DE112018005290T5 - Fluid control valve - Google Patents

Abstract

A fluid control valve (5) has a valve element (57) that opens and closes the inner passage (512) to toggle between an open valve state and a closed valve state. Pressure of a working fluid acts on the valve element in a direction toward the valve open state. The fluid control valve has a first path, which is a magnetic path through which a magnetic flux passes between a piston (55) and a yoke (56), and a second path, which is a magnetic path, through which a magnetic flux passes between the Passes through the piston and the yoke at a position different from the first path. At the start of energization in the open valve state, a magnetic path is formed in which the magnetic flux in the first path is greater than in the second path. In the closed valve state, a magnetic path is formed in which the magnetic flux in the second path is larger than in the first path. Accordingly, valve closing performance at the time of closing the valve against the pressure of the working fluid can be improved while an increase in size is reduced.

Description

CROSS REFERENCE TO RELATED APPLICATION

This application is based on and by reference to the Japanese patent application number 2017 - 179 306 which was submitted on September 19, 2017.

TECHNICAL AREA

The present disclosure relates to a fluid control valve.

BACKGROUND

Patent Literature 1 discloses an on-off valve provided in an engine cooling circuit to allow and block flow of a fluid that has flowed out of an engine. The on-off valve has a coil spring that constantly urges a valve element in a valve closing direction, and has a solenoid that generates an attractive force that drives the valve element in the valve closing direction when the solenoid is energized. When an electric pump is in operation, pressure of the fluid also acts in one direction to open the valve element. Therefore, to close the on-off valve, the attraction force of the solenoid is used in addition to the urging force of the coil spring. To open the on-off valve, in addition to reducing the energy of the solenoid, the fluid must be delivered from the electric pump such that the fluid pressure received by the valve element exceeds the urging force of the coil spring.

PRIOR ART LITERATURE

PATENT LITERATURE

Patent literature 1: JP 5 811 797 B2

SUMMARY OF THE INVENTION

In the on-off valve of Patent Literature 1, when the valve is shifted from an open state to a closed state, depending on an order of magnitude of the fluid pressure acting in the opposite direction to the valve closing direction, the valve may even be driven by the one with energy acted upon and the attraction generating solenoid is not closed. In order to reliably close the valve, a method can be adopted that uses a spring that has a large urging force, but in this case, there is a problem that the size of the device becomes large. There is also a concern that the valve can be closed by the urging force of the spring when the fluid pressure is relieved after energization is complete.

An object of the disclosure is to provide a fluid control valve that is capable of reducing its size and improving valve closing performance at the time of closing the valve against a pressure of a working fluid.

The disclosed aspects in this description incorporate different technical solutions from each other to accomplish their respective tasks. It should be noted that the reference numerals in parentheses described in this section and the scope of the claims are each examples, which are the correspondence with the certain means described as an embodiment in the embodiments described later, and the technical scope of the In no way limit the invention.

One of the fluid control valves disclosed has: a housing having an internal passage through which a liquid working fluid flows; a valve element that opens and closes the inner passage to switch between an open valve state and a closed valve state, the valve element being separated from the valve seat in the open valve state to restrict the flow of the working fluid through the inner passage enable pressure of the working fluid in a direction toward the valve open condition to act on the valve member; a piston that drives the valve element in an axial direction of the valve element; a coil that generates a magnetic force that drives the piston in the axial direction to switch from the open valve state to the closed valve state due to energization of the coil; a yoke which, together with the piston, forms a magnetic circuit while being energized; a first path who is a magnetic path through which a magnetic flux passes between the piston and the yoke; and a second path who is a magnetic path through which a magnetic flux between the piston and the yoke is in a different position from the first path goes through. The first path and the second path are positioned so that the first path in its magnetic flux larger than the second path is at the start of energizing in the open valve state, and the second path is larger in its magnetic flux, and the second path larger than the first in its magnetic flux path is in the closed valve state.

