KR101438701B1 - Hot water mat including overheat detecting part - Google Patents

Abstract

Provided is a hot water mat including an overheating detection unit. The hot water mat includes: a fluid pipe; a water heating unit connected to the fluid pipe and has the overheating detection unit; and a heat consumption mat. The overheating detection unit includes: an overheating detection pipe connected to the fluid pipe; and a contact switch arranged on the overheating detection pipe.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hot water mat,

Embodiments of the present invention relate to a hot water mat, and more particularly, to an overheat sensing unit that senses a fluid flow in a fluid pipe passing through a heat consuming mat in a hot water mat.

Generally, a hot water mat is used in a period having a large absolute value in the difference between the inside temperature and the outside temperature of the house including winter iron, or in a situation having a large absolute value in the difference between the temperature of the floor of the house and the temperature of the user's body ≪ / RTI > In this case, the hot water mat is used to artificially warm the user's body through the heat-consuming mat to make the user enjoy life outside the house.

However, when the heat consuming mat of the hot water mat is crushed by a structure (e.g., a chair) in the house, the hot water mat does not stably maintain the flow of hot water between the hot water tank and the heat consuming mat. Subsequently, the hot water mat increases the temperature of the hot water by using the heater without controlling the flow of hot water.

The continuous rise of the temperature of the hot water is located between the hot water tank and the heat consuming mat and excessively increases the internal pressure of the fluid pipe passing through the interior of the heat consuming mat to deteriorate the components of the hot water mat. Deterioration of the components of the hot water mat may deteriorate the user's experience of using the hot water mat.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and apparatus for detecting a fluid in a hot water mat by sensing an excessive increase in internal pressure of the fluid pipe when the heat consumption mat of the hot water mat is crushed by the structure, The present invention also provides a hot-water mat comprising a part of the hot-

Other problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems not mentioned here will be fully understood by those skilled in the art from the following description.

There is provided a hot water mat including an overheat sensing unit according to embodiments of the present invention. The hot water mat having two ends open at one side and extending from the two ends toward the other side to connect the two ends at the other side; A hot water tank communicating with the two ends of the fluid tube at the one side of the fluid tube; an overheat sensing part positioned between the two ends of the fluid tube and communicating with the fluid tube; A hot water heating unit including a control unit electrically connected to the sensing unit; And a heat consumption mat surrounding the fluid tube at the other side of the fluid tube, wherein the overheat sensing unit includes an overheat sensing tube connected to the fluid tube and a contact switch positioned on the overheat sensing tube, And a plunger of the superheat sensing tube is configured to be able to contact the contact terminal of the contact switch in correspondence with the difference in the internal pressure of the fluid tube between the one side portion and the other side portion of the fluid tube.

The fluid tube is formed along a straight line between the hot water tank and the heat consuming mat and has at least one bend in the interior of the heat consuming mat.

The fluid tube is surrounded by the heater section between the hot water tank and the superheat sensing tube.

Wherein the hot water tank includes a check valve extending from the interior toward one of the two ends of the fluid tube and the check valve is configured to open and close the hot water tank with respect to the one of the two ends do.

Wherein the hot water mat further comprises a connection pipe between the hot water tank and the heater portion, the connection pipe connecting the hot water tank and one of the two ends of the fluid tube, A hot water tank and the connecting pipe.

The overheat sensing tube includes a lower channel molding part, an upper channel molding part, a first pressure reaction part and a second pressure reaction part which are stacked in order.

The lower channel molding part forms a channel communicating with the fluid channel by being coupled with the upper channel molding part.

Wherein the upper channel molding portion includes a second connecting pipe and a third connecting pipe extending respectively toward the one side portion and the other side portion of the fluid tube and a second connecting pipe extending from the flow path between the second connecting pipe and the third connecting pipe, And a discharge hole branched toward the opposite side of the molding part.

The first pressure responsive portion includes one of rubber and silicon.

The first pressure responsive portion has a wrinkle shape.

The first pressure-responsive portion and the second pressure-responsive portion are located on the discharge hole of the upper flow-molding portion and are surrounded by the upper flow-field molding portion. The first pressure-responsive portion is fixed to the upper- And the second pressure reaction part covers the first pressure reaction part while being coupled with the upper flow path molding part, and the second pressure reaction part covers the first pressure reaction part and the second pressure reaction part together with the first pressure reaction part Thereby defining a second hollow.

