KR20170135776A - Heater for electronic thermostat and method for fabricating elecronic thermostat - Google Patents

Abstract

The present invention provides a heater for an electronic thermostat and a method for manufacturing an electronic thermostat which can increase durability and operation reliability of an electronic thermostat while increasing productivity and reducing the manufacturing costs by reducing the number of components and reducing the production costs while increasing a fastening force between a wax case and the heater by improving a structure of the heater for the electronic thermostat. To this end, the heater for an electronic thermostat comprises: a hollow structural tube of which one side is opened, and the other side is closed; a heating member provided inside the tube, and heating by an electric resistor; and a lead line for supplying power to the heating member. The tube is directly inserted into a fastening hole of the wax case through forcible fitting so as to install the heater in the wax case.

Description

Technical Field [0001] The present invention relates to a heater for an electronic thermostat and an electronic thermostat using the same,

The present invention relates to an electronic thermostat, and more particularly, to a heater applied to an electronic thermostat applied to open and close a valve at a predetermined temperature to circulate cooling water to keep the temperature of an automobile engine constant, and a thermostat ≪ / RTI >

Generally, the thermostat for automobile is installed between the engine and the radiator, and automatically keeps the temperature of the cooling water in the set temperature range by controlling the flow rate to the radiator while automatically opening and closing the cooling water according to the temperature change.

In the mechanical thermostat, the wax expands according to the temperature of the cooling water, and the piston causes the opening and closing displacement of the valve by the expansion force.

Such a mechanical thermostat operates in accordance with an opening / closing temperature set at a specified temperature, and simply opens and closes a valve at a predetermined temperature. In this way, the mechanical thermostat can actively cope with a demand for high performance and high efficiency of the vehicle, can not do it.

In order to overcome the disadvantages of the mechanical thermostat, an electronic thermostat having a variable control system that can artificially control the expansion of the wax has been developed and applied to real vehicles.

The electronic thermostat can maintain the optimum cooling water temperature by actively controlling the cooling water temperature of the engine according to the driving environment such as the load condition of the vehicle, and it can be expected to improve the fuel economy and reduce the exhaust gas compared with the mechanical thermostat .

In order to actively control the cooling water temperature, a cartridge heater is employed for the electronic thermostat. The heater for the thermostat is coupled to the wax case to act as a heat source for artificially supplying heat to the wax filled in the wax case, It is possible to improve the open /

In other words, the electronic thermostat is usually composed of a basic component of the conventional mechanical thermostat, and includes a cartridge heater which reacts with the wax by generating heat when power is supplied, so that the temperature of the vehicle, the temperature of the intake air, And the opening / closing timing of the valve is variably controlled by adjusting the amount of heat generated by the cartridge heater according to the driving environment of the vehicle.

FIG. 1 is a cross-sectional view showing an example in which a heater for a conventional thermostat is mounted on a wax assembly, and FIG. 2 is a perspective view of a heater for a thermostat in FIG.

1 and 2, a conventional cartridge heater 100 for an electronic thermostat, as shown in FIG. 1, expands and contracts according to temperature in a wax case 9 built in a thermostat, Is inserted into the wax (W) reciprocating the wax (20).

Here, the wax case 9 has a wax receiving space in which the wax W is filled, and a fixing part 15 on which the cartridge heater 100 is mounted is formed.

That is, the cartridge heater 100 is mounted on the fixing portion 15 of the wax case 9 by a screw fastening method using a fastening metal fitting 150 and is heated according to whether power is applied thereto, As shown in FIG.

The thermostat cartridge heater 100 includes a bobbin 110, a tube 120, an insulating material 130, an insulating cap 140, and a fastening bracket 150, as shown in Figs. .

First ends of the lead wires 111 connected to the external power source are inserted into both sides of the bobbin 110 and coils 113 connected to the respective lead wires 111 are wound on the outer circumferential surface.

Here, each of the lead wires 111 is connected to an external power source via a connection connector (not shown), and currents of different polarities are applied thereto. The coil 113 has one end thereof connected to one of the lead wires 111, And the other end may be connected to one lead wire 111 that is left.

