KR101175778B1 - Heating bed using heater - Google Patents

Abstract

PURPOSE: A thermal bed using a heater is provided to make rapid and uniform heating possible and to effectively block electro magnetic waves. CONSTITUTION: A thermal bed using a heater comprises an upper plate(110), a base unit(100), a heater(10), a reflecting member(140), and a metal plate(115). The upper plate is able to be formed in the shape of thin board. The base unit comprises a base frame in which a support leg is formed in the lower part thereof, and a mattress mounted on the base frame. The heater of a pipe shape is accepted to a heater receiving unit and heats the upper plate. The reflecting member reflects the heat created from the heater upward. The metal plate covers the heater receiving unit and intercepts the electromagnetic wave created from the heater.

Description

Heating bed using heater

The present invention relates to a thermal bed using a heater, and more particularly, to a thermal bed that can be uniformly heated in a short time because it is safe for the human body and has excellent heat generation characteristics by effectively blocking electromagnetic waves.

Beds have evolved into more diverse and luxurious forms. Western bedroom culture, in particular, is basically a bed with a room, while oriental culture is an ondol culture, and each bedroom culture has its own advantages and disadvantages.

The importance of sound sleep and rest has emerged as a major concern in today's busy life and mental stress. As society develops, beds with convenient functions are spreading, but various needs of consumers who are able to sleep more comfortably and comfortably continue to increase, and in order to meet them, various kinds of beds that combine the benefits of ondol culture with beds are available. Research and efforts are underway.

In general, the thermal bed used in the home is heated and used at a constant temperature by wiring an electrically operated heating wire inside the slab, and has a certain thickness and a rectangular shape so that a user can lie down.

The heating wire for heating the bed typically uses a heating element wrapped with iron chromium, nichrome and the like using an insulating material.

However, a thermal bed using alternating current electricity generates harmful electromagnetic waves. That is, there is a problem in that electromagnetic waves, which are electric fields and magnetic fields of 60 mV generated from alternating current electricity, are generated.

Thus, in order to reduce the damage from the electromagnetic waves, a thermal bed having a function of shielding electromagnetic waves has been developed, but it is difficult to completely protect from electromagnetic waves.

In addition, the heating wire of the metal material such as iron chromium, nichrome, etc. used as a conventional heating element has a problem that the heat capacity is large, the rise and fall temperature is poor, and the high temperature durability is weak in a non-oxidizing atmosphere. In addition, since the heating is mainly performed around the hot wire, the whole is not uniformly heated and the initial heating efficiency is low.

The present invention has been made to improve the above problems, and is an object of the present invention to provide a hot bed that can be uniformly heated at a fast time by effectively shielding electromagnetic waves and excellent heat generation characteristics to the human body.

The heating bed using the heater of the present invention for achieving the above object is the top plate; A base portion for supporting the top plate and forming a heater receiving portion in the lower portion of the top plate; A pipe-shaped heater that is accommodated in the heater accommodating unit and heats the upper plate when power is applied; A reflection member installed at a bottom of the heater accommodating part and reflecting heat generated from the heater upward; And a metal plate installed between the heater and the upper plate and covering the heater accommodating unit to block electromagnetic waves generated from the heater.

A support means for supporting the heater is installed in the heater accommodating portion, the support means is installed along the bottom edge of the heater accommodating portion and formed lower than the base to form a seating jaw in which the edge of the metal plate is seated. A side frame, a holder frame formed inside the side frame and having a through hole through which the heater penetrates, and formed at the same height as the side frame, and installed inside the side frame to be parallel to the holder frames. It is formed lower than the side frame is characterized in that it comprises a support bar for supporting the heater from the bottom.

The support means is further provided in a direction intersecting the holder frames and the support bars further comprises a partition partition partitioning the inner space of the side frame into two, wherein the heaters are respectively installed with the partition partition therebetween. It is characterized by.

The heater includes a hollow tube containing a heating tube, a heating element received inside the receiving tube, a porous filler filled inside the receiving tube to surround the heating element, and a liquid heat exchange medium impregnated in the filler. It features.

The heater is installed inside the receiving tube is connected to the ground terminal and the heating element further comprises a ground wire wound in a spiral, the heating element is connected to a power source and a heating wire made of carbon fiber bundles, and an insulating coating layer surrounding the heating wire It is characterized by including.