When, according to the fluid control valve, energizing in the open state When the valve is started, the attraction of the piston against the fluid pressure can be started by using the driving force generated by the magnetic flux generated by the first path passes through, which has a greater magnetic flux than the second path . In addition, when the valve element changes from the open valve state to the closed valve state, the piston can be attracted to and contacted by the yoke so that the closed valve state is maintained using the driving force generated by the magnetic flux is that by the second path that has a larger magnetic flux than the first path having.

Thus, the first one path dominant than a magnetic path when energization is started in the open valve state. Thus, the attractive force that attracts the piston to the valve seat can be exerted, and a driving force for moving the valve member in the direction against the pressure of the working fluid can be obtained. In the closed valve state, the second path as a magnetic path dominant so that the pull to maintain the valve element in contact with the valve seat can be exerted to shut off the internal passage. Thus, both the closing of the valve from the open valve state and maintaining the closed state can be performed without being dependent on an urging force of a spring or the like. Thus, an increase in size due to the addition of the spring or an improvement in the urging force can be reduced. Accordingly, the fluid control valve capable of reducing the size and improving valve closing performance at the time of closing the valve against a pressure of the working fluid can be provided.

Figure list

• The 1 12 is a configuration diagram showing a cooling water circuit according to a first embodiment.
• The 2nd 12 is a sectional view showing an open valve state of a fluid control valve according to the first embodiment.
• The 3rd 12 is a sectional view showing a closed valve state of the fluid control valve according to the first embodiment.
• The 4th is an enlarged view showing a magnetic path between a yoke and a piston in the open valve state.
• The 5 is an enlarged view showing a magnetic path between the yoke and the piston in the closed valve state.
• The 6 Figure 3 is a characteristic diagram showing a relationship between the stroke and the force of attraction for a first path and a second path shows.
• The 7 is a view showing a magnetic path between a yoke and a piston in an open valve state of a fluid control valve according to a second embodiment.
• The 8th is an enlarged view showing a magnetic path between the yoke and the piston in a closed valve state.
• The 9 is a view showing a magnetic path between a yoke and a piston in an open valve state of a fluid control valve according to a third embodiment.
• The 10 is an enlarged view showing a magnetic path between the yoke and the piston in a closed valve state.
• The 11 is a view showing a magnetic path between a yoke and a piston in an open valve state of a fluid control valve according to a fourth embodiment.
• The 12th is an enlarged view showing a magnetic path between the yoke and the piston in a closed valve state.
• The 13 is a view showing a magnetic path between a yoke and a piston in an open valve state of a fluid control valve according to a fifth embodiment.
• The 14 is an enlarged view showing a magnetic path between the yoke and the piston in a closed valve state.
• The 15 is a view showing a magnetic path between a yoke and a piston in an open valve state of a fluid control valve according to a sixth embodiment.
• The 16 is an enlarged view showing a magnetic path between the yoke and the piston in a closed valve state.
• The 17th is a view showing a magnetic path between a yoke and a piston in an open valve state Fluid control valve according to a seventh embodiment.
• The 18th is an enlarged view showing a magnetic path between the yoke and the piston in a closed valve state.
• The 19th is a view showing a magnetic path between a yoke and a piston in an open valve state of a fluid control valve according to an eighth embodiment.
• The 20 is an enlarged view showing a magnetic path between the yoke and the piston in a closed valve state.

DETAILED DESCRIPTION

Embodiments for implementing the present disclosure will be described below with reference to the drawings. In each embodiment, portions corresponding to the elements described in the previous embodiments are given the same reference numerals, and repeated explanations can be omitted. If only part of a configuration is described in one embodiment, another previous embodiment can be applied to the other parts of the configuration. The present disclosure is not limited to the combinations of the embodiments that combine parts that are explicitly described as combinable. As long as there is no problem, the various embodiments can be partially combined with one another even if this is not explicitly described.