Accordingly, when power is supplied to the lead wire 111, a current is transmitted to the coil 113 through the lead wire 111, and the coil 113 can generate heat as the current flows along the coil 113.

One end of each of the lead wires 111 mounted on the bobbin 110 is inserted into the tube 120 while the other end of the tube 120 is closed and the bobbin 110 is inserted from one end to the other end of the tube 120 And is mounted so as to protrude outward.

One end of the tube 120 is closed inside the wax W and the temperature of the wax W is increased by using the heat generated from the coil 113 to prevent the coil 30 from being chemically attacked .

The insulating material 130 is filled in the tube 120 in a state where the bobbin 110 is inserted. The insulating material 130 is made of magnesium oxide (MgO) powder.

The magnesium oxide (MgO) powder maintains insulation between the tube 120 and the coil 113 to prevent the current flowing in the coil 113 from being transmitted to the tube 120, And the heat generated in the coil 113 is transmitted to the tube 120.

The tube 120 is filled with the insulating material 130 in a state where the lead wire 111 and the bobbin 110 with the coil 113 are inserted and the insulating cap 140 is completely mounted , Swaging molding is performed so that the outer diameter of the set dimension and the closed end have a curved surface.

The fastening metal bracket 150 is attached to the other end of the tube 120 while being wrapped around the outer circumferential surface of the other end of the tube 120 and fastened to the wax case 9, ) Is held in the state of being inserted into the wax (30).

In this case, the tube 120 is press-fitted and fixed in a state where a closed end of the tube 120 is partially protruded from the fastening bracket 150, so that the tube 120 is not separated from the fastening bracket 150 Can be prevented.

The fastening metal bracket 150 is threaded along the circumference of the outer circumferential surface and screwed to the fixing portion 15 of the wax case 9 through the thread N. [

The fastening bracket 150 may have a bush 160 for fixing the lead wires 111 protruding from the end of the tube 120 opposite to the tube 120.

However, such a heater for an existing electronic thermostat uses a fastening bracket 150 for fastening to a wax case and hermetically sealing the wax, and has the following problems.

The conventional thermostat heater structurally requires a fastening metal fitting 150. The fastening metal fitting 150 functions as an intermediate medium for fastening the heater to the wax case and prevents leakage of the wax, It also serves as a minus terminal for grounding and is therefore recognized as an essential part.

Accordingly, the fabrication and assembling steps of the fastening bracket 150 must be accompanied by a complicated manufacturing process of the thermostat, which leads to a decrease in productivity and an increase in manufacturing cost there was.

Specifically, conventionally, in order to apply the heater for the thermostat, a separate manufacturing step of a metal fitting to be connected to a tube constituting the heater for the thermostat must be accompanied, and a step of forming a female thread on the wax case is essential And a step of forming male threads corresponding to female threads of the wax case on the outer surface of the metal fitting.

The heater for the conventional thermostat has a structure in which the lead wire 111 is inserted into the bobbin 110 and the coil 113 is wrapped around the bobbin 110 and the lead wire 111 and the coil 113) are connected to each other.

Accordingly, the number of components is increased due to the necessity of a metal bracket to fasten the heater for the thermostat to the wax case, and the complicated and many manufacturing processes and assembling processes are involved. There is a problem that the cost is increased.

Further, conventionally, when used for a long period of time, there is a case that the fastening force is decreased due to the loosening phenomenon of the metal fittings and the wax case in the screw fastening part due to the vibration of the vehicle, and consequently, the airtightness to the wax is deteriorated.

In addition, the conventional thermostat heater requires a bobbin to be prepared, a lead wire is inserted into the bobbin, a coil is wound on the bobbin, and a coil is connected to the lead wire. The process is also complicated and a large number of parts are required, which also has a disadvantage of lowering the productivity and increasing the manufacturing cost in manufacturing the thermostat.

Therefore, in manufacturing an electronic thermostat, it is possible to increase the productivity and reduce the manufacturing cost, and furthermore, there is a continuing need for a structural improvement that improves the durability and operation reliability when the thermostat is applied to the thermostat.

