KR20150002029U - Take-out robot with mold temperature measuring unit - Google Patents

Abstract

The purpose of the present invention is to propose a new method to measure the temperature inside the mold by a simplified method in the extraction stage of the injection molding and to prevent the failure of the injection molding by keeping the mold internal temperature within a certain range .
According to the above object, the present invention is characterized in that a non-contact type infrared ray temperature measuring device is installed on a robot arm end of a take-out robot for taking out an article from a mold, and infrared radiation radiated from the inside of the mold is received instantaneously, As shown in Fig.
In addition, the non-contact infrared temperature measuring apparatus mounted on the end of the take-out robot of the present invention can measure the temperature of the injection object after opening the mold also in a noncontact manner to predict whether the injection temperature is positive or negative.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a mold temperature measuring apparatus,

The present invention relates to a take-out robot for taking out an injection material from an injection molding machine.

Injection products such as various mold products are widely produced throughout the industry, and the extraction work of such injection products is performed by a take-out robot.

The general take-out robot is capable of XYZ motion, and a traveling road is installed so that it can travel in the X direction, and a lateral arm is mounted thereon through a roller wheel. The side arm is orthogonal to the travel path, and the robot arm has a predetermined length to enable Y motion. The elevating portion, which is perpendicular to both the traveling line and the side arm, is mounted on the side arm, and a robot arm capable of moving up and down with a belt, gear, etc. is mounted in the elevating portion.

The configuration of the rotating part and the members for its taking out function is shown in more detail.

The take-out robot is provided with a rotatable rotatable portion on the end portion of the robot arm so that the injection material can be taken out of the injection molding machine, and a support member capable of fixing the jig to the rotatable portion can be mounted with a fixing member. That is, a jig having one or more adsorption members is fixed to a support by a fixing member such as a bolt. The rotary part is arranged in the vertical direction, and the support part and the jig are also mounted side by side in the vertical direction to approach the injection part.

Injection products taken out by the take-out robot must be controlled within a certain range of the temperature of the mold. If the temperature deviates from the intended range, physical characteristics such as the shape, density, and strength of the injection molding are changed and a defect occurs . However, a take-out robot configuration capable of measuring the mold internal temperature at the take-out stage is not known.

The conventional mold temperature measuring device is a contact type temperature measuring device in which a thermometer for temperature measurement is provided on the mold surface in a contact manner and the internal temperature is calculated from the measured value by a gauge. Since the unit needs to be installed, it becomes a costly structure, and it is very troublesome to connect the wire for each individual temperature measuring device even on the installation side.

Korean Patent Registration No. 10-0401157 discloses a technique of detecting a temperature by installing a thermocouple inside a mold. However, such a configuration has the above-described problem as it is, and since it is installed inside the mold itself, , It is difficult to apply it to a mold that has already been used because it needs to change the mold itself.

Therefore, the purpose of the present invention is to propose a new method to measure the temperature inside the mold by a more simplified method at the take-out stage of the injection molding, and to prevent the failure of the injection molding by keeping the mold internal temperature within a certain range will be.

According to the above object, the present invention provides a non-contact type infrared temperature measuring device, a thermal image camera or a contact type temperature sensor at the robot arm end of a take-out robot for taking out an object from a mold. When the mold is opened, And the temperature inside the mold is measured.

In addition, the temperature measuring apparatus mounted on the end of the take-out robot of the present invention can measure the temperature of the molded article after the mold is opened by noncontact or contact type to predict whether it is good or poor according to the temperature of the injection mold, So that the injection mold temperature control section and / or the mold temperature control section controls the mold temperature to the optimum range.

According to the present invention, the mold temperature can be controlled within a certain range by measuring the internal temperature of the mold and the temperature of the injection mold in a non-contact manner at the stage of taking out the injection molding with the take-out robot, And the temperature of the injection molding is also measured in a noncontact manner, so that the amount / defect of the injection molding can be predicted at the extraction stage.

1 is a cross-sectional view for explaining the measurement of the mold internal temperature and the temperature of the injection mold according to the present invention by a non-contact type infrared ray temperature measuring apparatus installed at the end of the take-out robot.
Fig. 2 is a cross-sectional view showing that the mold internal temperature according to the present invention is measured immediately after the injection molding is taken out.
Fig. 3 is a flowchart for explaining an embodiment of the present invention.