(First embodiment)

The fluid control valve to achieve the object of the present disclosure switches between an open valve state in which a fluid passage is open and a closed valve state in which the fluid passage is shut off. A valve closing direction is defined as a direction opposite to a pressure direction of a working fluid flowing through the fluid control valve. The working fluid controlled by the fluid control valve may be a liquid such as water or an oil.

A first embodiment showing an example of the fluid control valve is described with reference to FIG 1 to 6 described. The fluid control valve 5 the first embodiment is in a cooling water circuit 1 using a liquid as a working fluid. The cooling water circuit 1 is a circle through which engine cooling water circulates and has a function of an engine provided in a vehicle 2nd effectively warm up and cool. As from the 1 can be seen, the cooling water circuit 1 the machine 2nd , a pump 3rd , a first flow path 10 , a second flow path 11 , a third flow path 12th , On-off valve 4th , a heater core 6 , a fluid control valve 5 , a cooler 7 and a controller 8th .

The cooling water flows out of the pump 3rd flows out through the machine 2nd , the first flow path 10 , the second flow path 11 and the third flow path 12th and returns to the pump 3rd back. The control 8th has at least one processor and at least one storage device as a storage medium for storing a program and data. The control 8th is provided by a microcontroller with a computer readable storage medium. The storage medium is a non-transferable substantive storage medium that stores a computer readable program in a non-temporary manner. A semiconductor memory, a magnetic disk, or the like can serve as the storage medium. The control 8th or a set of computing resources linked together by a data link device can serve as the controller. The program is controlled by the controller 8th executed to cause control 8th functions as the device described in this description and as the controller 8th works to perform the procedure described in this description. A functional unit of the control 8th to perform various processes for warming up and cooling the machine 2nd is made of hardware and / or software.

The pump 3rd works in conjunction with an operation of the machine 2nd to drive the cooling water when the machine 2nd is in an operating state. So the pump works 3rd when the machine 2nd is in the operating state to circulate the cooling water and does not work when the machine is 2nd is in a stopped state. The pump 3rd can be powered by an electric motor as a drive source and regardless of the operating state of the machine 2nd operated and stopped. In this case, the pump 3rd a discharge amount of a fluid by a controller of the controller 8th to change.

The first flow path 10 is a flow path through which the out of the machine 2nd outflowing fluid through the pump 3rd into the machine 2nd flows. The machine 2nd has a flow path through which the cooling water flows. That inside the machine 2nd flowing cooling water absorbs heat from the machine 2nd and raises its own temperature, and decreases it internal temperature of the machine 2nd . The second flow path 11 is a flow path in which that from the machine 2nd outflowing cooling water from a downstream side of the machine 2nd in the first flow path 10 branches and through the fluid control valve 5 and the heater core 6 returns to a section that is between the machine 2nd and the first flow path 10 is positioned. The second flow path 11 is with the fluid control valve 5 and the heater core 6 provided. The third flow path 12th is a flow path in which the cooling water from an upstream side of the fluid control valve 5 in the second flow path 11 branches and through the cooler 7 returns to the section between the machine 2nd and the first flow path 10 is positioned.

The third flow path 12th is with the cooler 7 provided. The switching valve 4th is provided on a link at which the third flow path 12th with the first flow path 10 connected is. The switching valve 4th is configured to be able to between a first state in which the first flow path 10 and the third flow path 12th are not connected to each other in such a way that the cooling water in the first flow path 10 circulates, and a second state in which the first flow path 10 and the third flow path 12th are connected to each other in such a way that the cooling water to the machine 2nd through the third flow path 12th returns to switch. For example, the switching valve switches 4th the flow path to the first state when the cooling water meets a predetermined temperature condition, and switches the flow path to the second state when the predetermined temperature condition is not met. The switching valve 4th can have a thermostatic valve, for example. An opening degree of the switching valve 4th can change according to a quantity of heat (cooling water temperature), which is also applied to a temperature-sensitive wax. In addition, the switching valve 4th have a configuration that can be switched to a valve opening degree that, in addition to the first state and the second state, enables a third state in which all three connected passages are open.

