KR20120070234A - A water pump of temperature response - Google Patents

Abstract

PURPOSE: A temperature-sensing water pump is provided to improve the fuel efficiency of vehicles with preventing an engine from becoming overheated by adjusting the angle of a blade and the supply amount of coolants according to the temperature of the coolants. CONSTITUTION: A temperature-sensing water pump comprises a rotary shaft(10), and an impeller(20). The rotary shaft is rotated by the driving force of an engine. The impeller supplies coolants to the engine by the rotation force of the rotary shaft. The impeller controls the supply amount of the coolants by adjusting the angle of a blade according to the temperature of the coolants.

Description

A water pump of temperature response

The present invention relates to a temperature-sensitive water pump, and more particularly, to a temperature-sensitive water pump for shortening the warm-up time of the engine and the automatic transmission at low temperature cold start by adjusting the supply amount of the cooling water according to the temperature of the cooling water. It is about.

The mixture of air and fuel combusting in the engine cylinder of the vehicle rises to a temperature of 2200 ° C. or higher, and the heat may cause the problem of damage to the engine parts due to decomposition of lubricating oil or deterioration of lubricating performance.

In order to solve this problem, a cooling device is used in a vehicle, and one of the cooling devices, the water pump, supplies coolant to the engine to maintain the engine at an appropriate temperature. The water pump is directly connected to the engine through the drive belt, and is immediately driven as the engine is driven to supply the coolant. Since the water pump has a structure driven by the engine, the rotation speed of the water pump operates in dependence on the rotation speed of the engine, so that the engine supplies excessive cooling water regardless of the amount of cooling water actually required, and thus the engine and the automatic transmission at the time of cold start. It is an obstacle to raising the temperature of

That is, during cold start of low temperature of the engine and the automatic transmission, it is necessary to supply a small amount of cooling water in order to shorten the warm-up time of the engine and the automatic transmission, but the conventional water pump is immediately driven as the engine is driven to supply the cooling water. Therefore, there is a problem that can not control the supply amount of the cooling water in accordance with the temperature of the cooling water.

As described above, the conventional water pump does not control the supply amount of the cooling water according to the temperature, there is a problem that the engine and the automatic transmission takes a considerable time to warm up.

In addition, the engine driven during the warm-up time increases the friction due to the viscosity of the high oil according to the low temperature, there is a problem that the fuel economy of the vehicle is significantly reduced.

The problem to be solved by the present invention is to provide a temperature-sensitive water pump for reducing the warm-up time of the engine and automatic transmission during cold start.

In addition, the problem to be solved by the present invention is to provide a temperature-sensitive water pump for adjusting the supply amount of the cooling water in accordance with the temperature of the cooling water.

In addition, an object of the present invention is to provide a temperature-sensitive water pump for adjusting the angle of the blade according to the temperature of the cooling water.

The temperature-sensitive water pump may include a rotating shaft rotating based on a driving force of the engine; And an impeller supplying coolant to the engine based on the rotational force of the rotating shaft and controlling the supply amount of the coolant according to the temperature of the coolant.

In addition, the impeller, it is preferable that the angle of the blade is adjusted according to the temperature of the cooling water to control the supply amount of the cooling water.

In addition, the impeller, the lower frame receives a rotational force from the rotating shaft; A blade coupled to the lower frame, the angle of which is adjusted according to the temperature of the cooling water; An upper frame coupled to the blade and interlocked with an actuator to adjust an angle of the blade; And one end is coupled to the lower frame and the other end is coupled to the upper frame, the length is variable according to the temperature of the coolant is preferably further comprising an actuator for rotating the upper frame.

In addition, the impeller, the lower frame receives a rotational force from the rotating shaft; A blade coupled to the lower frame, the angle of which is adjusted by an actuator; An actuator having one end coupled to the lower frame and the other end coupled to the inner end of the blade, the actuator being variable in length depending on the temperature of the cooling water to adjust the angle of the blade; And by the interaction of the blade and the actuator, it is preferable to further include an upper frame that rotates to change the angle of the blade.

In addition, the impeller, the lower frame receives a rotational force from the rotating shaft; A blade coupled to the lower frame, the angle of which is adjusted according to the temperature of the cooling water; An upper frame coupled to the blade and interlocked with an actuator to adjust an angle of the blade; And one end is coupled to the rotary shaft and the other end is coupled to the upper frame, the length is variable according to the temperature of the coolant is preferably further comprising a scroll-type actuator for rotating the upper frame.

