JP5424102B2 - Vibrating feeder - Google Patents

Description

  The present invention relates to a vibration feeder such as an electromagnetic feeder.

Generally, a vibration feeder such as an electromagnetic feeder includes a feeder body, a vibration spring, and a drive unit for vibrating the vibration spring. And the trough attached to the vibration feeder vibrates by the drive of a drive part, and it is comprised so that a to-be-conveyed object may be conveyed.
The vibration feeder described in Patent Document 1 has the above-described configuration and can be washed with water.
The reason why the vibration feeder can be washed with water is generally as follows. In other words, for example, a transported object such as a granular material or a powdered material scatters from the trough and falls to the feeder main body, and then falls to the feeder main body when another type of transported object is transported. This is to prevent the currently transported object from being mixed into the currently transported object.

JP-A-4-358617

In the vibration feeder described in Patent Document 1, the water after washing easily remains on the upper surface of the feeder body.
If the water remains on the upper surface of the feeder body, there is a possibility that the water is mixed into the next object to be conveyed due to the vibration of the vibration feeder.
Further, when the object to be conveyed next scatters from the trough and falls to the feeder main body, it is mixed with the remaining water and easily adheres to the feeder main body. Then, when the object to be conveyed is further conveyed, there is a possibility that the object to be conveyed adhering to the feeder main body due to vibration may be mixed into the object to be conveyed currently.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a vibration feeder that can prevent foreign matter from being mixed into an object to be conveyed by making it difficult for water to remain in the main body of the feeder or preventing it from remaining.

  The present invention provides a feeder main body, a vibration spring provided between the feeder main body and a trough attached to the upper side of the feeder main body, and an object to be conveyed forward by the trough by applying vibration to the vibration spring. And a drive part to be conveyed, wherein an inclined part that is inclined downward toward the side of the feeder main body is formed on the upper surface of the feeder main body.

  In the above configuration, the drainage is improved by the inclined portion. Therefore, when the vibration feeder is washed with water or the like, the washing water on the feeder main body is removed from the inclined portion toward the side of the feeder main body.

In the vibration feeder of the present invention, the inclined portion is an inclined surface provided on at least a part of the upper surface of the feeder body.
According to the said structure, the washing water on a feeder main body is excluded to the side of a feeder main body along an inclined surface.

In the vibration feeder of the present invention, the inclined surface is formed so as to incline downward to both sides of the feeder body with the center of the upper surface of the feeder body as a vertex.
According to the above configuration, the washing water is excluded from the center of the upper surface of the feeder body toward both sides.

In the vibration feeder according to the present invention, the inclined surface is inclined downward toward the side of the feeder main body and downwardly inclined toward one side in the front-rear direction.
According to the above configuration, the washing water is removed toward the side while being removed with the upper surface of the feeder main body directed toward the one side in the front-rear direction.

In the vibration feeder of the present invention, the inclined surface is characterized in that the one side in the front-rear direction of the feeder body is formed steeper in comparison with the other side in the front-rear direction.
By making the inclined surface steep one after another as in the above configuration, the cleaning water that has been removed from the feeder body to the one side in the front-rear direction is efficiently removed from the inclined surface.

  In the vibration feeder of the present invention, since the inclined portion inclined toward the side of the feeder main body is formed on the upper surface of the feeder main body, the drainage is remarkably good. Therefore, when the vibration feeder is washed with water or the like, the feeder The washing water on the main body is removed from the inclined part toward the side of the feeder main body, and therefore, it is difficult for the conveyed object to adhere to the upper surface of the feeder main body and effectively prevent foreign matter from entering the conveyed object. Can do.