The fluid control valve 5 is on an upstream side of the heater core 6 in the second flow path 11 provided, and an opening degree of the fluid control valve 5 can be switched between two states: a closed state and an open state. If the fluid control valve 5 is in the closed state, the cooling water in the first state flows only through the first flow path 10 and in the second state flows only through the third flow path 12th without going through the second flow path 11 to pour. If the fluid control valve 5 is in the open state, the cooling water flows in the first state both through the first flow path 10 as well as the second flow path 11 . As described above, the second flow path lies 11 and the third flow path 12th parallel to the first flow path 10 .

The control 8th controls the fluid control valve 5 assuming a temperature of the cooling water by one in the machine 2nd provided coolant temperature sensor is detected. After the machine 2nd the switching valve remains 4th the first state when the cooling water temperature is lower than a first predetermined first temperature, and the controller 8th acts on the fluid control valve 5 with energy and controls it in the closed state. Because the cooling water is only through the first flow path 10 circulates, the machine is warmed up 2nd carried out.

When the cooling water temperature becomes equal to or higher than the first temperature, the machine will warm up 2nd ended, and the switching valve 4th switches from the first state to the second state. Thus, the cooling water circulates through the third flow path 12th and gives in the cooler 7 the heat free. When the heat of the cooling water is to be released further, energizing the fluid control valve 5 through the controller 8th interrupted, and the fluid control valve 5 is controlled to be in the open state. Thus the cooling water circulates 8th through the third flow path 12th and the second flow path 11 and also gives the heat in the heating core 6 free. If also in the first state the heater core 6 a heat release from the cooling water is required, the application of the fluid control valve 5 through the controller 8th be interrupted to the fluid control valve 5 to control in the open state.

Next is the fluid control valve 5 with respect to the 2nd to 6 described. The 2nd shows the state of the open valve and the 3rd shows the state of the closed valve. The fluid control valve 5 has a seat valve that has a valve seat 511 and a valve element 57 has a piston 55 which is a moving core and an electromagnetic solenoid 54 . The fluid control valve 5 is an electromagnetic valve having a configuration in which a pressure of a working fluid acts in an open valve direction in which the valve element 57 away from the valve seat 511 moved away. In the fluid control valve 5 is namely the direction of the closed valve of the valve element 57 set in one direction against the fluid pressure. The fluid control valve 5 opens or closes an inner passage 512 provided in a case according to a balance between that of the working fluid received fluid pressure and one by energizing the fluid control valve 5 magnetic force generated with energy.

The piston 55 has a cylindrical section 551 having openings at an opposite end in an axial direction. The piston 55 has an upstream annular section 550 that at one end of the cylindrical section 551 is provided that to the valve element 57 is directed, and a downstream annular portion 552 that is at the other end of the cylindrical section 551 is provided. The upstream annular section 550 has the same outer diameter as the cylindrical section 551 , and has an upstream opening 550a as one coaxial with the cylindrical section 551 through hole. A surface of the upstream annular portion 550 opposite to the valve element 57 touches a downstream end portion of a support member 58 and supports the support element 58 to be movable in the axial direction. The axial direction is also a direction of movement of the valve element 57 . As a result, the support member moves 58 together with the piston 55 in the axial direction. The downstream annular section 552 is a flange portion that has a larger outer diameter than the cylindrical portion 551 and is radial in a direction perpendicular to the tubular portion 551 scattered. The downstream annular section 552 has a downstream coaxial with the cylindrical portion 551 lying opening on an inner side of the downstream annular portion 552 on. A fluid passage 553 is inside the cylindrical section 551 provided. The fluid passage 553 uses the upstream opening 550a as a fluid inlet. The piston 55 is made of a material through which magnetism passes, for example a magnetic material.

