KR20120010038A - Thermostat - Google Patents

Abstract

PURPOSE: A thermostat is provided to accurately operate a valve by preventing the loss of pressure due to wax expansion pressure by precisely controlling a valve. CONSTITUTION: A thermostat comprises a thermostat housing(110), a heater(120), a wax chamber(130), a diaphragm(140), an element(152), an element guide(150), an elevating member(160), a valve(170), and an elastic member(180). The flow path in which the cooling water flows is formed in the thermostat housing. The diaphragm is transformed by the wax swelling in the wax chamber. The element moves using the stress of the diaphragm. The elevating member ascends and descends by the pressure of the element in the flow path of the thermostat housing. The elastic member flexibly supports the inside of the thermostat housing valve.

Description

Thermostat {THERMOSTAT}

The present invention relates to a thermostat for operating the valve by using the expansion pressure of the wax as the heater is heated, more specifically, to maximize the heat generating area of the heater to improve the reaction speed of the valve, without malfunction of the valve It is about a thermostat that can operate correctly.

Generally, the combustion gas temperature in the engine of a vehicle is about 2000 ~ 2500 ℃, and a considerable amount of this heat is moved to the cylinder wall, cylinder head, piston valve, etc. If the temperature of the conducted heat is too high, The output will be lowered due to knocking or premature ignition due to the failure, shortening the lifespan, or poor engine combustion.

On the contrary, if the engine is excessively cooled, the amount of heat lost by cooling is high, so that the engine efficiency is lowered and fuel consumption is increased. Therefore, it is important to maintain the engine temperature at about 80 to 90 ° C. For this purpose, a thermostat is installed in the engine of the vehicle.

The thermostat is installed between the engine and the radiator to generate a displacement of the valve according to the change in the temperature of the coolant so as to adjust the flow rate of the coolant flowing to the radiator so that the coolant can be maintained at an appropriate temperature. The valve is opened above the temperature and closed below the set temperature to control the flow rate according to the temperature of the cooling water.

On the other hand, the setting of the vehicle cooling performance is designed to satisfy all conditions such as the full load condition and the air temperature of the actual vehicle, but the driving conditions of the actual vehicle are almost within 70% of the full load condition. As a result, the actual cooling capacity of the engine is limited to only a portion of the engine, and the engine is overcooled more than necessary, resulting in loss of fuel economy and excessive generation of exhaust gas.

Accordingly, the coolant temperature of the engine is always optimal by raising the coolant temperature level of the entire engine in the range of the conventional partial load and lowering the coolant temperature level of the engine in the full load or the maximum speed range of the vehicle. There is a need for a coolant control scheme to maintain the temperature.

To this end, in recent years, a variety of models for the electronic thermostat of the variable control method to maintain the optimum coolant temperature of the engine while compensating for the disadvantages of the general mechanical thermostat has been proposed.

The electronic thermostat of the variable control method can maintain the best engine cooling state at all times by controlling the engine coolant temperature according to the driving state or load state of the vehicle, and can expect the improvement of fuel economy and the reduction of exhaust gas. .

For example, an electronic thermostat including a heater capable of reacting in association with the expansion of wax may be divided into a plate type and a rod type according to the installation structure of the heater. This will be described with reference to FIGS. 1 and 2.

1 is a schematic cross-sectional view showing a conventional plate-type thermostat. Referring to the drawings, the plate-shaped thermostat 10 has a shape of a tube in communication with the top and bottom, the wax chamber 11 is filled with wax (W) therein, and the wax chamber 11 of A plate-shaped heater 12 inserted and fixed through an upper end, an element 13 installed through a lower end of the wax chamber 11 and installed in a linear motion, and wax W filled in the wax chamber 11; It is composed of a diaphragm 14 provided between the elements 13 to deform in accordance with the expansion pressure of the wax (W) to lift the element (13).

Referring to the operation of the conventional plate-type thermostat as described above, when the power is supplied to the heater 12 through the plug 15, the heater 12 generates heat, the wax (W) in contact with the heater 12 Will expand. The pressure generated by the expansion of the wax W deforms the diaphragm 14 to push the element 13, thereby actuating the valve 16 associated with the element 13 to open the flow of coolant.

However, in the conventional plate-type thermostat 10 as described above, since the heater 12 for heating and expanding the wax is formed in a plate shape, heat transfer is uniformly made because the heat generating area of the heater 12 is limited to one side or both sides. There is a disadvantage that the reaction speed of the valve 16 is not slow.

Therefore, a rod thermostat has been proposed to improve the reaction speed of the valve.

Figure 2 is a schematic cross-sectional view showing a conventional rod thermostat. Referring to the drawings, the rod-shaped thermostat 20 is filled with wax (W) in the interior of the element 21 having a hollow shape with the top open and the bottom closed, the top of the element 21 The heater 22 is inserted through the heater 22 so that the heater 22 is immersed in the wax (W).

In this case, the heater 22 is fixed to the valve housing 23 in which the flow path for cooling water is formed, and the lower end is inserted into the upper end of the element 21 so that the element 21 can be linearly moved.

