KR101272078B1 - Heater jacket monitoring device and heater jacket with the same - Google Patents

Abstract

PURPOSE: A heater jacket monitoring device and a heater jacket including the same are provided to easily detect a heater jacket whose wire is disconnected in a system consisting of multiple heater jackets connected in series with an adjacent heater jacket. CONSTITUTION: A heater jacket monitoring device includes a first diode(37), a first light source(41) and a first resistance(45) which are electrically connected in series and compose a first monitoring unit(36) connected in series to a heating element(14) of a heater jacket. If the heating element(14) of a heater jacket is electrically disconnected, the first light source does not emit light although a power supply is connected to the heater jacket.

Description

Heater jacket monitoring device and heater jacket with the same

TECHNICAL FIELD The present invention relates to a heater jacket, and more particularly, to a mechanism for monitoring the heater jacket for disconnection and the resulting malfunction, and a heater jacket having the same.

Liquids or gases transported through pipes or tubes in a semiconductor liquid crystal manufacturing process or chemical product manufacturing process may become solid and close the pipe or tube if they are not maintained above a certain temperature, which may cause product defects. Therefore, a heater jacket is used to wrap the pipe or tube so that the temperature inside the pipe or tube can be kept constant.

Typically, because the path of the pipe or tube is long and bent more than once, a plurality of heater jackets are arranged and connected in the length direction of the pipe or tube. Each heater jacket has a heating element that generates heat by electric energy therein, and the heating element of each heater jacket is connected in series with the heating element of an adjacent heater jacket. For example, a heating element such as a heating wire consumes a lot of power, and often disconnection may occur. However, when a problem occurs in the heating element inside any one heater jacket among a plurality of heater jackets connected to each other, all the heater jackets connected in series do not work. Find a heater jacket. Therefore, after-sales time and cost are increased.

The present invention provides a heater jacket monitoring mechanism capable of easily grasping a heater jacket having an internal disconnection in a system including a plurality of heater jackets connected in series with adjacent heater jackets, and a heater jacket having the same.

In addition, in a system having a plurality of heater jackets connected in series with adjacent heater jackets, when an internal disconnection occurs in any heater jacket, the heater jacket monitoring mechanism configured to operate normally before the heater jacket is connected to the power source And it provides a heater jacket having the same.

The present invention is installed on the heater jacket to indicate whether the heating element inside the heater jacket is electrical disconnection, and has a first diode, a first light source, and a first resistor electrically connected in series with each other, the heater jacket A heater jacket having a first monitoring unit electrically connected in series with a heating element of the heater jacket, wherein the first light source does not emit light even when power is connected to the heater jacket when the heating element of the heater jacket is electrically disconnected. Provide monitoring mechanisms.

In addition, the present invention surrounds the outer circumferential surface of the flow path to insulate and maintain the housing, a heating element provided inside the housing to generate heat generated by electrical energy, and a heater jacket monitoring mechanism for notifying whether the heating element is electrically disconnected. It provides a heater jacket having a.

The heater jacket monitoring mechanism of the present invention includes a second diode, a second light source, and a second resistor, which are electrically connected in series with each other, and are electrically connected in series with a heating element of the heater jacket and the first monitoring unit. And a second monitoring unit electrically connected in parallel, and may be configured such that the second light source does not emit light even when power is connected to the heater jacket when the heating element of the heater jacket is electrically disconnected. have.

The first light source and the second light source may be mounted one by one on an upper printed circuit board (PCB) and a lower PCB arranged parallel to each other.

In the case where another heater jacket is interposed between the power source and the heater jacket so that the heating element of the other heater jacket is connected to the power source in advance of the heating element of the heater jacket, when the heating element of the other heater jacket is electrically disconnected, the heater jacket All light sources of the monitoring mechanism can be configured to not emit light.

When another heater jacket is connected behind the heater jacket so that the heating element of the other heater jacket is connected to the power supply behind the heating element of the heater jacket, the heating element of the heater jacket is disconnected even though the heating element of the other heater jacket is electrically disconnected. If not disconnected, all the light sources of the heater jacket monitoring mechanism can be configured to emit light.