The support element 58 is so with the valve element 57 added that it is integral with the valve element 57 is trained. The support element 58 has an upstream cylindrical section 582 , an upstream flat section 580 , which is integrally formed at an upstream end of the upstream cylindrical portion 582 is formed, and a downstream cylindrical portion 583 , which is integrally formed at a downstream end of the downstream cylindrical portion 582 is formed and smaller in diameter than the upstream cylindrical portion 582 is. The valve element 57 is at the upstream flat section 580 attached. The upstream cylindrical section 582 has a fluid passage 581 that extends in a radial direction through the upstream cylindrical portion 582 extends. The upstream cylindrical section 582 has at least one of the fluid passageway 581 on. An upstream side of the fluid passage 581 is with the inner passage 512 in communication, and a downstream side of the fluid passage 581 is with the fluid passage 553 through the upstream opening 550a in connection.

The downstream cylindrical section 583 is in an opening 560a inserted at an upstream first annular section 560 of a yoke 56 is provided such that the downstream cylindrical portion 583 is supported to be slidable in the axial direction. If a downstream end of the upstream cylindrical section 582 of the support element 58 the upstream first annular portion 560 touched in the open valve state is the support member 58 restricted to continue moving in the direction of the open valve. That is why the movement of the downstream cylindrical section 583 through the yoke 56 limited to be movable within a predetermined range in the axial direction and substantially unmovable in the radial direction. The support element 58 is made of a material through which magnetism is difficult to pass, such as a resin material. The support element 58 is configured not to form a magnetic circuit.

The valve element 57 is made of an elastically deformable material such as a rubber. The valve element 57 is in one piece on the support element 58 assembled in a state in which a downstream shaft in the axial direction into a through hole of the upstream flat portion 580 is fitted. The valve element 57 is positioned axially to the valve seat 511 to be directed to an inflow housing 51 is provided.

The fluid control valve 5 has a housing body that the inner passage 512 defined for the working fluid. The housing body has the inflow housing 51 that with an inlet connection 510 is provided, into which the working fluid flows, and an outflow housing 53 that with a delivery port 530 is provided, from which the working fluid flows out, and an intermediate housing 52 that the inflow housing 51 and the outlet housing 53 couples. A downstream side of the inflow housing 51 is in one piece with the intermediate housing 52 provided and takes the valve element 57 and most of the support elements 58 on. The inflow housing 51 has a valve seat in it 511 that around the inlet connection 510 is formed around, and on which the valve element moving in the closed valve direction 57 sits on. The valve seat is in the closed valve state 511 with the valve element 57 in contact to form an annular contact surface or line of contact therebetween.

An upstream side of the exhaust housing 53 is in one piece with the intermediate housing 52 coupled. An upstream end of the delivery port 530 is with the fluid passage 553 in connection. The inflow housing 51 , the intermediate housing 52 and the outlet housing 53 are formed of the resin material and are welded together.

The intermediate housing 52 has the yoke 56 , the piston 55 , a coil 540 , a reel 541 and a sliding support member 542 . The yoke 56 is made of a material through which magnetism passes, for example a magnetic material. The yoke 56 determines part of a magnetic circuit and supports the reel 541 and the sliding support member 542 inside the intermediate housing 52 . The yoke 56 covers the outer edge of the reel 541 and the coil 540 . The piston 55 , the sink 540 who have favourited Reel 541 , the sliding support element 542 , the support element 58 and the valve element 57 are coaxial.

The sliding support element 542 has a cylindrical body outside the reel 541 supports, and within an outer surface of the cylindrical portion 551 of the piston 55 supports such that the piston 55 is slidable in the axial direction. The sliding support element 542 is made of a non-magnetic material that makes magnetism difficult to pass through.