Korean Patent No. 10-1497655 (Feb. 23, 2015) Korean Patent Publication No. 10-2013-0114505 (October 17, 2013) Korean Patent Publication No. 10-2013-0113824 (October 16, 2013)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to improve the structure of a heater for an electronic thermostat, thereby reducing the number of parts and cost reduction while increasing the fastening force between the wax case and the heater, The present invention has been made to solve the above problems.

It is another object of the present invention to provide a heater for an electronic thermostat which can improve durability and operational reliability of an electronic thermostat.

According to an aspect of the present invention, there is provided a vacuum cleaner comprising: a hollow tube having an open side and a closed side; A heating member disposed inside the tube and generating heat by electrical resistance; And a lead wire for supplying power to the heating member, wherein the tube is tightly fitted to the fastening hole of the wax case directly, so that the heater is mounted on the wax case.

The heater for an electronic thermostat of the present invention provides the following effects.

First, the heater for an electronic thermostat according to the present invention omits a heater fastening bracket to simplify a structure and a processing step, thereby improving workability and productivity for mass production in manufacturing and assembling, Cost can be reduced.

That is, in the heater for the electronic thermostat according to the present invention, the bracket for mounting the heater through the screw connection is omitted in the heater mounting portion, so that the necessary components such as the insulator, o-ring, The air flow rate is reduced, productivity is improved, and manufacturing cost is reduced.

Particularly, in the past, the sealing performance of the electronic thermostat deteriorates due to the loosening phenomenon of the wax case due to the loosening of the metal fittings and the wax case. However, in the present invention, The electronic thermostat according to the present invention can improve the operational reliability and control response of the electronic thermostat because the tube is forcedly fitted to the wax case so that the tightening force between the parts of the heater and the wax assembly is further increased so that the airtightness of the wax does not deteriorate. Lt; / RTI >

Further, the heater for an electronic thermostat according to the present invention provides an effect of further increasing the service life of the heater and the reliability of the product as the insulation between the components disposed in the tube is sufficiently secured.

Meanwhile, since the heater for the electronic thermostat according to the present invention is constructed such that the first lead wire, the second lead wire, and the tube for supplying power are kept insulated from each other, unlike the conventional heater for the thermostat, There is no phenomenon that the foreign substance is fixed to the valve operating portion.

That is, in the conventional thermostat heater, the tube and the fastening metal are electrically connected to each other, and the metal is grounded to the vehicle body. Due to the electric conduction between the metal and the wax case, However, in the heater for the thermostat according to the present invention, since the tube is insulated from the heat generating coil, the electrolysis phenomenon of the cooling water is fundamentally eliminated.

Accordingly, the heater for the electronic thermostat according to the present invention can reliably solve the problem of foreign matter sticking at the valve operating area due to the cooling water electrolysis, thereby enhancing the durability and operational reliability of the electronic thermostat.

1 is a cross-sectional view showing a state where a heater for a conventional thermostat is mounted on a wax assembly
Fig. 2 is a perspective view of the heater for the thermostat of Fig. 1
3 is a longitudinal cross-sectional view of a heater for an electronic thermostat according to the present invention
4 is a cross-sectional view taken along the line I-I in Fig. 3;
Figure 5 is a perspective view of the insulation spacer of Figure 4;
Fig. 6 is a front view of the heating member of Fig. 4
7 is a longitudinal sectional view after the swaging of the heater for the electronic thermostat according to the present invention
8 is a cross-sectional view showing a state where a heater for an electronic thermostat of the present invention is mounted on a wax assembly
FIG. 9 is a process block diagram showing steps of manufacturing the electronic thermostat to which the heater for the electronic thermostat of the present invention is applied

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to FIGS. 3 to 9.

3 to 9, a heater H for an electronic thermostat according to the present invention includes a tube 1 having a hollow structure with one side opened and the other side closed, And a lead wire (3a, 3b) for supplying power to the heat generating member, wherein the tube (1) is directly connected to the fastening hole of the wax case (9) Fitted to the wax case 9 in an interference fit manner.

At this time, the lead wire is a positive terminal exposed at one end to the outside of the tube 1 and at the other end to the inside of the tube 1 and being powered from the outside through one end exposed to the outside of the tube 1 A first lead wire 3a and a second lead wire which is a minus terminal which is exposed at one end outside the tube 1 and is located at the other end inside the tube 1 and spaced apart from the first lead wire 3a, 3b.