The first pressure reacting portion is configured to isolate the first hollow and the second hollow between the upper flow molding portion and the second pressure reacting portion.

The second pressure responsive portion includes a plunger, an elastic member positioned around the plunger, and a plunger housing surrounding the plunger and the elastic member.

The plunger is in contact with the first pressure responsive portion and extends toward the contact terminal of the contact switch.

The elastic member is disposed on the upper side of the plunger and is configured to be spaced from the first pressure responsive portion using the lower side of the plunger.

The plunger housing has an opening that contacts the first pressure responsive portion and surrounds the second hollow portion, resiliently engages the plunger through the elastic member, and is aligned with the plunger.

The control unit is configured to illuminate a lamp in response to the difference in the internal pressure of the fluid tube to emit a visual warning signal or to sound an audible warning signal by ringing a buzzer.

The control unit is configured to be electrically connected to the contact switch and the heater unit.

Since the hot water mat according to the embodiments of the present invention is provided with the overheat sensing part between the hot water tank and the heat consuming mat,

The hot water mat can confirm the internal pressure of the fluid tube in real time during the flow of the fluid in the fluid tube.

The hot water mat can check the internal pressure of the fluid tube in real time to suppress the continuous increase of the temperature of the hot water even in the unstable flow of the fluid in the fluid tube.

The hot water mat can prevent the continuous increase of the temperature of the hot water to prevent deterioration of the components.

The hot water mat prevents deterioration of the components and can improve the user's use experience.

1 is a schematic view showing a hot water mat according to embodiments of the present invention.
2 is a schematic view showing the overheat sensing unit of FIG.
Figs. 3 to 7 are schematic views for explaining the driving method of the hot water mat of Fig.

First, a hot water mat including an overheat sensing unit according to embodiments of the present invention will be described in detail with reference to FIGS. 1 and 2. FIG.

1 is a schematic view showing a hot water mat according to embodiments of the present invention.

Referring to FIG. 1, a hot water mat 200 according to embodiments of the present invention includes a fluid pipe 30, 180, a hot water heating unit 170, and a heat consuming mat 190. The fluid tube (30, 180) is subdivided into a first fluid tube (30) and a second fluid tube (180). The hot water heating unit 170 includes a hot water tank 10, an overheat sensing unit 150, and a controller 160 at one side of the fluid pipes 30 and 180.

In this case, the fluid pipe (30, 180) has two ends which are opened to one side of the hot water tank (10). The fluid tube (30, 180) is configured to extend from the two ends toward the other side to connect the two ends at the other side. The hot water tank (10) communicates with two ends of the fluid pipe (30, 180).

The overheat sensing unit 150 is positioned between two ends of the fluid pipes 30 and 180 and communicates with the fluid pipes 30 and 180. That is, the overheat sensing unit 150 is located between the first fluid pipe 30 and the second fluid pipe 180 and communicates with the first fluid pipe 30 and the second fluid pipe 180. The overheat sensing unit 150 includes an overheating sensing pipe 130 connected to the fluid pipes 30 and 180 and a contact switch 140 disposed on the overheating sensing pipe 130.

The structure of the overheat sensing unit 150 will be described in detail with reference to FIG. The overheat sensing tube 130 is configured to be able to contact the contact switch 140 between the one side and the other side of the fluid tube 30, 180 corresponding to the difference in the internal pressure of the fluid tube 30, 180. Contact between the overheat sensing tube 130 and the contact switch 140 is described in detail in FIGS.

In this case, the first fluid pipe 30 is surrounded by the heater unit 40 between the hot water tank 10 and the overheat sensing pipe 150. The heater unit 40 includes a heating element. The controller 160 is configured to be electrically connected to the heater unit 40 and the contact switch 140. The controller 160 illuminates the lamp 165 corresponding to the difference in internal pressure of the fluid pipes 30 and 180 to emit a visual warning signal or to sound a buzzer instead of the lamp 165, And to send a warning signal.

At the other side of the fluid tube (30, 180), the heat consuming mat (190) surrounds the second fluid tube (180). In this case, the first fluid pipe (30) is formed along the straight line between the hot water tank (10) and the heat consuming mat (190). The second fluid conduit 180 has at least one bend in the interior of the heat-consuming mat 190.

