JP6270669B2 - Threshing device - Google Patents

Description

  The present invention relates to a threshing apparatus such as a combine equipped with a layer thickness sensor for detecting a layer thickness of a processed product.

  There is known a threshing apparatus including a layer thickness sensor that detects a layer thickness of a processed material on a rocking sorter. In this type of threshing apparatus, the fin opening of the chaff sheave provided in the swing sorter is variable, and the fining opening is automatically controlled according to the detection value of the layer thickness sensor to improve the sorting accuracy.

  The layer thickness sensor is usually configured to include a contact-type detection body that rotates in accordance with the layer thickness of the workpiece, and a potentiometer that detects the rotation position of the detection body. The layer thickness of the processed material is detected by being disposed above (see, for example, Patent Documents 1 to 3).

Japanese Utility Model Publication No. 05-2642 JP 2000-166365 A Japanese Patent Laid-Open No. 05-304824

  By the way, the threshing apparatus provided with the layer thickness sensor includes a sensor wiring electrically connected to the layer thickness sensor, and the sensor wiring connected to the layer thickness sensor is usually drawn out from the inside of the threshing apparatus. However, in the routing area inside the threshing apparatus, not only the processed material falling from the handling chamber is disturbed, but also there is a possibility that sawdust and the like may be caught.

The present invention has been created in view of the above-described circumstances in order to solve these problems, and the invention of claim 1 includes a handling cylinder provided rotatably in a handling chamber, and a handling cylinder. A front-view arc-shaped receiving net disposed along the lower outer periphery, a front-view arc-shaped receiving net support member that supports the receiving net from below at an intermediate position of the handling chamber, and the handling chamber via the receiving net A swing sorting body for swinging and sorting the processed material leaked from the layer, a layer thickness sensor for detecting a layer thickness of the processed product on the swing sorting body, and a sensor wiring electrically connected to the layer thickness sensor. wherein the sensor wiring is a threshing apparatus that will be routed by crawl the受網support member when withdrawn from the interior of the threshing device on the outside, the layer thickness sensor is distributed form around the受網support member A pair of wirings connected to the pair of layer thickness sensors. In the configuration in which the members are arranged on the members, the pair of layer thickness sensors are configured to include a detection body that rotates according to the layer thickness of the processing object, and a potentiometer that detects the rotation position of the detection body. The potentiometer has a connector to which sensor wiring is connected, and the threshing device is characterized in that the potentiometers of the pair of layer thickness sensors are arranged in opposite directions so that the connector faces the receiving net support member side. is there.
In the invention of claim 2, the upper end portion of the receiving net support member is fixed to the side wall of the threshing device via a bracket, and the sensor wiring is arranged from the lower end side to the upper end side of the receiving net support member. 2. The threshing device according to claim 1, wherein the threshing device is pulled out and pulled out of the threshing device below the bracket.
According to a third aspect of the present invention, the receiving net support member has a bow metal along the radial direction of the handle cylinder, and a rib projecting rearward from the rear surface of the bow metal. The threshing apparatus according to claim 1, wherein the threshing apparatus is routed behind the ribs and under the ribs.

According to the invention of claim 1, the sensor wiring of the layer thickness sensor is not only routed over the receiving net support member when being pulled out from the inside of the threshing apparatus, but also before and after the receiving net support member. Since a pair of layer thickness sensors are arranged in a distributed manner, and the potentiometers of the pair of layer thickness sensors are arranged in the reverse direction so that the connector faces the receiving net supporting member side, the potentiometers are arranged on the receiving net supporting member. A pair of sensor wires can be easily connected to a pair of layer thickness sensors.
According to the second aspect of the present invention, the upper end portion of the receiving net support member is fixed to the side wall of the threshing device via the bracket, and the sensor wiring extends from the lower end side to the upper end side of the receiving net support member. Therefore, the wiring distance of the sensor wiring in the threshing device can be shortened, and the catching of sawdust etc. can be reduced.
According to the invention of claim 3, the sensor wiring of the layer thickness sensor is routed behind the bow of the receiving net support member and so as to crawl under the rib. In addition to not hindering things, it is possible to reduce the catch of sawdust and the like.

