JP2020100089A - Injection nozzle temperature control method - Google Patents

Abstract

To provide a temperature control method for an injection nozzle capable of surely preventing resin burning and dripping and injecting a resin having high fluidity.SOLUTION: A temperature of an injection nozzle is controlled by first temperature control in other steps of a molding cycle, and the temperature of the injection nozzle is controlled by second temperature control that is different from the first temperature control in some steps including an injection step. For example, a first temperature sensor (14) and a second temperature sensor (15) on a tip side of the first temperature sensor are embedded in an injection nozzle (5), and the first temperature control is configured to control the temperature with the first temperature sensor (14), and the second temperature control is configured to control the temperature with the second temperature sensor (15). Alternatively, the first temperature control is configured to control the temperature with a first target temperature, and the second temperature control is configured to control the temperature with a second target temperature higher than the first target temperature.SELECTED DRAWING: Figure 2

Description

The present invention relates to a method for controlling the temperature of an injection nozzle provided at the tip of an injection device, and is not limited thereto, but for shift molding in which touch/separation of the injection nozzle with respect to a mold is repeated for each molding cycle. The present invention relates to a preferable temperature control method for an injection nozzle.

As is well known in the art, an injection molding machine includes a pair of molds, a mold clamping device that molds these molds, an injection device that melts a resin material and injects the resin material into the mold. Injection devices include plunger type and in-line screw type. In the latter case, the injection device is composed of a heating cylinder and a screw that can be driven in the rotational direction and the axial direction inside the heating cylinder, and an injection nozzle is provided at the tip of the heating cylinder. The heating cylinder and the injection nozzle are provided with a plurality of heaters, and a temperature sensor is embedded therein. The heating cylinder is heated by the heater, the screw is rotated while a predetermined back pressure is applied to the screw, and resin pellets of the material are supplied from the hopper behind the heating cylinder. Then, the resin pellets are melted in the process of being sent forward by the screw. The molten resin accumulates in front of the screw and the screw moves backward. That is, it is measured. Clamp the mold. If the injection nozzle is separated from the mold sprue, the injection nozzle touches the mold. When the screw is driven in the axial direction, the molten resin is filled in the mold cavity. A molded product is obtained by holding the pressure, waiting for cooling and solidification, and then opening the mold.

In injection molding, the temperature of the injection nozzle, that is, the resin temperature is important. For example, when the resin temperature is high, the resin viscosity is low and the fluidity is high, so that a good molded product can be obtained. However, there is a risk that the resin will burn and that the resin will leak from the injection nozzle separated from the mold during shift molding. On the other hand, if the temperature of the resin is low, there is no possibility that the resin will be burnt or dripped, but the viscosity of the resin will be high, the fluidity will be low, and the injection pressure must be increased. Furthermore, there is a risk of nozzle clogging and molding defects such as short shots. That is, there is a problem if the resin temperature in the injection nozzle is too high or too low, and it is necessary to control so that the resin temperature becomes appropriate.

JP, 2002-160276, A

Patent Document 1 describes a method of calculating a virtual temperature at an arbitrary position in an injection nozzle and controlling the virtual temperature by the virtual temperature. In order to carry out the method described in Patent Document 1, when the injection nozzle is divided into the first and second heating zones by the first and second heaters, the first to third temperature sensors are provided as follows. .. First, the first temperature sensor is provided at the end of the first heating zone. The second temperature sensor is provided near the boundary between the first and second heating zones, and the third temperature sensor is provided at the end of the second heating zone. That is, the first and second temperature sensors can measure the temperatures at both ends of the first heating zone, and the second and third temperature sensors can measure the temperatures at both ends of the second heating zone. The controller of the injection molding machine calculates a virtual temperature at an arbitrary point in the first heating zone by performing arithmetic operation with a predetermined weight from the actual temperature measured by the first and second temperature sensors. Similarly, from the actual temperatures measured by the second and third temperature sensors, a virtual temperature at an arbitrary point in the second heating zone is calculated by performing a predetermined weighting operation. The first and second heating zones are feedback-controlled by the virtual temperature at the arbitrary position calculated in this way. That is, the virtual temperature can be estimated even in the portion where the temperature sensor is not provided, and the temperature can be appropriately controlled.