In addition, one end of the actuator is fixedly coupled to the rotating shaft and the other end is preferably coupled to the upper frame to be rotatable.

In addition, the impeller, the lower frame receives a rotational force from the rotating shaft; A blade coupled to the lower frame, the angle of which is adjusted by an actuator; And an end coupled to a position at which the lower frame and the blade are coupled, and the other end coupled to an inner end of another blade adjacent to the blade, the length of the actuator being variable according to the temperature of the coolant to adjust the angle of the blade. It is preferable to further include.

In addition, the impeller, the lower frame receives a rotational force from the rotating shaft; A blade coupled to the lower frame, the angle of which is adjusted by an actuator; And an actuator having a donut shape and coupled to an outer end of the blade, the length of the actuator being variable according to the temperature of the cooling water to adjust the angle of the blade.

In addition, the central portion of the blade is rotatably coupled to the lower frame and the inner end of the blade is rotatably coupled to the upper frame, it is preferable that the angle of the blade changes as the upper frame rotates.

In addition, the actuator is preferably coupled to the lower frame and the upper frame to be rotatable.

In addition, the actuator is preferably coupled to the lower frame and the blade rotatably.

According to the present invention, by adjusting the supply amount of the cooling water according to the temperature of the cooling water, it is possible to rapidly increase the temperature of the cooling water by reducing the supply amount of the cooling water at low temperature cold start, thereby reducing the warm-up time of the engine and automatic transmission, Has the effect of significantly improving the fuel economy.

In addition, by using an actuator that varies depending on the temperature, the angle of the blade can be adjusted by immediately reflecting the temperature of the cooling water that is changed, so that the supply amount of the cooling water can be more effectively controlled. That is, by reducing the supply amount of the cooling water during cold start, it is possible to effectively shorten the warm-up time of the engine and the automatic transmission, and when the engine is overheated, it is possible to effectively prevent the engine from overheating by increasing the supply of the cooling water. As described above, the fuel consumption of the vehicle can be further improved by appropriately adjusting the supply amount of the cooling water in accordance with the temperature of the cooling water.

1 is a perspective view showing a first embodiment of the present invention, a temperature sensitive water pump.
2 is a front view showing the operating state of FIG.
3 is a plan view showing the operating state of FIG.
4 is a front view showing an operating state according to a second embodiment of the present invention, a temperature sensitive water pump.
5 is a plan view showing the operating state of FIG.
6 is a front view showing an operating state according to a third embodiment of the present invention, a temperature sensitive water pump.
7 is a plan view showing the operating state of FIG.
8 is a plan view showing an operating state according to a fourth embodiment of the present invention, a temperature sensitive water pump.
9 is a plan view showing an operating state according to the fifth embodiment of the present invention, a temperature sensitive water pump.

Hereinafter, a preferred embodiment of a temperature sensitive water pump will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

The present invention, the temperature-sensitive water pump, the rotating shaft 10 rotates based on the driving force of the engine; And an impeller 20 for supplying coolant to the engine based on the rotational force of the rotary shaft 10 and controlling the supply amount of the coolant according to the temperature of the coolant.

In addition, the impeller 20 is characterized in that the angle of the blade 22 is adjusted according to the temperature of the cooling water to control the supply amount of the cooling water.

The rotating shaft 10 receives the driving force from the engine to rotate the impeller 20, and is connected to the engine through a driving belt (not shown). That is, when the engine is driven, the rotating shaft 10 receives the driving force from the engine to rotate the impeller 20, and when the driving of the engine is stopped, the driving of the rotating shaft 10 is also stopped.

The impeller 20 supplies the coolant to the engine based on the rotational force of the rotating shaft 10, and controls the supply amount of the coolant by changing the angle of the blade 22 according to the temperature of the coolant. That is, when the temperature of the coolant is low, the amount of coolant is relatively small. Therefore, the angle of the blade 22 is reduced so that a small amount of coolant is supplied. When the coolant temperature is high, the amount of coolant is relatively large. The angle of the blade 22 is enlarged so that positive cooling water is supplied.

As such, since the supply amount of the cooling water is adjusted based on the temperature of the cooling water supplied independently of the driving of the engine, the warm-up time of the engine and the automatic transmission may be significantly reduced during cold start. That is, since the temperature of the coolant is low during cold start, the angle of the blade 22 is reduced, so that a small amount of coolant is supplied, thereby rapidly increasing the temperature of the engine and the automatic transmission.