The electromagnetic solenoid 54 has the yoke 56 , the sink 540 who have favourited Reel 541 , the sliding support element 542 and a connector. The connector is on one side or outside the yoke 56 positioned. The connector is for loading the coil 540 provided with energy and has an internal connector that is electrically connected to the coil 540 connected is. In the electromagnetic solenoid, one can pass through the coil 540 continuous current can be controlled by electrically connecting the connection to, for example, a current control via the connector. The reel 541 is formed in a cylindrical shape from a resin material, and the coil 540 is around an outer peripheral surface of the reel 541 wrapped.

The yoke 56 is a cylindrical body that has openings at opposite ends in the axial direction. The yoke 56 has the upstream first annular section 560 that is at one end of the yoke 56 is provided that to the valve element 57 is directed, an inclined portion 561 , an upstream second section 562 that extends radially from a downstream end of the inclined portion 561 extends, and a downstream cylindrical portion 563 extending in the axial direction from an outer peripheral edge of the upstream second annular portion 562 extends.

The upstream first annular section 560 is capable of the upstream annular section 550 of the piston 55 Touching in the axial direction has a larger diameter than the upstream annular portion 550 and has an opening 560a than one with the upstream opening 550a of the piston 55 coaxial through hole. The upstream first annular section 560 and the upstream annular portion 550 are parallel portions to face each other in the axial direction and have sectional shapes extending along each other. In the following, the sectional shapes related to the inclined portion and the parallel portions mean vertical sectional shapes along the axial direction of the piston or the like. In the closed valve state in which the valve element 57 yourself with the valve seat 511 is in contact, there is a downstream surface 560b of the upstream first annular portion 560 by the valve element 57 is directed away, in contact with an upstream surface 550b of the upstream annular portion 550 that to the valve element 57 is directed. The downstream surface 560b and the upstream surface 550b are parallel portions to face each other in the axial direction and to extend along each other. Like from the 3rd and 5 can be seen is a second in the closed valve state path as a magnetic path through which a magnetic flux passes through a portion in which the upstream first annular portion 560 and the upstream annular portion 550 are in contact with each other.

The sloping section 561 is a cylindrical section that has an upstream end (that connects to the valve element 57 is directed), that with the upstream first annular portion 560 connected and a downstream end (that to the piston 55 is directed) that with the upstream second annular portion 562 connected is. The sloping section 561 has a sectional shape that is related to the cylindrical portion 551 of the piston 55 is inclined. The sloping section 561 is formed such that the upstream end (that to the valve element 750 is smaller in diameter than the downstream end (that facing the piston 55 is directed). That is why the inclined section 561 with respect to the cylindrical section 551 so inclined that the diameter is in the downstream direction (ie a direction towards the piston 55 towards) increases.

The upstream end of the inclined section 561 (that to the valve element 57 is larger in diameter than the cylindrical section 551 . Therefore, an upstream end portion of the cylindrical portion is 551 in particular, designed the inclined section 561 approximate when the condition of the open valve coming from the 2nd can be seen shifts to the closed valve state, which from the 3rd and 5 can be seen. At the beginning of the application, energy is in the open valve state as from the 2nd can be seen is a distance between the inclined portion 561 and the cylindrical section 551 the shortest between the pistons 55 and the yoke 56 on their upstream sides. Thus, when the valve is open, it has a magnetic one path who is a first path through which the magnetic flux flows between the inclined section 561 and the cylindrical section 551 passes through, a larger magnetic flux than the second described above path on. As described above, at the start of energization in the open valve state, the first is path a magnetic path in which the magnetic flux is greater than that of the second path. In the closed valve state, the second forms path a magnetic path in which the magnetic flux is greater than that of the first path.

The upstream second annular section 562 is a flange portion that has a larger outer diameter than the downstream end of the inclined portion 561 and is radial in a direction perpendicular to the downstream cylindrical portion 563 spreads. The upstream second annular section 562 lies in cross section parallel to the upstream first annular section 560 . An inner peripheral surface of the downstream cylindrical section 563 is positioned to an outer peripheral edge of the downstream annular portion 552 to be in the axial direction in the closed valve state and the open valve state. At the time of energizing, it becomes magnetic path through which a magnetic flux flows between the downstream cylindrical portion 563 and the outer peripheral edge of the downstream annular portion 552 goes through.