The perspective view from the front which shows the whole structure of the electromagnetic feeder which shows 1st embodiment of this invention Similarly perspective view from the rear side Same side view Similarly longitudinal section Similarly, a perspective view from the front of the feeder body (the electromagnet is also shown) Similarly perspective view from the back of the feeder body Same side view Similarly, AA cross-sectional view in FIG. Similarly, a cross-sectional view taken along line BB in FIG. CC sectional view similarly in FIG. Similarly, a cross-sectional view taken along line DD in FIG. Similarly, a cross-sectional view taken along line EE in FIG. Similarly, a cross-sectional view taken along line FF in FIG. The perspective view from the front of the feeder main body of a vibration feeder which shows 2nd embodiment of this invention Similarly perspective view from the rear of the vibration feeder Similarly, a longitudinal sectional view of the feeder body Also side view of feeder body Similarly, A1-A1 arrow sectional view in FIG. Similarly B1-B1 arrow sectional drawing in FIG. Similarly, C1-C1 arrow sectional view in FIG. Similarly, D1-D1 arrow sectional view in FIG. E1-E1 arrow sectional view similarly in FIG. Similarly F1-F1 arrow sectional drawing in FIG. The perspective view from the front of the feeder main body of a vibration feeder which shows 3rd embodiment of this invention Similarly perspective view from the rear of the vibration feeder Similarly, a longitudinal sectional view of the feeder body Also side view of feeder body Similarly A2-A2 arrow sectional view Similarly B2-B2 arrow sectional view in FIG. Similarly, C2-C2 arrow sectional view in FIG. Similarly, D2-D2 arrow sectional view in FIG. Similarly, E2-E2 arrow sectional view in FIG. Similarly, F2-F2 arrow sectional view in FIG. The width direction sectional view showing the important section of another embodiment of the present invention Width direction sectional drawing which shows the principal part of another embodiment of this invention Width direction sectional drawing which shows the principal part of another embodiment of this invention The side view which shows the shape of the feeder main body adapted to embodiment of FIG. 34 thru | or FIG. Side view showing the shape of another feeder body

Hereinafter, a vibration feeder (electromagnetic feeder) according to the present invention will be described with reference to the drawings. First, based on FIG. 1 thru | or FIG. 12, 1st embodiment of this invention is described.
1 is a perspective view from the front showing the overall configuration of the vibration feeder according to the first embodiment of the present invention, FIG. 2 is a perspective view from the rear side, FIG. 3 is a side view, and FIG. FIG.

  5 is a perspective view from the front of the feeder main body (electromagnet is also shown), FIG. 6 is a perspective view from the rear of the feeder main body, FIG. 7 is also a side view, and FIGS. Cross-sectional views in the width direction of the first mounting portion, and FIGS. 11 to 13 are cross-sectional views in the width direction of the second mounting portion. 8 to 10 are sectional views taken along arrows AA, BB, and CC in FIG. 7, respectively, and FIGS. 11 to 13 are DD, EE, and FF arrows in FIG. 7, respectively. FIG.

  The vibration feeder 1 is supported by the feeder main body 11 and vibration springs supported by the feeder main body 11, that is, the first plate spring 12 and the second plate spring 13, and the upper ends of the first plate spring 12 and the second plate spring 13. The attachment member 14 for attaching the attachment type trough, the electromagnet 16 for attracting the attracted member 15 (see FIG. 3) fixed to the attachment member 14, and the vibration state of the trough 17 are controlled via the electromagnet 16. And a controller (not shown). The electromagnet 16 and the controller are a drive unit that applies vibration to the trough 17.

The configuration of the feeder body 11 will be described.
In this case, the feeder body 11 is a counterweight. This is made of stainless steel and formed by casting. A main body bottom surface 110 of the feeder main body 11 is formed on a flat surface, and vibration-proof springs 111 are arranged at four corners.
The feeder main body 11 includes a leaf spring mounting portion 112 disposed at the front portion thereof and an electromagnet mounting portion 113 disposed at the rear portion. The feeder body 11 has a longitudinal direction (hereinafter referred to as “front-rear direction”) and a short length as a whole. It is formed in a substantially rectangular shape having a hand direction (hereinafter referred to as “width direction”).

When comparing the electromagnet mounting portion 113 and the leaf spring mounting portion 112 in terms of the length in the width direction, the electromagnet mounting portion 113 is formed slightly longer in the width direction than the leaf spring mounting portion 112. As a result, stepped surfaces 112a and 112a that expand in the left-right direction from the rear end portion of the leaf spring mounting portion 112 (first mounting portion 1121 described later) are formed at the left and right lower portions at the front end portion of the electromagnet mounting portion 113. (See FIG. 5).
When the electromagnet mounting portion 113 and the leaf spring mounting portion 112 are compared in height, the electromagnet mounting portion 113 is formed higher than the leaf spring mounting portion 112.