The light source provided in the heater jacket monitoring mechanism may be a light emitting diode (LED).

The heater jacket monitoring mechanism may be embedded in a connector that connects to another heater jacket.

According to the present invention, it is possible to easily find only a heater jacket in which internal disconnection occurs in a system in which a plurality of heater jackets are connected in series through whether the lamp of the heater jacket monitoring mechanism provided for each heater jacket is blinking.

In addition, according to the present invention, even if an internal break occurs in some heater jackets in a system in which a plurality of heater jackets are connected in series, the heater jackets connected to the power source in advance of the heater jacket operate normally. Therefore, it is possible to reduce the damage area and the amount of damage caused by the failure of the heater jacket than when all the heater jackets are inoperative.

1 is a perspective view illustrating a heat insulating system configured by connecting a plurality of heater jacket monitoring mechanisms and a heater jacket having the same according to a first embodiment of the present invention.
2 is a side view schematically showing the heater jacket monitoring mechanism of FIG.
3 and 4 are plan views illustrating the upper PCB and the lower PCB of FIG. 2, respectively.
5 is a schematic circuit diagram of the thermal insulation system of FIG. 1.
6 is a perspective view illustrating a heat insulating system configured by connecting a plurality of heater jacket monitoring mechanisms and a heater jacket including the heater jacket according to a second embodiment of the present invention.
FIG. 7 is a side view schematically showing the heater jacket monitoring mechanism of FIG. 6.
8 and 9 are plan views illustrating the upper PCB and the lower PCB of FIG. 7, respectively.
FIG. 10 is a schematic circuit diagram of the thermal insulation system of FIG. 6.

Hereinafter, a heater jacket monitoring mechanism according to an embodiment of the present invention, and a heater jacket having the same will be described in detail with reference to the accompanying drawings. The terminology used herein is a term used to properly express the preferred embodiment of the present invention, which may vary depending on the intention of the user or operator or the custom of the field to which the present invention belongs. Therefore, the definitions of the terms should be made based on the contents throughout the specification.

1 is a perspective view illustrating a heat insulating system configured by connecting a plurality of heater jacket monitoring mechanisms and a heater jacket having the same according to a first embodiment of the present invention. Referring to FIG. 1, a thermal insulation system for preventing a temperature drop of a flow path formed of a pipe 1 is connected along the pipe 1, and includes a plurality of heater jackets that surround and insulate an outer circumferential surface of the pipe 1. 10A and 10B are provided. Each heater jacket 10A, 10B is provided with the housing 12A, 12B and the heat generating body 14 inside the housing 12A, 12B. The heating element 14 generates heat when electric energy is supplied, and may be, for example, a heating wire.

The heater jacket 10A disposed at the far right of the plurality of heater jackets 10A and 10B has a power supply having a power plug 27 capable of receiving a 220V AC voltage and a pair of wires 24 and 25 connected thereto. It is electrically connected to the connection unit 23, and the remaining heater jackets 10A, 10B are connected in a line. The leftmost heater jacket 10B of the plurality of heater jackets 10A and 10B further includes a female connector 20 to be electrically connected to an adjacent heater jacket 10A, and the remaining heater jackets 10A are provided. Each of the male connector 16 and the female connector 20 is provided. The male connector 16 is provided at the other end of the power connection unit 23 having the power plug 27 at one end thereof to be electrically connected to the heater jacket 10A disposed at the rightmost side.

The male connector 16 and the female connector 20 of the adjacent heater jackets 10A and 10B are connected, and the female connector 20 and the male connector of the power connection unit 23 of the heater jacket 10A disposed at the rightmost side. If 16 is connected and the power plug 27 is plugged into a socket for power supply (not shown), the heat generating elements 14 of each heater jacket 10A, 10B are connected in series and generate heat by electric energy. The male connector 16 is provided with a hook 17 (see FIG. 2) so as not to be inadvertently released after being engaged with the female connector 20. On the other hand, Figure 1 is shown a thermal insulation system having four heater jackets (10A, 10B), the invention is not limited to the number of heater jackets (10A, 10B) connected.