The heating member is a heat generating coil 2, which is generally helically wound, and is connected to the ends of the first lead wire 3a and the second lead wire 3b, respectively.

The lower end portion and the upper end portion of the heat generating coil 2 are in the form of a coil whose diameter is reduced in accordance with the diameters of the lead wires 3a and 3b different from the rest of the large diameter and the first lead wire 3a and the second lead wire 3b After the end portions of the first lead wire 3a and the second lead wire 3b and the lower end portion and the upper end portion of the heat generating coil 2 are fitted to each other, electrical resistance welding or laser welding is performed, (3a, 3b) and the corresponding end of the heat generating coil (2) are joined to each other.

Since the lower end portion of the heat generating coil 2 is formed to be disposed at the center of the tube, the middle portion of the first lead wire 3a is bent and the insulation and the withstand voltage of the second lead wire 3b are secured A first section linkage 8a is provided.

That is, the portion above the folding point of the first lead wire 3a is a distance at which sufficient insulation with the second lead wire 3b is maintained, but a portion below the folding point is located at the center of the tube 1, Since the first lead wire 3a can be brought close to the second lead wire 3b in the coupling relation, the first lead wire 8a is provided below the bending point of the first lead wire 3a for securing the insulation property and the withstand voltage between the lead wires in this area will be.

Therefore, both side ends of the heat generating coil 2 must be inserted before being welded to the tip portions of the first lead wire 3a and the second lead wire 3b, and the phenomenon of being released before welding in the inserted state can be prevented The ends of the heat generating coil 2 may have a reduced diameter.

Inside the tube 1, an insulating cap 4 for sealing the inlet of the tube 1 is provided. Inside the tube 1, a powdery insulating material (not shown) ), And as the insulating material powder, MgO powder is preferably applied.

The first lead wire 3a and the second lead wire 3b are spaced apart from each other at a lower portion of the insulation cap 4 so that the first lead wire 3a and the second lead wire 3b are spaced apart from each other. An insulating spacer 6 is provided to maintain the insulation resistance.

The insulating spacer 6 is inserted into the tube 1 and is arranged in a circumferential direction on the inner circumferential surface of the tube 1 so that the insulating material can be easily filled into the tube 1, A geometric structure having an isolated region, for example, in the form of a quadrangle, an oval or a slot hole in a plan view (that is, viewed from the top), and the first lead wire 3a and the second lead wire A through hole 600 through which the lead wire 3b penetrates is formed and the insulating spacer 6 is made of MgO which is the same material as the insulating material powder.

An insulating ring 7 for ensuring insulation between the tip of the first lead wire 3a and the tube 1 is provided on the lower side of the tip of the first lead wire 3a inside the tube 1.

A second arc tube connection 8b is provided below the insulating spacer 6 of the tube 1 for securing insulation between the tube 1 and the heat generating coil 2 provided inside the tube.

It is preferable that the second insulation link 8b is formed to have a length that can insulate a section from the lower portion of the insulation spacer 2 to the upper portion of the insulation ring 7.

A process for manufacturing the electronic thermostat using the heater (H) for thermostat according to the present invention will be described below.

FIG. 9 is a process block diagram showing the steps of manufacturing the electronic thermostat to which the heater H for the electronic thermostat of the present invention is applied, and will be described with reference to FIGS. 3 to 8. FIG.

(A) a process of manufacturing a heat generating coil assembly by joining a heat generating coil 2 and lead wires 3a and 3b to each other, (B) ) Filling the tube (1) with the heat generating coil assembly, filling the tube (1) with an insulating material powder, and then completing the outer diameter of the tube (1); (C) And pressing the tube 1 into the wax case 9 in an interference fit manner to mount the heater H to the wax case 1. The process will be described in more detail below.

First, in the manufacturing process of the heat generating coil assembly (A), the small-diameter winding portions 2a and 2b for inserting and electrically connecting ends of the lead wires 3a and 3b are provided at the upper and lower ends, 2a and 2b, a heat generating coil 2 having a large diameter winding portion 2c is prepared (S1).

Here, the large-diameter winding portion 2c is a spiral winding portion having a diameter that is smaller than the inner diameter of the tube 1 but large enough to wrap around the lead wires 3a and 3b.