1, 2, and 3 illustrating a first embodiment of a temperature-sensitive water pump of the present invention, the impeller 20 includes: a lower frame 21 receiving a rotational force from the rotation shaft 10; A blade 22 coupled to the lower frame 21 and whose angle is adjusted according to the temperature of the cooling water; An upper frame 23 coupled to the blade 22 and interlocked with the actuator 24 to adjust the angle of the blade 22; And an actuator 24 having one end coupled to the lower frame 21 and the other end coupled to the upper frame 23, the length of which is varied according to the temperature of the coolant to rotate the upper frame 23. It is characterized by.

The lower frame 21 is formed of a circle, the center of the circle is fixedly coupled to the rotating shaft (10). That is, since the lower frame 21 and the rotation shaft 10 are fixedly coupled, the lower frame 21 receives the rotation force directly from the rotation shaft 10 and rotates the entire impeller 20 based on the rotation force.

One end of the actuator 24 is coupled to the upper surface of the lower frame 21 and the other end is coupled to the lower surface of the upper frame 23. At this time, the actuator 24 is rotatably coupled to the lower frame 21 and the upper frame 23, it is preferable to combine using a ball joint. In addition, the actuator 24 is preferably provided inside the portion where the blade 22 is located, it is preferable that the actuator 24 is provided with one or more.

In addition, the actuator 24 uses a metal, a shape memory alloy, or a wax-type actuator, the length of which varies with temperature. The metal decreases in length at temperatures below the reference temperature and increases in length at temperatures above the reference temperature. The shape memory alloy is an alloy that exhibits a shape memory reaction at a predetermined temperature, and an alloy is used in which the length decreases below a predetermined temperature and increases in length above a predetermined temperature. The wax type actuator utilizes the characteristics of a wax that expands and contracts when the temperature rises, and wax is provided inside the actuator. When the temperature decreases, the wax shrinks and the length of the actuator decreases, and the wax rises when the temperature rises. Inflation increases the length of the actuator.

In the present invention, such a variable length characteristic is used, and when the temperature of the cooling water rises, the length of the actuator 24 increases, and as the length increases, the upper frame 23 rotates in a predetermined direction. At this time, since one or more blades 22 are coupled to the upper frame 23, the angles of all the blades 22 coupled by the rotation of the upper frame 23 increase. As the angle of the blade 22 increases, the amount of coolant supplied to the engine increases.

On the contrary, when the temperature of the cooling water decreases, the length of the actuator 24 is reduced, and as the length is reduced, the upper frame 23 rotates in the opposite direction to the above. That is, by rotating the upper frame 23 in the opposite direction as the temperature of the cooling water rises, the angle of the blade 22 is reduced to reduce the amount of cooling water supplied to the engine.

The upper frame 23 is formed in a circle, the through groove is formed in the center of the circle so that the rotating shaft 10 penetrates. That is, the upper frame 23 and the rotating shaft 10 are coupled to be rotatable, whereby the upper frame 23 is driven independently of the rotational force of the rotating shaft 10. In addition, the upper frame 23 is coupled to the upper portion of the blade 22, in which the outer side of the upper frame 23 and the inner end of the blade 22 is coupled to be rotatable. In addition, the upper frame 23 is preferably formed smaller than the size of the lower frame 21.

Since the actuator 24 is rotatably coupled to the lower surface of the upper frame 23, the upper frame 23 rotates in a predetermined direction according to the operating state of the actuator 24. That is, when the coolant temperature is increased and the length of the actuator 24 is increased, the upper frame 23 rotates in the direction in which the angle of the blade 22 is increased, and when the temperature of the coolant is lowered and the length of the actuator 24 is reduced, The upper frame 23 rotates in a direction in which the angle of the blade 22 decreases. As described above, the angle of the blade 22 is adjusted by the interaction of the actuator 24 and the upper frame 23 according to the coolant temperature, thereby controlling the amount of coolant supplied to the engine.

The blade 22 is located between the lower frame 21 and the upper frame 23, it is coupled to the lower frame 21 and the upper frame 23 to be rotatable. That is, the center portion of the blade 22 is rotatably coupled to the lower frame 21, and the inner end of the blade 22 is rotatably coupled to the upper frame 23. At this time, it can be combined to be rotatable using a ball joint, it can be combined to be rotatable using a separate connection (not shown).