Here, the configuration of the electromagnet mounting portion 113 will be described in more detail. The electromagnet mounting portion 113 is formed as a whole shape that is cut out so that the upper surface of the cube-shaped lump is inclined downward toward the rear, and is cut out so that the front surface is inclined downward toward the front.
A mounting recess 1131 for mounting the electromagnet 16 is formed in the center of the inclined mounting portion front surface 113a of the electromagnet mounting portion 113 so as to be formed obliquely rearward in a direction orthogonal to the mounting portion front surface 113a.

The mounting recess 1131 is internally supported with the electromagnet 16 molded. The electromagnet mounting portion 113 is formed with an insertion hole 1132 for inserting a lead wire (not shown) for electrically connecting the electromagnet 16 and the controller (see FIG. 4).
Corners w1 and w1 which are continuous portions of the mounting portion upper surface 113b and the mounting portion side surface 113c of the electromagnet mounting portion 113 are chamfered in a curved surface shape. A corner portion w2 that is a continuous surface between the mounting portion upper surface 113b and the mounting portion rear surface 113d of the electromagnet mounting portion 113 is chamfered into a curved surface shape.

  The configuration of the leaf spring mounting portion 112 will be described in more detail. In this embodiment, the first leaf spring 12 is disposed in the middle of the leaf spring mounting portion 112 in the front-rear direction, and the second leaf spring 13 is disposed at the front end portion of the leaf spring mounting portion 112.

The leaf spring attachment portion 112 includes a first attachment portion 1121 for the first leaf spring and a second attachment portion 1122 for the second leaf spring, which are continuous in the front-rear direction.
The first mounting portion 1121 has a first upper surface 1121a, first side surfaces 1121b on both sides in the width direction, and a first mounting surface 1121c for the first leaf spring.
The second mounting portion 1122 has a second upper surface 1122a, second side surfaces 1122b on both sides in the width direction, and a second mounting surface 1122c for a second leaf spring. The first upper surface 1121a is at a relatively higher position than the second upper surface 1122a.

The first mounting surface 1121c and the second mounting surface 1122c of the first mounting portion 1121 and the second mounting portion 1122 are both formed to be inclined in a direction along the mounting portion front surface 113a (parallel to the mounting portion front surface 113a). . Further, the first mounting surface 1121c and the second mounting surface 1122c are formed with holes into which lower mounting bolts 1123 described later are inserted.
Note that both side surfaces of the leaf spring mounting portion 112 are parallel. In other words, both the first side surface 1121b and the two second side surfaces 1122b of the first mounting portion 1121 and the second mounting portion 1122 are formed in parallel with each other and in a plane along the front-rear direction.

The first upper surface 1121a of the first mounting portion 1121 is formed between the upper end portion of the first mounting surface 1121c and the mounting portion front surface 113a. That is, the first mounting surface 1121c and the mounting portion front surface 113a are at a position separated by a first predetermined distance L1 in the front-rear direction (see FIG. 4).
The first upper surface 1121a is formed as an inclined surface that is inclined downward from the front to the rear. Moreover, the inclined surface is formed into a curved surface that is curved so that the end in the width direction is located below the center in the width direction. In the first mounting portion 1121, the inclined portion in the first embodiment is the entire first upper surface 1121a.

Further, the curvature of the first upper surface 1121a which is a curved surface is formed to be larger (steep) toward the rear side, that is, the electromagnet mounting portion 113 side. Such a difference in curvature in the front-rear direction is shown in FIGS.
A corner w3, which is a continuous surface between the first upper surface 1121a and the mounting portion front surface 113a, is chamfered to form a curved surface.
The corners w4 and w4, which are continuous surfaces of the first upper surface 1121a and the first side surfaces 1121b, are chamfered to form curved surfaces.

  The second upper surface 1122a of the second mounting portion 1122 is formed between the upper end portion of the second mounting surface 1122c and the first mounting surface 1121c. That is, the second mounting surface 1122c and the first mounting surface 1121c are related to each other at a position separated by a second predetermined distance L2 in the front-rear direction. The second predetermined distance L2 is set longer than the first predetermined distance L1.

The second upper surface 1122a is formed as an inclined surface that is inclined downward from the front to the rear. Moreover, the inclined surface is formed into a curved surface that is curved so that the end in the width direction is located below the center in the width direction.
In the second attachment portion 1122, the inclined portion in the first embodiment is the entire second upper surface 1122a.