A first lead wire 3a and a second lead wire 3b electrically connected to the heat generating coil 2 are prepared (S2).

Then the end of the first lead wire 3a is inserted and connected to the small diameter winding portion 2a at the lower end of the heat generating coil 2 and the second lead wire 3b is connected to the small diameter winding portion 2b at the upper end of the heat generating coil 2, (3b) is inserted and connected (S3).

The small diameter winding portion 2a of the lower end of the heat generating coil 2 and the end portion of the first lead wire 3a and the small diameter winding portion 2b of the upper end of the heat generating coil 2 and the end portion of the second lead wire 3b (S4).

The manufacturing process of the heating coil assembly (A) includes the step of providing an insulating spacer 6 for supporting the first lead wire 3a and the second lead wire 3b so as to keep the gap therebetween, It is preferable that the spacer 6 is disposed at a bending point of the first lead wire 3a (S5).

This is because, in the process of inserting the insulating material in powder form into the spacing space between the insulating spacer 6 and the tube 1, when the ultrasonic filling is performed for even filling of the insulating material powder, the insulating spacer 6 To prevent the rising phenomenon.

The insulating spacer 6 may be provided after the lead wires 3a and 3b and the heating coil 2 are connected to each other. However, the insulating spacer 6 is not limited to the lead wires 3a and 3b and the heating coil 2 may be provided on lead wires 3a, 3b before connection.

Meanwhile, after the step (A) for manufacturing the heat generating coil assembly is completed, the step (B) is performed.

Specifically, the step (B) includes a step (S6) of inserting the insulating ring 7 and the first and second flange connections 8a and 8b, inserting the heating coil assembly into the tube 1 A step S8 of filling the inside of the tube 1 with an insulating material powder S8 and a step S9 of inserting an insulating cap 4 at the inlet of the tube 1, (S10) of completing the outer diameter dimension of the outer circumferential surface

Here, the outer diameter of the tube 1 is finished to a predetermined dimension, and the outer diameter of the tube 1 is completed through swaging.

The swaging step proceeds to reduce the diameter of the tube 1 and to increase the length of the tube 1. The insulating spacer 6 may be fractured while being swaged.

That is, since the insulating spacer 6 is made of MgO which is the same material as that of the insulating material powder although the processing shape is different from that of the insulating material powder, when pressure is applied in the swaging molding process, State.

The step of inserting the insulating ring 7 and the first and second insulating joints 8a and 8b in the tube 1 prior to inserting the heat generating coil assembly into the tube 1 includes the steps of: And between the tube and the lead wire, and between each lead wire.

Insertion of the first fulcrum connection 8a into the lead wire may be performed before welding of the lead wire and the heat generating coil 2.

After the above step (B) is performed, a press-fitting step is carried out (S11) in which the tube 1 with the outer diameter finished is fit tightly to the wax case 9 and the insulating plug 10 (S12). Thus, the process (C) of mounting the heater (H) for thermostat to the wax case according to the present invention is completed.

In step S12 of inserting the insulating plug 10 at the entrance of the wax case 9, after inserting the insulating plug, the side wall of the wax case inlet is pushed inward to fix the insulating plug.

The operation and effects of the heater (H) for an electronic thermostat and the electronic thermostat using the same according to the present invention are as follows.

The heater (H) for an electronic thermostat of the present invention is characterized in that the tube 1 portion is fixed to the wax case 9 constituting the thermostat, The tube 1 is directly fixed to the wax case 9 without being interposed therebetween.

That is, in the heater (H) for an electronic thermostat of the present invention, the tube (1) itself is forcedly fitted in the fastening hole provided in the wax case (9), so that the heater (H) As shown in Fig.

In other words, the minimum allowable dimension of the diameter of the tube (1) is larger than the maximum allowable dimension of the fastening hole diameter of the wax case (9) for interference fit, so that interference always occurs.

Therefore, unlike the prior art, the fastening bracket for fastening the heater (H) for the electronic thermostat to the wax case is omitted, so that the structure and the process are simplified, and the manufacturing cost can be reduced. Thereby preventing leakage of wax by screw loosening.