It is a left view of a combine. It is a left view of a threshing apparatus. It is a principal part top view of a threshing apparatus. It is a principal part front view of the threshing apparatus which shows a cover closed state. It is a principal part front view of the threshing apparatus which shows a cover open state. It is a principal part right view of a threshing apparatus. It is a perspective view of a receiving net support frame. It is a principal part enlarged front view of the threshing apparatus which shows attachment / detachment of a receiving net. It is a principal part rear view of the threshing apparatus which shows the example of wiring of sensor wiring. It is a perspective view of the threshing apparatus which shows the example of a wiring of sensor wiring. It is a principal part expansion perspective view of a receiving net support frame. It is a right view which shows the arrangement structure of a layer thickness sensor. It is a top view which shows the arrangement structure of a layer thickness sensor. (A) is a perspective view of the layer thickness sensor which shows a cover body mounting state, (B) is a perspective view of the layer thickness sensor which shows a cover body removal state.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In FIG. 1, 1 is a general-purpose combiner, and the general-purpose combine 1 includes a harvesting unit 2 that harvests stem stalks, and a threshing unit (threshing device) 3 that threshs and sorts grains from stems and straws that are put into whole straws. A grain tank 4 for storing the selected grain, a discharge auger 5 for discharging the grain in the grain tank 4 to the outside of the machine, a post-processing unit 6 for post-processing the threshed waste, A driving unit 7 on which the driver gets on and a crawler type traveling unit 8 are provided.

  The cutting unit 2 includes a header 9 that is connected to the front end of the machine body so as to be able to move up and down, a divider 10 that weeds uncut stems at the front end of the header 9, and a cutting blade (not shown) that cuts off the uncut stems. ), A reel 11 for picking up uncut stems and cut stems, an auger 12 for collecting the scraped stems at predetermined positions in the width direction, and a threshing unit 3 for collecting stems collected by the auger 12 And a feeder 13 that feeds the whole grain into the threshing unit 3.

  As shown in FIG. 2, the threshing unit 3 includes a handling chamber 14 into which all the cutting stalks are thrown in, and a sorting chamber 15 that is disposed below the handling chamber 14 and that sorts the processed material that has leaked from the handling chamber 14. The grain selected in the sorting chamber 15 is transferred to the grain tank 4 via the first cerealing device (not shown).

  The handling chamber 14 rotates around a rotation shaft 17a along the front-rear direction, and is arranged along a lower outer circumference of the handling cylinder 17 that hooks and pulls the pedicles with a handling tooth 16 that protrudes from the outer circumference. The receiving net 18 having a circular arc when viewed from the front and leaking the processed product that has been shed by rubbing with the stem and the waste that has reached the end of the handling chamber 14 without leaking from the receiving net 18 is discharged. It is provided with a dust mouth 19.

  The sorting chamber 15 collects the first thing, the swinging sorter 20 that sorts the processed material leaked from the receiving net 18 while transporting it, the red pepper 21 that generates the sorting wind in front of the swinging sorter 20, and the like. The first horizontal spiral 22 and the second horizontal spiral 23 for recovering the second thing. The first thing recovered by the first horizontal spiral 22 is the grain tank through the first cerealing device. The second product transferred to 4 and collected by the second horizontal spiral 23 is returned to the inside of the handling chamber 14 or on the rocking sorter 20 via the second cerealing device 24 (see FIG. 3).