FIG. 2 is a side view schematically showing the heater jacket monitoring mechanism of FIG. 1, FIGS. 3 and 4 are plan views respectively showing the upper PCB and the lower PCB of FIG. 2, and FIG. 5 is a schematic view of the thermal insulation system of FIG. 1. It is a circuit diagram. 2 to 5, each male connector 16 indicates whether the heating element 14 (see FIG. 1) provided in each heater jacket 10A (see FIG. 1) is electrically disconnected. The heater jacket monitoring mechanism 30 is embedded. In circuit view, the heater jacket monitoring mechanism 30 includes a first diode having a first diode 37, a first light source 41, and a first resistor 45 electrically connected in series with each other. A monitoring unit 36 and a second diode 39, a second light source 43, and a second resistor 47, which are electrically connected in series with each other similarly to the first monitoring unit 36, are provided. The second monitoring unit 38 is provided. The 1st monitoring unit 36 and the 2nd monitoring unit 38 are electrically connected in series with the heat generating body 14 of the heater jacket 10A (refer FIG. 1) to which it belongs, respectively. However, the first monitoring unit 36 and the second monitoring unit 38 are electrically connected in parallel. The first light source 41 and the second light source 43 are, for example, light emitting diodes (LEDs). In addition, the magnitudes of the first resistor 45 and the second resistor 47 are, for example, 56 K ?.

Structurally, the heater jacket monitoring mechanism 30 has an upper printed circuit board (31) and a lower PCB (32) arranged in parallel inside the male connector (16), and the first light source (41). Is mounted on the upper PCB 31, and the second light source 43 is mounted on the lower PCB 32. The male connector 16 is provided with a transparent or open window (not shown) so that the light can be projected to the outside when the first light source 41 and the second light source 43 emit light. The upper PCB 31 is provided with first and second terminals 33 and 35, and the first and second terminals 33 and 35 are electrically connected to the lower PCB 32.

In addition, the male connector (20) from the female connector (20) fastened to the male connector (16) and the pair of wires (24, 25) introduced into the male connector (16) from the heater jacket (10A) to which the male connector (16) belongs. The pair of wires 24 and 25 introduced into the 16 are connected through the first terminal 33 and the second terminal 35. Specifically, the wire 24 directly connected to the heating element 14 may be connected through the first terminal 33, and the other wire 25 may be connected through the second terminal 35. In addition, the first and second diodes 37 and 39 and the first and second resistors 45 and 47 are properly arranged to form the circuit shown in FIG. 5 on the upper PCB 31 and the lower PCB 32. Can be. For example, as illustrated in FIG. 3, a first light source 41, a first resistor 45, a first terminal 33, and a second terminal 35 may be mounted on the upper PCB 31. As shown in FIG. 4, the lower PCB 32 may be equipped with a second light source 43, a first diode 37, a second diode 39, and a second resistor 47.

On the other hand, unlike shown in Figures 2 to 4, the heater jacket monitoring mechanism 30 is mounted with the elements and terminals of the first monitoring unit 36 on one PCB and the second monitoring unit 38 is provided It may be provided with a configuration that does not. On the other hand, the same configuration as the heater jacket monitoring mechanism 30 is also included in the male connector 16 provided in the power connection unit 23, but this is the power monitoring mechanism 29 informing the presence or absence of power supply abnormality. In addition, the heater jacket 10B disposed on the leftmost side in FIG. 1 does not include the male connector 16 and does not have a heater jacket monitoring mechanism separately.