In the following description, the coupling using the connection part (not shown) will be described. In the case where the connection part (not shown) is formed on the upper and lower surfaces of the blade 22, the upper frame 23 corresponding to the connection part (not shown) of the upper surface is shown. A connecting groove (not shown) is formed at the position of the bottom and a connecting groove (not shown) is formed at the position of the lower frame 21 corresponding to the connecting portion (not shown) of the lower surface. That is, the connecting portion (not shown) is fixed to the blade 22, the upper connecting portion (not shown) of the blade 22 is inserted into the connecting groove (not shown) formed in the upper frame 23 and the blade 22 The lower connection part (not shown) is inserted into a connection groove (not shown) formed in the lower frame 21.

In addition, when the connecting portion (not shown) is formed on the upper surface of the lower frame 21 and the lower surface of the upper frame 23, the connecting groove (at the position of the blade 22 corresponding to the connecting portion (not shown) of the lower frame 21 ( A connecting groove (not shown) is formed at a position of the blade 22 corresponding to the connecting portion (not shown) of the upper frame 23. That is, each connecting portion (not shown) is fixed to the lower frame 21 and the upper frame 23, and the connecting portion (not shown) of the lower frame 21 is the connecting groove of the blade 22 formed at the corresponding position ( The connecting portion (not shown) of the upper frame 23 is inserted into the connecting groove (not shown) of the blade 22 formed at the corresponding position.

Blade 22 coupled as described above is adjusted in accordance with the rotation direction of the upper frame (23). That is, when the temperature of the cooling water rises, the angle of the blade 22 is increased by the upper frame 23, and when the temperature of the cooling water is lowered, the angle of the blade 22 is reduced by the upper frame 23. Thus, the amount of coolant supplied to the engine can be adjusted according to the temperature of the coolant separately from the driving of the engine.

4 and 5 showing a second embodiment of the temperature-sensitive water pump of the present invention, the impeller 20 includes: a lower frame 21 receiving a rotational force from the rotating shaft 10; A blade 22 coupled to the lower frame 21 and whose angle is adjusted by an actuator 24; An actuator 24 having one end coupled to the lower frame 21 and the other end coupled to the inner one end of the blade 22 and having a variable length depending on the temperature of the coolant to adjust an angle of the blade 22; And by the interaction of the blade 22 and the actuator 24, it characterized in that it further comprises an upper frame 23 that rotates so that the angle of the blade 22 is changed.

The lower frame 21 is formed of a circle, the center of the circle is fixedly coupled to the rotating shaft (10). That is, since the lower frame 21 and the rotation shaft 10 are fixedly coupled, the lower frame 21 receives the rotation force directly from the rotation shaft 10 and rotates the entire impeller 20 based on the rotation force.

One end of the actuator 24 is coupled to the upper surface of the lower frame 21 and the other end is coupled to the inner end of the blade 22. At this time, the actuator 24 is rotatably coupled to the lower frame 21 and the blade 22, it is preferably coupled using a ball joint. In addition, the actuator 24 is preferably provided with one or more.

In addition, the actuator 24 uses a metal, a shape memory alloy, or a wax-type actuator, the length of which varies with temperature. The metal decreases in length at temperatures below the reference temperature and increases in length at temperatures above the reference temperature. The shape memory alloy is an alloy that exhibits a shape memory reaction at a predetermined temperature, and an alloy is used in which the length decreases below a predetermined temperature and increases in length above a predetermined temperature. The wax type actuator utilizes the characteristics of a wax that expands and contracts when the temperature rises, and wax is provided inside the actuator. When the temperature decreases, the wax shrinks and the length of the actuator decreases, and the wax rises when the temperature rises. Inflation increases the length of the actuator.

In the present invention, such a variable length characteristic is used, and when the temperature of the coolant increases, the length of the actuator 24 increases, and as the length increases, the blade 22 coupled to the actuator 24 rotates in a predetermined direction. Done. At this time, since all the blades 22 are rotatably coupled to the upper frame 23, all the blades 22 coupled to the upper frame 23 when the angle of one blade 22 is changed by the actuator 24. ) Will change the angle. Therefore, as the length of the actuator 24 is increased, the angles of all the blades 22 are increased, and as the angle is increased, the amount of coolant supplied to the engine is increased.

On the contrary, when the temperature of the coolant drops, the length of the actuator 24 is reduced, and as the length decreases, the blade 22 coupled to the actuator 24 rotates in the opposite direction. That is, by rotating the blade 22 in the opposite direction as the temperature of the cooling water rises, the angle of the blade 22 is reduced to reduce the amount of cooling water supplied to the engine.