  As shown in FIGS. 2 and 3, the rocking sorter 20 includes a grain pan 25 that sequentially transfers the processed material leaked from the receiving net 18 backward, and a chaff sheave 26 that sifts and sorts the grain behind the grain pan 25. Further, a grain sieve 27 for further sieving and selecting the grain that has leaked from the chaff sheave 26, an extended chaff sheave 28 that is selectively attached to the rear of the chaff sheave 26 or the grain sheave 27, and a rear part of the chaff sheave 26 or the grain sieve 27 are selectively attached. The stroking assembly includes a stroking rack 29, and is reciprocally swung continuously at a predetermined cycle by a swinging mechanism (not shown).

  The chaff sheave 26 includes a plurality of fins 26a arranged in parallel at a predetermined interval in the front-rear direction. Each of the fins 26a is inclined in a front-rear and rear-high shape, and the processed material is caused to leak from the gap between the fins 26a while the processed material is transferred rearward along with the swinging of the swing sorter 20. The treated product leaked here is collected as the first product through the grain sieve 27, and the treated product not leaked is collected as the second product.

  Each fin 26a is configured to be able to rotate back and forth with the upper end side as a fulcrum, and is connected to a fin driving motor (not shown) via a cam mechanism (not shown). The gap (fin opening) between the fins 26a in the chaff sheave 26 can be changed based on the change in the angle of each fin 26a according to the driving. The balance between the amount of processed material leaked from the chaff sheave 26 and the amount of processed material to be reduced second is appropriate by executing automatic sorting control that automatically increases or decreases the fin opening according to the amount of processed material (layer thickness). This makes it possible to perform a highly accurate sorting process.

  The swing sorting body 20 of the present embodiment is provided with a plurality of gathering plates 30 for bringing the processed material closer to the center in the left-right width direction. In the present embodiment, four approach plates 30 are provided on both the left and right ends of the swing sorter 20 from the grain pan 25 to the chaff sheave 26, respectively.

  As shown in FIGS. 4 and 5, a maintenance opening 31 a that can be opened and closed by the cover body 31 is formed on the outer surface portion of the handling chamber 14. As shown in FIG. 5, the cover body 31 is opened. When operated, maintenance work such as attachment / detachment of the receiving net 18 can be performed through the opening 31a.

  As shown in FIGS. 4 to 6, the receiving network 18 of the present embodiment is divided into four in the front and rear and left and right, and each of the four divided receiving networks 18 (18FL, 18FR, 18RL, 18RR) is respectively A receiving frame 18a that defines the outer shape and a net member 18b provided inside the receiving net frame 18a are provided.

  As shown in FIG. 7, the handling chamber 14 is provided with a receiving net support frame 32 for detachably supporting the receiving net 18. The receiving net support frame 32 of the present embodiment is integrated with a square pipe-shaped receiving net support frame 35 laid between the front side plate 33 and the rear side plate 34 of the handling chamber 14, and an intermediate portion of the receiving net support frame 35. And a receiving net support member 36 having a circular arc when viewed from the front.

  The receiving net support member 36 has a bow metal 36a along the radial direction of the handling cylinder 17, and ribs 36b and 36c projecting from the front and rear surfaces of the right half (the inner half of the machine body) of the bow metal 36a. Is provided. In addition, ribs 33 a and 34 a that are equivalent to the ribs 36 b of the receiving net support member 36 are formed so as to protrude at positions facing the ribs 36 b and 36 c on the front side plate 33 and the rear side plate 34. Note that the upper right end portion of the receiving net support member 36 has a bracket 36c, and is fixed to the side wall 3a of the threshing portion 3 via the bracket 36c.

  Next, a procedure for removing the receiving network 18 will be described with reference to FIGS. In addition, since the attachment procedure of the receiving net | network 18 becomes a reverse procedure of a removal procedure, description is abbreviate | omitted.