Hereinafter, referring to FIGS. 1 and 5 again, an operation and a configuration of the heater jacket monitoring mechanism 30 will be described. Hereinafter, for convenience of description, the first to fourth heater jackets will be referred to in order from the rightmost heater jacket 10A to the leftmost heater jacket 10B based on FIG. 1. Arrange the first to fourth heater jackets 10A and 10B and the power connection unit 23 in a line, connect the male connector 16 and the female connector 20, and connect the power plug 27 to a power supply socket (not shown). ), The heat generators 14 of the first to fourth heater jackets 10A and 10B generate heat to heat the pipe 1. However, if power is not supplied through the power supply socket (not shown) or if there is a disconnection in the power connection unit 23, all of the heating elements of the first to fourth heater jackets 10A and 10B connected in series. No power is supplied to the 14 and the first and second light sources 41 and 43 of one power monitoring mechanism 29 and three heater jacket monitoring mechanisms 30 embedded in the four male connectors 16. This does not all light up. Therefore, the user of the thermal insulation system can easily identify that the problem has occurred in the power supply system by seeing that all the light sources 41 and 43 of the four monitoring mechanisms 29 and 30 are not turned on.

On the other hand, if there is a disconnection in the heating element 14 of the first heater jacket 10A, power is not supplied to all the heating elements 14 of the first to fourth heater jackets 10A and 10B connected in series. Power is supplied to the power monitoring mechanism 29. Accordingly, the first and second light sources 41 and 43 of the power source monitoring mechanism 29 are turned on, but the first and second light sources 41 and 43 of the three heater jacket monitoring mechanisms 30 are not turned on. The user of the thermal insulation system can easily grasp that the problem occurs in the heating element 14 of the first heater jacket 10A by viewing the lighting state of the monitoring mechanisms 29 and 30 as described above.

If there is a disconnection in the heating element 14 of the second heater jacket 10A (see Fig. 1), the three heating elements 14 of the second to fourth heater jackets 10A and 10B, and the second and the second Although no power is supplied to the heater jacket monitoring mechanism 30 of the three heater jacket 10A, the heating element 14 of the power source monitoring mechanism 29, the first heater jacket 10A (see FIG. 1), and the first heater Electric power is supplied to the heater jacket monitoring mechanism 30 of the jacket 10A. Accordingly, the first and second light sources 41 and 43 of the heater jacket monitoring mechanism 30 of the power monitoring mechanism 29 and the first heater jacket 10A are turned on but the second and third heater jackets 10A are turned on. The first and second light sources 41 and 43 of the heater jacket monitoring mechanism 30 are not turned on. The user of the thermal insulation system can easily grasp that the problem occurs in the heating element 14 of the second heater jacket 10A by looking at the lighting state of the monitoring mechanisms 29 and 30 as described above.

If there is a disconnection in the heating element 14 of the third heater jacket 10A (see FIG. 1), the heating element 14 of the third heater jacket 10A and the fourth heater jacket 10B, and the third heater Although no power is supplied to the heater jacket monitoring mechanism 30 of the jacket 10A, the heating element 14 of the power source monitoring mechanism 29, the first heater jacket 10A, and the second heater jacket 10A (see FIG. 1). ) And the heater jacket monitoring mechanism 30 of the first heater jacket 10A and the second heater jacket 10A are supplied with electric power. Thus, the first and second light sources 41 of the power source monitoring mechanism 29, the heater jacket monitoring mechanism 30 of the first heater jacket 10A, and the heater jacket monitoring mechanism 30 of the second heater jacket 10A. , 43 is lit, but the first and second light sources 41, 43 of the heater jacket monitoring mechanism 30 of the third heater jacket 10A are not lit. The user of the thermal insulation system can easily grasp that a problem has occurred in the heating element 14 of the third heater jacket 10A by looking at the lighting states of the monitoring mechanisms 29 and 30 as described above.

If there is a disconnection in the heating element 14 of the fourth heater jacket 10B (see Fig. 1), no power is supplied to the heating element 14 of the fourth heater jackets 10A and 10B. 29), the heating element 14 of the first heater jacket 10A to the third heater jacket 10A (see FIG. 1), and the heater jacket monitoring mechanism of the first heater jacket 10A to the third heater jacket 10A. 30 is supplied with electric power. Thus, the first and second light sources 41 and 43 of the power source monitoring mechanism 29 and the three heater jacket monitoring mechanisms 30 are turned on. However, since the heating element 14 of the fourth heater jacket 10B is not kept warm, a problem may be detected through temperature measurement through a tactile touch or a thermometer. The user of the thermal insulation system can easily determine that a problem has occurred in the heating element 14 of the fourth heater jacket 10B by viewing the lighting state of the monitoring mechanisms 29 and 30 and the temperature of the fourth heater jacket 10B. Can be.