The heater further includes a coating part surrounding the ground wire and the heating element so that the heating element can be fixed while being wound around the ground wire, and the filler is made of ceramic fiber made of basalt material.

A first ground wire installed inside the accommodation pipe and connected to a ground terminal, a cap coupled to both sides of the accommodation pipe to seal the inside of the accommodation pipe, and connected to the cap to the first ground wire or the ground; And a second ground line connected to the terminal.

As described above, the thermal bed of the present invention may provide a safe thermal bed by effectively blocking electromagnetic waves generated from the heater by the ground wire and the metal plate installed in the heater.

In addition, when the carbon fiber is used as the heating element of the heater, the heat generation property is excellent, uniform heating is possible at a quick time, and the heat efficiency is high, and power consumption is low.

1 is an exploded perspective view showing a heated bed according to an embodiment of the present invention,
2 is a cross-sectional view of FIG. 1,
3 is a cutaway perspective view of a heater applied to FIG. 1,
4 is a cross-sectional view of FIG. 3,
5 is a perspective view illustrating a heater applied to a heated bed according to another embodiment of the present invention,
6 is a cross-sectional view showing a heater applied to a thermal bed according to another embodiment of the present invention,
7 is an exploded perspective view showing a heater applied to a warm bed according to another embodiment of the present invention,
8 is an exploded perspective view showing a heater applied to a warm bed according to another embodiment of the present invention.

Hereinafter, a thermal bed using a heater according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in detail.

1 to 4, a thermal bed according to an embodiment of the present invention has a large top plate 110, a base portion 100, a heater 10, a reflective member 140, and a metal plate 115. ).

The upper plate 110 is in the form of a rectangle, is formed in a thin plate shape. The top plate 110 may be made of stone. In addition, it can be formed by kneading the ocher molded into a plate shape. The top plate 110 is formed flat so that people can lie down.

The base part 100 is for supporting the upper plate 110, and includes a base frame 101 having a support leg formed thereon, and a complementary material 105 mounted on the base frame 101.

Base frame 101 is to form the overall frame of the thermal bed, can be formed in a variety of shapes and sizes in addition to those shown. In addition, the base frame 101 may be made of various materials such as natural wood, synthetic wood, plywood, ceramics.

The complementary material 105 is mounted to the base frame 101 to be coupled and separated. The complement 105 has a larger rectangular shape than the top plate. The edge of the complementary material 105 may be covered with a material such as cloth or leather. One side of the complementary 105 is provided with a conventional controller 109 for controlling the on and off and temperature of the heater 10.

In the illustrated example, two controllers 109 are installed. Accordingly, two heaters 10 are also installed in the heating space 107 which will be described later. The two heaters 10 are connected to each controller 109 and controlled independently. This is to divide the top plate 110 into two parts so that each can be independently heated. And unlike that shown, one controller and one heater can be installed, of course.

The base portion 100 is formed with a rectangular heater accommodating portion 107. In the example shown, the heater accommodating part 107 is formed in the base material 105 of the base part. When the upper plate 110 is mounted on the base portion 100, the heater accommodating portion 107 is formed at the lower portion of the upper plate 110.

The heater accommodating part 107 is provided with a heater 10 for heating the upper plate 110. As described above, the heater 10 is provided with two heaters connected to the two controllers 109 and independently controlled.

The bottom of the heater accommodating part 107 is provided with a reflective member 140 for reflecting the heat generated from the heater 10 upward. The silver foil sheet may be applied to the reflective member 140. The silver foil sheet has a structure in which silver foil is formed on an upper surface thereof, and is installed to cover the entire bottom of the heater accommodating part 107.

The pipe-shaped heater 10 is wired in a zigzag shape on the reflective member 140. The support means for supporting the heater 10 wired in this way is provided in the heater accommodating part 107.

As an example of the support means, the side frame 120 formed at the bottom of the heater accommodating part 107, the holder frames 130 having a through hole through which the heater 10 penetrates, and the holder frames 130 are parallel to each other. It is provided with support bars 135 for supporting the heater 10, and a partition partition 125 for dividing the inner space of the side frame 120 into two.