  The removal of the receiving net 18 is performed through the opening 31a by opening the cover body 31 as shown in FIG. Among the installed receiving nets 18, the left receiving nets 18 FL and RL near the opening 31 a are engaged with the engaging pin 18 c provided at the upper end on the receiving net support frame 32 side, and the lower end is a bolt. 37 is fastened to the receiving net support frame 35, and further, one side portion is fastened to the bow metal 36a via a bolt (not shown) so as to be attached to the receiving net support frame 32. Further, the right receiving nets 18FR and RR far from the opening 31a have engaging pins 18c provided at the upper end engaged with the receiving net support frame 32 and the lower end supported by the net via bolts 37. By being fastened to the frame 35, it is attached to the receiving net support frame 32. Note that the upper ends of the left receiving nets 18FL and RL may be bolt-fixed instead of being held by the engaging pins 18c.

  When removing the receiving net 18, first, the bolt 37 fixing the lower end of the receiving net 18 and the bolt fixing one side are removed. Next, when the engaging pins 18c of the left receiving nets 18FL and 18RL are removed from the receiving net support frame 32, the left receiving nets 18FL and 18RL can be detached and taken out through the opening 31a. . Next, when the engagement pins 18c of the right receiving nets 18FR, 18RR are removed from the receiving net support frame 32, the right receiving nets 18FR, 18RR can be removed. When removing the right receiving nets 18FR, 18RR, it is necessary to pull out from the back side of the handling cylinder 17. At this time, the ribs 33a, 34a, 36b described above support the both sides of the receiving nets 18FR, 18RR from below. By functioning as a guide member, the receiving nets 18FR and 18RR can be easily pulled out.

  Next, the layer thickness sensor 38 which is a main part of the present invention will be described with reference to FIGS.

  As shown in FIGS. 2 to 14, a layer thickness sensor 38 for detecting the layer thickness of the processed material transferred on the rocking sorter 20 is provided above the rocking sorter 20. The layer thickness sensor 38 includes a detection body 39 that freely rotates in accordance with the layer thickness of the processing object, a potentiometer 41 that detects a rotation position of the detection body 39 connected via the rotation shaft 40, and a detection body 39. And a stopper member 42 that contacts and supports the detection object 39 at the initial position of the detection state. The detection body 39 contacts the processing object and rotates according to the layer thickness, thereby detecting the potentiometer 41. It becomes possible to specify the layer thickness of the processed material based on the value. Incidentally, the detection body 39 of the present embodiment is arranged such that the drooping posture slightly retracted from the vertical is the initial posture, and the receding angle increases as the layer thickness of the processed material increases.

  In the present embodiment, the layer thickness sensor 38 is attached using the receiving net support frame 35 that is located above the swinging sorter 20 and approximately in the center of the left and right width of the swing sorter 20 in plan view. In this way, as shown in FIG. 3, it becomes possible to accurately detect the layer thickness of the processed product brought to the left and right center side of the swinging sorter 20 by the gathering plate 33.

  Further, in the present embodiment, a plurality of layer thickness sensors 38 are provided at a predetermined interval in the front-rear direction with respect to the receiving network support frame 35. Specifically, a layer thickness sensor 38 on the front side for detecting the layer thickness of the processed material transferred on the start side of the chaff sheave 26 and a layer thickness of the processed material transferred on the terminal side of the chaff sheave 26 are detected. Side layer thickness sensor 38.

  The detection body 39 of the layer thickness sensor 38 can be arbitrarily selected as long as it is in contact with the object to be processed and rotates according to the layer thickness. For example, the detection body 39 of the present embodiment is formed of a relatively hard material, but the detection body 39 can also be formed of an elastically deformable spring material or a soft resin material. Further, it is possible to prevent the detection body 39 from being plastically deformed or damaged due to catching of branches or the like included in the processed material.

  As the potentiometer 41, there are a spring built-in type with a built-in spring for urging the rotating shaft 40 in a predetermined direction, a springless type without a built-in spring, and the like. Any type can be selected. The potentiometer 41 has a connector 41 a to which the sensor wiring 43 is connected, and is electrically connected to a control unit (not shown) disposed outside the threshing unit 3 through the sensor wiring 43.