That is, in the heater (H) for an electronic thermostat according to the present invention, the fastening metal, which is a medium for mounting the heater (H) through screwing, is omitted from the wax case (9) And omission of the fastening bracket eliminates the existing insulator, o-ring, and ring nut, thereby reducing the number of components of the thermostat.

The heater (H) for an electronic thermostat according to the present invention includes a step of forming a female thread for fastening with a fastening metal (150) to the heater fixing portion of the wax case (9) in the thermostat manufacturing process, The conventional processes such as press fitting of the fastening metal for the tube (1), airtightness inspection, inserting the insulator inside the upper end of the fastening metal bracket, and metal fitting are omitted, thereby reducing the number of assembling steps in manufacturing the thermostat do.

Particularly, in the conventional method, the fastening metal is used to screw the heater H to the wax case 9, and the fastening force is lowered due to the fastening of the fastening metal and the wax case 9 at the screw fastening portion The airtightness to the wax is deteriorated, and as a result, the operating reliability and control responsiveness of the electronic thermostat are deteriorated.

However, in the electronic thermostat according to the present invention, since the heater H is firmly fitted to the wax case 9, the phenomenon of deterioration of the fastening force does not occur. Therefore, the airtightness of the wax does not deteriorate. Operation reliability and control responsiveness are improved, thereby improving the fuel efficiency of the vehicle.

Since the heater H for an electronic thermostat according to the present invention has a structure in which the first lead wire 3a and the second lead wire 3b for power supply are kept insulated from the tube 1, Unlike the heater for the thermostat, the foreign matter does not stick to the valve operating portion of the outer wall of the component.

That is, in the conventional thermostat heater, the heat generating coil 2 and the tube 1 are electrically connected, the tube is electrically connected to the fastening metal, and the fastening metal is grounded to the body. The electronic thermostat may not operate due to the foreign matter being fixed to the valve operation site by the electrolysis of the cooling water composed of the antifreeze and the water due to the electric conduction between the fastening metal and the wax case 9. However, In the stator heater H, the electrolytic phenomenon of the cooling water is fundamentally eliminated because the tube 1 and the heat generating coil 2 are insulated by the second insulating tube 8b.

Accordingly, the heater (H) for an electronic thermostat according to the present invention can reliably solve the problem of foreign matter sticking at a valve operating site due to the cooling water electrolysis, thereby providing an effect of increasing the service life and operational reliability of the thermostat .

The heater H for an electronic thermostat according to the present invention is improved in both side end structures of the heat generating coil 2 so as to fit the end portions of the lead wires 3a and 3b so that both end portions of the heat generating coil 2, It is possible to easily connect and bond the lead wire 3a and the second lead wire 3b so that the structure and processing steps of the heater H for the electronic thermostat are simplified and the workability and productivity And the manufacturing cost can be reduced.

It is to be understood that the present invention is not limited to the above-described embodiment, and various changes and modifications may be made without departing from the scope of the present invention.

Therefore, it should be understood that the above-described embodiments are to be considered as illustrative rather than restrictive, and that the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof .

The present invention relates to a heater for an electronic thermostat, which is installed between an engine of an automobile and a radiator so that cooling water can be maintained at a proper temperature, thereby reducing the time required for raising the heating temperature of the heater to a target temperature By improving the response, it is possible to control the cooling water temperature more effectively than the conventional thermostat, and it is structurally simplified so as to improve the productivity and manufacturing cost in the manufacture of the electronic thermostat, and to improve the durability and the product reliability It is a very highly industrially applicable invention.

H: Heater for electronic thermostat
1: tube 2: heating coil
2a, 2b: small diameter winding portion 2c: large diameter winding portion
3a: first lead wire 3b: second lead wire
4: Insulation cap 6: Insulation spacer
600: through hole 7: insulating ring
8a: Section 1 Association 8b: Section 2 Association
9: wax case 10: insulating plug

Claims (19)

