JP2007222768A - Material applying apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a material applying apparatus capable of discharging and applying a material at a pressure set in the start-up of the discharge even when the viscosity of the material is changed with the change of temperature or the like. <P>SOLUTION: A nozzle 13 is attached to a booster 11 for giving pressure to the viscous material M via a discharge valve 15. A pressure sensor 28 for detecting the discharge pressure given to the viscous material M inside of a cylinder 21 is provided in the cylinder 21 constituting the booster 11. The pressure sensor 28 detects the pressure in the cylinder 21 when applying the material and the detected pressure is stored in a controller 18 as the pressure set in the start-up of the discharge. The discharge work is carried out by opening the discharge valve 15 when a plunger 21 is moved downward and the pressure in the cylinder 20 reaches the set pressure. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a material application apparatus, and more particularly to a material application apparatus that can stably discharge and apply a viscous material such as a sealant from a predetermined application start point.

  A material application device that supplies a viscous material such as silicone resin into a cylinder of a booster and applies the material in a bead shape to a surface to be applied while discharging the material from the tip of the nozzle by a pressurizing operation of a plunger constituting the booster. Are known.

  Since the known material application apparatus manually sets the pressure at the discharge start point, it cannot cope with the viscosity change accompanying the temperature change of the material during the day. There was a disadvantage that the discharge amount of the material became unstable. That is, as shown in FIG. 2A, the actual application start position of the material M precedes the application start point (see the two-dot chain line position in the figure) or is delayed (solid line in the figure). In addition to the occurrence of position reference, it is difficult to keep the bead thickness constant.

  As described above, when the bead is formed before the actual application start position, when the material application is performed in a closed loop shape in plan view, an area overlapping the application end position of the material is generated. Therefore, the bead diameter of the area becomes too thick. On the other hand, the material application delayed from the application start position results in a region S where no material is applied between the application end position, and if the material is used as a sealant, a seal failure is caused. There is a disadvantage that it occurs. Even if the material is discharged from the application start position, if the discharge amount is not stable, the expected bead thickness cannot be secured.

  Therefore, in Patent Document 1, let the discharge pressure in a state in which the material is satisfactorily applied be the set pressure, and operate the pump for supplying the material at the set pressure to achieve stable material discharge and application. A material coating apparatus is disclosed.

Japanese Patent Publication No. 5-36804

  However, the material application apparatus described in Patent Document 1 has a configuration in which a pressure sensor is connected to a hose connecting a pump and an application gun. Therefore, expansion, deformation, etc. of the hose become disturbance factors, and even if a set pressure is given to the controller that controls the pump, it may not be possible to discharge the material under optimum conditions when applying the material, and it is said that reliability is lacking. There is an inconvenience.

[Object of invention]
The present invention has been devised by paying attention to such inconveniences, and its purpose is to accurately detect and set the pressure during stable application by detecting the pressure in the cylinder constituting the booster. An object of the present invention is to provide a material application apparatus that can acquire pressure and can accurately discharge and apply a material by updating the set pressure even if the viscosity of the material changes due to a temperature change or the like.

In order to achieve the above object, the present invention includes a booster that applies pressure to a viscous material supplied into a cylinder, and a nozzle that communicates with the cylinder through a discharge valve, and applies pressure to the material in the cylinder. In the material application device that discharges the material from the tip of the nozzle and applies it to the surface to be applied,
A pressure sensor for detecting the pressure in the cylinder, and a controller for storing and updating the detected pressure of the sensor and for giving a material discharge operation signal of the booster,
The controller is configured to store the pressure of the pressure sensor when the material is stably discharged and applied, and to control the booster using the pressure as a set pressure at the start of discharge.

  According to the present invention, the nozzle is attached to the cylinder via the discharge valve, and the pressure applied to the material in the cylinder is detected to detect the pressure during stable application. The pressure value is not confused by disturbance, and the pressure can be trusted as the set pressure at the start of material discharge. Therefore, by storing the pressure at the time of stable application in the controller as the set pressure, making it updatable and configuring the discharge operation when the pressure in the cylinder reaches the set pressure, the material discharge start position Therefore, the material can be discharged and applied in a state of having an expected bead shape.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a partial cross-sectional front view of a material coating apparatus according to the present embodiment. In this figure, the material application apparatus 10 includes a booster 11 supported by a frame F, a balance tank 12 provided alongside the booster 11, a nozzle 13 connected to the booster 11, and the nozzle 13 and the booster 11. A discharge valve 15 that opens and closes communication between the balance tank 12, a supply valve 16 that supplies the material M in the balance tank 12 to the cylinder 20 by communicating the balance tank 12 and the booster 11, and the balance tank 12. A material supply source 17 composed of a pump or the like for replenishing the material M and a controller 18 for controlling the entire system such as the booster 11 are provided.