In addition, by installing a valve 24 capable of opening and closing the flow of the cooling water around the outer diameter of the element 21, the wax W on which the heater 22 is immersed expands as the heater 22 generates heat. The volume is increased inside the element 21. As the wax W expands in the element 21, the inflation pressure is concentrated to the lower end of the element 21 while the element 21 moves together with the valve 24 to be opened and returned and closed by a spring. .

However, the conventional rod thermostat 20 as described above is excellent in heat transfer because the heat generation of the heater is made in all directions, but the heat generation area is reduced while the element 21 is moved, so that sufficient expansion to operate the valve 24 There is a disadvantage in that it is not suitable for a valve for controlling the flow of cooling water having a relatively high flow rate or a high flow rate due to the inability to exert pressure.

The present invention is to solve the above problems, by increasing the heat generating area of the heater to improve the reaction rate of the valve, it is possible to obtain a pressure that can quickly expand the wax from the valve to operate the valve from there quickly The purpose is to provide a thermostat.

In addition, the object is to provide a thermostat capable of precisely controlling the valve by thermal movement over all areas of the wax.

It is also an object of the present invention to provide a thermostat in which a loss of the expansion pressure of the wax does not occur so that the valve can be operated correctly.

According to the technical idea of the present invention for achieving the above object, a thermostat housing having a flow path for cooling water is formed, a heat generating portion fixed to the inside of the thermostat housing to prevent flow, the heat generating portion is inserted and wax Filled with a wax chamber, a diaphragm deformed by wax expanded in the wax chamber, an element moved by the deformation force of the diaphragm, an element guide supporting the outer circumferential surface of the element and guiding the element, and the element guide A lifting member which is lifted on the flow path of the thermostat housing by the pressing force of the element moving while being guided to the valve, and a valve which is coupled to the lifting member and moves with the lifting member to open and close the flow path of the thermostat housing. Resilient support inside the thermostat housing It is achieved by a thermostat including a resilient member.

Here, the heating unit is fixed to the thermostat housing and the cylindrical case having one side, the cap for shielding the open one side of the cylindrical case, the bobbin embedded in the cylindrical case sealed by the cap and It is preferable to include a heating wire wound on the bobbin.

The heat generating part may include a spacer for uniformly filling the heat transfer material between the heat wire and the inner circumferential surface of the cylindrical case by separating the heat transfer material filled in the cylindrical case and the hot wire wound on the bobbin from the inner circumferential surface of the cylindrical case. desirable.

In addition, the heat transfer material is composed of at least one of powdered aluminum oxide (Al ₂ O ₃ ) or magnesium oxide (MgO) to transfer the heat of the hot wire, the bobbin is a plastic having heat resistance to the heat of the hot wire. Consists of, the spacer is preferably composed of a protrusion protruding to the outer diameter of the bobbin.

In addition, the cylindrical case is formed in the shape of a cup having a length by deep drawing, it is preferable to have a slope on one side open.

In addition, the wax chamber has one side shielded by the diaphragm, the wax is filled therein, and a first step in which a part of the heat generating part is caught and a second step in which a part of the element guide is fitted are caught on one side and the other side. It is preferably composed of both ends of the open type hollow tube, the diaphragm is interposed between the second step of the hollow tube and a portion of the element guide is preferably fixed to one side of the hollow tube.

The method may further include a sealing member interposed between the first stepped portion of the hollow tube and a portion of the heat generating portion to seal the contact portion of the first stepped portion and the heat generating portion.

Here, the sealing member is preferably at least one of an O-ring interposed between the first step and the portion of the heat generating portion or a protrusion protruding from the first step and pressed by a portion of the heat generating portion.

In addition, the element guide has one side shielded by a diaphragm in a state in which the diaphragm can be deformed, and a transmission oil for transmitting a deformation force of the diaphragm while being compressed by the deformed diaphragm, is moved by the deformation force of the diaphragm transmitted by the transmission oil. It is preferable that the element is inserted into the other side, the cylinder is open at both ends of the other side is shielded by the element.

In addition, the element guide is preferably provided with an inclined surface for compressing the transfer oil on the inner peripheral surface of one side shielded by the diaphragm.

In addition, the elevating member is preferably a cup-shaped receptacle formed with a communication hole in which the element is inserted into the inside to support the lower end of the element, the valve is fixed to the outside, the coolant of the thermostat housing is in communication.

In the thermostat according to the present invention, since the cylindrical case is immersed in the wax filled in the storage of the wax chamber, since the outer diameter and the bottom surface of the cylindrical case are in contact with the wax, a heat generating area capable of heating and expanding the wax is increased. Increase in pressure from which the wax can expand and open the valve, thereby improving the reaction rate of the valve.

In addition, since the exothermic area for releasing heat energy to heat the wax increases, heat transfer occurs over all areas of the wax so that a uniform expansion pressure can be obtained from all portions of the wax-filled reservoir. By precisely operating the lifting member, the valve can be precisely controlled.

In addition, the diaphragm formed in the element guide forms an inclined surface in which the diameter of the diaphragm gradually decreases toward the guide hole in which the element is installed, and the transfer space is filled in the active space, whereby Because the pressure is concentrated on the top of the element, there is no loss of the expansion pressure of the wax, which allows the valve to operate correctly, which is suitable for controlling the flow of coolant with relatively high flow rates or high flow rates.

