A method for detecting looseness of a rotating belt, wherein the colors of the surfaces of the plurality of weights are different from each other. In the rotation belt looseness detection device that detects the looseness of the rotation belt wound around two pulleys,
A thread-like sensing element that is cut by sliding the surface of the rotating belt for a certain period;
An informing means that operates when the detection element is disconnected,
The detection element is disposed in a direction intersecting the traveling direction of the rotating belt, and is disposed at a predetermined interval from the surface of the rotating belt,
When the looseness of the rotating belt increases, the surface of the loosened rotating belt is in sliding contact with the detecting element, and the detecting element is cut after sliding for a certain period of time, the notification means is activated ,
An attachment portion disposed on one side of the direction intersecting the traveling direction of the rotating belt and to which one end of the detection element is attached;
A transparent plate having an insertion hole that is disposed on the other direction side of the direction intersecting the traveling direction of the rotating belt and from which the other end side of the detection element is drawn,
An apparatus for detecting looseness of a rotating belt, wherein the attachment portion and the transparent plate are integrally connected by a connection member . In the loosening detection device of the rotating belt according to claim 4 ,
The notification means is a weight that is attached to the other end of the detection element and is suspended.
An apparatus for detecting looseness of a rotating belt, characterized in that a guide member having a guide surface for smoothly guiding the detection element drawn out from the insertion hole toward the weight is provided on the transparent plate.

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