According to the temperature control method of the injection nozzle described in Patent Document 1, the virtual temperature is estimated and the temperature control is performed based on the virtual temperature. Therefore, the temperature control is performed even in a place where the temperature sensor is not provided. it can. Therefore, the resin temperature of the injection nozzle can be accurately controlled. In addition, although not particularly described, other documents also make various proposals regarding the temperature control method of the injection nozzle, and most of such control methods are as accurate as possible when a predetermined target temperature is given. The purpose is to control so as to reach the target temperature well. With such a control method, if the parameters of the PID are properly adjusted, it should be possible to accurately control the temperature so as to reach the target temperature. However, it seems that there is room to devise the temperature control method of the injection nozzle described in Patent Document 1 or other temperature control methods. Specifically, at the time of injection, the ideal resin temperature that can further reduce the resin viscosity and increase the fluidity, while surely preventing resin burning and preventing dripping during shift molding It seems that there is a control method of. In other words, there is a problem if the resin temperature is raised or lowered too much, but there is a method for controlling the resin temperature that can obtain both the advantages obtained when the resin temperature is raised and the advantages obtained when the resin temperature is lowered. It seems to be. There are other problems to be solved. Specifically, it is a countermeasure against a phenomenon in which the temperature of the injection nozzle fluctuates and temporarily falls significantly below the target temperature. The mold has a high temperature in the injection process and is cooled and has a low temperature in the pressure holding process. That is, the temperature greatly changes in the molding cycle. Since the injection nozzle touches such a sprue of the mold, when the temperature of the mold decreases, a large amount of heat is taken by the mold, and the temperature of the injection nozzle temporarily falls significantly below the target temperature. This phenomenon remarkably appears in shift molding in which the injection nozzle is repeatedly touched/separated from the mold in each molding cycle. If you touch the die with an injection nozzle that is hotter than the die, even if the temperature of the injection nozzle is kept near the target temperature by the temperature control, a large amount of heat is taken away and the temperature drops. Is. Such a phenomenon of abrupt temperature decrease of the injection nozzle occurs because a large amount of heat is temporarily taken away, so it is difficult to prevent this temperature decrease only by adjusting each parameter of the PID.

An object of the present invention is to provide a method for controlling the temperature of an injection nozzle that solves the above-mentioned problems, and specifically, an advantage obtained by a high resin temperature and a low resin temperature. Even if a large amount of heat is taken from the injection nozzle to the mold by the temperature change of the mold or by touching the mold, it is possible to obtain all of the advantages obtained by It is an object of the present invention to provide a method for controlling the temperature of an injection nozzle, which is capable of preventing a significant decrease.

The present invention is configured as a temperature control method for an injection nozzle, in which the first and second temperature controls are switched in synchronization with the molding cycle process. That is, in the other steps of the molding cycle, the temperature control of the injection nozzle is performed by the first temperature control, and in some steps including the injection step, the injection nozzle is controlled by the second temperature control different from the first temperature control. Control the temperature. The first and second temperature controls can be configured to switch the temperature sensor, for example. That is, the first temperature sensor and the second temperature sensor located on the tip side of the first temperature sensor are embedded in the injection nozzle, and the first temperature control is performed based on the temperature detected by the first temperature sensor. The second temperature control is performed so that the temperature control is performed based on the temperature detected by the second temperature sensor. Alternatively, the first and second temperature controls can be configured to switch the target temperature. That is, the first temperature control is configured to control the temperature with the first target temperature, and the second temperature control is configured to control the temperature with the second target temperature higher than the first target temperature.