  Further, the curvature of the second upper surface 1122a, which is a curved surface, is formed to be larger (steep) toward the rear side, that is, the first mounting portion 1121 side. Such a difference in curvature in the front-rear direction is shown in FIGS. The curvature of the rear side portion of the second upper surface 1122a is larger than the curvature of the rear side portion of the first upper surface 1121a by the amount that the second predetermined distance L2 is longer than the first predetermined distance L1.

A corner w5, which is a continuous surface between the second upper surface 1122a and the first mounting surface 1121c, is chamfered to form a curved surface.
Corners w6 and w6, which are continuous surfaces of the second upper surface 1122a and the second side surfaces 1122b, are chamfered to form curved surfaces.

The first mounting surface 1121c is disposed at a position retracted from the continuous surface of the first upper surface 1121a and the second upper surface 1122a by the thickness of the first leaf spring 12. The second attachment surface 1122 c is disposed at a position that is retracted by the thickness of the second leaf spring 13 from the attachment portion front surface 112 b of the leaf spring attachment portion 112.
The attachment portion front surface 112b is inclined in the same direction as the second attachment surface 1122c. The corner portions w7 and w7, which are continuous surfaces of the mounting portion front surface 112b and the second side surfaces 1121b, are chamfered to form curved surfaces.

The widths of the first leaf spring 12 and the second leaf spring 13 are set equal to the width of the leaf spring mounting portion 112. The lower ends of the first plate spring 12 and the second plate spring 13 are fixed so as to be crimped to the first mounting surface 1121c and the second mounting surface 1122c via lower mounting bolts 1123, respectively.
The first plate spring 12 and the second plate spring 13 are set to have the same height, and the mounting member 14 that supports the trough 17 with the lower surface 171 is passed in the front-rear direction at the upper end portion thereof.

  The mounting member 14 includes a mounting plate 141 on which the trough 17 is mounted, a rear first mounting piece 142 and a front second mounting piece 143 that are inclined obliquely forward and downward from the lower surface of the mounting plate 141. . Upper ends of the first leaf spring 12 and the second leaf spring 13 are fixed to the front surfaces of the first attachment piece 142 and the second attachment piece 143, respectively, via an upper attachment bolt 1124.

  The first mounting piece 142 and the second mounting piece 143 are integrally formed with the lower surface of the mounting plate 141 at the same inclination angle as the first plate spring 12 and the second plate spring 13, respectively. The first mounting piece 142 is arranged in the middle of the mounting plate 141 in the front-rear direction, and the second mounting piece 143 is arranged at the front end of the mounting plate 141.

The mounting plate 141 has an extension portion 1411 that extends horizontally further from the portion corresponding to the first plate spring 12 in the vertical direction. The rear end portion of the extension portion 1411 is bent downward to form a support wall portion 1412 parallel to the first attachment piece 142 and the second attachment piece 143.
The support wall portion 1412 supports and fixes the attracted member 15 to the rear surface 1412a.

The support wall portion 1412 is disposed to face the mounting portion front surface 113a of the electromagnet mounting portion 113 in the front-rear direction with an interval L3 having a predetermined length in the front-rear direction.
Further, the vertical length of the support wall portion 1412 is formed longer than the vertical length of the second mounting piece 143. These configurations are for supporting the attracted member 15 on the rear surface 1412a of the support wall portion 1412, and adopt a configuration in which the attracted member 15 is interposed between the support wall portion 1412 and the mounting portion front surface 113a. That is why.

Further, a reinforcing rib 144 is integrally formed across the first mounting piece 142 and the support wall portion 1412. The reinforcing rib 144 is formed in a trapezoidal shape in which the rear side is longer than the front side when viewed from the side.
That is, the first predetermined distance L1 is specified as a distance including the first mounting piece 142, the reinforcing rib 144, the support wall portion 1412, the attracted member 15, and the interval L3.

  In the vibration feeder 1 having the above-described configuration, the attachment member 14 vibrates in the front-rear direction by driving the electromagnet 16 and attracting / separating the attracted member 15 with respect to the electromagnet 16 so that the attachment member 14 is the first leaf spring. The trough 17 that vibrates in the front-rear direction together with the second plate spring 12 and the second plate spring 13 vibrates in the front-rear direction and conveys the object to be conveyed on the trough 17 in the conveying direction, that is, forward.

