KR200293205Y1 - Magnetic field reducing safety heating plate - Google Patents

Abstract

Disclosed information is to increase the heating effect and to attenuate the magnetic field by using a magnetic pole reducing heating wire using a carbon diagonal heating element, and to arrange the magnetic pole reducing heating line in a stable state to improve the safety in use It relates to a reduced safety heating plate.

The present invention has a main nonwoven fabric made of flame retardant long fibers having a thickness of 3 to 5 mm, a heat resistant auxiliary nonwoven fabric laminated on the main nonwoven fabric having a thickness thinner than that of the main nonwoven fabric, and a receiving portion is provided between the auxiliary nonwoven fabric and the main nonwoven fabric. Quilting member for quenching and fixing the auxiliary nonwoven fabric in the longitudinal direction with a 1/2 inch gap on the main nonwoven fabric, and the remaining portions except the bent portion are inserted and fixed in a zigzag shape in the middle of the receiving portion to generate heat by heat resistance. The heating wire is composed of a carbon fiber group having a predetermined heat resistance and braided and wound around with an insulated yarn and coated with silicon on the carbon wire heating element and the carbon wire heating element having the same length as the carbon wire heating element. Metallic resistive conductors coated with pron or silicon are braided and rinsed through an insulator It is composed of close contact with each other.

Description

Magnetically polarized safety heating plate {omitted}

The present invention relates to a magnetic pole-type safety heating plate, and more particularly, by using a magnetic pole-type heating wire using a carbon diagonal heating element, the heating effect is increased and the magnetic field is attenuated, and the gap between the magnetic pole-type heating wires is stably maintained. It is to improve the safety in use by being arranged in a state.

As is well known, the heating plate is fixed in a zigzag form of a heating wire in a flat and flat member such as a cotton ball, and when the power is applied, the heating wire acts as a resistor and generates heat and uses the heat. It is applied to bedding-type medical devices such as electric blankets, mats, electric stone beds, home thermotherapy machines, home prepositioning machines, home thermoelectric positioners, home transformer devices, and the like.

However, in the case of such a common heating plate, a large amount of electromagnetic waves are generated from the copper wire that is used as the heating wire, which causes harm to the human body. Recently, research on the magnetic field-reducing heating wire which has a high heating effect but generates little magnetic field is actively conducted. Indeed, the present inventors have registered a carbon yarn linear heating element which is processed by braiding and rinsing on the exposed surface of a carbon yarn group heating element and a carbon yarn group heating element formed of at least one carbon fiber having a predetermined thermal resistance in the Korean Utility Model Registration No. 207404. And a magnetic pole-type heating wire using a carbon yarn linear heating element having a silicon member which has a length substantially the same as that of the carbon diagonal heating element, and which is coated with one of enamel and tin plating and a flame retardant non-resistive metal wire coated in the order of Teflon. Utility Model No. 209064 In which the conductive metal wire is plated with a silicone rubber or synthetic resin around the two (2) conductors which have a constant distance between the non-resistive conductive metal wire coated with a flame retardant insulator such as Teflon and the carbon yarn heating element. A magnetic pole type electric heating wire using a carbon fiber linear heating element in which an outermost coating layer is formed has been disclosed.

In the electric heating wire using the carbon diagonal heating element, a plurality of carbon fibers thinner than the hair are arranged in a group, and when power is applied, hot electrons are emitted from the plurality of carbon fibers to generate heat having a predetermined temperature. According to the bundled state, the heat resistance according to the electric conduction is shown differently, and the heat generated from each carbon fiber is combined to generate high heat.The heating element and the heating wire are provided on the heating element body, and each wire is connected at one end of the heating element. When the power is connected to both terminals of the other end, the reciprocating current flows along each line, and when the same amount of reciprocating current flows in the heat generating line and the lead line, the generated magnetic flux increases the paramagnetic coupling, Heating is very small and no magnetic field is generated. Heating wire and lead wire The magnetic field offset rate is high only when the wires have the same length and the wires are completely in contact with each other.However, the resistance of the carbon wire heating element and the resistance wire can be prevented from being deteriorated by the heat generated from the carbon wire heating element. Many devises such as the above appeared to be in close contact with keeping the minimum spacing.