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

1 shows the operation of the take-out robot provided with the non-contact infrared temperature measuring device 700 according to the present invention. 3 is a flowchart illustrating a process of measuring the temperature of an injection mold installed in the take-out robot and the mold internal temperature.

First, a detailed configuration of the robot arm 350 of the take-out robot for taking out the molded article 200 from the mold 100 will be described.

The robot arm 350 includes a rotation part 400 rotatably mounted at an end thereof and a detachable member 500 fixed to the rotation part 400 by a fixing member. The attachment / detachment member 500 is preferably applied to facilitate attachment / detachment of the jig 600, but is not essential and may be omitted. The jig 600 is fixed to the attachment / detachment member 500 using a fixture formed on the attachment / detachment member 500, and a plurality of chucking members are fixed to the jig 600. Although the adsorption member 650 is illustrated in FIG. 1, an adhesive member, a vacuum chuck member, an electrostatic chuck member, a magnet chuck member, or the like may be applied.

The robot arm 350 of the takeout robot can travel (X-motion) along a traveling path (not shown), can be moved in a lateral direction (Y-motion) through a lateral arm (not shown) XYZ motion is possible.

The robot arm 350 executes the XY motion to adjust the position of the jig 600 with the attracting member 650 more precisely in the vicinity of the injection product 200 and to adjust the position of the jig 600 with the attracting member 650 The injection object 200 is chucked and the injection object 200 is transported.

As described above, when the temperature at which the injection product 200 is extruded out of the specific range is changed, the shape of the injection product 200 is changed, or the density or strength is weak, and a part of the injection product 200 is released during the extraction process or transportation It is possible to measure the temperature inside the molds 100 and 105 and perform the feedback control accordingly, thereby contributing to lowering the defect rate of the injection mold 200. [

The present invention is characterized in that at least one non-contact type infrared ray temperature measuring apparatus 700 is installed in a rotary member 400 or a removable member 500 additionally mounted on a rotary part 400. When the molds 100 and 105 are opened in a take- And the temperature of the mold 200 and the temperature of the mold 200 are measured.

Since the removable member 500 can be prepared in various sizes, the present embodiment selectively removes the removable member 500 having a proper size and installs the non-contact type infrared temperature measuring device 700 on both sides thereof.

In the case of the present embodiment, the non-contact infrared temperature measuring apparatus 700 is mounted with a small stick type having a diameter and a length of 1 to 2 cm, respectively, but the size and the shape of the housing can be varied. The non-contact infrared temperature measuring apparatus 700 is commercially available, and includes a laser irradiating unit, an infrared receiving unit, and an infrared / temperature converting unit. A laser irradiating unit irradiates a laser to examine a temperature measurement object to identify a kind of alignment. A thermocouple integrated thermopile of an infrared receiver receives an infrared ray radiated from a target to increase the temperature of the thermopile, .

Although the small non-contact type infrared ray temperature measuring apparatus 700 is mounted on the lower end of the attaching / detaching member 500 in this embodiment, it can be mounted on other members of the robot arm, and the non-contact type infrared ray temperature The number of measurement apparatuses 700 and the layout distribution can be set differently.

Immediately after the moving side 105 is opened with respect to the mold fixing side 100, the non-contact infrared temperature measuring apparatus 700 is operated to measure the temperature inside the mold. It is possible to measure both temperatures by emitting a laser beam to both the mold fixing side 100 and the moving side 105 and receiving infrared rays. However, even if only one of the temperatures is measured without measuring the temperature on both sides do. The temperature measured immediately after the mold is opened is the internal temperature of the injection mold 200 and the moving side 105.

That is, when measuring the surface temperature of the injection molded article 200, it is possible to operate as follows.

When the movable side 105 is opened with respect to the mold fixing side 100 and the molded product 200 is exposed, the robot arm 350 descends to approach the position of the molded product 200 and the position of the non- And is set and controlled in advance in the control device so as to match the position of the injection mold 200. When the non-contact type infrared ray temperature measuring apparatus 700 reaches the position of the injection object 200, the injection object 200 is first controlled to be irradiated with a laser beam to check whether the position of the injection object 200 is capable of measuring the surface temperature, Infrared rays radiated from the injection molded article 200 are received and the temperature is measured. If the non-contact infrared temperature measuring apparatus 700 is disposed on both sides as shown in FIG. 1, the internal temperature of the moving side 105 of the mold is measured simultaneously with the surface temperature of the mold 200.