By the way, when the object to be conveyed is conveyed in the vibration feeder 1, the object to be conveyed (for example, a granular material) may rise and fall on the feeder main body 11 along with the vibration. Hereinafter, the transported object dropped on the feeder main body 11 will be referred to as a dropped transported object.
When the transported object is transported next with the fallen transported object attached to the feeder main body 11, the transported object on the feeder main body 11 now rises on the trough 17 due to the vibration of the vibration feeder, and the transported object on the trough 17. It will be mixed as a foreign object in the conveyed product. For this reason, it is necessary to clean the vibration feeder 1 regularly or irregularly.

Since the electromagnet 16 is molded and supported in the mounting recess 1131 and the feeder body 11 is formed as an integral body made of stainless steel, there is no problem even if the vibratory feeder 1 is washed with water.
And the 1st upper surface 1121a of the feeder main body 11 is formed in the inclined surface which inclines downward toward the back from the front. Moreover, the inclined surface is formed in a curved surface that is curved in the width direction so that the end in the width direction is located below the center in the width direction. Further, the curvature of the first upper surface 1121a is formed so as to increase toward the rear side.

  The second upper surface 1122a is formed as an inclined surface that is inclined downward from the front to the rear. Moreover, the inclined surface is formed in a curved surface that is curved in the width direction so that the end in the width direction is located below the center in the width direction. Further, the curvature of the second upper surface 1122a is formed so as to increase toward the rear side.

  With this configuration, the washed water on the feeder main body 11 of the vibration feeder 1 is removed with the first upper surface 1121a and the second upper surface 1122a facing rearward and sideward. The first upper surface 1121a and the second upper surface 1122a are inclined downward toward the rear. For this reason, when the cleaning water is guided rearward, a large amount of cleaning water is removed on the rear side of each of the first upper surface 1121a and the second upper surface 1122a.

  However, the first upper surface 1121a and the second upper surface 1122a each have a larger curvature on the rear side than the curvature on the front side in the width direction. For this reason, even if much washing water is excluded on the rear side of each of the first upper surface 1121a and the second upper surface 1122a, the washing water can be smoothly removed.

Further, the corner portions w4 and w6 of the leaf spring mounting portion 112 are chamfered to be curved surfaces. The wash water is smoothly removed by the corners w4 and w6 of the leaf spring mounting portion 112 toward the first side surface 1121b at the first mounting portion 1121 and toward the second side surface 1122b at the second mounting portion 1122.
Further, stepped surfaces 112a and 112a that expand in the left-right direction from the rear end portion of the first mounting portion 1121 are formed at the left and right lower portions at the front end portion of the electromagnet mounting portion 113. A part of the washing water removed in step (b) is smoothly dropped and removed along the stepped surfaces 112a and 112a.

  The electromagnet mounting portion 113 has a shape in which the upper surface of the cubic block is notched so as to be inclined downward toward the rear, and the front surface is notched so as to be inclined downwardly toward the front. For this reason, in the electromagnet mounting portion 113, a part of the washing water after washing the vibration feeder 1 is easily removed backward from the mounting portion upper surface 113b.

  Further, the corners w1 and w1 which are continuous portions of the mounting portion upper surface 113b and the mounting portion side surface 113c of the electromagnet mounting portion 113 are chamfered in a curved shape, and the mounting portion upper surface 113b of the electromagnet mounting portion 113 and the mounting portion rear surface 113d are formed. The corner w2 which is a continuous surface is chamfered into a curved surface shape. For this reason, part of the cleaning water is smoothly removed from the mounting unit upper surface 113b to the mounting unit back surface 113d or the mounting unit side surface 113c.

  As described above, since the cleaning water is excluded from the feeder main body 11, the cleaning water hardly remains on the feeder main body 11. For this reason, a fall conveyance thing becomes difficult to adhere to surfaces, such as the upper surface of a feeder main body 11, and a side surface. Then, when the transported object is transported next, the fall transported object can be prevented from being mixed into the transported object as a foreign object.

  The first mounting surface 1121c and the mounting portion front surface 113a are at a position separated by a first predetermined distance L1 in the front-rear direction. That is, the first predetermined distance L1 is specified as a distance including the first attachment piece 142, the reinforcing rib 144, the support wall portion 1412, the attracted member 15, and the interval L3. In short, the length of the first upper surface 1121a in the front-rear direction is long enough to insert an operator's hand or finger between the first mounting surface 1121c and the mounting portion front surface 113a, and also above that. Sufficient space is secured to insert the operator's hands and fingers.