The hot water mat (200) further includes a connecting pipe (20) between the hot water tank (10) and the heater unit (40). The connecting pipe 20 connects the hot water tank 10 and one of the two ends of the fluid pipe 30, 180.

2 is a schematic view showing the overheat sensing unit of FIG.

Referring to FIG. 2, the overheat sensing unit 150 includes an overheat sensing tube 130 and a contact switch 140 according to embodiments of the present invention. The overheat sensing tube 130 includes a lower channel molding part 50, an upper channel molding part 70, a first pressure reaction part 80 and a second pressure reaction part 120 which are stacked in order.

The lower flow path molding part 50 is coupled with the upper flow path molding part 70 through a seal 60 to form a flow path 73 communicating with the fluid pipes 30 and 180 of FIG. The upper channel molding part 70 includes a second connecting pipe 71 and a third connecting pipe 77 which extend toward one side and the other side of the fluid pipes 30 and 180, respectively.

The second connecting pipe 71 and the third connecting pipe 77 are in contact with the first fluid pipe 30 and the second fluid pipe 180 to form the first fluid pipe 30 and the second fluid pipe 180 ). The upper flow path molding part 70 includes a discharge hole 75 branched from the flow path 73 toward the opposite side of the lower flow path molding part 50 between the second connection pipe 71 and the third connection pipe 77 .

The first pressure reaction unit 80 and the second pressure reaction unit 120 are located on the discharge hole 75 of the upper flow molding unit 70 and are surrounded by the upper flow molding unit 70. In this case, the upper channel molding part 70 has the first pressure-reacting part 80 and the first coupling part 79 around the second pressure-reacting part 120.

The first pressure reaction part 80 is fixed to the upper flow molding part 70 and covers the discharge hole 75 and defines a first hollow 76 together with the upper flow molding part 70. The first hollow 76 between the upper flow molding part 70 and the first pressure responsive part 80 is connected to the upper end of the fluid pipe 30 through the discharge hole 75 of the upper flow molding part 70, The pressure corresponding to the difference between the internal pressure of the side and the other side can be received.

The first pressure responsive part 80 includes one of rubber and silicon. The first pressure-responsive portion 80 has a wrinkle shape. The second pressure reaction part 120 is positioned on the upper flow path molding part 70 to cover the first pressure reaction part 80. That is, the second coupling portions 118 of the second pressure reaction portion 120 are engaged with the first coupling portions 79 of the upper channel molding portion 70.

The second pressure reaction unit 120 defines the second hollow 114 together with the first pressure reaction unit 80. In this case, the first pressure reaction unit 80 is configured to isolate the first hollow 76 and the second hollow 114 between the upper flow molding unit 70 and the second pressure reaction unit 120 do.

The second pressure reacting unit 120 includes a plunger 90 and an elastic member 100 disposed around the plunger 90. The plunger 90 is connected to the plunger 90. The second pressure reacting unit 120 includes a plunger 90, (90) and a plunger housing (110) surrounding the elastic member (100).

The plunger 90 is positioned in the central region of the first pressure responsive portion 80 and has the same central axis as the discharge hole 75 of the upper flow molding portion 70. The plunger 90 contacts the first pressure responsive portion 80 and extends toward the contact terminal 145 of the contact switch 140.

The plunger 90 can vertically move in the direction D toward the contact terminal 145 or the discharge hole 75 together with the first pressure reaction part 80. [ The upward and downward movement of the plunger 90 will be described in detail in FIGS. The elastic member 100 is located on the upper side of the plunger 90 and is configured to be separated from the first pressure responsive portion 80 by using the lower side of the plunger 90.

The elastic member 100 may engage with the plunger 90 while surrounding the plunger 90. The plunger housing 110 contacts the first pressure-responsive portion 80 and surrounds the second hollow portion 114. The plunger housing 110 has an opening 119 that resiliently engages the plunger 90 through the resilient member 100 and aligns with the plunger 90.

In this case, the plunger 90 and the elastic member 100 occupy the second hollow 114. Also, the plunger 90 may be exposed from the plunger housing 110 through the opening 119 of the plunger housing 110. The contact switch 140 is located on the overheat sensing tube 130. The contact terminal 145 of the contact switch 140 is positioned directly above the plunger 90.