6 is a perspective view illustrating a heat insulating system configured by connecting a plurality of heater jacket monitoring mechanisms and a heater jacket including the heater jacket according to a second embodiment of the present invention.

Referring to FIG. 6, a second thermal insulation system for preventing a temperature drop of a flow path formed of the pipe 1 is connected along the pipe 1 and includes a plurality of thermal insulations surrounding the outer circumferential surface of the pipe 1. The heater jacket 50A, 50B is provided. Each heater jacket 50A, 50B is provided with the housing 52A, 52B, and the heat generating body 54 inside the housing 52A, 52B. The heating element 54 generates heat when electric energy is supplied, and may be, for example, a heating wire.

The heater jacket 50A disposed at the far right of the plurality of heater jackets 50A and 50B is a power source having a power plug 67 capable of receiving 220V AC voltage and a pair of wires 64 and 65 connected thereto. It is electrically connected to the connection unit 63, and the remaining heater jackets 50A, 50B are connected in a line. The leftmost heater jacket 50B of the plurality of heater jackets 50A and 50B further includes a female connector 60 to be electrically connected to an adjacent heater jacket 50A, and the remaining heater jackets 50A are provided. The male connector 56 and the female connector 60 are provided, respectively. The other end of the power connection unit 63 having the power plug 67 at one end is provided with a male connector 56 so as to be electrically connected to the heater jacket 50A disposed at the rightmost side.

The male connector 56 and the female connector 60 of the adjacent heater jackets 50A and 50B are connected, and the male connector 60 and the male connector of the power connection unit 63 of the heater jacket 50A disposed on the rightmost side. When 56 is connected and the power plug 67 is plugged into a power supply socket (not shown), the heating elements 54 of each heater jacket 50A, 50B are connected in series and generate heat by electric energy.

The leftmost heater jacket 50B has a heater jacket monitoring mechanism 70 on a pair of wires 64, 65 extending to the female connector 60, and the remaining heater jacket 50A has a male connector. A heater jacket monitoring mechanism 70 is provided on the pair of wires 64, 65 extending to 56. The heater jacket monitoring mechanism 70 informs whether or not the electric heater 54 of each heater jacket 50A, 50B is disconnected. On the other hand, Figure 6 is shown a thermal insulation system having four heater jackets (50A, 50B), the present invention is not limited to the number of heater jacket (50A, 50B) connected.

FIG. 7 is a side view schematically showing the heater jacket monitoring mechanism of FIG. 6, FIGS. 8 and 9 are plan views respectively showing the upper PCB and the lower PCB of FIG. 7, and FIG. 10 is a schematic view of the thermal insulation system of FIG. 6. It is a circuit diagram. 7 to 10, in circuit view, the heater jacket monitoring mechanism 70 includes a first diode 77, a first light source 81, and a first light source electrically connected in series with each other. A first monitoring unit 76 having a resistor 85, a second diode 79, a second light source 83, which are electrically connected in series similar to the first monitoring unit 76, And a second monitoring unit 78 having a second resistor 87. The 1st monitoring unit 76 and the 2nd monitoring unit 78 are electrically connected in series with the heat generating body 54 of the heater jacket 50A (refer FIG. 6) to which it belongs, respectively. However, the first monitoring unit 76 and the second monitoring unit 78 are electrically connected in parallel. The first light source 81 and the second light source 83 are, for example, light emitting diodes (LEDs). In addition, the magnitudes of the first resistor 85 and the second resistor 87 are, for example, 56 K ?.