  Therefore, even if the reinforcing rib 144, the support wall portion 1412, and the attracted member 15 are present on the upper side of the first mounting surface 1121c, the operator cannot move the hand between the first mounting surface 1121c and the mounting portion front surface 113a. By inserting a finger, the dirt on the first mounting surface 1121c that is difficult to clean due to the reinforcing rib 144, the support wall portion 1412, and the attracted member 15 being located above can be easily wiped off.

Next, a second embodiment will be described based on FIGS. In the second embodiment, only portions different from the first embodiment will be described with different reference numerals.
14 is a perspective view from the front of the feeder main body 11 of the vibration feeder 1 according to the second embodiment of the present invention, FIG. 15 is a perspective view from the rear of the vibration feeder 1, and FIG. 17 is a side view of the feeder body 11, FIGS. 18 to 20 are cross-sectional views in the width direction of the first mounting portion, and FIGS. 21 to 23 are cross-sectional views in the width direction of the second mounting portion, respectively. is there.

18 to 20 are cross-sectional views taken along arrows A1-A1, B1-B1, and C1-C1 in FIG. 17, respectively, and FIGS. 21 to 23 are arrows D1-D1, E1-E1, and F1-F1 in FIG. 17, respectively. FIG.
In the second embodiment, the configuration different from that of the first embodiment is that cross-sectional shapes of the first attachment portion 1141 and the second attachment portion 1142 in the feeder body 11, that is, the upper surfaces of the first attachment portion 1141 and the second attachment portion 1142. It is the shape.

Here, the shapes of the first upper surface 1141a of the first mounting portion 1141 and the second upper surface 1142a of the second mounting portion 1142 will be described.
The first upper surface 1141a and the second upper surface 1142a in the second embodiment are linearly inclined downward to both sides of the feeder body 11 with the centers in the width direction of the upper surface of the feeder body 11 as vertices 1151 and 1152. It is formed to do. That is, the first upper surface 1141a and the second upper surface 1142a are formed on flat surfaces that are inclined downward toward both sides of the feeder main body 11 with the centers in the width direction as vertices 1151 and 1152.

  Further, the first upper surface 1141a and the second upper surface 1142a are inclined downward and the width direction centers (vertices 1151, 1152) of the first upper surface 1141a and the second upper surface 1142a are slightly lower in the front-rear direction. (See FIG. 16). The first upper surface 1141a is at a relatively higher position than the second upper surface 1142a.

Further, the widths of the first mounting portion 1141, the second mounting portion 1142, and the electromagnet mounting portion 113 are formed to be equal (the stepped surfaces 112a and 112a in the first embodiment are not provided).
Since other configurations are the same as those of the first embodiment, the same reference numerals are given and description thereof is omitted.

  According to the second embodiment of the present invention, the first upper surface 1141a and the second upper surface 1142a are inclined downward toward the rear and downwardly inclined toward both sides, and therefore remain on the feeder main body 11 after cleaning. The washed water is smoothly removed to both sides of the feeder body 11 along the inclination of the first upper surface 1141a and the second upper surface 1142a. Other functions and effects are the same as those of the first embodiment.

Next, based on FIG. 24 thru | or FIG. 33, 3rd embodiment of this invention is described. In the third embodiment, only parts different from the first embodiment will be described with different reference numerals.
24 is a perspective view from the front of the feeder main body 11 of the vibration feeder 1 according to the third embodiment of the present invention, FIG. 25 is a perspective view from the rear of the vibration feeder 1, and FIG. 27 is a side view of the feeder body 11, FIGS. 28 to 30 are cross-sectional views in the width direction of the first mounting portion, and FIGS. 31 to 33 are cross-sectional views in the width direction of the second mounting portion, respectively. is there.

  In the third embodiment, the configuration different from that of the first embodiment is that cross-sectional shapes of the first attachment portion 1121 and the second attachment portion 1122 in the feeder body 11, that is, the upper surfaces of the first attachment portion 1121 and the second attachment portion 1122. It is the shape.