The upper frame 23 is formed in a circle, the through groove is formed in the center of the circle so that the rotating shaft 10 penetrates. That is, the upper frame 23 and the rotating shaft 10 are coupled to be rotatable, whereby the upper frame 23 is driven independently of the rotational force of the rotating shaft 10. In addition, the upper frame 23 is coupled to the upper portion of the blade 22, in which the outer side of the upper frame 23 and the inner end of the blade 22 is coupled to be rotatable. In addition, the upper frame 23 is preferably formed smaller than the size of the lower frame 21.

The blade 22 is located between the lower frame 21 and the upper frame 23, it is coupled to the lower frame 21 and the upper frame 23 to be rotatable. That is, the center portion of the blade 22 is rotatably coupled to the lower frame 21, and the inner end of the blade 22 is rotatably coupled to the upper frame 23. At this time, it can be combined to be rotatable using a ball joint (not shown), it can be combined to be rotatable using a separate connection (not shown). The method of coupling to the lower frame 21 and the upper frame 23 through a separate connecting portion (not shown) is the same as the method described in the first embodiment.

As the blade 22 coupled to the actuator 24 rotates as described above, the upper frame 23 rotates, and all the blades 22 coupled to the upper frame 23 rotate. That is, when the temperature of the coolant rises, the blades 22 are rotated in the direction in which the angle is increased by the actuator 24, and thus the upper frame 23 is rotated so that all the blades coupled to the upper frame 23 are rotated. Reference numeral 22 rotates in the direction in which the angle increases. In addition, when the temperature of the coolant drops, the actuator 22 rotates the blade 22 in a direction in which the angle decreases. Accordingly, the upper frame 23 rotates so that all the blades coupled to the upper frame 23 ( 22) rotates in the direction of decreasing angle. Thus, the amount of coolant supplied to the engine can be adjusted according to the temperature of the coolant separately from the driving of the engine.

6 and 7 showing a third embodiment of the temperature-sensitive water pump of the present invention, the impeller 20, the lower frame 21 receives the rotational force from the rotating shaft 10; A blade 22 coupled to the lower frame 21 and whose angle is adjusted according to the temperature of the cooling water; An upper frame 23 coupled to the blade 22 and interlocked with the actuator 24 to adjust the angle of the blade 22; And one end is coupled to the rotary shaft 10 and the other end is coupled to the upper frame 23, the length is variable depending on the temperature of the coolant further scroll type actuator 24 for rotating the upper frame 23 further It is characterized by including.

The lower frame 21 is formed of a circle, the center of the circle is fixedly coupled to the rotating shaft (10). That is, since the lower frame 21 and the rotation shaft 10 are fixedly coupled, the lower frame 21 receives the rotation force directly from the rotation shaft 10 and rotates the entire impeller 20 based on the rotation force.

The actuator 24 is provided in a scroll form so that one end is fixedly coupled to the rotation shaft 10 and the other end is coupled to the upper frame 23. At this time, the actuator 24 is rotatably coupled to the upper frame 23, it is preferably coupled using a ball joint. In addition, one end of the actuator 24 may be fixedly coupled to the lower frame 21.

In addition, the actuator 24 uses a metal, a shape memory alloy, and the like, the length of which varies with temperature. The metal decreases in length at temperatures below the reference temperature and increases in length at temperatures above the reference temperature. The shape memory alloy is an alloy that exhibits a shape memory reaction at a predetermined temperature, and an alloy is used in which the length decreases below a predetermined temperature and increases in length above a predetermined temperature.

In the present invention, such a variable length characteristic is used, and when the temperature of the coolant is increased, the length of the actuator 24 increases, and as the length increases, the upper frame 23 coupled to the actuator 24 in a predetermined direction. Will rotate. At this time, since all the blades 22 are rotatably coupled to the upper frame 23, when the upper frame 23 is rotated by the actuator 24, of all the blades 22 coupled to the upper frame 23 The angle will change. Therefore, as the length of the actuator 24 is increased, the angles of all the blades 22 are increased, and as the angle is increased, the amount of coolant supplied to the engine is increased.

On the contrary, when the temperature of the cooling water decreases, the length of the actuator 24 is reduced, and as the length decreases, the upper frame 23 coupled to the actuator 24 rotates in the opposite direction. That is, by rotating the upper frame 23 in the opposite direction as the temperature of the cooling water rises, the angle of the blade 22 is reduced to reduce the amount of cooling water supplied to the engine.