The side frame 120 is formed along the bottom edge of the heater accommodating part 107. Therefore, the side frame 120 is formed in a rectangular frame structure with a space formed inside. Side frame 120 is formed lower than the base material 105 of the base portion. Therefore, the side frame 120 forms a seating jaw in which the edge of the metal plate 115 is seated. The difference between the height of the side frame 120 and the filler material 105 is equal to or greater than the sum of the metal plate 115 and the top plate 110.

When the metal plate 115 is mounted on the base part 100, the edge of the metal plate 115 is seated on the upper surface of the side frame 120, that is, the seating jaw. The upper plate 110 is placed on the metal plate 115 in a state where the metal plate 115 is seated. The metal plate 115 is formed to have the same size as the top plate 120. The metal plate 115 covers the heater accommodating part 107 to block electromagnetic waves generated from the heater 10. The metal plate 115 may be formed of a copper material. The metal plate 115 may be connected to the ground terminal of the controller 109.

The partition partition 125 is installed in the inner space of the side frame 120. The partition partition 125 divides the inner space of the side frame 120 into two. The partition bulkhead 125 is formed at the same height as the side frame 120. Therefore, the upper surface of the partition partition 125 is in contact with the metal plate 115 serves to support the metal plate 115 and the top plate 110. The partition partition 125 is installed in a direction intersecting with the holder frames 130 and the support bars 135 to be described later. Two heaters 10 are installed one by one with the partition partition 125 therebetween.

A plurality of holder frames 130 are installed inside the side frame 120 at regular intervals. The holder frame 130 is formed at the same height as the side frame 120. The holder frame 130 is formed at the same height as the side frame 120. The holder frame 130 is provided with a plurality of through holes at regular intervals.

The support bars 135 are installed inside the side frame 120 to be parallel to the holder frames 130. A plurality of support bars 135 are installed at regular intervals. The support bars 135 are formed lower than the side frames 120 to support the heater 10 passing through the through holes of the holder frames 130 from the bottom.

As described above, the heaters 10 are installed one by one with the partition partition 125 interposed therebetween. The heater 10 is formed in a pipe shape. The heater 10 is disposed in a zigzag shape in the heater accommodating part 107.

In the present invention, any material capable of generating heat by being connected to a power source as a heating element of the heater 10 is not particularly limited. As the heating element, a metal or carbon fiber 27 such as iron chromium or nichrome may be used. Hereinafter, the illustrated examples will be described taking the carbon fiber 27 as an example of the heating element. The heater 10 using the carbon fiber has a smaller heat capacity and superior rising and falling temperature characteristics as compared with the heater using the metal heating element, and also has excellent high temperature durability in a non-oxidizing atmosphere.

The illustrated heater 10 includes a receiving tube 11, a heating element 20, and a filler 30.

The accommodating pipe 11 has a hollow structure and may be formed of various materials. For example, it may be formed of metal, synthetic resin, quartz, or the like. Preferably it may be made of a flexible material to enable bending deformation. The receiving tube may have a structure in which both ends are sealed, or both ends may be in an open structure, and both ends of the receiving tube may be coupled to a cap capable of sealing the inside.

The heating element 20 is installed inside the accommodation tube 11. The heating element 20 generates heat when power is applied. The heating element 20 is formed long along the longitudinal direction of the accommodation tube (11). The heating element 20 is supported by the filler 30, which will be described later, and is disposed in the central portion of the accommodation tube 11.

An example of the heating element 20 shown is provided with a heating wire 25 made of carbon fiber 27, and an insulating coating layer 21 surrounding the heating wire 25.

The hot wire 25 is a form in which the bundle of carbon fibers 27 of several strands. For example, 1000 to 5000 carbon fibers 27 may be arrayed to form a diameter of 1.5 mm to 3.0 mm. The number of strands of the carbon fiber 27 and the diameter of the heating wire can be variously adjusted according to the heater capacity. And unlike shown, the heating wire can be formed in a rope shape by twisting a plurality of carbon fiber 27 strands.

The hot wire 25 is connected to the power supplied to the controller 109. The connection or disconnection of the power source is controlled by the controller 109. Connection terminals for electrically connecting the heating wire 25 to the controller 109 may be formed at both ends of the accommodation pipe 11.