1 is a schematic cross-sectional view showing a conventional plate-type thermostat.
Figure 2 is a schematic cross-sectional view showing a conventional rod thermostat.
3 is a cross-sectional view showing a thermostat according to the present invention.
Figure 4 is a partial cutaway perspective view showing the remaining portion of the thermostat except the thermostat housing according to the present invention.
5 is an exploded perspective view of FIG. 4.
6 is a cross-sectional view showing the structure of the heating unit of the thermostat according to the present invention.
7 is a cross-sectional view showing another embodiment of the heating unit of the thermostat according to the present invention.
8 is a perspective view showing a bobbin of a heating part of the thermostat according to the present invention.
9 is a partial cross-sectional view showing another embodiment of the cylindrical case of the heating portion of the thermostat according to the present invention.
10 is a cross-sectional view showing an operating state of the thermostat according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a cross-sectional view showing a thermostat according to the present invention. Referring to the drawings, the thermostat 100 according to the present invention is largely installed between the engine and the radiator, the thermostat housing 110, the flow path is formed so that the coolant flows, and fixed inside the thermostat housing and heat A heat generating unit 120 for emitting wax to heat the wax, a wax chamber 130 filling the wax W, a diaphragm 140 deformed according to the expansion of the wax W, and the diaphragm 140. The elevating member 160 which elevates and moves on the flow path of the thermostat housing 110 by the element 152 moving by the deformation force of the element, the element guide 150 which guides the element, and the pressing force of the element 152. And, the valve 170 for opening and closing the flow path of the thermostat housing 110 in accordance with the lifting of the elevating member 160 and the elastic member 180 to elastically support the valve 170 in the thermostat housing It is composed.

The thermostat housing 110 has a fixing part 112 for fixing the heat generating part 120 so that the heat generating part 120 is located on the flow path of the thermostat housing 110. It is formed through the side of the.

The fixing part 112 forms a drawing hole 114 so that a power cable 116 connecting electric energy supplied from an external power source to the heat generating part 120 can be introduced through the fixing part 112. The heat generating part 120 is fixed to the lower end of the inlet hole 114 by screwing or being fixed by interference fit.

The heating unit 120 is fixed to the inside of the thermostat housing 110 and installed to prevent flow, the wax chamber 130 and the diaphragm 140 and the element guide 150 and the lifting and lowering associated with the heating unit 120 The member 160 will be described in detail with reference to FIGS. 4 and 5.

Figure 4 is a partial cutaway perspective view showing the remaining portion of the thermostat other than the thermostat housing according to the present invention, Figure 5 is an exploded perspective view of FIG.

Referring to the drawings, the heat generating unit 120 is fixed to the cylindrical case 122 having an open side, the fixing portion 112 formed in the thermostat housing 110, the cylindrical case 122 Cap 125 for shielding the open one side of the bobbin 124 is located in the hollow formed inside the cylindrical case 122, the heating wire 126 wound on the bobbin 124, and the bobbin ( And a spacer 128 spaced apart from the inner circumferential surface of the cylindrical case 122.

The cylindrical case 122, the upper end is opened and the lower end is formed in a hemispherical shape, the bobbin 124 wound around the heating wire 126 is located therein, the material of the cylindrical case 122 is workability It is preferable that it is stainless steel which is excellent in weldability and mechanical property, and especially excellent in thermal conductivity.

In addition, the bobbin 124 is located in the hollow formed inside the cylindrical case 122 to form a cylindrical shape having a diameter smaller than the diameter of the hollow formed in the cylindrical case 122.

In particular, the bobbin 124 to which the heating wire 126 is wound is made of a plastic having heat resistance, and the power cable 116 connecting electrical energy supplied from a power source outside the thermostat housing 110 to the heating wire 126. It is preferable that the insert is molded by injection molding.

In other words, the heating wire 126 wound around the bobbin 124 receives electrical energy through the power cable 116 and converts the thermal energy into thermal energy around the bobbin 124.

In this case, the material of the bobbin 124 is made of a plastic having heat resistance, and the power cable 116 is molded by insert injection to be embedded in the bobbin 124, so that the power cable 116 when the heating wire 126 is heated. It becomes possible to prevent melting and wiring by this heating wire.

Here, the bobbin 124 may be made of a plastic having heat resistance, for example, poly phenylene sulfide (PPS) or liquid crystal polymer (LCP).

In addition, when the bobbin 124 with the heating wire 126 wound around the hollow of the cylindrical case 116 is located, the distance between the outer circumference of the bobbin 124 and the inner circumference of the cylindrical case 122 is a predetermined interval. Spacer 128 is installed to be maintained. This will be described based on FIG. 8.

8 is a perspective view showing a bobbin of a heating part of the thermostat according to the present invention. Referring to the drawings, the spacer 128 is formed to have a predetermined length between the outer periphery of the bobbin 124 and the inner periphery of the cylindrical case 122, and the outer periphery of the bobbin 124 and the cylindrical case 122. It may be made of a single member that can be detached between the inner circumference of the bobbin 124 may be formed integrally with the bobbin 124 to protrude in the direction intersecting the axial direction of the bobbin 124 at the outer circumference of the bobbin 124.