Structurally, the heater jacket monitoring mechanism 70 has an upper printed circuit board (71) and a lower PCB (72) arranged in parallel inside the housing (89), and the first light source (81) It is mounted on the upper PCB 71, and the second light source 83 is mounted on the lower PCB 72. The housing 89 is provided with a transparent or open window (not shown) so that the light can be projected to the outside when the first light source 81 and the second light source 83 emit light. The upper PCB 71 is provided with first and second terminals 73 and 75, and the first and second terminals 73 and 75 are electrically connected to the lower PCB 72.

The pair of wires 64, 65 cut by the heater jacket monitoring mechanism 70 are electrically connected through the first terminal 73 and the second terminal 75. Specifically, the wire 64 directly connected to the heating element 54 (see FIG. 6) may be connected through the first terminal 73, and the other wire 65 may be connected through the second terminal 75. In addition, the first and second diodes 77 and 79 and the first and second resistors 85 and 87 are appropriately arranged to form the circuit shown in FIG. 10 on the upper PCB 71 and the lower PCB 72. Can be. For example, as illustrated in FIG. 8, the upper PCB 71 includes a first light source 81, a first resistor 85, a first diode 77, a first terminal 73, and a second terminal 75. As shown in FIG. 9, a second light source 83, a second diode 79, and a second resistor 87 may be mounted on the lower PCB 72. 7 to 9, the heater jacket monitoring mechanism 70 is mounted with elements and terminals of the first monitoring unit 76 on one PCB and the second monitoring unit 78 is provided. It may be provided with a configuration that does not.

Hereinafter, with reference to FIGS. 6 and 10 again, the operation and configuration of the heater jacket monitoring mechanism 70 will be described. Hereinafter, for convenience of description, the first to fourth heater jackets will be referred to sequentially from the heater jacket 50A disposed at the rightmost side to the heater jacket 50B disposed at the leftmost side with reference to FIG. 6. The first to fourth heater jackets 50A and 50B and the power connection unit 63 are arranged in a line, and the male connector 56 and the female connector 60 are connected, and the power plug 67 is connected to a power supply socket (not shown). ), The heat generating element 54 of the first to fourth heater jackets 50A and 50B generates heat to keep the pipe 1 warm.

However, if power is not supplied through the power supply socket (not shown), or there is a disconnection in the power connection unit 63, or a disconnection in the heating element 54 of the first heater jacket 50A. ), Power is not supplied to all the heating elements 54 of the first to fourth heater jackets 50A and 50B connected in series, and the first and second light sources 81 of the four heater jacket monitoring mechanisms 70 83) does not all light up. Therefore, the user of the thermal insulation system sees that all the light sources 81 and 83 of the four heater jacket monitoring mechanisms 70 are not turned on, and thus the problem is caused by the heating element 54 of the power supply system or the first heater jacket 50A. It can be easily identified that it occurred.

On the other hand, if there is a disconnection in the heating element 54 of the second heater jacket 50A, power is not supplied to the three heating elements 54 of the second to fourth heater jackets 50A and 50B. Electric power is supplied to the heating element 54 of the heater jacket 50A and the heater jacket monitoring mechanism 70 of the first heater jacket 50A. Accordingly, the first and second light sources 81 and 83 of the heater jacket monitoring mechanism 70 of the first heater jacket 50A are turned on, but the heater jacket monitoring mechanisms of the second to fourth heater jackets 50A and 50B ( The first and second light sources 81 and 83 of 70 are not turned on. The user of the thermal insulation system can easily grasp that the problem occurs in the heating element 54 of the second heater jacket 50A by looking at the lighting state of the heater jacket monitoring mechanism 70 as described above.

