JPH0749364A - Heater disconnection detector in temperature controller - Google Patents

Abstract

PURPOSE:To provide a heater disconnection detector in a temperature controller which individually executes equivalent of heater disconnection detection function without the use of a current transformer CT. CONSTITUTION:Heaters 2, 2,... which heat a to-be-heated body 1, temperature sensors 3, 3,... which generate the output corresponding to the temperature of the to-be-heated body 1, and switching elements 8, 8,... which on/off-control the power supply for the heaters so that, by comparing actual temperature of the to-be-heated body 1 detected with output from the temperature sensors 3 with a preset temperature for the to-be-heated body, the temperature of the to-be-heated body 1 be the preset temperature are provided in a temperature control device, and relating to the device, a circuit that outputs heater disconnection signal when on-state of the switching elements, while the temperature control device is in operation, is longer than the preset time corresponding to heater disconnection is provided, or otherwise, heater disconnection signal is outputted when the output characteristics from the temperature sensor, while the temperature controller is in operation, is different from that when the heater is on.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a temperature control device for heating an object to be heated to a preset temperature using a heater,
For example, the present invention relates to a heater disconnection detection device in a temperature control device that uses a large number of heaters such as cylinder heating in an injection molding machine.

[0002]

2. Description of the Related Art Conventionally, in a temperature control device for heating an object to be heated to a preset temperature by using a plurality of heaters of this kind, when the number of heaters is large, even if one heater is disconnected, Since the temperature of the heating element rises as it is, the work may proceed as it is, but in that case, there is a drawback that the quality of the product deteriorates due to uneven temperature of the heating element. 56-222
The device described in Japanese Patent No. 9 is known. That is,
FIG. 5 shows a disconnection detection circuit of an electric heater group in which a plurality of electric heaters of various capacities are connected. 101
Is a thermometer inserted into the controlled object, 102 is its controller, and 103 is an electromagnetic contactor that opens and closes according to the signal of the controller. Reference numeral 104 is a heater group attached to the controlled object, 105 is a control transformer, and 107 is a proportional / integral amplifier 1.
12 is a constant voltage power supply unit provided so as not to malfunction the relay 113. The load current of the heater portion 104 is detected by the control current transformer 106, full-wave rectified by the rectifier 109, and the current is converted into a voltage by the resistor 111.
On the other hand, the power supply side voltage is stepped down by the control transformer 105, full-wave rectified by the rectifier 108, and applied to the setting resistor 110. The setting voltage of the setting resistor 110 is adjusted so as to have the same value as the voltage generated by the resistance of the resistor 111 when the heater is not broken, and the difference between the power supply side voltage and the load side voltage is proportional / integral amplifier. The polarities of the rectifiers 108 and 109 are opposite to each other so that they are input to 112.

Now, when a part of the heater group 104 is broken,
The relay 113 operates, the contact 117 is turned on, and the alarm buzzer 115 and the alarm lamp 114 issue a disconnection alarm.
The contact point 116 is an auxiliary contact point of the electromagnetic contactor 103 and is connected in series with the contact point 117 at this time. Therefore,
The disconnection is to be detected only when the electromagnetic contactor 103 is closed, that is, when the load is on. The control relay 118 is self-held by its contact 119, and continuously displays an alarm even when the electromagnetic contactor 103 is opened.

To explain the operation, heaters often used for electric heating include a resistance heater using a resistance wire and an induction heater using induction heating by a coil. A current proportional to flows. As shown in FIG. 5, if the voltage entering the proportional-integral amplifier 112 is δV and the load current is I, then δV = V ₂ −V ₁ (1) V ₂ ∝V ₀ , I ∝V ₀・ ・ ・ (2) V ₁ ∝I ・ ・ ・ (3) From formulas (2) and (2) V ₁ ∝V ₀・ ・ ・ (4) Also, formula (1) , (2) and (4), δV = V ₂ −V ₁ = kV ₀ (5) That is, the equation (5) is an input to the proportional-integral amplifier 112.

[0005] Now, V ₂ = V ₁ and so as to set the resistor 1
When 10 is set, when the wire breakage occurs in a part of the heater group at a certain moment, the load current I naturally decreases, and V decreases accordingly. However, the setting resistor 110 is V ₂ −V ₁
Since it is set so that = 0, a signal of (V ₂ −V ₁ )> 0 naturally enters the proportional / integral amplifier 112 due to the disconnection of a part of the heater group. Proportional / integral amplifier 112
Since the output has 1 when the input is positive, the relay 113 operates to display the disconnection alarm. Further, even if the power supply voltage V ₀ fluctuates, since V ₁ and V ₂ are both proportional to V ₀ as shown in equations (2) and (4), if the heater is disconnected, the power supply The disconnection alarm is always issued regardless of voltage fluctuations.