Preferably, as shown in the figure, the spacer 128 is formed to protrude in a direction intersecting with the axial direction of the bobbin 124 and to be arranged at regular intervals around the outer circumferential surface of the bobbin 124, thereby It is possible to form a space in which the heat transfer material described later can be filled between the 128.

As such, the spacer 128 is formed between the outer periphery of the bobbin 124 and the inner periphery of the cylindrical case 122, so that the bobbin 124 and the cylindrical case (1) are inserted when the bobbin 124 is inserted into the cylindrical case 122. 122 may be positioned on the same axis so as to be spaced apart from each other so that a constant distance is maintained between the outer periphery of the bobbin 124 and the inner periphery of the cylindrical case 122.

As such, when a constant interval is maintained between the outer periphery of the bobbin 124 and the inner periphery of the cylindrical case 122, the thermal energy emitted from the heating wire 126 wound on the bobbin 124 is uniformly transferred to the cylindrical case 122. By moving, the entire surface of the cylindrical case 122 may be evenly heated.

In addition, the outer periphery of the bobbin 124 according to the impact that can be applied from the outside after the transport and storage of the thermostat 100 to the thermostat 100 is installed between the engine and the radiator of the cylindrical case 122 Tilt to the inner circumference can prevent the bias.

In addition, the inner circumference of the cylindrical case 122 so that the axis of the bobbin 124 and the axis of the cylindrical case 122 can be more easily matched when the bobbin 124 is inserted into the hollow of the cylindrical case 122. The bobbin entry hole 122a is formed, and the slot 122b is formed at the outer periphery of the cylindrical case 122 so as to maximize the heat generating area of the cylindrical case 122 in contact with the wax (W). This will be described based on FIG. 9.

9 is a partial cross-sectional view showing another embodiment of the cylindrical case of the heating portion of the thermostat according to the present invention. Referring to the drawings, the bobbin entry port 122a is formed with an inclination in which the diameter thereof becomes narrower from the inner peripheral upper end inlet of the cylindrical case 122 to the lower end thereof. That is, the cylindrical case 122 has a slope on the open side.

Accordingly, when the bobbin 124 is inserted into the cylindrical case 122, the other end is smoothly inserted into the cylindrical case 122 because the other end is guided to the downwardly inclined bobbin entry opening 122a.

In other words, the spacer 128 for maintaining a distance between the outer circumference of the bobbin 124 and the outer circumference of the bobbin 124 and the inner circumference of the cylindrical case 122 at a predetermined interval on the outer circumference of the bobbin 124. Is formed.

As described above, the heating wire 126 and the spacer 128 positioned at the outer circumference of the bobbin 126 act as an obstructing element when the bobbin 124 is inserted into the hollow of the cylindrical case 122. ) And the spacer 128 may be damaged.

However, as described above, the bobbin entry hole 122a is formed such that the diameter thereof becomes narrower from the upper inlet to the lower end of the inner diameter of the cylindrical case 122, so that the bobbin 124 is inserted into the hollow of the cylindrical case 122. The other end of the 124 is guided to the downwardly inclined bobbin entry port 122a can be inserted smoothly.

In addition, the slot 122b is formed on the outer periphery of the cylindrical case 122 so as to maximize the heat generating area of the cylindrical case 122, and the slot 122b protrudes from the outer periphery of the cylindrical case 122, or It is formed to have the shape of a recessed elongated groove.

That is, the slot 122b may be continuously formed horizontally along the outer circumference of the cylindrical case 122 as shown in the drawing, or in some cases vertically along the outer circumference of the cylindrical case 122 or It may be formed so that the vertical and horizontal intersect.

As such, when the slot 122b is continuously formed along the outer circumference of the cylindrical case 122, the surface area of the outer circumference of the cylindrical case 122 in contact with the wax W is increased, and thus the cylindrical case ( Fast heat transfer occurs over all areas of the wax W on which 122 is immersed.

Meanwhile, in the hollow of the cylindrical case 122 in which the bobbin 124 wound around the heating wire 126 is inserted, the heat transfer material 121 so that the heat energy emitted from the heating wire 126 is thermally moved to the cylindrical case 122 more quickly. ) Is charged. This will be described based on FIG. 6.

6 is a cross-sectional view showing the structure of the heating unit of the thermostat according to the present invention. Referring to the drawings, the heat transfer material 121 is filled between the outer periphery of the bobbin 124 and the inner periphery of the cylindrical case 122, the heat transfer material 121 is a powder of aluminum oxide (Al ₂ O ₃ ) or magnesium oxide (MgO) is preferred.

As such, the heat-transfer material 121 processed into powder is densely filled in the gap formed between the cylindrical case 122 and the bobbin 124, thus forming the hot wire 126 and the spacer 128 wound on the bobbin 124. The gap may be filled so that no gap formed between the cylindrical case 122 and the bobbin 124 is generated.

As described above, the heat transfer material 121 made of aluminum oxide (Al ₂ O ₃ ) or magnesium oxide (MgO) filled between the cylindrical case 122 and the bobbin 124 is superior to other materials because the heat conductivity The thermal energy released at 126 can be thermally transferred to the cylindrical case 122 more quickly.

