KR102544843B1 - Protection device for heating jacket - Google Patents

Abstract

A heating jacket protection device supplies power for each channel under the control of a temperature controller and cuts off the power supply for each channel according to a warning signal. The heating jacket protection device includes a plurality of non-contact relays respectively corresponding to a plurality of channels and supplying first-phase alternating current, a plurality of switching relays corresponding to each of the plurality of channels and supplying second-phase alternating current, and the plurality of relays. receives one of a plurality of types of warning signals from one of a plurality of temperature controllers respectively corresponding to a channel of , and outputs a switching off signal to a switching relay of a channel corresponding to the received warning signal among the plurality of channels; and a signal splitter outputting a warning display signal indicating the type of one warning signal.

Description

Heating jacket protection device {Protection device for heating jacket}

The present invention relates to a heating jacket protection device.

In general, gas piping used in semiconductor, display, chemical processes, etc. is a facility for removing gas generated during the process. High-temperature gas in a gaseous state can smoothly pass through the gas pipe. However, as the time passing through the gas pipe increases, the temperature of the gas may decrease, and at a low temperature, the gas may sublimate into a solid and be adsorbed on the inner wall of the gas pipe. As a result, the pressure in the gas pipe increases, and exhaust efficiency may decrease.

To solve this problem, a heating jacket is installed outside to enclose the gas pipe. The heating jacket heats the gas pipe to maintain a constant temperature inside the gas pipe. Accordingly, deterioration in exhaust efficiency due to gas adsorption can be prevented.

The heating jacket temperature controller is a device for maintaining a constant temperature of the heating jacket, and includes one or more temperature control units (TCUs). A thermocouple element (Thermo Couple, TC) is installed between the gas pipe and the heating jacket to detect the temperature. The temperature control device compares the detected temperature with a set temperature and supplies or cuts power to the heating jacket. The heating jacket protection circuit includes a first relay supplying/cutting off power under the control of a temperature controller and a second relay supplying/cutting off power according to a warning signal from the temperature controller.

It is intended to provide a heating jacket protection device capable of reducing the number of required parts and miniaturizing by converting an analog operating method into a digital operating method.

On the other hand, it is intended to provide a heating jacket protection device that can be expanded or reduced according to the required number of channels.

In addition, it is intended to provide a heating jacket protection device having application compatibility that can be operated regardless of the type of temperature controller.

A heating jacket protection device supplies power for each channel under the control of a temperature controller and cuts off the power supply for each channel according to a warning signal. The heating jacket protection device includes a plurality of non-contact relays respectively corresponding to a plurality of channels and supplying first-phase alternating current, a plurality of switching relays corresponding to each of the plurality of channels and supplying second-phase alternating current, and the plurality of relays. receives one of a plurality of types of warning signals from one of a plurality of temperature controllers respectively corresponding to a channel of , and outputs a switching off signal to a switching relay of a channel corresponding to the received warning signal among the plurality of channels; and a signal splitter outputting a warning display signal indicating the type of one warning signal.

In one embodiment, the heating jacket protection device includes a main protection device for supplying power to a first channel group among the plurality of channels, and a sub protection device for supplying power to a second channel group among the plurality of channels. can do.

In one embodiment, the main protection device transmits the switching off signal to the non-contact relay and the switching relay belonging to the first channel group, and the switching relay belonging to the first channel group and the second channel group. and a main printed circuit board on which a signal distributor for outputting is disposed, and the sub protection device includes a sub printed circuit board on which the contactless relay and the switching relay belonging to the second channel group are disposed, and the signal distributor may output the switching off signal to a switching relay belonging to the second channel group through a signal cable and output a warning display signal indicating the type of the received warning signal.

In one embodiment, the main protection device, the contactless relay and the switching relay belonging to the first channel group, and a first signal distributor for outputting the switching off signal to the switching relay belonging to the first channel group and a main printed circuit board on which is disposed, and the sub protection device transmits the switching off signal to the non-contact relay and the switching relay belonging to the second channel group, and the switching relay belonging to the second channel group. and a sub printed circuit board on which a second signal distributor for outputting is disposed, wherein the second signal distributor may output a warning display signal representing the type of the received warning signal to the first signal distributor through a signal cable. there is.