The contact terminal 145 can move up and down in the same direction D as the plunger 90. The touch switch 140 includes a micro switch.

Next, a method of driving the hot water mat including the overheat sensing unit according to the embodiments of the present invention will be described in detail with reference to FIGS.

Figs. 3 to 7 are schematic views for explaining the driving method of the hot water mat of Fig.

Referring to FIG. 3, in the hot water mat 200 of FIG. 1 according to the embodiments of the present invention, the hot water tank 10 has a fluid supply hole 13, an outlet 18 and an inlet 19. The hot water tank 10 includes a check valve 16 extending from the inside toward one of the two ends of the fluid pipe 30, 180.

That is, the check valve 16 is located in the interior of the hot water tank 10 and in the support hole 25 of the connecting pipe 20 so as to pass through the outlet 18. The check valve 16 is configured to open and close the hot water tank 10 for one of the two ends. The check valve 16 moves up and down in the first movement M1 and the second movement M2 in the hot water tank 10 and the connection pipe 20. [

Before the hot water mat 200 is driven, the hot water tank 10 is moved along the first fluid flow line F1 to a water conducting state or a fluid (for example, cold water W Can be supplied. The fluid W may move the check valve 16 according to the first movement M1 and / or the second movement M2.

The fluid W is guided to the overheat sensing unit 150 and the fluid pipe (not shown) via the outlet port 18 and the inlet port 19 of the hot water tank 10 by using its own weight, 30, and 180 so that the hot water tank 10 can be filled with a predetermined height. In this case, the fluid W can completely fill the superheat sensing unit 150 and the fluid tubes 30 and 180 along the second fluid flow line F2 and the third fluid flow line F3.

The second fluid flow line F2 flows out of the hot water tank 10 and the connecting pipe 20 to indicate the flow of the fluid W in the first fluid pipe 30 to explain the present invention briefly. The third fluid flow line F3 flows out of the overheat sensing unit 150 to indicate the flow of the fluid W in the second fluid pipe 180.

Referring to FIG. 4, in order to drive the hot water mat 200, the hot water mat 200 may supply electricity to the heater unit 40 through the controller 160. The heater unit 40 may heat the fluid W in FIG. 3 in the first fluid pipe 30. The heater 40 can form hot water from the cold water by using the fluid W.

In this case, when the structure is not located on the heat consumption mat 190, the fluid W flows through the second fluid flow line F2 using the temperature difference, the self weight, the earth gravity and / The fluid pipes 30 and 180 and the inside of the superheat sensing pipe 130 along the detailed lines F31, F32, F33 and F34 of the third fluid flow line F3 and the third fluid flow line F3 have.

5, the fluid W flows from the flow path 73 between the lower flow molding part 50 and the upper flow molding part 70 through the discharge hole 75 of the upper flow molding part 70 Can be supplied to the first hollow (76). The fluid W may fill or partially fill the first cavity 76.

In addition, when the fluid W only fills a portion of the first cavity 76, the remaining portion of the first cavity 76 may be filled with hot air. When the fluid W is heated in the first fluid pipe 30 and supplied to the second fluid pipe 180, the fluid W flows from the inner pressure of the connecting pipe 20 to the second fluid pipe 180, It is possible to generate the first pressure P1 corresponding to the difference between the internal pressures.

When the first pressure P1 is generated between the first fluid pipe 30 and the second fluid pipe 180, the first pressure P1 is applied to the check valve 16 of the hot water tank 10, And can move from the motion M1 to the second motion M2. The check valve 16 may close the outlet 18 of the hot water tank 10.

In this case, the first pressure P1 may be transmitted to the first pressure responsive unit 80 through the discharge hole 75 and the first hollow 76 of the overheat sensing pipe 70. However, since the first pressure is not sufficiently large, the first pressure responsive portion 80, the plunger 90, and the elastic member 100 can not be pushed up against the plunger housing 110.

This is because the first pressure responsive part 80, the plunger 90 and the elastic member 100 are designed not to move against the first pressure P1 generated in the stable flow of the fluid W. For this purpose, each of the first pressure responsive part 80, the plunger 90 and the elastic member 100 may be prepared in consideration of their own weight and / or their own materials.