The upper frame 23 is formed in a circle, the through groove is formed in the center of the circle so that the rotating shaft 10 penetrates. That is, the upper frame 23 and the rotating shaft 10 are coupled to be rotatable, whereby the upper frame 23 is driven independently of the rotational force of the rotating shaft 10. In addition, the upper frame 23 is coupled to the upper portion of the blade 22, in which the outer side of the upper frame 23 and the inner end of the blade 22 is coupled to be rotatable. In addition, the upper frame 23 is preferably formed smaller than the size of the lower frame 21.

In addition, the actuator 24 is coupled to the upper frame 23, and as the length of the actuator 24 is changed, the upper frame 23 rotates in a predetermined direction, the blade according to the rotation direction of the upper frame 23 Angle of 22 is adjusted.

The blade 22 is located between the lower frame 21 and the upper frame 23, it is coupled to the lower frame 21 and the upper frame 23 to be rotatable. That is, the center portion of the blade 22 is rotatably coupled to the lower frame 21, and the inner end of the blade 22 is rotatably coupled to the upper frame 23. At this time, it can be combined to be rotatable using a ball joint (not shown), it can be combined to be rotatable using a separate connection (not shown). The method of coupling to the lower frame 21 and the upper frame 23 through a separate connecting portion (not shown) is the same as the method described in the first embodiment.

As the upper frame 23 coupled to the actuator 24 rotates as described above, all the blades 22 coupled to the upper frame 23 rotate. That is, when the temperature of the cooling water rises, the upper frame 23 rotates in the direction in which the angle of the blade 22 is increased by the actuator 24, and thus all the blades 22 coupled to the upper frame 23 are rotated. ) Rotates in the direction of increasing angle. In addition, when the temperature of the cooling water is lowered, the upper frame 23 rotates in the direction in which the angle of the blade 22 is reduced by the actuator 24, and thus all the blades 22 coupled to the upper frame 23. Rotates in the direction of decreasing angle. Thus, the amount of coolant supplied to the engine can be adjusted according to the temperature of the coolant separately from the driving of the engine.

According to Figure 8 showing a fourth embodiment of the temperature-sensitive water pump of the present invention, the impeller 20, the lower frame 21 receives a rotational force from the rotating shaft; A blade 22 coupled to the lower frame 21 and whose angle is adjusted by an actuator 24; And one end is coupled to a position where the lower frame 21 and the blade 22 are coupled, and the other end is coupled to an inner one end of the other blade 22 adjacent to the blade 22 and has a length depending on the temperature of the cooling water. Is variable is characterized in that it further comprises an actuator for adjusting the angle of the blade (22).

The lower frame 21 is formed of a circle, the center of the circle is fixedly coupled to the rotating shaft (10). That is, since the lower frame 21 and the rotation shaft 10 are fixedly coupled, the lower frame 21 receives the rotation force directly from the rotation shaft 10 and rotates the entire impeller 20 based on the rotation force.

One end of the actuator 24 is rotatably coupled to a position where the lower frame 21 and the blade 22 are coupled, and the other end is coupled to an inner end of another adjacent blade 22. That is, the actuator 24 connects the blade 22 and the other blade 22 adjacent to each other. At this time, the actuator 24 and the blade 22 are preferably hinged or coupled using a ball joint so as to be rotatable.

In addition, the position at which the actuator 24 is coupled is not limited to the above description, and may be coupled to any position where the angle of the blade 22 may be changed according to the change in the length of the actuator 24.

In addition, the actuator 24 uses a metal, a shape memory alloy, or a wax-type actuator, the length of which varies with temperature. The metal decreases in length at temperatures below the reference temperature and increases in length at temperatures above the reference temperature. The shape memory alloy is an alloy that exhibits a shape memory reaction at a predetermined temperature, and an alloy is used in which the length decreases below a predetermined temperature and increases in length above a predetermined temperature. The wax type actuator utilizes the characteristics of a wax that expands and contracts when the temperature rises, and wax is provided inside the actuator. When the temperature decreases, the wax shrinks and the length of the actuator decreases, and the wax rises when the temperature rises. Inflation increases the length of the actuator. In the fourth embodiment of the present invention, since the actuator 24 is installed between the blade 22 and the adjacent blade 22, the actuator 24 having the same expansion coefficient according to temperature is used.

In the present invention, such a variable length characteristic is used, and when the temperature of the coolant increases, the length of the actuator 24 increases, and as the length increases, the blade 22 coupled to the actuator 24 rotates in a predetermined direction. Done. At this time, since all the blades 22 are coupled to the actuator 24 so as to be rotatable, the angles of all the blades 22 are changed by the actuators 24. Therefore, as the length of the actuator 24 is increased, the angles of all the blades 22 are increased, and as the angle is increased, the amount of coolant supplied to the engine is increased.