However, the heating wire using the carbon diagonal heating element disclosed in Korean Utility Model Registration No. 207404 or 209064 has a very complicated structure, and the carbon fiber or the outer covering layer is made of expensive silicone rubber or synthetic resin. As a result, manufacturing costs are increased, and heat resistance, but the thickness is too thick, workability and productivity are falling. When the heating wire using the carbon diagonal heating element is actually fixed to the heating plate, its volume and weight are heavy, which makes it difficult to handle as well as difficult to fix the heating plate.

On the other hand, the heating plate using a heating wire as described above is using a method of fixing the heating sheet alternately by fixing the heating sheet up and down by bonding an aluminum sheet thereon in a state in which the heating wires are arranged at regular intervals, or a hole in a general nonwoven fabric. In this case, as the high heat generated from the heating wire is repeatedly supplied to the aluminum sheet, the adhesive state that fixes the heating wire is deformed, and eventually, the bonded aluminum sheet is dropped and the arrangement of the heating wire is collapsed. Since a number of hand movements are repeatedly made because they must be staggered along the formed holes, there is a problem in that productivity is reduced.

Therefore, the general method as described above has a problem in that the productivity is lowered, the production cost is increased, the life is shortened due to frequent failures, and the risk of fire is always inherent due to an incomplete arrangement.

The present invention was devised to solve the above problems, but the heating wire is configured using carbon diagonal heating element, but the configuration is very simple and the volume is minimized, and the magnetic pole reducing heating wire is used to configure the heating plate. It is possible to easily fix the heating wire to the base fabric at uniform intervals, and to maintain the fixed position against any external force so that the heating performance is maintained at the same level, while reducing manufacturing cost, workability and productivity. It is an object of the present invention to provide a magnetic pole reducing safety heating plate capable of improving and minimizing magnetic field and improving safety and reliability in use.

1 is a block diagram of a magnetic pole reducing safety heating plate according to the present invention.

2 is a cross-sectional view taken along the line AA ′ of FIG. 1.

3 is a perspective view of a heating wire using a carbon diagonal heating element according to the present invention.

*** Explanation of symbols for main parts of drawing ***

10: main nonwoven fabric 20: auxiliary nonwoven fabric

30: accommodating part 40: quilting member

50: heating wire 51: carbon fiber or carbon fiber group

52,57: insulator 53: silicon

54 carbon diagonal heating element 55 Teflon or silicon

56: non-resistive conductor

Hereinafter, the present invention will be described in detail through embodiments of the present invention.

Magnetically sensitive safety heating plate according to the present invention is relatively flame-retardant and has a thickness of 3 to 5mm in the same area as the electric blanket or the electric blanket of the target as shown in Figures 1 and 2 Between the main nonwoven fabric 10, the heat-resistant auxiliary nonwoven fabric 20 laminated on the main nonwoven fabric 10 with a thickness thinner than the main nonwoven fabric 10, and between the auxiliary nonwoven fabric 20 and the main nonwoven fabric 10. 륵 quilting member (40) for fixing the auxiliary nonwoven fabric 20 to the main nonwoven fabric 10 in the longitudinal direction with a gap of 1/2 inch to the receiving portion 30, and the remaining portion except the bent portion Is inserted into and fixed in a zigzag shape in the middle of the receiving portion 30 is composed of a heating line 50 for generating heat by heat resistance.

At this time, the auxiliary nonwoven fabric 20 is composed of a paper nonwoven fabric having a heat resistance of about 0.2mm, the length of the heating wire 50 is 30 ~ 45m, the size of the heating plate is 120 ~ 140cm x 100 ~ 120cm, heating wire 50 The quilting member 40 is fixed every three or four spaces in the 1 / 2-inch spaced receiving portion 30 is quilting, when the space is arranged in a zigzag every three spaces, the interval between the 3.8cm ± 5% In the case of being arranged in zigzag every four spaces, the interval therebetween is 5 cm ± 5%, which indicates the heating range of the heating wire 50.