Here, the shapes of the first upper surface 1181 of the first mounting portion 1121 and the second upper surface 1191 of the second mounting portion 1122 will be described.
The first upper surface 1181 is a first side inclined surface 1181a having a part inclined downward toward both sides, and the remaining portion is a first lower inclined surface 1181b inclined downward only rearward. . The second upper surface 1191 is a second side inclined surface 1191a having a part inclined downward toward both sides, and the remaining portion is a second lower inclined surface 1191b inclined downward only rearward. . In the third embodiment, the inclined portions are the first side inclined surface 1181a and the second side inclined surface 1191a.

The first side inclined surface 1181a is a plane inclined to both sides in the width direction with the center in the width direction as a vertex P1. The vertex P1 extends across both ends of the first upper surface 1181 in the front-rear direction. The first front end side 1181c of the first side inclined surface 1181a is inclined rearward from the front end of the apex P1 to the side in plan view. A front side of the first front end side 1181c is a first lower inclined surface 1181b.
Such a change in the shape of the first upper surface 1181 is shown in FIGS. 28 to 30 are sectional views taken along arrows A2-A2, B2-B2, and C2-C2 in FIG. 27, respectively.

The second side inclined surface 1191a is a plane inclined to both sides in the width direction with the center in the width direction as a vertex P2. The vertex P2 of the second upper surface 1191 extends from the rear end of the second upper surface 1191 to the middle in the front-rear direction. The second front end side 1191c of the second side inclined surface 1191a is inclined rearward from the front end of the apex P2 to the side in plan view. A front side of the second front end side 1191c is a second lower inclined surface 1191b.
Such a change in the shape of the second upper surface 1191 is shown in FIGS. 31 to 33 are sectional views taken along arrows D2-D2, E2-E2, and F2-F2 in FIG. 27, respectively.
Since other configurations are the same as those of the first embodiment, the same reference numerals are given and description thereof is omitted.

  In the above configuration, the cleaning water after cleaning on the first upper surface 1181 of the first mounting portion 1121 is removed from the first side inclined surface 1181a toward the side, and from the first lower inclined surface 1181b toward the rear. And eliminated from the first side inclined surface 1181a toward the side.

  On the second upper surface 1191 of the second mounting portion 1122, the washing water is removed from the second side inclined surface 1191a toward the side, and is also removed rearward from the second lower inclined surface 1191b. Excluded laterally from the side inclined surface 1191a. Other functions and effects are the same as those of the first embodiment.

  34 to 38 show still another embodiment. FIG. 34 and FIG. 35 are different embodiments, respectively, but on the first upper surface and the second upper surface of the leaf spring mounting portion of the feeder main body, a stripping groove or a concave portion that is a streak in plan view. Is forming.

In the case of FIG. 34, the upper surface (first upper surface and second upper surface) of the feeder body 11 is inclined rearward, and a plurality of stripping grooves 1120a having a V-shaped cross section are formed on the upper surface in the width direction. They are spaced apart and formed.
In the case of FIG. 35, the upper surface (the first upper surface and the second upper surface) of the feeder main body 11 is inclined downward with the width direction center as an apex toward both sides thereof, and the upper surface is inclined downward toward the rear. A plurality of strips 1120b having the same depth and having a V-shaped cross section are formed on the upper surface, spaced apart in the width direction.

  In the case of FIG. 36, a concave curved surface 1120c that protrudes downward is formed in the front-rear direction at the center in the width direction of the upper surface (first upper surface and second upper surface) of the feeder body 11, and is formed on both sides of the concave curved surface 1120c. A convex curved surface 1120d that is convex upward is continuously formed. The upper surface of the feeder body is inclined downward toward the rear.

  In the embodiment shown in FIG. 34 to FIG. 36, as an inclined portion for removing the washing water to the side of the feeder main body 11, as shown in FIG. 37 or FIG. 38, an inclined groove 1120e continuous to the removing grooves 1120a and 1120b. Are formed such that the side portions thereof are inclined downward along the width direction of the upper surface. In FIG. 37, the inclined groove 1120e is formed at one location along the width direction at the rear of each of the first upper surface and the second upper surface. In FIG. 38, the inclined groove 1120e is formed at two locations along the width direction in the middle part of each of the first upper surface and the second upper surface in the front-rear direction.

  Alternatively, in the embodiment shown in FIG. 34 and FIG. 35, the rear end portions of the exclusion grooves 1120a and 1120b may be formed to face the side of the feeder main body 11 so as to form an inclined portion. Since other configurations are the same as those of the first embodiment, the same reference numerals are given and description thereof is omitted.