In one embodiment, the signal distributor may include a plurality of switching-off signal generators respectively corresponding to the plurality of temperature controllers, receiving all of the warning signals of the plurality of types and outputting the switching-off signal; and It may include a plurality of warning display signal generators respectively corresponding to warning signals, receiving warning signals of the same type from the plurality of temperature controllers and outputting the warning display signals.

According to the embodiments of the present invention, the number of components required for the heating jacket protection device is reduced and the structure is simplified, so the manufacturing cost and time required for the heating jacket temperature control device are reduced and maintenance can be facilitated.

On the other hand, the reduced number of required parts and the resulting simplified structure enable expansion according to the required number of channels, thereby providing relatively more channels than a conventional heating jacket temperature control device having the same size. .

In addition, since there is no need to change the structure of the heat jacket protection device according to the type of temperature controller, the mass productivity of the heating jacket temperature control device can be greatly improved.

Hereinafter, the present invention will be described with reference to embodiments shown in the accompanying drawings. For ease of understanding, like reference numerals have been assigned to like elements throughout the accompanying drawings. The configurations shown in the accompanying drawings are only exemplary implementations to explain the present invention, and are not intended to limit the scope of the present invention thereto. In particular, in the accompanying drawings, in order to help understanding of the invention, some components are somewhat exaggerated. Since the drawings are means for understanding the invention, it should be understood that the width or thickness of components represented in the drawings may vary in actual implementation.
1 is a view showing a conventional heating jacket temperature control device by way of example.
2 is a diagram showing a heating jacket temperature control device including a heating jacket protection device according to a preferred embodiment of the present invention by way of example.
3 is a diagram showing a heating jacket protection device according to an embodiment of the present invention by way of example.
4 is a diagram functionally illustrating the structure of a signal splitter.
5 is a view showing a heating jacket protection device according to another embodiment of the present invention by way of example.

Since the present invention can have various changes and various embodiments, specific embodiments are illustrated in the drawings and will be described in detail through detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. In particular, the functions, features, and embodiments described below with reference to the accompanying drawings may be implemented alone or in combination with other embodiments. Therefore, it should be noted that the scope of the present invention is not limited only to the forms shown in the accompanying drawings. Meanwhile, throughout the accompanying drawings, like elements are referred to using like reference numerals.

1 is a diagram showing a conventional heating jacket temperature control device by way of example, (a) a conventional heating jacket temperature control device capable of 5-channel control, (b) a conventional heating jacket temperature control device structure and It is a block diagram to explain the operation.

Referring to (a) and (b) of FIG. 1 together, a conventional heating jacket temperature control device includes a front panel 10, a heating jacket protection device 20, and a rear panel 30. On the front panel 10, a temperature controller TCU and a warning display unit 11 are disposed. The heating jacket protection device 20 includes a solid state relay (SSR) that controls the power delivered to the channel by the temperature controller TCU and blocks the power delivered to the channel by the warning signal output from the temperature controller TCU. It includes a switching relay unit 21 and an alarm relay unit 22 that outputs a display signal according to the type of warning signal. A connector for receiving power from the outside and a cable for supplying power to the heating jacket are installed on the rear panel 30 .

The temperature controller TCU adjusts the power delivered to the heating jacket by switching on or off the non-contact relay SSR according to the measured temperature. The temperature controller TCU, the non-contact relay SSR and the channel relay 21 correspond to one channel. One channel may correspond to one heating jacket, or a plurality of channels may correspond to one heating jacket. The switching relay unit 21 is composed of a plurality of relays, and the number of relays is equal to the number of warning signals output by the temperature controller TCU. The plurality of relays constituting the switching relay unit 21 may be a double pole single throw (DPST) relay or a double pole double throw (DPDT) relay. That is, the switching relay unit 21 is composed of two switches, and each switch operates by the same warning signal. When a warning signal is input, the first switch is turned off to block power delivered to the channel, and the second switch transfers a warning display signal to the alarm relay unit 22 . Here, since the voltage applied to the ends of the first and second switches is an AC voltage, the warning display signal is also an AC voltage.