Thus, in order to achieve the above-mentioned object, the invention according to claim 1 controls the temperature of the injection nozzle by the first temperature control in another step of the molding cycle, and in some steps including the injection step, The temperature control of the injection nozzle is characterized by controlling the temperature of the injection nozzle by a second temperature control different from the first temperature control, and switching the first and second temperature controls in synchronization with the process of the molding cycle. Configured as a method.
A second aspect of the present invention is the temperature control method according to the first aspect, wherein the injection nozzle includes a first temperature sensor and a second temperature sensor on a tip side of the first temperature sensor. Embedded, the first temperature control controls temperature based on the temperature detected by the first temperature sensor, and the second temperature control controls temperature based on the temperature detected by the second temperature sensor. It is configured as a method for controlling the temperature of an injection nozzle.
The invention according to claim 3 is the temperature control method according to claim 1 or 2, wherein the first temperature control is performed by a first target temperature, and the second temperature control is performed by the first temperature control. A temperature control method for an injection nozzle is characterized in that the temperature is controlled by a second target temperature higher than the first target temperature.

As described above, according to the present invention, the temperature control of the injection nozzle is performed by the first temperature control in the other process of the molding cycle, and the second temperature different from the first temperature control in some processes including the injection process. The temperature of the injection nozzle is controlled by the temperature control, and the first and second temperature controls are switched in synchronization with the process of the molding cycle. In other words, since the temperature control is switched between another process in which there is no problem even if the resin temperature is slightly different and the injection process in which the resin temperature needs to be controlled with high precision, resin burning is prevented in other processes. The temperature can be controlled, and in the injection process, the resin temperature can be accurately controlled to inject the resin having sufficient fluidity. That is, the molding can be performed with high precision. According to another invention, a first temperature sensor and a second temperature sensor on the tip side of the first temperature sensor are embedded in the injection nozzle, and the first temperature control is detected by the first temperature sensor. The temperature control is performed based on the temperature, and the second temperature control is performed based on the temperature detected by the second temperature sensor. Since the injection nozzle draws heat from the mold, a lower temperature is generally detected by the second temperature sensor on the tip side than the first temperature sensor. If the temperature is controlled based on the second temperature sensor in the injection process, the temperature of the resin inevitably becomes temporarily high. This is because the temperature detected by the second temperature sensor is low. Then, at the time of injection, a resin having a relatively high temperature and a high fluidity is injected, so that molding can be performed with high accuracy. In the other steps, the first temperature control is performed according to the temperature detected by the first temperature sensor, so the temperature of the resin does not rise and there is no problem of resin burning. In the shift molding method, there is no fear of snarling. According to still another aspect, the first temperature control is configured to control the temperature by the first target temperature, and the second temperature control is configured to control the temperature by the second target temperature higher than the first target temperature. There is. Also in this invention, since the temperature of the resin can be temporarily raised in the injection step, the fluidity of the resin is high and a good molded product can be obtained. Moreover, since the temperature of the resin only temporarily rises, there is no problem of resin burning. In the other steps, the temperature is controlled at the first target temperature, so that the temperature can be set to a relatively low temperature, and the problem of resin burning and the problem of sag in the shift molding method can be substantially completely prevented.

FIG. 3 is a front cross-sectional view showing a cross section of a part of the injection device and the mold according to the embodiment of the present invention. It is a process graph showing each process which constitutes a molding cycle, and temperature control implemented in each process.

An embodiment of the present invention will be described. The injection molding machine 1 in which the method of controlling the temperature of the injection nozzle according to the embodiment of the present invention is implemented, although only a part is shown in FIG. 1, the injection device 2 and the mold are similar to those of the conventional injection molding machine. It consists of a fastening device. The injection device 2 is composed of a heating cylinder and a screw driven in the heating cylinder in the rotational direction and the axial direction. A nozzle adapter 4 is provided at the tip of the heating cylinder, and an injection nozzle 5 is provided at the tip of the nozzle adapter 4. The injection nozzle 5 is provided with heaters 7, 7,... Like the heating cylinder so that the injection nozzle 5 can be heated. The mold clamping device is composed of, for example, a toggle type mold clamping device, and a part of the fixed-side mold 9 provided on the stationary platen of the mold clamping device is shown in FIG. A sprue 11 is formed on the stationary die 9, and a sprue bush 12 is provided on the sprue 11.