Subsequently, the fluid W may flow from the second fluid pipe 180 to the inlet 19 of the hot water tank 10. The fluid W may form a difference in pressure between the hot water tank 10 and the connecting pipe 20 to move the check valve 16 from the second movement M2 to the first movement M1. Through this, the check valve 16 can open the outlet 18 of the hot water tank 10.

When the fluid W has a stable flow between one side and the other side of the fluid tube 30,80 the fluid W will flow through the first movement M1 of the check valve 16 and the second movement & It is possible to repeatedly move up and down along the second axis M2.

6, when a structure is positioned on an access point AP of the heat-consuming mat 190, the fluid W is heated by a temperature difference, self weight, gravity and / The fluid in the hot water tank 10, the fluid pipes 30 and 180 and the superheat sensing pipe 130 may flow unstably along the second fluid flow line F2 and the deformed detail lines F41 and F42 .

This is because the structure presses down the second fluid tube 180 at the contact position AP of the heat consumption mat 190 to increase the flow pressure of the fluid W relative to the first pressure P1 in Figures 4 and 5 Or may not have a flow of fluid W in the second fluid conduit 180. When the fluid W flows for a long time at an increased flow pressure, the fluid W can shorten the service life of the components of the hot water mat 200.

The fluid W will flow from the second fluid conduit 180 to the second fluid conduit 180 when the fluid W does not flow in the second fluid conduit 180, ). ≪ / RTI >

7, the fluid W flows from the flow path 73 between the lower flow molding part 50 and the upper flow molding part 70 through the discharge hole 75 of the upper flow molding part 70 Can be supplied to the first hollow (76). The fluid W may fill the first cavity 76. Subsequently, the fluid W may be supplied to the second fluid pipe 180 through the overheat sensing pipe 130.

In order to simplify the present invention, the fluid W will be described only when it has a flow in the second fluid pipe 180. This is because when the structure is located on the contact position AP of the heat consuming mat 190 the fluid W flows into the second fluid tube 180 rather than into the second fluid tube 180, Because it exhibits a greater pressure in the second fluid conduit 180 when there is no flow.

Accordingly, the fluid W may generate a second pressure P2 corresponding to the difference between the internal pressure of the connecting pipe 20 and the internal pressure of the second fluid pipe 180. [ The second pressure P2 may have a value greater than the first pressure P1. When the second pressure P2 is generated between the first fluid pipe 30 and the second fluid pipe 180, the second pressure P2 is supplied to the discharge hole 75 of the overheat sensing pipe 70, Can be transmitted to the first pressure responsive part (80) through the hollow (76).

Since the second pressure P2 is sufficiently large, the first pressure responsive portion 80, the plunger 90 and the elastic member 100 can be pushed up against the plunger housing 110. This is because the first pressure responsive portion 80 and the plunger 90 and the elastic member 100 are designed to move in response to the second pressure P2 generated in the unstable flow of the fluid W. [

More specifically, the first pressure responsive unit 80 may deform the shape in the direction D1 toward the contact switch 140 in response to the second pressure P2. The first pressure-responsive portion 80 may be extended from the central region toward the upper portion to push up the plunger 90.

The plunger 90 may be supported by the first pressure reaction unit 80 to compress the elastic member 100 with respect to the plunger housing 110. The plunger 90 may contact the contact terminal 145 of the contact switch 140 through the opening 119 of the plunger housing 110. [

The contact of the plunger 90 and the contact terminal 145 may be performed to transmit the electrical signal of the contact switch 140 to the control unit 160 in Fig. The controller 160 may illuminate the lamp 165 in response to the electrical signal of the touch switch 140 to emit a visual warning signal. Alternatively, the control unit 160 may emit an audible warning signal by ringing a buzzer in response to an electrical signal of the contact switch 140. [

When the structure is removed from the heat consuming mat after the warning signal of the controller 160 is emitted, the hot water mat 200 can reliably flow the unstable flow of the fluid W in the fluid tube 30, . The first pressure reaction unit 80 in the superheat sensing tube 130 may be restored to a shape as shown in FIG.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