In addition, the heating wire 50 is braided and rinsed through the insulated yarn 52 such as glass fiber is carbon fiber group 51 having a predetermined heat resistance as shown in Figure 3, coated with silicon 53 thereon Insulating yarns, such as glass fibers, are formed of a carbon diagonal heating element 54 and a metallic non-resistive conductor 56 coated with Teflon or silicon 55 having the same length as the carbon diagonal heating element 54 and having heat resistance to the outside. 57) is braided and rinsed and is in close contact with each other.

In addition, although not shown in the middle of the heating line 50 and the heating line 50 is installed a temperature sensor for sensing the temperature and bimetal for preventing overheating, respectively, because the interval between the heating line 50 and the heating line 50 is constant It is designed to create a safety heating plate with a uniform thermal distribution and no risk of overheating because the function of the sensor is operated correctly and the bimetal operation function to prevent overheating is operated correctly.

Referring to the operation of the magnetic pole reducing safety heating plate according to the present invention configured as described as follows.

First, since the heating wire 50 according to the present invention uses the carbon diagonal heating element 54, a plurality of carbon fibers 51 thinner than the hair are basically arranged in a group in the longitudinal direction, so that a constant power source is provided at the terminal of the terminal. When it is applied, hot electrons are emitted from the plurality of carbon fiber groups 51, and thus heat having a temperature of cleansing is generated, and the carbon fiber 51 is one strand, two strands, three strands, and a conductive material that emits hot electrons. According to the bundled state, etc., the heat resistance according to the electric conduction appears differently and heat can be generated accordingly.

In addition, the heating wire 50 is formed of two strands of the carbon diagonal heating element 54 and the non-resistive conductor 56, and the wires 54 and 56 are connected at one end thereof, and power is supplied to both terminals of the other end. Since it is applied, the reciprocating current flows along each of the lines 54 and 56, so that the generated magnetic flux increases the paramagnetic coupling degree, thereby minimizing leakage stimulation, and heating, but no magnetic field is generated.

By the way, in order to cancel the total amount of the magnetic field as described above, each of the lines 54 and 56 arranged in the same length should be configured to be in close contact with each other so that the same amount of reciprocating current flows. In the case of the same length of each wire, even if the thickness of the heating wire is too thick it is difficult to be fixed to the heating plate has been described above.

In this design, it is easy to handle and fix the heating plate in consideration of this, and to provide heating lines 50 having the maximum magnetic field offset effect by knowing that the lines 54 and 56 are not deteriorated while being in close contact with each other. , The heating wire 50 according to the present invention is braided and rinsed through the carbon fiber group 51 having a predetermined heat resistance through an insulated yarn 52 such as glass fiber, coated with silicon 53 thereon The carbon yarn-like heating element 54 and the metallic non-resistive conductor 56 coated with Teflon or silicon 55 having the same length as the carbon yarn-like heating element 54 and having heat resistance to the outside are insulated yarns 57 such as glass fibers. Braided and rinsed through)

Even when the two wires 54 and 56 are in close contact with the insulated yarn 52 and silicon 53 surrounding the carbon fiber group 51 and the Teflon or silicon 55 surrounding the non-resistive conductor 56, the carbon diagonal heating element The non-resistive conductor 56 is not deteriorated by the heat generated from the 54, and each of the wires 54 and 56 is braided and rinsed with the insulated yarn 57 again so that the contact state is not thick. You can keep it as it is.