The first relay of the first to fifth switching relay units 21 operates in response to a first warning signal and outputs a first warning display signal, and the second relay operates in response to a second warning signal and outputs a second warning display signal. , and the third relay is operated by the third warning signal and outputs a third warning display signal. The first warning display signals output by the first relays of the first to fifth switching relay units 21 are concentrated in the first alarm relay of the alarm relay unit 22, and the second warning display signals are transmitted to the second alarm relay. , and the third warning display signal is concentrated in the third alarm relay. An input of the alarm relay unit 22 is an AC voltage, and is output to the warning display unit 11 by the first to third warning display signals. The warning display unit 11 may include a plurality of lamps indicating the type of warning generated and a buzzer outputting a warning sound.

As described above, the conventional heating jacket protection circuit 20 required a switching relay unit 21 composed of a plurality of relays per temperature controller TCU. Therefore, when the heating jacket temperature control device includes a plurality of temperature controller TCUs, the number of relays used also increases in proportion. An increase in the number of relays used causes a lack of installation space and requires a lot of time for cable wiring connecting the installed relays. This is not only a cause of an increase in manufacturing cost, but also a cause of an increase in maintenance cost and time. In addition, since alternating current is used not only for power supplied to the heating jacket, but also for signals used for warning signal processing, safety risks exist.

2 is a diagram showing a heating jacket temperature control device including a heating jacket protection device according to a preferred embodiment of the present invention by way of example.

Referring to (a) of FIG. 2 , the heating jacket temperature control device includes a front panel 10, a heating jacket protection device 100, and a rear panel (not shown). On the front panel 10, a temperature controller TCU and a warning display unit 11 are disposed. The heating jacket protection device 100 distributes the warning signal output by the non-contact relay 110 and the temperature controller TCU to control the supply of the first-phase AC current in order to adjust the power delivered to the channel by the temperature controller TCU. and a signal distributor 120 that blocks the supply of second-phase alternating current delivered to the channel in response to a warning signal output from the temperature controller TCU.

The heating jacket protection device 100 includes the same number of non-contact relays 110 and switching relays 130 as the number of channels. The conventional heating jacket protection device 20 requires a switching relay unit 21 composed of a plurality of relays to operate according to different types of warning signals output by the temperature controller TCU and display them on the warning display unit. The number (or type) of warning signals may be different for each temperature controller TCU. Therefore, when the temperature controller TCU is replaced, the number of relays included in the switching relay unit 21 and the alarm relay unit 22 has to be changed accordingly.

Referring to (a) to (c) of FIG. 2 together, the signal distributor 120 receives warning signals output from a plurality of temperature controller TCUs, and the switching relay corresponding to the temperature controller TCU outputting the warning signal ( 130) and outputs a warning display signal indicating the type of warning signal. In order to simultaneously cut off power transmission to the channel and generate a warning signal, the relay 21a constituting the switching relay unit 21 of the conventional heating jacket protection device 20 must be a DPST relay or a DPDT relay, whereas the present invention The switching relay 130 of the heating jacket protection device 100 according to may be a single pole single throw (SPST) relay or a single pole double throw (SPDT) relay. In particular, since the terminals of the relay 21a are arranged at the bottom, wiring work is difficult. Therefore, in the conventional heating jacket protection device 20, a socket 21b having connection terminals corresponding to the number of terminals exposed on the upper surface had to be used. As will be described in detail in FIG. 3 , since the switching relay 130 is disposed on a printed circuit board (PCB), a socket occupying a considerable area can be replaced with a connector 150 for cable wiring. Due to this, since a larger number of relays can be disposed in the same space, the number of channels that the heating jacket protector 100 can provide increases.

FIG. 3 is a diagram exemplarily showing a heating jacket protection device according to an embodiment of the present invention, and is an example of implementing the heating jacket protection device functionally shown in FIG. 2 with a PCB.

Referring to FIG. 3 , the heating jacket protection device 100 includes a main protection device 100m and a sub protection device 100s. Among the plurality of channels controlled by the heating jacket protector 100, the first channel group, for example, the first to third channels are controlled by the main protector 100m, and the second channel group, for example , The fourth to sixth channels are controlled by the sub protection device 100s. A channel is composed of one non-contact relay 110 and one switching relay 130. Here, the main protection device 100m receives all of the warning signals AL ₁ to AL _m for the first channel group and the second channel group, and switches off according to the warning signals AL ₁ to AL _m for the second channel group. The signal is transmitted to the sub protection device 100s through the signal cable 160.