  As shown in FIGS. 6, 7, and 9 to 13, the sensor wiring 43 is routed over the receiving net support member 36 when being pulled out from the inside of the threshing unit 3. At this time, the sensor wiring 43 is routed behind the bow 36a constituting the receiving net support member 36 and so as to crawl under the rib 36b. According to the sensor wiring 43 routed in this way, not only does it not interfere with the processed material falling from the handling chamber 14, but also it is possible to reduce the catch of sawdust and the like.

  In the present embodiment, when the sensor wiring 43 is routed from the lower end side to the upper end side of the receiving net support member 36, the sensor wiring 43 is arranged below the bracket 36 c of the receiving net support member 36. Pull out to the outside. For example, a hole (not shown) in which the grommet 44 is mounted is formed in the side wall 3a of the threshing portion 3 below the bracket 36c, and the sensor wiring 43 is drawn out of the threshing portion 3 from this hole. If it does in this way, the wiring distance of the sensor wiring 43 in the threshing part 3 can be shortened, and catches, such as sawdust, can be reduced. In addition, as shown by the imaginary line (two-dot chain line) shown in FIG. 9, the sensor wiring 43 can be extended to the upper end portion of the receiving net support member 36 and can be pulled out of the threshing portion 3 therefrom.

  In the present embodiment, when the pair of front and rear layer thickness sensors 38 are attached to the receiving net support frame 35, the pair of front and rear layer thickness sensors 38 are arranged in a distributed manner before and after the receiving net support member 36, and Two sensor wires 43 connected to the layer thickness sensor 38 are put together on the receiving net support member 36. If it does in this way, it will not become the hindrance of the processed material which falls from the handling chamber 14, even if it exists in which sensor wiring 43, but also catches, such as a sawdust, can be reduced.

  In this embodiment, when the pair of front and rear layer thickness sensors 38 are attached to the receiving net support frame 35, the potentiometers 41 of the pair of front and rear layer thickness sensors 38 are reversed so that the connector 41a faces the receiving net support member 36 side. Is arranged. In this way, it is possible to easily connect the pair of sensor wirings 43 disposed on the receiving net support member 36 to the pair of front and rear layer thickness sensors 38 at the shortest distance.

  Next, the mounting structure and protective structure of the layer thickness sensor 38 will be described with reference to FIGS.

  The potentiometer 41 of the layer thickness sensor 38 is attached to the side portion of the receiving net support frame 35 via an attachment bracket 45. As shown in FIG. 14B, the mounting bracket 45 is made of a bent plate member, and is fixed to a side portion of the receiving net support frame 35 with a fixing portion 45a and a side of the receiving net support frame 35. The sensor mounting part 45b which opposes a part with a predetermined space | interval and the connection part 45c which connects the sensor mounting part 45b and the fixing | fixed part 45a are provided integrally. And the potentiometer 41 is arrange | positioned between the attachment bracket 45 and the receiving net support frame 35 in planar view by attaching to the inner side part of the sensor attachment part 45b.

  The rotation shaft 40 that is the input shaft of the potentiometer 41 passes through the sensor mounting portion 45b of the mounting bracket 45 and protrudes outward, and the detection body 39 is integrally mounted on the tip side thereof. The potentiometer 41 is fixed to the mounting bracket 45 with a screw 46. By loosening the screw 46, the mounting position of the potentiometer 41 can be adjusted.