In addition, the components inserted in the cylindrical case 122 are separated from the upper edge of the inner circumference of the cylindrical case 122 into which the heating wire 126, the bobbin 124, the spacer 128, and the heat transfer material 121 are inserted as described above. It can be sealed with an insulating material 123 to prevent the foreign matter, such as to prevent the supply of electrical energy, such as cooling water to prevent the inflow through the upper end of the cylindrical case (122).

In particular, the insulating material 123 is preferably made of epoxy. Since the insulating material 123 made of epoxy is hardened within a short time and has excellent sealing properties and excellent insulating properties, the short circuit of the heating wire or the power cable 116 due to the inflow of cooling water, which may be generated, may be delayed. It can be prevented.

The insulating material 123 is filled from the bobbin entry hole 122a formed in the inner diameter of the cylindrical case 122 to the upper end of the inner circumference of the cylindrical case 112 as shown in the drawing, and is connected to supply electric energy to the heating wire 126. The power cable 116 is sealed so that it can be drawn out through the insulating material 116.

On the other hand, a cap 125 is installed at the upper end of the inner circumference of the cylindrical case 122 to fix the heat generating part 120 to the inside of the thermostat housing 110 and shield the upper end of the outer circumference of the cylindrical case 122. That is, the cylindrical case 122 may be shielded by the cap 125.

The cap 125 is provided with a screw thread or interference fit shape on the outer circumference thereof so as to be screwed to the aforementioned fixing part 112 formed in the thermostat housing 110 or to be tightly fitted, and the cylindrical case 122 It has a shape that is tightly fixed to the top of the cylindrical case 122 to shield the open top.

Meanwhile, the wax chamber 130 wrapped around the heat generating unit 120 and filled with the wax W has a body 132 having a shape of a tube in which top and bottom surfaces are in communication with each other, and inside the body 132. It is formed of a storage unit 134 is formed is filled with the wax (W) surrounding the heat generating unit 120.

In other words, the body 132 of the wax chamber 130 is formed to have a shape of a tube in which the top and the bottom is in communication with a hollow storage unit 134 therein, the heat generating unit 120 of the through After the cylindrical case 122 is introduced, the wax W is immersed in the reservoir 134 filled with the wax (W).

At this time, the storage unit 134 of the wax chamber 130 so that the expansion pressure of the wax (W) by the thermal energy emitted from the surface of the cylindrical case 122 can be directed to the open lower end of the wax chamber 130. The cross section of the surface in direct contact with the heavy wax (W) is formed to have a straight shape.

In some cases, the storage unit 134 formed in the wax chamber 130 may concentrate the expansion pressure of the wax (W) due to the heat energy emitted from the heat generating unit 120 to the lower end of the wax chamber 130. The diameter of the wax chamber 130 may be formed in the shape of the upper and lower straits (上 廣 下 狹) that gradually decreases in size from the top to the bottom of the wax chamber 130.

In addition, a stepped first step 132a is formed at an upper end of the inner circumference to fix the heating unit 120 inserted through the upper end of the body 132, and an element guide inserted through the lower end of the body 132. A second stepped portion 132b which is stepped at the lower end of the inner circumference is formed to fix the 150.

The flange of the upper outer diameter of the upper end of the cylindrical case 122 is caught on the first step 132a so that the heating unit 120 is seated and fixed to the first step 132a formed at the upper end of the inner circumference of the body 132 as described above. An extension part 135 having a shape is provided, and the first step 132a and the extension part 135 are hermetically fixed by the sealing member 136.

The sealing member 136 has a ring shape and an O-ring 136 made of a flexible material is interposed between the first step 132a and the extension part 136 to fill the reservoir 134 of the wax chamber 130. When the wax W is expanded by the heat generating part 120, the wax W is prevented from flowing out to the coupling part of the wax chamber 130 and the heat generating part 120.

In some cases, the first stepped portion without using a sealing member such as an O-ring 136 to prevent the wax (W) expanded to the coupling portion of the wax chamber 130 and the heat generating portion 120 to flow out. The structures of the 132a and the extension 135 may be changed to prevent the expanded wax W from leaking out. This will be described based on FIG. 7.

7 is a cross-sectional view showing another embodiment of the heating unit of the thermostat according to the present invention. Referring to the drawings, a sealing member 136 such as an O-ring 136 is formed when the extension 135 formed in the heating unit 120 is seated and fixed to the first step 132a formed in the wax chamber 130. A protrusion 137a is formed on each surface of the first step 132a and the extension 135 facing each other so that the expanded wax W is not leaked by the structural coupling without using.

When the protrusion 137a is formed on the first step 132a of the wax chamber 130 as described above, the protrusion 137a is extended when the extension 135 is seated and fixed to the first step 132a. The first step 132a and the extension part 135 are hermetically shielded while being compressed to the 135, so that the wax W expanded in the storage part 134 of the wax chamber 130 is separated from the wax chamber 130. It is possible to prevent the outflow to the coupling portion of the heat generating unit 120.

 In addition, the shape of the protrusion 137a may be formed in any one of a hemispherical shape, a triangle, a quadrangle.

In addition, the expanded wax (W) to prevent the leakage of the expanded wax (W) to the coupling portion of the wax chamber 130 and the heat generating unit 120, the wax (W) of the storage unit 134 of the wax chamber 130 is filled In order to improve the size of the pressure due to the expansion of the wax (W) by increasing the volume, the bevel inclined portion (122c) is formed in the outer diameter of the cylindrical case 122 from the top to the bottom to decrease the size of the diameter .