As from the 6 can be seen, the attraction for tightening the piston 55 during the open valve state, the closed valve state shifts in the first path larger than in the second path , and then a reverse phenomenon occurs just before the valve is closed. In the closed valve state, the attractive force is in the second path larger than in the first path . As from the 4th it can be seen that in the open valve state at the time of power down there is a magnetic one path provided, in which the first drawn by the continuous part path over the second indicated by the dashed part path becomes dominant. This is because between the piston 55 and the yoke 56 the distance between the inclined section 561 and the cylindrical section 551 is shortest where the magnetic resistance is the smallest and the magnetic flux is the greatest. Thus is in the fluid control valve 5 because of the distinctive diagram of the 6 the attraction that the piston 55 attracts in the first path larger than in the second path in the open valve state where a stroke is large. Because the fluid control valve 5 incorporates such a configuration in which the attraction of the piston 55 through the first path starts, therefore the piston 55 be attracted against the fluid pressure on the valve element 57 works while improving attraction at the start of energizing.

If the condition of the open valve coming from the 4th can be seen, is shifted to the closed valve state, and that from the 5 apparent state is closed valve, a reverse phenomenon occurs in which the second path about the first path becomes dominant. This is because the upstream annular section 550 and the upstream first annular portion 560 that form the parallel portions, come into contact with each other, or between the piston 55 and the yoke 56 closest to each other. Thus, between the upstream annular section 550 and the upstream first annular portion 560 the smallest magnetic resistance and the greatest magnetic flux. In the fluid control valve 5 will, as in the characteristic diagram of the 6 that the piston 55 attractive attraction in the second path larger than in the first path just before the closed valve state where the stroke is small. Because the fluid control valve 5 assumes such a configuration in which the valve element 57 through the second path to the valve seat 511 the valve element can be tightened and ensured that it touches it 57 therefore be concluded against the fluid pressure on the valve element 57 acts, thereby improving the attraction holding force at the time of closing the valve. As described above, the fluid control valve 5 an electromagnetic valve ready, the advantageous characteristic with respect to the attractive forces of both the first path like the second one path has that in the 6 are shown.

Next, through the fluid control valve 5 effects provided in the first embodiment. The fluid control valve 5 has the valve element 57 that the inner passage 512 opens and closes, which is to be switched between the open valve state and the closed valve state. The pressure of the working fluid acts on the valve element 57 in the valve opening direction. The fluid control valve 5 has the first path who is a magnetic path is through which the magnetic flux flows between the pistons 55 and the yoke 56 goes through, and the second path who is a magnetic path is through which the magnetic flux flows between the pistons 55 and the yoke 56 on one of the first path goes through different positions. At the start of energization in the open valve state, a magnetic becomes path trained in which the magnetic flux in the first path larger than in the second path is. In the closed valve state, a magnetic one path trained in which the magnetic flux in the second path larger than in the first path is.

When the energization is started in the open valve state, according to the fluid control valve 5 the attraction of the piston 55 against the fluid pressure and the use of the driving force generated by the magnetic flux generated by the first path passes through, which has a greater magnetic flux than the second path , be started. If also the valve element 57 from the open valve state to the closed valve state, the piston can 55 to the yoke in such a manner that they are in contact with the yoke in such a way that the closed valve state is maintained using the driving force generated by the flow generated by the second path that has a larger magnetic flux than the first path having. Thus, the first one path as a magnetic path dominant when energy is started in the open valve state. Thus, the force of attraction that the piston 55 to the valve seat 511 attracts, are exerted, and a driving force for moving the valve element 57 in the valve closing direction against the pressure of the working fluid can be obtained. Accordingly, the closed valve state can be obtained while the fluid pressure is on the valve element 57 works. The fluid control valve 5 can be provided by having no time to energize.