  Further, the mounting bracket 45 of the present embodiment is integrally provided with a wiring support portion 45 d that supports the sensor wiring 43 connected to the potentiometer 41. The wiring support portion 45d supports the sensor wiring 43 via the clamp member 47, and is formed in an inverted L shape in front view so as to cover the upper side and one side of the supporting sensor wiring 43. According to the mounting bracket 45 provided with such a wiring support portion 45d, not only can the mounting position of the potentiometer 41 be accurately adjusted in a stable state in which the sensor wiring 43 is supported, but also the upper side and one side of the sensor wiring 43. By covering the side, it is also possible to suppress catching of sawdust and the like on the sensor wiring 43. In the present embodiment, since the potentiometer 41 of the pair of front and rear layer thickness sensors 38 is arranged in the front-rear reverse direction as described above, the mounting bracket 45 is also formed in the front-rear reverse direction, and the sensor wiring to the receiving net support member 36 is provided. It is easy to attract 43.

  A cover body 48 that protects the potentiometer 41 is provided above the mounting bracket 45. The cover body 48 covers the upper side of the potentiometer 41 and the upper cover part 48 a that covers the upper side of the potentiometer 41, and extends from one end of the upper cover part 48 a to the lower side of the rotary shaft 40. A side cover portion 48b and a front cover portion 48c extending from the front end portion of the upper cover portion 48a to the lower side of the rotation shaft 40 and covering the front of the potentiometer 41 and the rotation shaft 40 are provided. In the present embodiment, the front and rear mounting brackets 45 have a reverse front and rear shape, so that the front cover body 48 that protects the front potentiometer 41 and the rear cover body that protects the rear potentiometer 41. Although the shape is different from that of 48, it is also possible to have the same shape. In FIG. 8, the front of the potentiometer 41 and the rotation shaft 40 is opened because part of the cover body 48 is omitted in the drawing.

  According to such a cover body 48, one side covers the upper, front and other sides of the potentiometer 41 covered with the receiving network support frame 35, so that troubles such as sawdust being caught on the potentiometer 41 are prevented. It can be reliably reduced. Moreover, the cover body 48 covers the upper side of the potentiometer 41 and one side of the upper cover portion 48a and extends downward from the rotary shaft 40 to cover one side of the potentiometer 41 and the rotary shaft 40. Since the side cover portion 48b is provided, it is possible to suppress the catching of the sawdust and the like with respect to the rotating shaft 40, and as a result, it is possible to prevent the detection accuracy from being lowered due to the catching of the sawdust and the accompanying sorting accuracy. It becomes possible.

  Moreover, the cover body 48 is detachably attached to the attachment bracket 45 as shown in FIG. For example, in this embodiment, the cover body 48 is attached to the mounting bracket 45 with a plurality of bolts 49, and the cover body 48 can be removed from the mounting bracket 45 by loosening these bolts 49. According to such a configuration, the attachment position of the potentiometer 41 can be easily adjusted by removing the cover body 48.

  In the present embodiment, the stopper member 42 is attached to the cover body 48. If it does in this way, it will become possible to aim at reduction of a number of parts and simplification of a structure by using cover body 48 also as a stopper support member.

  According to the present embodiment configured as described, the handling cylinder 17 provided rotatably in the handling chamber 14, and the receiving net 18 having a circular arc when viewed from the front arranged along the lower outer periphery of the handling cylinder 17, The receiving net support member 36 having a circular arc when viewed from the lower side and supporting the receiving net 18 from below at the intermediate position of the handling chamber 14, and the swing that sorts the processed material leaking from the handling chamber 14 via the receiving net 18. A combine 1 comprising a sorting body 20, a layer thickness sensor 38 for detecting a layer thickness of a processed material on the swing sorting body 20, and a sensor wiring 43 electrically connected to the layer thickness sensor 38. The wiring 43 is routed over the receiving net support member 36 when being pulled out from the inside of the threshing portion 3, and the receiving net support member 36 includes an arch metal 36 a along the radial direction of the handling cylinder 17, and an arch metal. Rib 36b projecting rearward from the rear surface 36a, and sensor wiring of the layer thickness sensor 38 3 is routed behind the bow metal 36a and below the rib 36b, so that not only does it not interfere with the processed material falling from the handling chamber 14, but also reduces the catch of sawdust and the like. Can do.