  The booster 11 includes a cylinder 20 to which a material M whose pressure is adjusted in the balance tank 12 is supplied, and a plunger 21 that applies a discharge pressure to the material M supplied to the cylinder 20. A discharge head 23 having a passage 22 communicating with the cylinder 20 is attached to the lower part of the cylinder. The plunger 21 is provided so as to be able to advance and retract in the vertical direction via a ball screw 25, and a gear 26 is attached to the upper portion of the ball screw 25. The gear 26 is provided so as to be engaged with a gear 27A fixed to the output shaft of the stepping motor 27 and transmit a driving force for moving the plunger 21 up and down.

  In the cylinder 20, a pressure sensor 28 is disposed below the cylinder 20. The pressure sensor 28 detects the pressure in the cylinder 20, that is, the discharge pressure of the material M, and outputs the pressure signal to the controller 18.

  The balance tank 12 includes a pressure adjustment cylinder 30, an adjustment plunger 31 that can be moved up and down in the pressure adjustment cylinder 30, and a material that is positioned below the pressure adjustment cylinder 30 and communicates with the pressure adjustment cylinder 30. And a head 33 having a supply passage 32. The head 33 is connected to a tip 34 </ b> A of a material supply pipe 34 led out from the material supply source 17 so that material can be supplied into the material supply passage 32. The operation of the adjustment plunger 31 is controlled via an air cylinder 39, whereby the pressure of the material M supplied from the material supply source 17 into the material supply passage 32 and the pressure adjustment cylinder 30 is kept constant. In order to prepare for the supply of the booster 11 into the cylinder 20.

  The nozzle 13 is connected to the cylinder 20 of the booster 11 through the discharge valve 15 so as to be opened and closed. The discharge valve 15 is attached to the discharge head 23, and includes a valve rod 36 that can be moved forward and backward with respect to a valve seat 35 that forms a valve hole communicating with the cylinder 20. When the valve rod 36 moves to the left side and moves away from the valve seat 35, the cylinder 20 and the nozzle 15 are blocked. To communicate with each other.

  The liquid supply valve 16 includes a rod-shaped valve body 42 that opens and closes a valve hole 41 provided between the material supply passage 32 and the cylinder 20. The valve body 42 opens the valve hole 41 so that the material M in the balance tank 12 can be supplied to the cylinder 20, while the communication between the balance tank 12 and the booster 11 is cut off when the valve hole 41 is closed. It is supposed to be. In the present embodiment, the shaft diameter of the valve body 42 is smaller than the inner diameter of the material supply passage 32, so that the material M replenished from the material supply source 17 has a space and pressure around the valve body 42. The adjustment cylinder 30 is replenished.

  The controller 18 is provided to control the operation of the booster 11 and to control the opening and closing of the discharge valve 15 and the liquid supply valve 16. The controller 18 includes a CPU (not shown), and the CPU can store and update the pressure in the cylinder 20 by using the output of the pressure sensor 28 as an input, and the optimum discharge pressure when the material M is discharged and applied. The plunger 21 is stored so as to operate at a constant speed with the discharge pressure set as a set pressure at the start of the next discharge.

  Next, the discharge and application operations of the material M in the present embodiment will be described.

  Here, as the initial position (origin), the plungers 21 and 31 of the booster 11 and the balance tank 12 are at the ascending end, and the discharge valve 15 and the liquid supply valve 16 are closed, and the cylinders 20, 30 and It is assumed that a certain amount of material M is supplied into the material supply passage 32.

  As the stepping motor 27 rotates and the plunger 21 of the booster 11 descends, the inside of the cylinder 20 is pressurized and the inside of the cylinder 20 is raised to a set pressure. This set pressure is a pressure that is set and stored in the controller 18 by detecting the pressure when the application is performed in a state where a stable bead is formed in the previous discharge and application of the material M by the pressure sensor 28. is there.

  When the pressure sensor 28 detects that the inside of the cylinder 20 has risen to the set pressure as the plunger 21 descends, the controller 18 outputs an opening operation signal to the discharge valve 15 according to the signal from the pressure sensor 28. The discharge valve 15 is opened, and the discharge of the material M is started. Then, when the plunger 21 descends at a constant speed, the material M is continuously discharged from the tip of the nozzle 13 and the material is applied to a workpiece (not shown) in a bead shape.

  After the material M is discharged and applied in this way, the discharge valve 15 is closed, the driving of the stepping motor 27 is stopped, and the lowering operation of the plunger 21 in the booster 11 is also stopped.