As is clear from the above description, the conventional heater burnout detector has a simple circuit, and one heater in a circuit where a large number of heaters are connected in parallel appears to be burnt out. It can be sensitive to a slight change in current,
This has the effect of preventing false alarms and malfunctions due to fluctuations in the power supply voltage. When the load shown in FIG. 6 is three-phase, two heater burnout detectors 120 are used as shown. Other configurations, operations and effects are the same as those in the case where the load in FIG. 5 is a single phase.

[0007]

However, in this type of device, in order to detect heater breakage, the current is monitored by the current transformer CT.
A heater break must be detected. Since only one current transformer CT is attached to several heater groups, it is impossible to identify which heater is broken. Therefore, in actuality, in order to individually identify abnormal heaters, it is necessary to individually install the current transformer CT for each heater, which has a disadvantage of requiring considerable cost and space.

The present invention has been proposed in view of such circumstances, and heater breakage detection in a temperature control device capable of individually performing an equivalent function of heater breakage detection without using a current transformer CT. The purpose is to provide a device.

[0009]

To this end, the invention of claim 1 is directed to a heater for heating an object to be heated, a temperature sensor for generating an output corresponding to the temperature of the object to be heated, and an output from the temperature sensor. It is equipped with a switching element that compares the actual temperature of the heated object with a preset temperature of the heated object and controls ON / OFF of power supply to the heater so that the heated object reaches the set temperature. The temperature control device is provided with a circuit for outputting a heater disconnection signal when the ON state of the switching element in the temperature control device operating state is longer than a preset time corresponding to the heater disconnection.

The invention according to claim 2 is a heater for heating an object to be heated, a temperature sensor for generating an output corresponding to the temperature of the object to be heated, and an object to be heated detected by the output from the temperature sensor. In a temperature control device equipped with a switching element that compares the actual temperature with a preset temperature of the heated object and controls ON / OFF of power supply to the heater so that the heated object reaches the set temperature, It is characterized in that a circuit for outputting a heater disconnection signal is provided when the output characteristic from the temperature sensor in the control device operating state is different from the output characteristic when the heater is in the on state.

[0011]

In this structure, when the temperature control device is activated, the heater is turned on and the temperature of the heated object to be controlled rises to the set temperature. Although the output from the temperature sensor changes according to this temperature rise, for example, it rises, if the heater is disconnected, the output of the temperature sensor does not rise because the object to be heated is not heated. If one of the wires is broken, the temperature rise of the object to be heated is slow, and the output rise of the temperature sensor is also slow.

As a result, in the former case, the on-time of the switch ig element including the electromagnetic contactor becomes longer than the on-time when the heater is not disconnected. Therefore, the heater disconnection signal is output when the on time of the switch ig element is longer than the preset time corresponding to the heater disconnection, for example, the switch ig element on time when the heater is not disconnected. This makes it possible to identify which heater is broken. In the latter case, the output characteristic from the temperature sensor when the heater is not disconnected is stored in advance, and the heater disconnection signal is output when the output characteristic from the temperature sensor is different from the output characteristic when the heater is not disconnected. In this case also, the abnormal heater can be individually identified.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring to the drawings, an embodiment in which the present invention is applied to a cylinder heating temperature control device of an injection molding machine will be described with reference to FIG.
Is an overall circuit diagram of the temperature control device of the first embodiment, FIG. 2 is an ON / OFF characteristic diagram of each relay contact of FIG. 1, FIG. 3 is an output characteristic diagram of each temperature sensor of the second embodiment of the present invention, 4 is shown in FIG.
3 is a flowchart of the temperature control of FIG.

First, in FIGS. 1 and 2, the heated body 1 corresponds to the heater 2 for heating the heated body 1 and the temperature of the heated body 1 at the position of each heater 2 for each heater 2. A temperature sensor 3 for generating an output is attached. The output from the temperature sensor 3 is input to the temperature controller 4 and compared with the preset temperature stored in the memory 6 via the CPU 5 of the computer, and the actual temperature of the heated object 1 is set in advance. When the temperature is lower than the set temperature of 1, the power source 9 is supplied to the heater 2 via the relay 7 and the relay contact 8 of the switching element.

On the other hand, the actual temperature of the object to be heated 1 detected by the output from the temperature sensor 3 is compared with the preset temperature of the object to be heated 1 so that the object to be heated 1 reaches the set temperature. In addition, the ON state of the relay contact 8 in the operating state of the temperature control device 10 for controlling ON / OFF of the power supply to the heater 2 via the relay 7 and the relay contact 8
When the installation time stored in advance in the memory 6 of the computer corresponding to the heater 2 disconnection, for example, longer than the ON time of the relay contact 8 set corresponding to the temperature rise of the heated body 1 when the heater 2 is not disconnected Then, the disconnection signal of the heater 2 is output from the computer.

