KR20110138449A

KR20110138449A - Auto labeller top belt

Info

Publication number: KR20110138449A
Application number: KR1020100058340A
Authority: KR
Inventors: 최상식
Original assignee: 최상식
Priority date: 2010-06-21
Filing date: 2010-06-21
Publication date: 2011-12-28

Abstract

PURPOSE: A top belt of an automatic labeling machine is provided to reduce an error in a labeling position caused by an instant load when attaching a label to a container. CONSTITUTION: A top belt of an automatic labeling machine comprises a first plate, a second plate, and a spring. The spring is fixed to a protruding part of the first plate and supports the plates. The protruding portion of the first plate is inserted into a groove of the second plate, and a downward pressing force is created by the elasticity of the spring in a gap of the groove. The plates are coated with Teflon in order to minimize the friction of the part that contacts a belt.

Description

AUTO LABELLER TOP BELT}

The present invention to uniformly attach the sticker supplied from the label device to the oval container

It is the upper belt (TB) to hold the posture of the oval container conveyed by the conveyor (CON) constantly and stably.

The overall flow of the labeling device is that when the controller is turned on, the conveyor (CON) is activated and the conveyor transfers the container to the labeling device (LH) where the sticker is issued.

At this time, the upper belt (TB) while pressing the upper portion of the container to enter the container to the label device (LH) transfers the container reaches a fixed position, the labeling machine issues a sticker and the issued sticker is attached to the container.

The reason for pressing the container conveyed on the conveyor with the upper belt (TB) is to prevent shaking or posture of the container which may come due to the load received while the label is attached to the container.

The reason for preventing the shaking of the container or the misalignment of the posture is to reduce the labeling position error caused by this.

In general, an upper belt is used to prevent shaking or posture of the container so that the sticker can be properly attached to the oval container coming along the conveyor (CON).

Conventional upper belt is not enough to align the container stably because one plate cannot support each container individually when several containers flow into the upper belt section by rotating the belt on one long plate. have.

In addition, the force that pushes all the containers in the upper belt section is concentrated in one plate, which shortens the life of the belt driven by friction with the plate.

The uneven pressure of the upper belt creates the speed and gap of the conveyor.

The product is moved to the position where the label is attached as the product is inclined without being in a stable posture, causing the label to be attached to the container at an angle.

To compensate for this, the upper belt was developed to support each container individually.

The present invention is to solve the stability of the container transfer and durability of the belt (BT) that the existing upper belt can not solve.

Containers used in actual production show differences in height within some margin of error.

Due to this height difference, no matter how precisely the operator adjusts the distance between the conveyor (CON) and the upper belt (TB) of the automatic label, each container can have the difference between the bearing force of the conveyor (CON) and the pressing force of the upper belt. There is no way but to label the correct position, there is no way other than lowering the height of the upper belt (TB) so that all containers can be pressed over a certain force.

Due to the overload generated here, there is a problem in that a high capacity motor is required to drive the upper belt in order to reduce the life of the belt and prevent the container from tipping.

The present invention is a method of modifying the existing plate

The spring (SR) is connected to the plate (PPT) to add elasticity and work individually to develop each container individually.

When the container enters the upper belt (TB) section, the individual plates (PPT) connected with the spring (SR) hold the container one by one. It is conveyed to the position where the label is attached without being twisted or twisted.

The elasticity of the spring (SR) connected to each plate (PPT) ensures that all containers are subjected to a constant pressure up and down.

The container is transported under constant pressure regardless of the height variation of all containers due to the elasticity of the spring (SR) connected to each plate (PPT). The mounting position error can be reduced.

In addition, since the pressing force of all the containers in the section of the upper belt (TB) is distributed to each plate (PPT), the belt (BT), which is rubbed with the plate (PPT) and driven, receives less load than the existing method. The effect of extending the life of (BT) can be seen.

Reducing the load between the plate (PPT) and the belt (BT) also means that even with a low-capacity motor, the speed of the upper belt (TB) can be kept constant regardless of the number of vessels in the upper belt (TB) section. The container is transported without tilting so that the label is attached to the container without any skew.

Reference Drawing 1 Layout
Reference Drawing 2 Upper Belt (1)
Reference Drawing 3 Upper Belt (2)
Reference Drawing 4 PERFORMANCE
Reference Drawing 5 DETAIL DRAWING

Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Reference Drawing 1

There is a conveyor (CON) for product transfer, an upper belt (TB) for pressing and transferring the container to prevent the shake posture of the product during transfer, and a labeling device (LH) for labeling the container.

Reference Drawing 3,

The upper belt TB transmits the rotational force of the motor MO to the timing pulley TP so that the belt BT operates according to the rotation of the timing pulley TP.

The belt BT uses a timing belt to prevent slippage with the driving roller TP, which may occur due to the load generated during operation.

PLATE (PT 1) was bolted to FRAME (FM) to prevent movement.

Reference Drawing 5

The spring is fixed to the protrusion of the plate (PT 1) and supports each plate (PPT).

PLATE (PT 2) was bolted to FRAME (FM) to prevent movement.

Each projecting part of the plate (PPT) is assembled into the groove of the plate (PT 2), and the spring (SR) in the groove of the groove generates a pressing force down.

Each plate (PPT) is Teflon coated (TF 1) to minimize the friction of the belt contact.

Reference Drawing 4

In Figure 4, the belt (BT) is omitted to show the perfor- mance of the upper belt (TB).

The pressing pressure of the upper belt is transmitted to each plate (PPT) through the spring (SR) and each plate (PPT) presses the container individually, so even when there are several containers with different heights in the section of the upper belt. Constant pressure is applied to all vessels.

Claims

(Reference drawing 5)
Spring (SR) that is fixed to the protruding part of the plate (PT 1) to support each plate (PPT).

(Reference drawing 5)
The projecting part of each plate (PPT) is assembled into the groove of plate (PT 2), and it receives the elasticity of the spring (SR) in the groove of this groove to generate the pressing force, and the frictional force of the part in contact with the belt Each plate has a Teflon coating (TF 1) to minimize it.

(Reference drawing 3)

Bolt-free plate (PT 2) to FRAME (FM).
Bolt-free plate (PT 1) with bolts to frame (FM).