  Next, the liquid supply valve 16 is opened, the stepping motor 27 is rotated in the reverse direction, the plunger 21 of the booster 11 is raised, and the material M is taken into the cylinder 20. That is, since the pressure adjusting plunger 31 of the balance tank 12 is always urged downward via the air cylinder 39, it starts to descend and moves the material M from the balance tank 12 to the cylinder chamber 20 in the booster 11 at a constant pressure. Let

  When the limit sensor (not shown) detects that the material liquid level in the balance tank 12 has reached the lowering limit, the material supply source 17 pump is driven via the controller 18 to replenish the material M. . Then, when the pressure adjusting plunger 31 is raised by the replenishing pressure at the time of material replenishment, and its rising end is detected by a limit sensor (not shown), the pump operation of the material supply source 17 stops and the pressure adjusting plunger of the balance tank 12 31 will return to the initial position (origin). Note that when supplying the material, the supply valve 16 of the liquid supply valve 16 is considered in consideration of the magnitude of the material supply pressure from the material supply source 17 (ratio to the pressure in the balance tank 12) and the capacity of the balance tank 12. Adjust the opening and closing. For example, when the pressure of the material supply source 17 is high, it is possible to prevent exposure to high pressure in the booster 11 by closing the liquid supply valve 16 (material leakage or malfunction). When the pressure difference between the pressure in the balance tank 12 and the balance tank 12 is small, or the balance tank 12 has a small capacity, the liquid supply valve 16 may be opened to directly supply the material into the booster 11

  Then, the material M can be discharged and applied by repeating the same cycle thereafter. At this time, for each application cycle, the pressure in the cylinder 20 at the time of the previous stable application is detected by the pressure sensor 28, and the set pressure at the start of discharge is updated one by one.

Therefore, according to such an embodiment, the pressure in the cylinder 20 constituting the booster 11 is detected by the pressure sensor 28, the set pressure at the start of discharge is stored in the controller 18, and the material M is discharged at the set pressure. Since the plunger of the booster 11 is lowered at a constant speed, the material application can be continuously performed while effectively avoiding the discharge delay of the material and the insufficient discharge amount at the discharge start point. it can. That is, as shown in FIG. 2B, the material M can be applied in a state having a predetermined bead shape from the application start position, for example, a closed loop material in which the application path returns to the application start position. In the case of coating, the bead shape at the joint between the coating start position and the coating end position is also stable, and there is no inconvenience that a partial bead bulge or a bead-cut region is formed.
Even if the viscosity of the material changes due to temperature changes, the pressure at the time of stable application when the viscosity changes is detected, and the detected pressure is updated as the set pressure at the start of material discharge in the next cycle. Therefore, it is possible to eliminate the inconvenience that the discharge operation becomes unstable as the viscosity changes.

The best configuration, method and the like for carrying out the present invention have been disclosed in the above description, but the present invention is not limited to this.
That is, the invention has been illustrated and described with particular reference to certain specific embodiments, but the embodiments described above are within the scope of the technical idea and scope of the invention. On the other hand, those skilled in the art can make various modifications in shape, material, quantity, and other detailed configurations.
Accordingly, the description limiting the shape and the like disclosed above is illustrative for easy understanding of the present invention, and does not limit the present invention. The description by the name of the member which excluded the limitation of all or part is included in the present invention.

For example, in the above-described embodiment, the material application apparatus that discharges and applies one liquid material has been illustrated and described.However, the present invention is not limited to this, and a pair of boosters is provided, and each booster and nozzle are arranged. It can also be applied to a two-component mixing type material discharge and coating apparatus with a mixing function in between. In this case, it is sufficient to provide a pressure sensor in each booster cylinder.
In the above embodiment, the material application apparatus 10 provided with the balance tank 12 is shown. However, this does not hinder the adoption of the configuration in which the material M is directly supplied from the material supply source 17 to the booster 11.

FIG. 3 is a front view of a part of the material coating apparatus according to the present embodiment. (A) is explanatory drawing which shows the conventional inconvenience, (B) is explanatory drawing which shows the state in which application | coating is performed normally.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Material application apparatus 11 Booster 13 Nozzle 15 Discharge valve 18 Controller 20 Cylinder 28 Pressure sensor M Material

Claims (1)

A booster that applies pressure to the viscous material supplied into the cylinder, and a nozzle that communicates with the cylinder via a discharge valve, and discharges the material from the nozzle tip by applying pressure to the material in the cylinder. In the material application device that applies to the surface to be applied,
A pressure sensor for detecting the pressure in the cylinder, and a controller for storing and updating the detected pressure of the sensor and for giving a material discharge operation signal of the booster,
The controller stores the pressure of the pressure sensor when the material is stably discharged and applied, and controls the booster using the pressure as a set pressure at the start of discharge.

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