On the contrary, when the temperature of the coolant drops, the length of the actuator 24 is reduced, and as the length decreases, the blade 22 coupled to the actuator 24 rotates in the opposite direction. That is, by rotating the blade 22 in the opposite direction as the temperature of the cooling water rises, the angle of the blade 22 is reduced to reduce the amount of cooling water supplied to the engine.

The center portion of the blade 22 is rotatably coupled to the lower frame 21. At this time, it can be combined to be rotatable using a ball joint (not shown), it can be combined to be rotatable using a separate connection (not shown). The way in which the blade 22 is coupled to the lower frame 21 through a separate connection part (not shown) is the same as the method described in the first embodiment.

As described above, by connecting the blade 22 and the adjacent blade 22 using the actuator 24, the angle of the blade 22 is changed according to the change in the length of the actuator 24. That is, when the temperature of the coolant is increased, the length of the actuator 24 is increased to increase the angle of the blade 22, and when the temperature of the coolant is decreased, the length of the actuator 24 is reduced to decrease the angle of the blade 22. This decreases. Thus, the amount of coolant supplied to the engine can be adjusted according to the temperature of the coolant separately from the driving of the engine.

According to Figure 9 showing a fifth embodiment of the temperature-sensitive water pump of the present invention, the impeller 20, the lower frame 21 receives the rotational force from the rotating shaft 10; A blade 22 coupled to the lower frame 21 and whose angle is adjusted by an actuator 24; And an actuator 24 having a donut shape and coupled to an outer end of the blade 22, the length of which is varied according to the temperature of the cooling water to adjust the angle of the blade 22.

The lower frame 21 is formed of a circle, the center of the circle is fixedly coupled to the rotating shaft (10). That is, since the lower frame 21 and the rotation shaft 10 are fixedly coupled, the lower frame 21 receives the rotation force directly from the rotation shaft 10 and rotates the entire impeller 20 based on the rotation force.

The actuator 24 has a donut shape and is rotatably coupled to an outer end of the blade 22. At this time, the actuator 24 and the blade 22 is preferably hinged to be rotatable or coupled using a ball joint.

In addition, the position at which the actuator 24 is coupled is not limited to the above description, and may be coupled to any position where the angle of the blade 22 may be changed according to the change in the length of the actuator 24.

In addition, the actuator 24 uses a metal, a shape memory alloy, and the like, the length of which varies with temperature. The metal decreases in length at temperatures below the reference temperature and increases in length at temperatures above the reference temperature. The shape memory alloy is an alloy that exhibits a shape memory reaction at a predetermined temperature, and an alloy is used in which the length decreases below a predetermined temperature and increases in length above a predetermined temperature.

In the present invention, such a variable length characteristic is used, and when the temperature of the cooling water rises, the length of the actuator 24 is increased, and thus the donut-shaped actuator 24 is expanded in the outward direction. As it expands in the outward direction, the blade 22 coupled to the actuator 24 rotates in a predetermined direction. At this time, since all the blades 22 are coupled to the actuator 24 so as to be rotatable, the angles of all the blades 22 are changed by the actuators 24. Therefore, when the actuator 24 expands in the outward direction, the angles of all the blades 22 increase, and as the angle increases, the amount of coolant supplied to the engine increases.

On the contrary, when the temperature of the cooling water decreases, the length of the actuator 24 is reduced, and thus the donut-shaped actuator 24 contracts inward. As it contracts inward, the blade 22 coupled to the actuator 24 rotates in the opposite direction. That is, by rotating the blade 22 in the opposite direction as the temperature of the cooling water rises, the angle of the blade 22 is reduced to reduce the amount of cooling water supplied to the engine.

The center portion of the blade 22 is rotatably coupled to the lower frame 21. At this time, it can be combined to be rotatable using a ball joint (not shown), it can be combined to be rotatable using a separate connection (not shown). The way in which the blade 22 is coupled to the lower frame 21 through a separate connection part (not shown) is the same as the method described in the first embodiment.

By coupling the donut-shaped actuator 24 to the outer end of the blade 22 as described above, the angle of the blade 22 is changed in accordance with the expansion or contraction of the actuator 24. That is, when the temperature of the coolant rises, the actuator 24 expands outward and the angle of the blade 22 increases, and when the temperature of the coolant falls, the actuator 24 contracts inward and the blade 22 ) Is reduced. Thus, the amount of coolant supplied to the engine can be adjusted according to the temperature of the coolant separately from the driving of the engine.