The coating layer 21 is formed outside the hot wire 25. The coating layer 21 binds the carbon fiber strands and at the same time insulates the hot wire 25. The insulating coating layer 21 may be formed by coating a resin having heat resistance together with insulation such as Teflon resin.

As described above, since the heating element 20 is arranged by forming or twisting a plurality of carbon fiber 27 strands, the heating element 20 is rich in bending deformation and flexibility, and is easy to process into various structures and shapes.

Filler 30 is filled in the interior of the receiving tube 11 to surround the heating element (20). Filler 30 has a porous structure. One example of such a filler consists of a cotton structure in which a plurality of short fibers are entangled with each other. Therefore, the filler 30 has a porous structure in which a myriad of empty spaces exist between the fibers. In addition, the filler may be used a non-woven fabric, fabric, etc. that can be impregnated with liquid. In addition, the filler may of course be made of a sponge (sponge) structure in which numerous pores are formed on the surface and inside.

The filler 30 may be formed of various materials such as ceramics, rubber, resins, and fibers. Preferably, the filler 30 is made of a ceramic fiber of basalt material capable of far-infrared radiation (hereinafter referred to as basalt fiber).

Basalt fibers are made using basalt fiber production equipment. For example, a basalt crushed stone having a size of 20 mm or less is melted at 1,440 ° C. to 1,480 ° C., the molten basalt is drawn while maintaining at 1,380 ° C. to 1,480 ° C., and then cooled slowly. Can make The basalt fibers are cut into short fibers and then made into a cotton structure. In contrast, basalt fibers can melt basalt at a high temperature to fiberize in bulk. Basalt Fibers consist of SiO ₂ 47-56 wt%, Al ₂ O ₃ 14 to 19% by weight, Fe ₂ O ₃ 7.0 to 13.5% by weight, CaO 8 to 11% by weight, MgO 3.5 to 10.0% by weight, and the balance of K ₂ O, Na ₂ O, TiO ₂ It can be composed.

The filler 30 described above occupies a space in the accommodating pipe 11 while supporting the heating element 20. Filler (30) made of basalt fibers has a non-combustible and durable effect of preventing fire and improving life. In addition, when the filler 30 is heated, a large amount of far-infrared rays are continuously radiated from the basalt fiber, and may have an effect of heat treatment that promotes metabolism together with a thermal effect.

Far infrared rays are electromagnetic waves having a wavelength in the range of 3 ~ 1000㎛, and far infrared rays have better heat action than direct light, and radiant energy is direct and instantaneous heat transfer. Big.

The liquid heat exchange medium filled in the empty space of the filler 30 and impregnated in the filler serves to transfer the heat generated from the heating element 20 to the accommodation tube 11. The heat exchange medium may exist in a single phase to transfer heat or transfer heat through a phase change process between the gas and liquid phases. Preferably, in order to exert large heat transfer performance, the heat transfer medium transfers heat through a phase change process between the gas phase and the liquid phase. The heat transfer medium absorbs heat generated from the heating element 20 to vaporize, releases heat to the receiving tube, and then liquefies. Thereafter, the heat exchange medium receives heat from the heating element 20 again and repeats the evaporation. As such, heat may be efficiently transferred by using latent heat of evaporation of the heat exchange medium.

It is preferable that the heat exchange medium fills about 60 to 80% of the empty space, rather than all the empty space of the filler 30. Distilled water or brine may be used as the heat exchange medium. In addition, any one of methanol, acetone, and paraffinic compounds may be used.

As described above, the heater 10 using the carbon fiber has excellent temperature characteristics and strong durability. In addition, uniform heating is possible in a short time, so the thermal efficiency is high and the power consumption is low.

Another example of the heater is shown in FIG. Referring to FIG. 5, the heater 40 includes a receiving tube 11, a heating element 20, a ground wire 35, and a filler 30 impregnated with a heat transfer medium. Since the structure of the accommodation tube 11, the heat transfer medium, the filler 30 is the same as the embodiment of Figure 3 will not be described in detail.

The grounding wire 35 is installed inside the accommodation pipe 11. The ground wire 35 is formed of a conductive wire 37 through which current can flow, and an insulating coating layer 39 surrounding the conductive wire 37. One end of the ground line 35 may be connected to the accommodation pipe 11, and the other end may be connected to the ground terminal of the controller 109. Since the ground wire 35 is built in the accommodating pipe 11 itself, safety can be ensured when the heat generator 20 is shorted, and when the heater 40 is used, there is no need for a separate operation for grounding.