In the injection molding machine 1 according to this embodiment, the injection nozzle 5 has two temperature sensors 14 and 15 embedded therein. A first temperature sensor 14 near the root side, that is, the nozzle adapter 4, and a second temperature sensor 15 near the tip side, that is, the fixed-side mold 9. The resin temperature on the base side of the injection nozzle 5 is measured by the first temperature sensor 14, and the resin temperature on the tip side of the injection nozzle 5 is measured by the second temperature sensor 15. The injection molding machine 1 is provided with a controller 17, and the temperatures detected by the first and second temperature sensors 14 and 15 are input to the controller 17. The heaters 7 and 7 are turned on/off under the control of the controller 17.

In the injection molding machine 1 according to the present embodiment configured as above, the temperature control method of the injection nozzle according to the present invention is carried out. The temperature control method of the injection nozzle of the present invention is characterized in that the temperature control is switched during the molding cycle so that the resin temperature temporarily rises during the injection process. That is, the temperature control method of the injection nozzle of the present invention switches the temperature control for the purpose of temporarily raising the resin temperature in the injection step. However, as will be described below, when a shift molding method in which the injection nozzle 5 is separated from the mold 9 or touched is performed, the resin temperature is not necessarily higher in the injection process than in other processes. Not necessarily. However, even in this case, the effect of sufficiently suppressing the decrease in the resin temperature during the injection step can be obtained.

Now, FIG. 2 shows each step constituting a molding cycle in the shift molding method. That is, first, the ejecting device retracts the ejector pin to perform EJ return P1, and the mold clamping device performs mold closing/mold closing P2 to close the mold. A nozzle touch P3 in which the injection device 2 advances and the injection nozzle 5 touches the fixed-side mold 9 is performed, and an injection P4 in which resin is injected from the injection device 2 is performed. Pressure holding/plasticization P5 is performed, pressure holding is performed by the injection device 2, and the resin is plasticized for injection in the next molding cycle. The injection device 2 is retracted to perform the nozzle separation P6 in which the injection nozzle 5 is separated from the stationary mold 9, the mold opening device P7 is performed by the mold clamping device, and the ejector pin ejects the ejector pin to eject EJ. A molded product is obtained.

In the present invention, the temperature control of the injection nozzle is switched in the molding cycle including such a series of steps P1 to P8, but there are various methods. In the first embodiment of the present invention, the target temperature is fixed and the first and second temperature sensors 14 and 15 are switched. That is, the temperature from the first temperature sensor 14 is used as the first temperature control for the steps P1, P2, P5 to P8, and the second temperature sensor 15 is used as the second temperature control for the steps P3 and P4. PID control using the temperature of. Describing along each step of the molding cycle, first, in the EJ return P1 and the mold closing/mold closing P2, the first temperature control for performing temperature control based on the temperature from the first temperature sensor 14 is performed. The temperature from the first temperature sensor 14 is accurately controlled because the temperature near the base of the injection nozzle 5 is detected. When the nozzle touch P3 is performed, the amount of heat is taken from the injection nozzle 5 to the fixed-side mold 9 and the temperature of the injection nozzle 5 decreases. Immediately after the nozzle touch P3 or slightly earlier than the nozzle touch P3, the temperature is switched to the second temperature control and controlled by the temperature of the second temperature sensor 15. Since the fixed side mold 9 is deprived of the amount of heat, the temperature of the second temperature sensor 15 on the tip side is lower than that of the first temperature sensor 14. Since the second temperature control is controlled by the lower temperature thus detected, the temperature of the injection nozzle 5 can be quickly raised. That is, the temperature decrease of the injection nozzle 5 is suppressed as compared with the first temperature control. Alternatively, the temperature of the injection nozzle 5 temporarily rises slightly. As a result, in injection P4, a resin having high fluidity can be injected. That is, a good product can be obtained. After the injection P4, the control returns to the first temperature control. That is, the temperature is controlled by the temperature from the first temperature sensor 14. Since the temperature detected by the first temperature sensor 14 tends to be higher than the temperature detected by the second temperature sensor 15, the temperature of the injection nozzle 5 is higher than that during the second temperature control. Is controlled to be slightly lower. When the nozzle separation P6 is carried out through the pressure holding/plasticizing P5, the temperature of the resin becomes an appropriate temperature, and there is no fear of bunching. Moreover, since the resin temperature is not high, the problem of resin burning is eliminated. Mold opening P7 and EJ protrusion P8 are carried out, and the next molding cycle is started. Thereafter, the first and second temperature controls are similarly switched.