As described above, although the embodiment of the present invention has been described, the technical idea of the present invention is not limited to the above embodiment, and various temperature-sensitive water pumps may be implemented in a range that does not depart from the technical idea of the present invention.

10... Rotating shaft
20... Impeller
21 ... Underframe
22... blade
23 ... Upper frame
24 ... Actuator

Claims (11)

A rotating shaft 10 rotating based on the driving force of the engine; And
The temperature-sensitive water pump, characterized in that it comprises an impeller (20) for supplying the coolant to the engine based on the rotational force of the rotating shaft (10), and controls the supply amount of the coolant in accordance with the temperature of the coolant. The method of claim 1, wherein the impeller 20,
Temperature-sensitive water pump, characterized in that the angle of the blade 22 is adjusted according to the temperature of the cooling water to control the supply amount of cooling water. The method of claim 2, wherein the impeller 20,
A lower frame 21 receiving a rotational force from the rotation shaft 10;
A blade 22 coupled to the lower frame 21 and whose angle is adjusted according to the temperature of the cooling water;
An upper frame 23 coupled to the blade 22 and interlocked with the actuator 24 to adjust the angle of the blade 22; And
One end is coupled to the lower frame 21 and the other end is coupled to the upper frame 23, the length is variable depending on the temperature of the coolant further comprises an actuator 24 for rotating the upper frame 23 A temperature sensitive water pump. The method of claim 2, wherein the impeller 20,
A lower frame 21 receiving a rotational force from the rotation shaft 10;
A blade 22 coupled to the lower frame 21 and whose angle is adjusted by an actuator 24;
An actuator 24 having one end coupled to the lower frame 21 and the other end coupled to the inner one end of the blade 22 and having a variable length depending on the temperature of the coolant to adjust an angle of the blade 22; And
Temperature-sensitive water pump, characterized in that further by the upper frame (23) rotates so that the angle of the blade (22) by the interaction of the blade (22) and the actuator (24). The method of claim 2, wherein the impeller 20,
A lower frame 21 receiving a rotational force from the rotation shaft 10;
A blade 22 coupled to the lower frame 21 and whose angle is adjusted according to the temperature of the cooling water;
An upper frame 23 coupled to the blade 22 and interlocked with the actuator 24 to adjust the angle of the blade 22; And
One end is coupled to the rotary shaft 10 and the other end is coupled to the upper frame 23, the length is variable depending on the temperature of the coolant further comprises a scroll-shaped actuator 24 for rotating the upper frame 23 Temperature-sensitive water pump, characterized in that. The method of claim 5,
One end of the actuator 24 is fixedly coupled to the rotary shaft 10 and the other end is coupled to the upper frame 23 so as to be rotatable. The method of claim 2, wherein the impeller 20,
A lower frame 21 receiving a rotational force from the rotation shaft 10;
A blade 22 coupled to the lower frame 21 and whose angle is adjusted by an actuator 24; And
One end is coupled to the position where the lower frame 21 and the blade 22 are coupled, and the other end is coupled to the inner end of the other blade 22 adjacent to the blade 22, and the length is dependent on the temperature of the cooling water. Temperature-sensitive water pump, characterized in that it further comprises an actuator (24) that is variable to adjust the angle of the blade (22). The method of claim 2, wherein the impeller 20,
A lower frame 21 receiving a rotational force from the rotation shaft 10;
A blade 22 coupled to the lower frame 21 and whose angle is adjusted by an actuator 24; And
It has a donut shape and is coupled to the outer end of the blade 22, the length is variable depending on the temperature of the cooling water further comprises an actuator 24 for adjusting the angle of the blade 22 Water pump. The method according to any one of claims 3 to 5,
The center portion of the blade 22 is rotatably coupled to the lower frame 21 and the inner end of the blade 22 is rotatably coupled to the upper frame 23, the upper frame 23 is rotated Temperature-sensitive water pump, characterized in that the angle of the blade 22 changes as it changes. The method of claim 3, wherein the actuator 24,
Temperature-sensitive water pump, characterized in that coupled to the lower frame (21) and the upper frame (23) rotatably. The method of claim 4, wherein the actuator 24,
Temperature-sensitive water pump, characterized in that coupled to the lower frame (21) and the blade (22) rotatably.

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