The heating element 20 is spirally wound around the ground wire 35. The heating element 20 has the same structure as the heating element of FIG. 3, that is, a heating wire 25 made of a bundle of carbon fibers 27 and an insulating coating layer 21 surrounding the heating wire 25.

Meanwhile, as illustrated in FIG. 6, a coating unit 50 coated with a coating material may be formed so that the heating element 20 may be fixed in a spiral wound around the ground line 35. The coating part 50 surrounds the ground wire 35 and the heating element 20 to make the ground wire 35 and the heating element 20 integrally. Teflon resin may be used as the coating material.

7 illustrates a heater applied to another embodiment of the present invention.

Referring to FIG. 7, the heater 91 largely includes a receiving tube 11, a heating element 70, a filler 30, and a cap 95.

The accommodating pipe 11 has a cylindrical hollow structure and has an open shape at both ends. The heating element 70 and the first ground line 75 are provided inside the accommodation tube 11. The filler 30 impregnated with the heat transfer medium is filled in the inner space of the accommodation pipe 11. The heat transfer medium and the filler are the same as in the embodiment of FIG. 3.

The heating element 70 is installed so that one end may return to one end of the accommodating tube 11 so that both ends thereof may extend to the other end of the accommodating tube 11. The heating element 70 includes a heating wire (not shown) made of a carbon fiber bundle and an insulating coating layer 71 surrounding the heating wire. The first ground line 75 is installed inside the accommodation pipe 11. The first ground line 75 is formed of a conductive wire (not shown) through which current can flow, and an insulating coating layer 77 surrounding the conductive wire.

Cap 95 is provided to seal the open both ends of the receiving pipe (11). The cap 95 is formed with an insertion groove 97 into which the end of the receiving tube 11 can be inserted. The cap 95 may be provided with a sealing member such as an O-ring for airtightness. An end of the accommodation tube 11 is inserted into the insertion groove 97 is fitted to the cap (95). Cap 95 may be formed of a conductive metal material.

Caps 95 are respectively coupled to both sides of the receiving tube 11, the other side cap not shown may be formed with a connection terminal to which the heating element 70 and the first ground line 75 is connected. In this case, the connection terminal is connected to the power cable.

The second ground line 93 may be connected to the cap 95 to be connected to the first ground line 75 or to the ground terminal of the controller. When the second ground line 93 is installed, the cap 95 is formed of a conductive material such as metal. The electric charge charged to the accommodation pipe 11 can be sent by the second ground wire 93 to effectively block the electric wave.

8 shows a heater applied to another embodiment of the present invention. Referring to FIG. 8, the heater 60 largely includes a receiving tube 11, a heating element 70, a filler 30, a cover tube 61, and a cap 80.

The accommodating pipe 11 has a cylindrical hollow structure and has an open shape at both ends. The heating element 70 and the first ground line 75 are provided inside the accommodation tube 11. The filler 30 impregnated with the heat transfer medium is filled in the inner space of the accommodation pipe 11. The heat transfer medium and the filler are the same as in the embodiment of FIG. 3.

The heating element 70 is installed so that one end may return to one end of the accommodating tube 11 so that both ends thereof may extend to the other end of the accommodating tube 11. The heating element 70 includes a heating wire (not shown) made of a carbon fiber bundle and an insulating coating layer 71 surrounding the heating wire. The first ground line 75 is installed inside the accommodation pipe 11. The first ground line 75 is formed of a conductive wire (not shown) through which current can flow, and an insulating coating layer 77 surrounding the conductive wire.

The cover tube 61 is formed in a cylindrical shape having a diameter larger than the diameter of the accommodation tube 11. Both ends of the cover tube 61 has an open structure. The cover tube 61 may be formed to the same length as the receiving tube (11). The cover tube 61 protects the accommodating tube 11 by accommodating the accommodating tube 11 therein.

Cap 80 is provided to seal the open both ends of the cover tube 61 and the receiving tube (11). The cap 80 has a first coupling portion 83 forming a first insertion groove 81 into which one end of the accommodation tube 11 can be inserted, and a second insertion groove into which the cover tube 61 can be inserted. The second coupling part 87 forming the 85 is provided. The cap 80 may be provided with a sealing member such as an O-ring for airtightness.