In the temperature control method for the injection nozzle according to the second embodiment of the present invention, the temperature control is switched by changing the target temperature. The temperature sensors 14 and 15 are not switched. Explaining with reference to FIG. 2, first, in the EJ return P1 and the mold closing/mold closing P2, the temperature control is performed by the first target temperature as the first temperature control. Since the first target temperature is relatively low, the resin temperature is low, and resin burning and hanning do not occur. The second temperature control is switched when the nozzle touch P3 is performed or before and after the touch. The second temperature control is controlled by the second target temperature higher than the first target temperature. Then, the resin temperature is controlled to be high. Even if the amount of heat is deprived from the injection nozzle 5 by the stationary mold 9 and the temperature of the injection nozzle 5 decreases, the decrease in temperature of the injection nozzle 5 is suppressed. Alternatively, the temperature of the injection nozzle 5 temporarily rises slightly. Therefore, in the injection P4, a resin having high fluidity can be injected and a good product can be obtained. After the injection P4, the control returns to the first temperature control. That is, the temperature is controlled by the first target temperature. Since the resin temperature is slightly lowered, the problem of resin burning is eliminated, and there is no risk of slumping when the nozzle separation P6 is performed after the pressure holding/plasticizing P5. Mold opening P7 and EJ protrusion P8 are carried out, and the next molding cycle is started. Thereafter, the first and second temperature controls are similarly switched.

The injection nozzle temperature control method according to the first and second embodiments of the present invention can be variously modified. For example, in the second embodiment, it is described that the first and second temperature sensors 14 and 15 are not switched, but they may be switched. That is, in the first temperature control, the first target temperature and the temperature from the first temperature sensor 14 are used, and in the second temperature control, the second target temperature and the temperature from the second temperature sensor 15 are used. It may be controlled. The step of switching the first and second temperature controls can also be modified. For example, although the timing for switching to the second temperature control is described as the nozzle touch P3, the timing may be switched at the timing of mold closing/mold clamping P2, or may be switched immediately before the injection P4. In any case, in the injection P4, it is sufficient that the resin temperature is sufficiently raised to inject the resin having high fluidity, and the resin temperature can be suppressed in other steps to prevent resin burning or the like. The shift molding method in which the injection nozzle 5 separates from or touches the mold 5 in the molding cycle has been described as an example. However, in the molding method in which the molding cycle is performed while the injection nozzle 5 continues to touch the mold 5. Even if there is, the temperature control method of the injection nozzle according to the present invention can be implemented.

1 Injection Molding Machine 2 Injection Device 4 Nozzle Adapter 5 Injection Nozzle 7 Heater 9 Fixed Side Mold 11 Sprue 12 Sprue Bushing 14 First Temperature Sensor 15 Second Temperature Sensor

The present invention is configured as a temperature control method for an injection nozzle, in which the first and second temperature controls are switched in synchronization with the molding cycle process. That is, in other steps of the molding cycle, the temperature control of the injection nozzle is performed by the first temperature control, and in some steps including the injection step, the injection nozzle is controlled by the second temperature control different from the first temperature control. Control the temperature. Temperature control of the first and second is to switch the temperature sensor. That is, the first temperature sensor and the second temperature sensor located on the tip side of the first temperature sensor are embedded in the injection nozzle, and the first temperature control is performed based on the temperature detected by the first temperature sensor. The second temperature control is performed so that the temperature control is performed based on the temperature detected by the second temperature sensor. Then, the first and second temperature controls can be configured to switch the target temperature. That is, the first temperature control is configured to control the temperature based on the first target temperature, and the second temperature control is configured to control the temperature based on the second target temperature higher than the first target temperature.