In addition, when the internal temperature of the fixed side 100 of the mold is to be measured, the temperature can be measured immediately after the molded product 200 is taken out (see FIG. 2).

That is, when the attracting member 650 presses and chucks the injection product 200, the inner surfaces of the mold fixing side 100 and the moving side 105 are exposed. The robot arm 350 is slightly raised so that the noncontact infrared temperature measuring apparatus 700 is controlled to be able to measure both the mold fixing side 100 and the moving side 105 temperature. The non-contact infrared temperature measuring apparatus 700 irradiates the laser again and receives the infrared rays to measure the temperature of the inner surface of the mold 100. Thereafter, the robot 200 carries the injection object 200 to the destination by the transportation operation of the robot arm 350.

Since the take-out robot includes the control unit, the measured temperature is transmitted from the control unit to the injection mold temperature control unit and / or the mold temperature control unit, and used as data for correcting or maintaining the mold temperature within the normal temperature range.

In this way, the non-contact type temperature measuring device mounted on the take-out robot measures the mold internal temperature and the temperature of the injection mold at the take-out stage to feed back the mold, thereby correcting the mold temperature, thereby eliminating or preventing defects in the molded product caused by temperature instability.

In addition, a thermal imaging camera can be applied as the noncontact temperature measuring device. The thermal imaging camera also displays the temperature variation of the injection mold and the mold in a non-contact manner, so that it can feed back the mold, correcting the mold temperature, thereby eliminating or preventing the defect of the injection molding due to temperature instability.

On the other hand, temperature measurement of an injection mold or a mold is not necessarily a noncontact type. More accurate temperature information can be obtained by providing one or more contact type temperature sensors in the rotary member 400 or the attaching / detaching member 500 additionally mounted on the rotary member 400.

According to the present invention, since it is not necessary to provide a separate temperature measuring device for each mold, the mold temperature can be immediately corrected by measuring the internal temperature of the mold every time the mold is taken out and feedback is performed, Can be greatly reduced.

It is to be understood that the invention is not limited to the embodiments described above but is defined by the appended claims and that those skilled in the art can make various modifications and alterations within the scope of the claims It is self-evident.

100, 105: mold
200: Injection
350: Robot arm
400:
500: attachment / detachment member
600: jig
650:
700: Non-contact infrared temperature measuring device

Claims (4)

A take-out robot for taking out an injection product from a mold,
The take-out robot is configured to be capable of XYZ motion,
The robot arm end of the take-out robot is provided with a temperature measuring device,
The robot arm end portion
A rotating portion rotatably mounted;
And a jig mounted on the rotating portion and having at least one chucking member for chucking the injection molded product,
The temperature measuring device is provided at a lower end of the robot arm. When the mold is opened, the robot arm descends to measure the temperature of the molded article formed by the temperature measuring device,
The robot arm is lifted after the chucking member takes out the injection product, and the temperature inside the mold where the temperature measuring device located at the lower end of the robot arm is opened is measured,
Wherein the temperature measuring apparatus includes a laser irradiating unit, an infrared ray receiving unit, and an infrared / temperature converting unit, and irradiates the laser beam with the laser beam and receives the infrared rays to measure the temperature of the laser beam. The temperature measuring apparatus according to claim 1, wherein at least one temperature measuring device is provided on each of lower and upper surfaces of the detachable member,
When the robot arm descends to reach the position of the injection object, the laser beam is irradiated to the injection object, the infrared ray is received, the temperature of the injection object is measured, the temperature measuring device irradiates the laser beam to the inner surface of the movement side of the mold, And the temperature of the inside of the mold is measured in a non-contact manner. The take-out robot according to claim 1, wherein the take-out robot comprises a control unit,
Wherein the control unit transmits the measured temperature of the temperature measuring device to the injector temperature control unit or the mold temperature control unit, and controls the internal temperature of the mold as feedback. The take-out robot according to claim 1, wherein the temperature measuring device includes a noncontact infrared temperature measuring device, a thermal imager or a contact temperature sensor.

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