As a heater for an electronic thermostat,
A hollow tube having one side open and the other side closed;
A heating member disposed inside the tube and generating heat by electrical resistance;
And a lead wire for supplying power to the heating member,
Wherein the tube is directly fit to the fastening hole of the wax case so that the heater is mounted on the wax case. The method according to claim 1,
The lead wire
A first lead wire having one end exposed to the outside of the tube and the other end positioned inside the tube and being a positive terminal to which power is externally applied through one end exposed to the outside of the tube;
And a second lead wire having one end exposed to the outside of the tube and the other end positioned inside the tube, the minus terminal being disposed apart from the first lead wire. 3. The method of claim 2,
Wherein the heating member is a spirally wound heating coil, and is connected to the ends of the first lead wire and the second lead wire, respectively. The method of claim 3,
The lower end portion and the upper end portion of the heat generating coil, unlike the remaining portions, are in the form of a coil whose diameter is reduced in accordance with the diameter of the lead wire,
The first lead wire and the second lead wire,
And the end portions of the first lead wire and the second lead wire and the lower end portion and the upper end portion of the heat-generating coil corresponding thereto are joined by electric resistance welding or laser welding. 3. The method of claim 2,
On the inside of the inlet of the tube,
And an insulating cap of an insulating material for sealing the tube inlet is provided. 6. The method of claim 5,
Wherein an inner space of the tube is filled with an insulating material in powder form. 6. The method of claim 5,
In the lower portion of the insulating cap,
Wherein an insulation spacer is provided to support the first lead wire and the second lead wire so that the first lead wire and the second lead wire are kept apart from each other and maintain the insulation resistance between the first lead wire and the second lead wire. 8. The method of claim 7,
Wherein the insulating spacer comprises:
And a plurality of tubes disposed inside the tube,
Wherein the heater is a geometric structure having a region isolated from a certain region along a circumferential direction on an inner circumferential surface of the tube so that filling of the insulating material into the tube is easily performed. 9. The method of claim 8,
Wherein the insulating spacer is in the form of a square, an oval or a slot hole in a plan view. 8. The method of claim 7,
And an insulation ring for ensuring insulation between the tip of the first lead wire and the tube is provided below the tip of the first lead wire inside the tube. 8. The method of claim 7,
Wherein a first section connection is provided below the bending point of the first lead wire for securing the insulation property and the withstand voltage of the lead wires,
And a second section connection is provided between the tube and a heat generating member installed inside the tube to ensure insulation. 12. The method of claim 11,
Wherein the second clause association comprises:
Wherein the insulating layer is provided to insulate a section from the lower portion of the insulating spacer to the upper portion of the insulating ring. (A) joining a heat generating coil and a lead wire to manufacture a heat generating coil assembly;
(B) inserting the heating coil assembly into a tube, filling the tube with an insulating material, and completing the outer diameter of the tube;
(C) pressing the tube having the outer diameter dimension to the wax case in an interference fit manner to fix the tube to the wax case. 14. The method of claim 13,
The manufacturing process of the heat generating coil assembly (A)
Preparing a heat generating coil having a small diameter winding portion for electrical connection with each lead wire at an upper end and a lower end and having a large diameter winding portion in an area between the small diameter winding portions;
Preparing a first lead wire and a second lead wire electrically connected to the heat generating coil;
Inserting the end of the first lead wire into the small diameter winding portion of the lower end of the heating coil and inserting the end of the second lead wire into the small diameter winding portion of the upper end of the heating coil;
And welding the small diameter winding portion of the lower end of the heating coil and the first lead wire and the small diameter winding portion of the upper end of the heating coil to the second lead wire. The method according to claim 13 or 14,
The manufacturing process of the heat generating coil assembly (A)
And inserting an insulating spacer for supporting the first lead line and the second lead line so as to keep the first lead line and the second lead line apart from each other. 16. The method of claim 15,
Wherein the insulating spacer is installed so as to be located at a bending point of the first lead wire. 16. The method of claim 15,
Wherein the insulating spacer is made of MgO which is the same material as the insulating material. 14. The method of claim 13,
The step (B)
Filling an insulating material through a spaced space between an insulating spacer and a tube installed inside the tube, and then mounting an insulating cap to the tube inlet,
Wherein the outer diameter of the tube is completed through swaging. 19. The method of claim 18,
Wherein the insulating spacer can be fractured inside the tube during swaging molding. ≪ RTI ID = 0.0 > 11. < / RTI >

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