Thus, in order to achieve the above-mentioned object, the invention according to claim 1 controls the temperature of the injection nozzle by the first temperature control in another step of the molding cycle, and in some steps including the injection step, In the temperature control method, wherein the temperature of the injection nozzle is controlled by a second temperature control different from the first temperature control, and the first and second temperature controls are switched in synchronism with the process of the molding cycle . A first temperature sensor and a second temperature sensor on the tip side of the first temperature sensor are embedded, and the first temperature control controls the temperature based on the temperature detected by the first temperature sensor, The second temperature control is performed as a temperature control method for the injection nozzle , which is characterized in that the temperature control is performed based on the temperature detected by the second temperature sensor .
The invention according to claim 2 is the temperature control method according to claim 1 , wherein the first temperature control is performed by a first target temperature, and the second temperature control is performed by the first temperature control. The temperature is controlled by a second target temperature higher than the target temperature, which is a method of controlling the temperature of the injection nozzle.

As described above, according to the present invention, the temperature control of the injection nozzle is performed by the first temperature control in the other process of the molding cycle, and the second temperature different from the first temperature control in some processes including the injection process. The temperature of the injection nozzle is controlled by the temperature control, and the first and second temperature controls are switched in synchronization with the process of the molding cycle. In other words, since the temperature control is switched between another process in which there is no problem even if the resin temperature is slightly different and the injection process in which the resin temperature needs to be controlled with high precision, resin burning is prevented in other processes. The temperature can be controlled, and in the injection process, the resin temperature can be accurately controlled to inject the resin having sufficient fluidity. That is, the molding can be performed with high precision. According to the present invention, a first temperature sensor and a second temperature sensor on the tip side of the first temperature sensor are embedded in the injection nozzle, and the first temperature control is performed by the temperature detected by the first temperature sensor. And the second temperature control is performed based on the temperature detected by the second temperature sensor. Since the injection nozzle draws heat from the mold, a lower temperature is generally detected by the second temperature sensor on the tip side than the first temperature sensor. When the temperature control is performed based on the second temperature sensor in the injection process, the temperature of the resin inevitably becomes temporarily high. This is because the temperature detected by the second temperature sensor is low. Then, at the time of injection, a resin having a relatively high temperature and a high fluidity is injected, so that molding can be performed with high accuracy. In the other steps, the first temperature control is performed according to the temperature detected by the first temperature sensor, so the temperature of the resin does not rise and there is no problem of resin burning. In the shift molding method, there is no fear of snarling. According to another invention, the first temperature control is configured to control the temperature with the first target temperature, and the second temperature control is configured to control the temperature with the second target temperature higher than the first target temperature. .. Also in this invention, the temperature of the resin can be temporarily raised in the injection step, so that the fluidity of the resin is high and a good molded product can be obtained. Moreover, since the temperature of the resin only temporarily rises, there is no problem of resin burning. In the other steps, the temperature is controlled at the first target temperature, so that the temperature can be set to a relatively low temperature, and the problem of resin burning and the problem of sag in the shift molding method can be substantially completely prevented.

Claims (3)

The temperature of the injection nozzle is controlled by the first temperature control in another step of the molding cycle, and the temperature of the injection nozzle is controlled by the second temperature control different from the first temperature control in some steps including the injection step. Is controlled and the first and second temperature controls are switched in synchronism with the process of the molding cycle. The temperature control method according to claim 1, wherein a first temperature sensor and a second temperature sensor on the tip side of the first temperature sensor are embedded in the injection nozzle,
The first temperature control may be temperature control based on a temperature detected by the first temperature sensor, and the second temperature control may be temperature control based on a temperature detected by the second temperature sensor. A method for controlling the temperature of an injection nozzle, comprising: It is a temperature control method of Claim 1 or 2, Comprising: The said 1st temperature control temperature-controls by a 1st target temperature, The said 2nd temperature control is a 2nd higher temperature than the said 1st target temperature. A method for controlling the temperature of an injection nozzle, wherein the temperature is controlled according to a target temperature.

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