The first coupling portion 83 is formed in a cylindrical shape that is open in the direction of the receiving tube 11 to form a circular first insertion groove 81 therein. One end of the accommodating tube 11 is inserted into the first insertion groove 81, and the accommodating tube 11 is fitted into the first coupling part 83. The inner diameter of the first coupling portion 83 is formed in such a size that the receiving tube 11 can be fit into the first insertion groove 81.

The second coupling portion 87 is formed in a cylindrical shape open in the cover tube 61 direction to form an annular second insertion groove 85 therein. The second coupling portion 87 is formed to surround the first coupling portion 83 at the outside of the first coupling portion 83. The first and second coupling portions 83 and 87 are formed concentrically. The second insertion groove 85 is provided between the first coupling portion 83 and the second coupling portion 87. One end of the cover tube 61 is inserted into the second insertion groove 85 so that the cover tube 61 is coupled to the second coupling portion 87. The inner diameter of the second coupling portion 87 is formed in such a size that the cover tube 61 can be pressed into the second insertion groove 85.

Caps are respectively coupled to both sides of the cover tube 61, the other side cap not shown may be formed with a connection terminal to which the heating element 70 and the first ground line 75 is connected. In this case, the connection terminal may be connected to the controller.

The second ground line 90 may be connected to the cap 80 to be connected to the first ground line 75 or to the ground terminal of the controller. When the second ground line 90 is installed, the cap is formed of a conductive material such as metal. When the accommodating pipe 11 and the cover pipe 61 are charged by the second grounding wire 90, electricity can be sent and the electric wave can be effectively blocked.

The heater according to the various embodiments described above is mounted to the heater mounting portion to heat the top plate.

In the above, the present invention has been described with reference to one embodiment, which is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments are possible.

Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

10: heater 11: receiving pipe
20: heating element 25: heating wire
27: carbon fiber 30: filler
35: ground wire 100: base portion
101: base frame 105: complementary
110: top plate 115: metal plate

Claims (7)

A top plate;
A base part supporting the upper plate and forming a heater accommodating part in a lower portion of the upper plate;
A pipe-shaped heater that is accommodated in the heater accommodating unit and heats the upper plate when power is applied;
A reflection member installed at a bottom of the heater accommodating part and reflecting heat generated from the heater upward;
And a metal plate installed between the heater and the upper plate and covering the heater accommodating part to block electromagnetic waves generated from the heater.
Support means for supporting the heater is provided in the heater housing,
The support means is installed along the bottom edge of the heater accommodating portion and is formed lower than the base portion to form a seating jaw for the edge of the metal plate is seated, and installed inside the side frame and the heater penetrates Holder frames having through holes formed and formed at the same height as the side frames, and supporting bars installed inside the side frames to be parallel to the holder frames and lower than the side frames to support the heaters from below. Equipped with
The support means further includes a partition partition wall installed in a direction crossing the holder frames and the support bars to divide the inner space of the side frame into two,
The heater is a thermal bed using a heater, characterized in that each installed between the partition partition. delete delete The method of claim 1, wherein the heater is a hollow tube receiving structure, a heating element accommodated in the interior of the receiving tube, a porous filler filled in the receiving tube to surround the heating element, and a liquid of the impregnated in the filler Thermal bed using a heater, characterized in that provided with a heat exchange medium. According to claim 4, wherein the heater is provided in the interior of the receiving tube is connected to the ground terminal and the heating element further comprises a ground wire wound spirally,
The heating element is connected to a power source and a heating bed made of a carbon fiber bundle, and a thermal bed using a heater, characterized in that it comprises an insulating coating layer surrounding the heating wire. The method of claim 5, wherein the heater further comprises a coating portion surrounding the ground wire and the heating element so that the heating element can be fixed in a state wound around the ground wire,
The filler is a thermal bed using a heater, characterized in that made of a ceramic fiber of basalt material. According to claim 4, The first grounding line is installed in the interior of the receiving tube connected to the ground terminal, Caps for coupling to both sides of the receiving tube to seal the inside of the receiving tube, respectively, and the cap is connected to the A heated bed using a heater further comprising a first ground line or a second ground line connected to the ground terminal.

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