In particular, the bent inclined portion (122c) is formed so as to narrow the size of the diameter from the upper end of the outer periphery of the cylindrical case 122, as shown, the coupling of the wax chamber 130 and the heating unit 120 It is possible to reduce the amount of wax W filled in the part.

Thus, when the amount of the wax (W) filled in the coupling portion of the wax chamber 130 and the heat generating portion 120 is reduced, the portion of the pressure is different depending on the expansion of the wax (W) located in the bent slope (122c) Compared to the lower portion, the expanded wax W may be prevented from flowing out to the portion where the wax chamber 130 and the heat generating unit 120 are coupled to each other.

In addition, the volume of the cylindrical case 122 immersed in the wax (W) can be reduced as much as the bent slope 122c is formed on the outer periphery of the cylindrical case 122 as described above. May be filled in the storage unit 134 of the wax chamber 130, thereby improving the magnitude of the pressure due to the expansion of the wax (W), and the pressure may be installed at the bottom of the wax chamber 130. Can be passed as an element.

Here, the above-described bending inclination portion 122c is formed together with the above-described bobbin entry hole 122a when drawing the cylindrical case 122. However, the bending inclination portion 122c may be omitted when the cylindrical case 122 is cut, injected, or die cast. That is, the bending inclination portion 122c is a technique that can be selectively applied.

Meanwhile, the elevating member 160 is elevated on the flow path of the thermostat housing 110 by using the expansion pressure of the wax W heated by the heat generating unit 120, as shown in FIG. 3. The lower end of the 130 is provided with a diaphragm 140, the element 152 and the element guide 150.

The diaphragm 140 is made of a material that is deformed according to the expansion pressure of the wax (W) and can be restored to its original state, and the stepped second step formed on the lower end of the inner circumference of the wax chamber 130 It has a shape of a thin plate that can be tightly fixed to the (132b).

In addition, an element guide 150 is installed below the diaphragm 140 fixed to the second step 132b so that the element guide 150 closely fixes the diaphragm 140 toward the second step 132b.

In other words, the element guide 150, as shown in Figure 3, the other end is shielded by the element 152 is composed of a cylinder open to the bar, the element guide 150 is in communication with the top and bottom It forms the shape of the tube, the outer peripheral edge has a shape that can be fixed to the second step 132b formed on the lower inner peripheral edge of the wax chamber 130.

In addition, the element guide 150 is provided with an inclined surface for compressing the transfer oil (O) on the inner peripheral surface of one side shielded by the diaphragm 140. To this end, the element guide 150 is formed in the upper inner periphery is formed an active space 154 through which the diaphragm 140, which is deformed by the inflation pressure of the wax W, can act, and to the lower portion of the active space 154. Guide holes 156 are formed to guide the elements 152.

In particular, the active space 154 and the guide hole 156 is filled with a transfer oil (O) for transmitting pressure to the element 152 according to the deformation of the diaphragm 140, the guide filled with the transfer oil (O) A portion of the active space 154 in contact with the hole 156 is formed with an inclined surface having a shape of a light-lower narrower, the size of the diameter gradually decreases toward the guide hole 156.

As described above, the delivery oil O is filled in the activity space 154 and the guide hole 156, and an inclined surface is provided in a part of the activity space 154, so that the pressure according to the deformation of the diaphragm 140 may be reduced. O) will be pressed.

In this case, the delivery oil O pressed by the diaphragm 140 flows from the activity space 154 to the guide hole 156, wherein the delivery oil O is formed on the inclined surface formed in the activity space 154. Since the pressure of the transfer oil O is concentrated at the upper end of the element 152 installed in the guide hole 156, the element 152 is pushed toward the lower part of the guide hole 156 with a greater force.

Here, the element guide 150 may be inserted and fixed to the lower end of the wax chamber 130 as shown in the drawing, but in some cases, the element guide 150 and the wax chamber 130 may be integrally formed. There will be.

Meanwhile, the elevating member 160 is installed in association with the element guide 150 to control the flow of the coolant supplied to the thermostat housing 110 according to the linear movement of the element 152 installed in the element guide 150. The valve 170 is installed at an upper end of the outer periphery of the elevating member 160.

As shown in FIG. 5, the elevating member 160 has a shape of a hollow tube having an upper end open and a lower end closed, and a communication hole 162 communicating coolant to a lower side of the elevating member 160. This formation is such that the flow of coolant is well formed around the wax chamber 130 to facilitate heat transfer between the wax chamber 130 and the coolant.

The lower end of the elevating member 160 is formed of a cup-shaped receptacle to close a portion facing the lower end of the element guide 150, that is, the lower end of the guide hole 156 for guiding the linear movement of the element 152. The lower outer diameter of the elevating member 160 is provided with a bypass valve 190, and a lower elastic member 192 is installed between the cover 182 and the bypass valve 190 which will be described later. Open and close the flow path formed in the lower part of the).

Accordingly, when the transfer oil O is pushed out to the lower end of the guide hole 156, the element 152 pushes the closed lower end of the elevating member 160 to lower the entire elevating member 160.