  In the embodiment shown in FIGS. 34 and 35, the washed water after washing is guided to the exclusion grooves 1120a and 1120b, respectively, and is removed to the side of the feeder body 11 by the inclined portions. In the embodiment shown in FIG. 36, the cleaning water after cleaning is guided to the concave curved surface 1120c and guided to the convex curved surface 1120d (which is also an inclined portion) and is removed to the side of the feeder main body 11 by the inclined portion. The Other functions and effects are the same as those of the first embodiment.

  The present invention is not limited to the above embodiment, and the specific configuration of each part is not limited to the above embodiment, and various modifications can be made without departing from the gist of the present invention.

  For example, in each of the above-described embodiments, the upper surface of the feeder main body is provided with an inclined portion having a symmetrical shape so that the side is inclined downward with the center in the width direction as an apex. However, the top of the feeder main body may be displaced from the center in the width direction to one side, and the top surface may be inclined downward from the top toward each side. Also in this case, the wash water after washing can be smoothly removed to the side.

  In each of the above-described embodiments, the longitudinal length of the second mounting portion is set longer than the longitudinal length of the first mounting portion. However, the front-rear direction length of the first attachment part and the front-rear direction length of the second attachment part are made equal, or the front-rear direction length of the first attachment part is set longer than the front-rear length of the second attachment part. It is also possible to do.

  In each said embodiment, the feeder main body was comprised from the 1st attachment part and the 2nd attachment part by arrange | positioning a leaf | plate spring in two places front and back. However, as a configuration in which the leaf springs are arranged further forward, it is possible to increase the number of attachment portions according to the number of leaf springs. Also in this case, by providing an inclined portion on the upper surface of each attachment portion, the cleaning water after cleaning can be eliminated laterally.

Moreover, in each said embodiment, it is set as the structure which provided the inclination part which inclines downward toward the side of a feeder main body only in the leaf | plate spring attachment part among feeder main bodies. However, the present invention is not limited to this, and in addition to providing an inclined portion on the leaf spring mounting portion, an upper surface of the electromagnet mounting portion is provided with an inclined portion that is inclined downward toward the side. Also good. The inclined portion may be configured as a surface in which the upper surface of the electromagnet mounting portion is inclined to the side, or may be a groove shape.
In this case, not only the leaf spring mounting portion but also the electromagnet mounting portion can facilitate the elimination of the washing water to the side thereof.

  Moreover, in each said embodiment, although it is set as the structure which provides an inclination part in the upper surface of all the attachment parts, this invention is not limited to this, The structure which provides an inclination part in the upper surface of a part of attachment part It is good. For example, it can also comprise so that an inclination part may be provided in the 1st upper surface of a 1st attachment part, and an inclination part may not be provided in the 2nd upper surface of a 2nd attachment part among a 1st attachment part and a 2nd attachment part.

  DESCRIPTION OF SYMBOLS 1 ... Vibration feeder, 11 ... Feeder main body, 12 ... 1st leaf | plate spring, 13 ... 2nd leaf | plate spring, 112 ... Leaf spring attachment part, 1121 ... 1st attachment part, 1121a ... 1st upper surface, 1222 ... 1st attachment part 1122a ... Second upper surface

Claims (5)

A feeder main body, a vibration spring provided between the feeder main body and a trough attached to the upper side of the feeder main body, and a drive unit that conveys an object to be conveyed forward by the trough by applying vibration to the vibration spring. And a vibration feeder comprising:
An oscillating feeder characterized in that an inclined portion that inclines downward toward the side of the feeder body is formed on the upper surface of the feeder body.   The vibration feeder according to claim 1, wherein the inclined portion is an inclined surface provided on at least a part of the upper surface of the feeder main body.   3. The vibration feeder according to claim 2, wherein the inclined surface is formed so as to be inclined downward to both sides of the feeder body with the center of the upper surface of the feeder body as a vertex.   4. The vibration feeder according to claim 2, wherein the inclined surface is inclined downward toward the side of the feeder main body and downwardly inclined toward one side in the front-rear direction.   5. The vibration feeder according to claim 4, wherein the inclined surface is formed so that the one side in the front-rear direction of the feeder body is steeper in comparison with the other side in the front-rear direction.

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