In the temperature control device 10 thus constructed, when the temperature control device 10 is operated, the heater 2 is turned on via the relay 7 and the relay contact 8 so that the temperature of the heated object 1 to be controlled is the set temperature. Rise to become. The output from the position-dependent temperature sensor 3 of each heater 2 changes, for example, increases in accordance with this temperature increase. However, when the heater 2 is disconnected, the object to be heated 1 is not heated, so the temperature sensor 3 Output does not rise, and multiple heaters 2
If one of the centers of the two is disconnected, the temperature rise of the heated body 1 at the disconnection position and the temperature rise of the output of the temperature sensor 3 are also affected. As a result, the ON time of the relay contact 8 for controlling ON / OFF of the heater 2 at the disconnection position is set to the set time stored in the memory 6 of the computer as shown in FIG. 2, that is, the relay contact when the heater 2 is not disconnected. 8 is longer than the ON time, and the heater disconnection signal is output from the computer.

In the case of the present embodiment, after the energization is started, the CPU 5 of the computer calculates the cumulative time t _i , t _j , t _k of the ON state of each heater 2 at a certain time t _s and stores it in the memory 6 of the computer. After that, during the energization time, the cumulative times T _i , T _j , and T _k of a certain time t _s of each heater 2 are calculated constantly or periodically, and the values are stored in the memory 6 of the computer in advance. It is checked whether or not there is something exceeding the allowable range by comparing with the set value, and the heater 2 exceeding the allowable range is disconnected and an alarm is issued.

Next, FIGS. 3 to 4 show a second embodiment of the present invention. In this case, as shown in FIG. 3, a change in the output of the temperature sensor 3 for each heater 2 (in this case, the center of the temperature sensor 3). The configuration, action, and effect are almost the same as those of the first embodiment except that the heater 3 disconnection) is controlled by a computer according to the flowchart shown in FIG. That is, step S1 shown in FIG.
At the output characteristic section of the temperature sensor 3 at t ₁
The temperature data of all the sensors 3 are sampled every Δt and stored in the memory TM1.
After it, in step S3, the temperature data of all the sensors 3 are sampled for each Δt in the section of the output characteristic of the temperature sensor 3 from time t ₂ and stored in the memory TM2. In the state in which the temperature data is sampled in this way, the temperature data at the same sensor and the same time stored in the memories TM1 and TM2 are read in step S4, and the patterns are compared in step S5. When the pattern comparisons are the same, since there is no disconnection, the M2 data is copied (updated) to TM1, and then control is continued returning to step S2. When the pattern comparisons are not the same in step S5, there is a disconnection. In the step, the disconnection alarm is issued and the operation of the entire control of the heater 2 is stopped.

[0019]

In summary, according to the first and second aspects of the present invention, the heater disconnection detection in the temperature control device is capable of individually exhibiting the equivalent function of the heater disconnection detection without using the current transformer CT. Since the device is obtained, the present invention is extremely useful in industry.

[Brief description of drawings]

FIG. 1 is an overall electric circuit diagram of a temperature control device 10 according to a first embodiment of the present invention.

FIG. 2 is an ON / OFF characteristic diagram of each relay contact 9 in FIG.

FIG. 3 is an output characteristic diagram of each temperature sensor 3 according to the second embodiment of the present invention.

FIG. 4 is a flowchart of temperature control in FIG.

FIG. 5 is an electric circuit diagram of a temperature control device in a plurality of heaters for heating a cylinder of a conventional injection molding machine.

FIG. 6 is an electric circuit diagram of a temperature control device for a plurality of heaters using a conventional three-phase power supply.

[Explanation of symbols]

 1 Heated Object 2 Heater 3 Temperature Sensor 4 Temperature Controller 5 CPU 6 Memory 7 Relay 8 Relay Contact 9 Power Supply 10 Temperature Control Device

Claims (2)

[Claims] 1. A heater for heating an object to be heated, a temperature sensor for generating an output corresponding to the temperature of the object to be heated, and an actual temperature of the object to be heated detected by an output from the temperature sensor are preset. A temperature control device comprising: a switching element that compares the set temperature of a heated object with ON / OFF control of power supply to a heater so that the heated object reaches a set temperature; A heater disconnection detecting device in a temperature control device, comprising a circuit for outputting a heater disconnection signal when the ON state of the heater is longer than a preset time corresponding to the heater disconnection. 2. A heater for heating an object to be heated, a temperature sensor for generating an output corresponding to the temperature of the object to be heated, and an actual temperature of the object to be heated detected by an output from the temperature sensor are preset. In a temperature control device comprising a switching element for comparing the set temperature of a heated object with a heating element to control ON / OFF of power supply so that the heated object reaches a set temperature, a temperature sensor in an operating state of the temperature control device A heater burnout detecting device in a temperature control device, comprising a circuit for outputting a heater burnout signal when the output characteristic from the heater is different from the output characteristic when the heater is in the ON state.