  Further, the upper end portion of the receiving net support member 36 is fixed to the side wall 3a of the threshing portion 3 via a bracket 36c, and the sensor wiring 43 is arranged from the lower end side to the upper end side of the receiving net support member 36. Since it is routed and pulled out of the threshing unit 3 below the bracket 36c, the wiring distance of the sensor wiring 43 in the threshing unit 3 can be shortened, and the catching of sawdust and the like can be reduced.

  In addition, the threshing unit 3 of the present embodiment includes a plurality of layer thickness sensors 38 arranged in a distributed manner before and after the receiving net support member 36, and includes a plurality of sensor wires 43 connected to the plurality of layer thickness sensors 38. Since the receiving net support member 36 is put together, it is possible to apply the routing structure of the present invention to the plurality of sensor wires 43 while accurately detecting the sorting state by the plurality of layer thickness sensors 38.

  Moreover, the threshing part 3 of this embodiment is provided with a pair of layer thickness sensor 38 arrange | positioned at the front and rear of the receiving net support member 36, and each layer thickness sensor 38 rotates according to the layer thickness of a processed material. The potentiometer 41 includes a connector 41a to which the sensor wiring 43 is connected, and the connector 41a supports the receiving network. Since the potentiometer 41 of the pair of layer thickness sensors 38 is disposed in the opposite direction so as to face the member 36 side, the pair of sensor wirings 43 laid over the receiving net support member 36 is connected to the pair of layer thickness sensors 38. Can be connected easily.

DESCRIPTION OF SYMBOLS 1 Combine 3 Threshing part 3a Side wall 14 Handling chamber 17 Handling cylinder 18 Receiving net 20 Oscillating sorter 32 Receiving net support frame 35 Receiving net support frame 36 Receiving net support member 36a Bow metal 36b Rib 36c Bracket 38 Layer thickness sensor 39 Detector 40 rotating shaft 41 potentiometer 41a connector 43 sensor wiring 45 mounting bracket 45b sensor mounting portion 45d wiring support portion 48 cover body 48a upper cover portion 48b side cover portion 48c front cover portion

Claims (3)

A handling cylinder rotatably provided in the handling room;
A front-view arc-shaped receiving net arranged along the lower outer periphery of the handling cylinder;
An arc-shaped receiving net support member that supports the receiving net from below at an intermediate position of the handling chamber;
An oscillating sorter for oscillating and sorting the processed material leaked from the handling chamber via the receiving net;
A layer thickness sensor for detecting the layer thickness of the processed material on the rocking sorter;
Sensor wiring electrically connected to the layer thickness sensor ,
The sensor wire is a Ru threshing apparatus is routed by crawl the受網support member when withdrawn from the interior of the threshing apparatus to the outside,
The layer thickness sensor is provided with a pair arranged in a distributed manner on the front and rear of the receiving net support member,
In making a configuration in which a pair of wirings connected to the pair of layer thickness sensors are put together on a net support member,
The pair of layer thickness sensors includes a detection body that rotates according to the layer thickness of the workpiece, and a potentiometer that detects a rotation position of the detection body,
The potentiometer has a connector to which sensor wiring is connected, and the threshing apparatus is characterized in that the potentiometers of a pair of layer thickness sensors are arranged in opposite directions so that the connector faces the receiving net support member side . The upper end portion of the receiving net support member is fixed to the side wall of the threshing device via a bracket,
The threshing apparatus according to claim 1, wherein the sensor wiring is routed from the lower end side to the upper end side of the receiving net support member, and is drawn to the outside of the threshing apparatus below the bracket. The receiving net support member is
  A bow along the radial direction of the barrel,
  A rib protruding rearward from the rear surface of the bow metal,
  The threshing device according to claim 1 or 2, wherein the sensor wiring of the layer thickness sensor is routed behind the bow and so as to crawl under the rib.

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