The main protection device 100m includes a main PCB 101m, a non-contact relay 110, a signal distributor 120, a switching relay 130, a DC generator 140 and a connector 150. The sub protection device 100s includes a sub PCB 101s, a non-contact relay 110, a switching relay 130, and a connector 150. The non-contact relay 110, the signal distributor 120, the switching relay 130, the DC generator 140, and the connector 150 are electrically connected to the main PCB 101m or the sub PCB 101s.

The main PCB 101m and the sub PCB 101s are printed boards with wires electrically connecting a plurality of connectors, the non-contact relay 110, the signal distributor 120, and/or the switching relay 130. The connector includes a connector 150 for connecting to an AC power supply, as well as a connector for receiving a DC signal from the temperature controller TCU and the main protection device. In addition, the main PCB 101m and the sub PCB 101s may include a thermocouple element and a wire for transmitting a signal between the temperature controllers. Wiring printed on the main PCB 101m and the sub PCB 101s may be substantially the same.

The signal distributor 120 included in the main protection device 100m generates a switching off signal and a warning display signal in the first channel group and the second channel group, and converts the switching off signal to a warning signal among the first to nth channels. is applied to the switching relay 130 of the channel corresponding to the output temperature controller TCU. The switching relay 130 included in the first channel group receives the switching off signal directly from the signal distributor 120, and the switching relay 130 included in the second channel group receives the signal cable 160. .

The DC generator 140 converts alternating current into direct current and provides power necessary for driving the main protection device 100m and the sub protection device 100s.

4 is a diagram functionally illustrating the structure of a signal splitter.

Referring to FIG. 4 , the signal distributor 120 includes a plurality of switching off signal generators 121a and 121n and a plurality of warning display signal generators 122a and 122m.

The switching-off signal generator and the temperature controller TCU correspond one-to-one. That is, the first switching-off signal generator 121a receives all warning signals AL ₁ to AL _m output from the first temperature controller TCU, and the n-th switching-off signal generator 121n receives all warning signals AL 1 to AL m output from the first temperature controller TCU. All output warning signals AL ₁ to AL _m are input. When any one of the warning signals _AL1 to _ALm is input from the nth temperature controller TCU, the switching off signal generator 121n outputs the switching off signal Off_relay #n to the switching relay 130 of the nth channel, but the rest The n-1 switching-off signal generators do not output switching-off signals. Power supply through the nth channel may be cut off by the switching off signal Off_relay #n. Additionally, the switching off signal Off_relay #n may be transmitted to the warning display unit 11 together with the warning display signal AL_display #m. The warning display unit 11 may further include a lamp displaying a channel on which a warning has occurred.

The warning display signal generator and the warning signals AL ₁ to AL _m have a one-to-one correspondence. That is, the first warning display signal generator 122a receives all first warning signals AL 1 output from the first to nth temperature controller TCU, and the m-th warning display signal generator 122m receives the first warning display signal AL ₁ output from the first to nth temperature controller TCU. All of the m th warning signals AL _m output from the to n th temperature controller TCU may be received. When any one of the first to n th temperature controller TCU outputs the m th warning signal AL _m , the m th warning display signal generator 122m outputs the warning display signal AL_display #m, but the remaining m−1 warnings The display signal generator does not output a warning display signal. The warning display signal AL_display #m is transmitted to the warning display unit 11.

In particular, the number of warning display signal generators may be determined in consideration of the number of warning signals provided by commercially available temperature controllers. For example, the number of warning display signal generators may be determined by the type of warning signal commonly provided by the temperature controller. If the number of warning display signal generators is sufficiently large, the heating jacket protection device 100 can interoperate with virtually all types of temperature controllers.

FIG. 5 exemplarily shows a heating jacket protection device according to another embodiment of the present invention, and is an example of implementing the heating jacket protection device functionally shown in FIG. 2 with a PCB. The same description as in FIG. 3 will be omitted and only differences will be described.