When fixing the heating wire 50 using the carbon diagonal heating element 54 to the heating plate, the upper side of the accommodating portion 30 of the auxiliary nonwoven fabric 20 is torn by using a long rod (not shown). 50 is inserted, tears the lower side of the receiving portion 30 of the auxiliary nonwoven fabric 50, draws out the heating wire 50, and skips the receiving portion 30 two or three spaces again to the secondary nonwoven fabric 20 By tearing the lower side of the receiving portion 30 of the heating wire 50 is inserted into the inside, and repeating the process of drawing the heating wire 50 by tearing the upper side of the receiving portion 30 of the auxiliary nonwoven fabric 20 (heating wire ( 50) are arranged in zigzag at regular intervals, 3.8cm ± 5% or 5cm ± 5%, on the heating plate.

At this time, the receiving portion 30 is quilted by the 1/2 inch interval by the quilting member 40, so that the heating wire 50 is inserted into the receiving portion 30 can be supported in place without flow to the left and right sides. Even if the insulated yarn 57, such as glass fiber, is destroyed by the heat of the carbon diagonal heating element 54, even if the carbon diagonal heating element 54 and the non-resistive conductor 56 are released, the narrow space forming the accommodating part 30 is obtained. Since it is positioned within (1/2 inch), the carbon diagonal heating element 54 and the non-resistive conductor 56 can be kept in close contact with each other to perform a continuous magnetic field attenuation function.

In addition, the temperature sensor and the bimetal is installed in the middle of the receiving portion 30 between the arrangement of the heating wire 50, which can also maintain the installation position by the receiving portion 30 of the 1/2 inch interval, so that the correct temperature Sensing function and temperature prevention function can be performed.

Therefore, the magnetic field attenuation function may be continuously performed through the configuration of the heating wire 50 itself, and the arrangement position of the heating wire 50 may be continuously maintained, thereby causing overheating or fire due to the close contact of the heating wire 50. It is possible to implement a safe heating plate without.

As described above, the heating wire and the heating wire are fixedly spaced and the heating wire accommodating part has a space of 1.27 cm, and the heating wire has the present invention in which the arrangement is continuously maintained without left and right flows. The uniformity of the heating wire and the risk of overheating due to the close contact with the heating wire, as well as the temperature sensing function and the prevention of overheating bimetal function, can be safe.

In addition, the structure of the magnetic field (magnetic field) ultra-short heating wire itself is simple, which reduces the cost of silicon coating, reduces the weight of the heating wire, and reduces the volume.It is easy to insert the heating wire into the heating wire accommodating part. Have

Claims (3)

A main nonwoven fabric 10 of flame retardant long fibers having a thickness of 3 to 5 mm; A heat resistant auxiliary nonwoven fabric 20 having a thickness thinner than that of the main nonwoven fabric 10 and laminated on the main nonwoven fabric 10; The auxiliary nonwoven fabric 20 is quilted in the longitudinal direction with a space of 1/2 inch between the auxiliary nonwoven fabric 20 and the main nonwoven fabric 10 so that the receiving portion 30 is provided between the auxiliary nonwoven fabric 20 and the main nonwoven fabric 10. Quilting member 40 to be fixed by; And Magnetic field reduction type safety heating plate, characterized in that the remaining portion other than the bent portion includes a heating wire (50) is inserted and fixed in a zigzag shape in the middle of the receiving portion 30 to generate heat by heat resistance. The method of claim 1, The length of the heating wire 50 is 30 ~ 45m, the size of the heating plate is 120 ~ 140cm × 100 ~ 120cm, the placement distance of the heating wire 50 is any one of 3.8cm ± 5%, 5cm ± 5% , The magnetic pole reducing safety heating plate, characterized in that the heating line 50 is arranged in a zigzag at intervals between the arrangement distance. The method of claim 1, The heating wire 50 is carbon fiber group 51 having a predetermined heat resistance is braided and rinsed through an insulated yarn 52 and coated with a silicon 53 on the carbon diagonal heating element 54, A metallic non-resistive conductor 56 having the same length as the carbon diagonal heating element 54 and coated with Teflon or silicon 55 on the outside is braided and rinsed through the insulated yarn 57 to be in close contact with each other. Magnetically polarized safety heating plate.