10; Hot water tank, 20; Connection pipe
30, 180; Fluid tube, 50; The lower-
70; An upper channel molding part 80; The first pressure-
90; Plunger, 100; Elastic member
110; Plunger housing, 120; The second pressure responsive member
130; Overheat sensing tube, 140; Contact switch
150; An overheating sensing unit 160; The control unit
170; A hot water heating unit 190; Heat Consumption Mat
200; Hot water mats

Claims (18)

A fluid conduit having two ends open at one side and extending from the two ends toward the other side to connect the two ends at the other side;
A hot water tank communicating with the two ends of the fluid tube at the one side of the fluid tube; an overheat sensing part positioned between the two ends of the fluid tube and communicating with the fluid tube; A hot water heating unit including a control unit electrically connected to the sensing unit; And
And a heat dissipation mat surrounding the fluid conduit at the other side of the fluid conduit,
Wherein the overheat sensing unit includes an overheat sensing tube connected to the fluid tube and a contact switch positioned on the overheating sensing tube, and a plunger of the overheat sensing tube is connected to the one side of the fluid tube, Wherein the contact portion of the contact portion of the contact tube is connected to the contact terminal of the contact switch in accordance with a difference in the internal pressure of the fluid tube. The method according to claim 1,
Wherein the fluid tube is formed along a straight line between the hot water tank and the heat consuming mat and has at least one bend in the interior of the heat consuming mat. The method according to claim 1,
Wherein the fluid tube is surrounded by a heater portion between the hot water tank and the superheat sensing tube. The method of claim 3,
Wherein the hot water tank includes a check valve extending from the interior toward one of the two ends of the fluid conduit, and
Wherein the check valve is configured to open and close the hot water tank with respect to the one of the two ends. 5. The method of claim 4,
Further comprising a connection pipe between the hot water tank and the heater unit,
The connecting tube connecting the hot water tank and one of the two ends of the fluid tube, and
Wherein the check valve is located in the hot water tank and the connecting pipe. The method according to claim 1,
Wherein the overheat sensing tube includes a lower channel molding part, an upper channel molding part, a first pressure reaction part and a second pressure reaction part which are stacked in order. The method according to claim 6,
And the lower channel molding part constitutes a channel communicating with the fluid tube by being coupled with the upper channel molding part. 8. The method of claim 7,
Wherein the upper channel molding portion includes a second connecting pipe and a third connecting pipe extending respectively toward the one side portion and the other side portion of the fluid tube and a second connecting pipe extending from the flow path between the second connecting pipe and the third connecting pipe, And a discharge hole branched toward the opposite side of the molding part. The method according to claim 6,
Wherein the first pressure responsive portion includes one of rubber and silicon. The method according to claim 6,
Wherein the first pressure responsive portion has a wrinkled shape. The method according to claim 6,
Wherein the first pressure-responsive portion and the second pressure-responsive portion are located on the discharge hole of the upper flow-molding portion and are surrounded by the upper flow-
The first pressure reacting part is fixed to the upper flow-molding part to cover the discharge hole and define a first hollow together with the upper flow-molding part,
Wherein the second pressure reacting portion covers the first pressure responsive portion while being coupled with the upper flow casting portion and defines the second hollow together with the first pressure responsive portion. 12. The method of claim 11,
Wherein the first pressure responsive portion is configured to isolate the first hollow and the second hollow between the upper flow molding portion and the second pressure responsive portion. 12. The method of claim 11,
Wherein the second pressure responsive portion includes a plunger housing surrounding the plunger, an elastic member positioned around the plunger, and a plunger housing surrounding the plunger and the elastic member. 14. The method of claim 13,
Wherein the plunger is in contact with the first pressure responsive portion and extends toward the contact terminal of the contact switch. 14. The method of claim 13,
Wherein the elastic member is located on an upper side of the plunger and is configured to be spaced apart from the first pressure responsive portion using the lower side of the plunger. 14. The method of claim 13,
Wherein the plunger housing has an opening that contacts the first pressure responsive portion and surrounds the second hollow portion, resiliently engages the plunger through the elastic member, and has an opening aligned with the plunger. The method according to claim 1,
Wherein the control unit is configured to illuminate a lamp in response to the difference in the internal pressure of the fluid tube to emit a visual warning signal or to sound a buzzer to emit an audible warning signal. The method of claim 3,
Wherein the control unit is configured to be electrically connected to the contact switch and the heater unit.

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