JPH036576Y2 - - Google Patents

Description

[Detailed description of the invention] The present invention is a device that changes the posture of the input article in the conveyance direction of the main conveyor and biases it when the article is inputted from the oblique side into the main conveyor.
This is to reduce the impact of articles when they are thrown in and to prevent them from overrunning and falling.

Conventionally, the conveyor S that inputs articles onto the main conveyor C from the diagonal side inputs the articles M onto the main conveyor C at the same speed with no speed change in the width direction, as shown in FIG. When the conveyance speed is high compared to the conveyance speed, the upstream corner A of the input article is pulled in by the main conveyor C and the article changes its posture in the flow direction of the main conveyor C, so that it does not overrun when being input. However, if the loading speed is higher than the conveying speed, there is a risk of overrunning and falling, so a guide wall G is erected on the side of the loading position of the main conveyor. The thrown article M collides with the guide wall G and stops, thereby preventing it from overrunning and falling.

However, there is a risk that the articles may be damaged or destroyed by colliding with the guide wall G, and in order to prevent damage or destruction, it is necessary to ensure that the main conveyor has a width sufficient to cushion the impact. However, this method has the disadvantage that it is necessary to install a main conveyor having a width larger than that required for conveyance.

The present invention eliminates the above-mentioned drawbacks of the conventional technology.An embodiment of the present invention will be described below with reference to FIG. There are a plurality of input conveyors 3 for loading articles into the tray conveyor 2, for example, a first input conveyor 3a, a second input conveyor 3b, and a third input conveyor 3c from the upstream side of the tray conveyor 2 to the downstream side of the tray conveyor 2. The speed Va of the first input conveyor 3a is
Assuming that the speed of the second input conveyor 3b is Vb and the speed of the third input conveyor 3c is Vc, the speed of each input conveyor 3a, 3b, 3c is Va that causes a component force on the input article in the feeding direction of the main transport conveyor.
＞Vb＞Vc.

FIGS. 3 and 4 show driving means for each input conveyor, and in FIG. 3, the input conveyance surfaces of the input conveyors 3a, 3b, and 3c are placed in the same plane to stabilize input articles. In this type of belt, each belt is suspended endlessly between a pair of pulleys of the same diameter, and on the return side, each belt is suspended around each of a plurality of drive pulleys fixed to a single drive shaft 4. The first input conveyor 3a has a speed Va of
has the largest diameter drive pulley 5a, the third input conveyor 3c has the smallest speed Vc, the third input conveyor 3c has the smallest diameter drive pulley 5c and has an intermediate speed Vb, preferably approximately equal to the speed of the tray conveyor 2. The second input conveyor 3b is driven by a drive pulley 5b having an intermediate diameter. In addition, in FIG. 4, each of the first to third input conveyors is suspended between drive pulleys with different diameters and driven pulleys with the same diameter, and each drive pulley is fixed on the same drive shaft 4'.
Although the structure is simple, the loading conveyance surface is tilted in the width direction, which deteriorates the stability of the loaded articles. Furthermore, in the drive mechanism shown in FIG. 4, it is conceivable to provide a slight step on the axis of the drive pulley in order to place the feeding and conveying surfaces within the same plane, but this has the disadvantage of complicating the drive mechanism.

No matter which of the drive mechanisms described above is used, as long as the speed relationship Va>Vb>Vc, which generates rotational torque in the feeding direction of the main transport conveyor on the input articles, is maintained, the articles will be transferred to the first to third input conveyors 3a. ,3b,3
Since the part of the article on the first input conveyor 3a is forwarded because it is on the input conveyance surface, a counterclockwise rotating torque is applied to the article in FIG. This results in a component force in the feed direction. Then, since the part of the article that has been postponed is first put into the tray 1 on the tray conveyor 2, the part of the article is pulled in the feeding direction by the tray conveyor 2 together with the rotational torque, so that the part of the article is pulled into the feeding position guide wall G. Even if a guide wall is provided, there will be no collision with the guide wall.
Being able to ride in the stream of the main transport conveyor prevents the risk of damage or breakage of the goods, and also eliminates the risk of overrunning and falling from the opposite side across the main transport conveyor 2. The width of the conveyor 2 does not need to be excessively large, and can be kept to the width necessary for conveying the articles, and
Since the input conveyor is diagonal to the main conveyor at the input end, the articles are gradually transferred onto the main conveyor and are not transferred all at once, so that the impact on the main conveyor due to the weight of articles during transfer is almost eliminated. Its practical effects are significant, such as being able to carry out loading operations with less noise.

[Brief explanation of the drawing]

Figure 1 is a schematic plan view of the main parts of a conventional loading device, Figures 2 to 4 show an embodiment of the present invention, Figure 2 is a schematic plan view of the main parts of the loading device, and Figure 3 is a driving mechanism of the loading device. FIG. 4 is a schematic front view of the main part of the second embodiment of the charging device drive mechanism. 2... Main conveyor, 3a, 3b, 3c...
Input conveyor.

Claims (1)

[Scope of utility model registration request] A plurality of input conveyors that intersect diagonally to the side of the main conveyor and are sequentially decelerated from the upstream side to the downstream side of the main conveyor, and have speed differences that cause a component force in the feeding direction of the main conveyor to be applied to the input articles. An article loading device that is arranged in parallel.