In addition, a valve 170 fixed integrally with the elevating member 160 is provided at an upper end of the outer periphery of the elevating member 160, and the valve 170 is positioned in close contact with a flow path formed in the thermostat housing 110. As a result of the lowering of the elevating member 160, the flow path that is in close contact with the elevating member 160 is opened.

In addition, an elastic member 180 is installed inside the thermostat housing 110 to elastically support the valve 170 so as to close the open flow path again according to the movement of the valve 170.

To this end, a cover 182 is installed at the lower end of the thermostat housing 110, and an elastic member that exerts an elastic restoring force toward the valve 170 between an upper surface of the cover 182 and a lower surface of the valve 170. 180 is installed.

In particular, the cover 182 is formed with a through hole 184 through the lower end of the elevating member 160, the portion except for the through hole 184 is the bypass valve 190 is located in the thermostat housing ( Since the opening of the lower end of the 110 is closed, the valve 170 controls the flow of the cooling water supplied through the flow path formed in the thermostat housing 110.

In other words, a communication hole 162 through which coolant is discharged is formed at a lower end of the elevating member 160 inserted into the through hole 184 formed in the cover 182, and the position of the elevating member is increased. The lower end of the 160 is formed along the circumference of the lower side of the elevating member 160 to be positioned above the cover 182 with the cover 182 in close contact with the lower end of the element guide 150.

At this time, the communication hole 162 formed along the lower side circumference of the elevating member 160 is preferably formed to be symmetrical about the axis of the elevating member 160. When the communication hole 162 is formed to be symmetric about the axis of the elevating member 160 as described above, the flow of the coolant is well formed around the wax chamber 130 to facilitate heat transfer between the wax chamber 130 and the coolant. do.

The operation of the thermostat according to the present invention having the configuration as described above will be described based on FIG. 10. 10 is a cross-sectional view showing an operating state of the thermostat according to the present invention.

Referring to the drawings, the thermostat 100 according to the present invention, when it is necessary to adjust the flow rate of the coolant in accordance with the temperature change of the coolant, supplies electrical energy to the heat generating unit 120 heat from the heat generating unit 120 The energy is released to expand the wax (W), and the expansion pressure of the wax (W) generated is linear motion by the diaphragm 140, the transfer oil (O) and the element 152 installed in the element guide 150. Switched to open the valve was closing the flow path formed in the thermostat housing 110 to communicate the coolant.

In other words, when the electric energy is supplied to the heating wire 126 winding the bobbin 124 through the power cable 116 from an external power source, the electrical wire 126 converts the electrical energy into thermal energy and emits it.

The released heat energy is transferred to the surface of the cylindrical case 122 by the heat transfer material 121 filled in the cylindrical case 122, and thus the wax (W) surrounding the cylindrical case 122 is heated to expand. Done. As the wax W expands, the pressure of the storage unit 134 of the wax chamber 130 increases to deform the diaphragm 140 installed at the bottom of the wax chamber 130.

As described above, when the diaphragm 140 is deformed by the inflation pressure of the wax W, the transfer oil O filled in the lower portion of the diaphragm 140 is concentrated on the upper end of the element 152 to form the element 152. The lower end of the element 152 is moved downwards by linearly moving toward the lower end of the guide 150 and the lifting member 160 in close contact with the lower end of the element guide 150.

As such, when the elevating member 160 moves downward, the valve 170, which is located at the top of the elevating member 160 and is in close contact with the flow path of the thermostat housing 110, moves downward so that the coolant flows. Will open.

When the valve 170 closing the flow path formed in the thermostat housing 110 is opened as described above, the coolant is supplied to the lower portion of the thermostat housing 110 along the flow path.

At this time, the bypass valve 190 provided on the lower outer diameter of the elevating member 160 to close the first flow path (111a) formed in the lower portion of the thermostat housing 110 in accordance with the downward movement of the elevating member (160). As a result, the coolant supplied through the third flow path 111c formed on the thermostat housing 110 is communicated with the second flow path 111b formed on the side surface of the thermostat housing 110.

On the contrary, when the wax W, which has been heated and expanded in the storage unit 134 of the wax chamber 130, gradually cools and contracts, the magnitude of the expansion pressure decreases. In this case, when the magnitude of the expansion pressure is smaller than the magnitude of the elastic restoring force of the elastic member 180 installed between the cover 182 and the valve 170, the valve 170 is formed by the elastic restoring force of the elastic member 180. In close contact with the flow path formed in the stat housing 110, the flow of the coolant supplied through the third flow path 111c formed on the thermostat housing 110 is blocked.

In addition, when the valve 170 is in close contact with the flow path formed in the thermostat housing 110, the bypass valve 190 closing the first flow path 111 a formed under the thermostat housing 110 is closed. While open, the coolant supplied through the first flow passage 111a communicates with the second flow passage 111b formed on the side surface of the thermostat housing 110.

In the thermostat 100 according to the present invention as described above, since the cylindrical case 122 is immersed in the wax (W) filled in the storage unit 134 of the wax chamber 130, the outer diameter of the cylindrical case 122 And an exothermic area in which the bottom surface is in contact with the wax W to heat and expand the wax W, thereby increasing the expansion pressure at which the wax W is expanded to open the valve 170. It can be obtained quickly to improve the reaction speed of the valve 170.