If there is a disconnection in the heating element 54 of the third heater jacket 50A, the two heating elements 54 of the third and fourth heater jackets 50A and 50B, and the third and fourth heater jackets 50A , But no power is supplied to the heater jacket monitoring mechanism 70 of 50B, the heating element 54 of the first heater jacket 50A and the second heater jacket 50A, and the first heater jacket 50A and the second heater 50A. Electric power is supplied to the heater jacket monitoring mechanism 70 of the heater jacket 50A. Accordingly, the first and second light sources 81 and 83 of the heater jacket monitoring mechanism 70 of the first heater jacket and the second heater jacket 50A are turned on, but the third heater jacket 50A and the fourth heater jacket ( The first and second light sources 81 and 83 of the heater jacket monitoring mechanism 70 of 50B are not turned on. The user of the thermal insulation system can easily grasp that the problem occurs in the heating element 54 of the third heater jacket 50A by looking at the lighting state of the heater jacket monitoring mechanism 70 as described above.

If the heating element 54 of the fourth heater jacket 50B has a disconnection, no power is supplied to the heating element 54 and the heater jacket monitoring mechanism 70 of the fourth heater jacket 50B. Electric power is supplied to the heating element 54 of the jacket 50A-the 3rd heater jacket 50A, and the heater jacket monitoring mechanism 70 of the 1st heater jacket-the 3rd heater jacket 50A. Accordingly, the first and second light sources 81 and 83 of the heater jacket monitoring mechanism 70 of the first to third heater jackets 50A are turned on, but the heater jacket monitoring mechanism 70 of the fourth heater jacket 50B is turned on. The first and second light sources 81 and 83 are not turned on. The user of the thermal insulation system can easily grasp that the problem occurs in the heating element 54 of the fourth heater jacket 50B by looking at the lighting state of the heater jacket monitoring mechanism 70 as described above.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention. Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

10 A, 10 B: jacket 14: heating element
16, 20: male, female connector 30: heater jacket monitoring mechanism
31, 32: PCB 33, 35: terminal
36, 38: first and second monitoring units 37, 39: diode
41, 43: LED 45, 47: resistance

Claims (8)

Is installed in the heater jacket to inform whether or not the electrical disconnection of the heating element in the heater jacket,
And a first monitoring unit having a first diode electrically connected in series with each other, a first light source, and a first resistor, and electrically connected in series with a heating element of the heater jacket.
The heater jacket monitoring mechanism, characterized in that the first light source is configured not to emit light even when power is connected to the heater jacket when the heating element of the heater jacket is electrically disconnected. The method according to claim 1,
A second diode electrically connected in series with each other, a second light source, and a second resistor, the second diode being electrically connected in series with the heating element of the heater jacket and electrically connected in parallel with the first monitoring unit. Further equipped with two monitoring units,
The heater jacket monitoring mechanism, characterized in that the second light source is configured not to emit light even when power is connected to the heater jacket when the heating element of the heater jacket is electrically disconnected. The method of claim 2,
And the first light source and the second light source are mounted one by one on an upper printed circuit board (PCB) and a lower PCB arranged in parallel with each other. 3. The method according to claim 1 or 2,
When another heater jacket is interposed between the power source and the heater jacket so that the heating element of the other heater jacket is connected to the power source in advance of the heating element of the heater jacket,
And the heater jacket monitoring mechanism is configured such that all light sources of the heater jacket monitoring mechanism do not emit light when the heating element of the other heater jacket is electrically disconnected. 3. The method according to claim 1 or 2,
When another heater jacket is connected behind the heater jacket so that the heating element of the other heater jacket is connected to the power supply behind the heating element of the heater jacket,
Heater jacket monitoring mechanism, characterized in that all the light source of the heater jacket monitoring mechanism is configured to emit light if the heating element of the heater jacket is not disconnected even if the heating element of the other heater jacket is electrically disconnected. 3. The method according to claim 1 or 2,
The heater jacket monitoring mechanism, characterized in that the light source provided in the heater jacket monitoring mechanism is a light emitting diode (LED). The method according to claim 1,
The heater jacket monitoring mechanism is inherent in a connector (connector) for connecting with other heater jackets. By keeping warm around the outer circumference of the flow path,
housing;
A heating element provided inside the housing and generating heat by electric energy; And
And a heater jacket monitoring mechanism according to any one of claims 1 to 3, which indicates whether the heating element is electrically disconnected.

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