Referring to FIG. 5 , the heating jacket protection device 100 includes a main protection device 102m and a sub protection device 102s. Compared to FIG. 3, the main protection device 102m and the sub protection device 102s include both signal distributors. That is, the main protection device 102m receives the warning signals AL ₁ to AL _m output to the first channel group, and the sub protection device 102s receives the warning signals AL ₁ to AL _m output to the second channel group. do. The DC generator 140 may be disposed in only one of the main protection device 102m and the sub protection device 102s, and may supply DC power to the protection device in which the DC generator is not disposed through the power cable 170 . Meanwhile, the DC generator 140 may be disposed in both the main protection device 102m and the sub protection device 102s.

The main protection device 102m includes a main PCB 103m, a non-contact relay 110, a signal distributor 120, a switching relay 130, a DC generator 140 and a connector 150. The sub protection device 102s includes a sub PCB 103s, a non-contact relay 110, a signal distributor 120, a switching relay 130, and a connector 150. The non-contact relay 110, the signal distributor 125, the switching relay 130, the DC generator 140, and the connector 150 are electrically connected to the main PCB 103m or the sub PCB 103s. The signal distributor 125 of the sub protection device 102s may output a warning display signal to the signal distributor 120 of the main protection device 102m through the signal cable 160. The signal distributor 120 may collect and process warning display signals for the first channel group and the second channel group.

The above description of the present invention is for illustrative purposes, and those skilled in the art can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. In particular, the features of the present invention described with reference to the drawings are not limited to the structures shown in the specific drawings, and may be implemented independently or in combination with other features.

The scope of the present invention is indicated by the following claims rather than the detailed description above, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts thereof should be construed as being included in the scope of the present invention. .

Claims (5)

A heating jacket protection device that supplies power for each channel under the control of a plurality of temperature controllers and cuts off the power supply for each channel according to a warning signal,
a plurality of contactless relays respectively corresponding to a plurality of channels and controlling supply of first-phase alternating current;
a plurality of switching relays respectively corresponding to the plurality of channels and blocking supply of second-phase AC current;
Receiving one of a plurality of types of warning signals from one of a plurality of temperature controllers respectively corresponding to the plurality of channels, and outputting a switching off signal to a switching relay of a channel corresponding to the received warning signal among the plurality of channels; a signal splitter outputting a warning display signal indicating the type of the received warning signal; and
A printed circuit board having a plurality of connectors connected to the plurality of temperature controllers through signal cables, and printed with wires electrically connecting the connector, the signal distributor, and the signal distributor and the plurality of switching relays, respectively. Heating jacket protection device. The method according to claim 1, wherein the heating jacket protection device,
a main protection device supplying power to a first channel group among the plurality of channels; and
A heating jacket protection device comprising a sub protection device for supplying power to a second channel group among the plurality of channels. The method of claim 2,
The main protection device includes a signal distributor for outputting the switching off signal to the non-contact relay and the switching relay belonging to the first channel group, and the switching relay belonging to the first channel group and the second channel group. It includes a main printed circuit board disposed thereon,
The sub protection device includes a sub printed circuit board on which the contactless relay and the switching relay belonging to the second channel group are disposed,
The signal distributor outputs the switching off signal to a switching relay belonging to the second channel group through a signal cable and outputs a warning display signal indicating the type of the received warning signal. The method of claim 2,
In the main protection device, the contactless relay and the switching relay belonging to the first channel group, and the first signal distributor for outputting the switching off signal to the switching relay belonging to the first channel group are disposed in the main printing device. Including a circuit board,
In the sub protection device, the non-contact relay and the switching relay belonging to the second channel group, and the second signal distributor for outputting the switching off signal to the switching relay belonging to the second channel group are arranged in the sub-printer. Including a circuit board,
The second signal distributor outputs a warning display signal indicating the type of the received warning signal to the first signal distributor through a signal cable. The method according to claim 1, wherein the signal splitter,
a plurality of switching-off signal generators corresponding to the plurality of temperature controllers, receiving all of the plurality of types of warning signals and outputting the switching-off signal; and
and a plurality of warning display signal generators respectively corresponding to the plurality of types of warning signals, receiving warning signals of the same type from the plurality of temperature controllers and outputting the warning display signals.

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