In addition, since the heat generation area for releasing heat energy to heat the wax (W) increases, heat transfer occurs over all the areas of the wax (W), and thus uniformity is obtained from all portions of the storage unit 134 filled with the wax (W). One inflation pressure can be obtained, and the inflation pressure thus obtained enables precise control of the valve 170 because the elevating member 160 is operated in detail.

In addition, the active space 154 through which the diaphragm 140 formed in the element guide 150 can act forms a sloped surface whose diameter gradually decreases toward the guide hole 156 in which the element 152 is installed. As the delivery oil O is filled in the active space 154, the pressure of the delivery oil O is concentrated on the upper end of the element 152 according to the deformation of the diaphragm 140. No loss of energy is required to allow the valve to operate accurately, making it suitable for controlling the flow of coolant with relatively high flow rates or high flow rates.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. .

For example, the first flow path 111a formed at the lower portion of the thermostat housing 110 described above is connected to a conduit through which the coolant discharged from the engine of the vehicle flows into the thermostat housing 110.

In addition, the second flow path 111b formed at the side of the thermostat housing 110 is connected to a pipeline for re-supplying the coolant introduced into the thermostat housing 110 to the engine of the vehicle.

In addition, the third flow path 111c formed at the upper portion of the thermostat housing 110 is connected to a conduit for introducing coolant discharged from the radiator of the vehicle into the thermostat housing 110.

100: thermostat
110: thermostat housing 112: fixed part
114: hole 120: heat generating portion
121: heat transfer material 122: cylindrical case
122a: bobbin entry port 122b: slot
122c: bending inclination 123: insulating material
124 bobbin 126 hot wire
128: spacer 130: wax chamber
132: body 132a: first step
132b: second step 134: storage unit
135: extension 136: sealing member
137a: turning
140: diaphragm 150: element guide
152: Element 154: Activity Space
156: guide hole 160: elevating member
162: communication hole 170: valve
180: elastic member 182: cover
O: transfer oil W: wax

Claims (11)

A thermostat housing in which a coolant flows;
A heating unit fixed to the inside of the thermostat housing to prevent flow;
A wax chamber in which the heating part is inserted and the wax is filled;
A diaphragm deformed by wax expanded in the wax chamber;
An element moved by the deformation force of the diaphragm;
An element guide supporting the outer circumferential surface of the element to guide the element;
An elevating member that elevates on the flow path of the thermostat housing by the pressing force of the element which is guided and moved by the element guide;
A valve coupled to the elevating member to open and close a flow path of the thermostat housing while moving together with the elevating member; And
And a resilient member that elastically supports the valve in the thermostat housing. The method according to claim 1, wherein the heat generating unit,
A cylindrical case fixed to the thermostat housing and having an open side;
A cap for shielding an open side of the cylindrical case;
A bobbin embedded in the cylindrical case sealed by the cap; And
A thermostat comprising; a heating wire wound on the bobbin. The method according to claim 2,
A heat transfer material filled in the cylindrical case; And
And a spacer configured to space the heat wire wound on the bobbin from the inner circumferential surface of the cylindrical case to uniformly fill the heat transfer material between the heat wire and the inner circumferential surface of the cylindrical case. The method according to claim 3,
The heat transfer material,
Is composed of at least one of powdered aluminum oxide (Al ₂ O ₃ ) or magnesium oxide (MgO) to transfer the heat of the hot wire,
The bobbin,
It is made of a plastic having heat resistance to the heat of the heating wire,
The spacer
A thermostat, characterized in that consisting of a protrusion projecting on the outer diameter of the bobbin. The method according to claim 2,
The cylindrical case is formed in a cup shape having a length by deep drawing, the thermostat characterized in that it has a slope on the open side. The method of claim 1, wherein the wax chamber,
One end is shielded by the diaphragm, the wax is filled in the inside, and the first step is caught on the part of the heat generating portion and the second step is caught on the one side and the other end of the second guide is caught in the open side hollow tube Consisting of;
The diaphragm is,
The thermostat is interposed between the second step of the hollow tube and a portion of the element guide is fixed to one side of the hollow tube. The method of claim 6,
And a sealing member interposed between the first step of the hollow tube and a portion of the heating part to seal a contact portion of the first step and the heating part. The method according to claim 7, wherein the sealing member,
The thermostat is characterized in that at least one of the O-ring interposed between the first step and the portion of the heat generating portion or a protrusion protruding from the first step and pressed by a portion of the heat generating portion. The method of claim 1, wherein the element guide,
One side is shielded by the diaphragm in a state in which the diaphragm is deformable, and a transmission oil for transmitting the deformation force of the diaphragm is compressed while being compressed by the deformed diaphragm, and the element moving to the deformation force of the diaphragm transferred by the transmission oil is on the other side. A thermostat, characterized in that it has a cylindrical shape inserted into the other end is shielded by the element. The method of claim 9, wherein the element guide,
Thermostat characterized in that the inclined surface for compressing the transfer oil is provided on the inner peripheral surface of one side shielded by the diaphragm. The method according to any one of claims 1 to 12,
The lifting member,
And a cup-shaped receptacle in which the element is inserted into the support to support the lower end of the element, the valve is fixed to the outside, and a communication hole in which the coolant of the thermostat housing communicates.

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