In the closed valve state, the second path as a magnetic path dominant, so the pull to keep the valve element 57 in contact with the valve seat 511 can be exercised to the inner passage 512 cordon off. According to the effects, both closing the valve from the open valve state and maintaining the closed state can be performed without depending on an urging force of a spring or the like. Thus, an increase in size due to the addition of the spring or the improvement in the urging force can be reduced. Accordingly, the fluid control valve 5 can be provided which is capable of reducing its size and improving valve closing performance at the time of closing the valve against the pressure of the working fluid.

The first path is a magnetic path in which the magnetic flux between the inclined section 561 which is a part of a from the piston 55 and the yoke 56 and has a cross section that is related to the other from the piston 55 and the yoke 56 is inclined, and the other from the piston 55 and the yoke 56 goes through. The second path is a magnetic path in which the magnetic flux flows through the parallel sections of the piston 55 and the yoke 56 passes through, which are directed towards each other in the axial direction and have sectional shapes which extend along one another. The parallel sections consist of the upstream annular section 550 of the piston 55 and the upstream first annular portion 560 of the yoke 56 .

Because according to this configuration the piston 55 and the yoke 56 with the inclined section 561 are provided, which are inclined with respect to each other, the first path be formed at the start of energizing in the open valve state. The first path is larger than the second in its magnetic flux path passing through the parallel sections of the piston 55 and the yoke 56 goes through. In addition, in the process in which the valve element 57 shifts from the open valve state to the closed valve state, the parallel portions trained, and the first path can go to the second path can be switched in the area of overlap or contact between the piston 55 and the yoke 56 is large and the magnetic flux is large. In this way, the shapes of the piston 55 and the yoke 56 dedicated to provide the magnetic paths, and thus the fluid control valve 5 is provided that is capable of performing valve closing operation from the valve open state and maintaining the valve closed state without being dependent on an urging force of a spring.

According to the fluid control valve 5 has the piston 55 the cylindrical section 551 , which extends in the axial direction, and the yoke 56 has the sloping section 561 which has a cross-sectional shape that is related to the cylindrical portion 551 is inclined. The parallel sections have the upstream annular section 550 , the upstream of the cylindrical section 551 of the piston 55 is provided lying in the flow of the working fluid, and the upstream first annular portion 560 , the upstream of the inclined section 561 of the yoke 56 is provided lying in the flow of the working fluid. Accordingly, the inclined section 561 in the yoke 56 provided with respect to the cylindrical portion 551 of the piston 55 is inclined. Thus, the inner diameter of the cylindrical section 551 increase. For this reason, the fluid control valve can be provided if the configuration is adopted in which the fluid passage 553 within the cylindrical section 551 is provided in which a flow resistance of the working fluid can be reduced while improving the performance of closing the valve against the pressure of the working fluid and the performance of maintaining the valve closed.

The fluid control valve 5 has the fluid passage 553 through which the working fluid inside the piston 55 flows. According to this configuration, in the fluid control valve 5 the piston 55 heat generated due to the lowering of its energy is dissipated by the working fluid.

The fluid control valve 5 has the fluid passage 553 through which the working fluid inside the piston 55 and inside the coil 540 flows. According to this configuration, in the fluid control valve 5 the piston 55 and the coil 540 due to their reduction in energy generated heat are dissipated by the working fluid.

The second path is formed at a position where the piston 55 and the yoke 56 come into contact with each other in the closed valve state. Because the fluid control valve 5 with the second path is provided at a portion where the piston 55 and the yoke 56 are in contact with each other, therefore, an attractive force can be provided that the valve element 57 against that on the valve element 57 acting fluid pressure closes. Thus, the attraction holding force at the time of closing the valve can be improved.

Because the fluid control valve 5 through the piston 55 and the yoke 56 forms a magnetic circuit carries the fluid control valve 15 contribute to a reduction in the number of components of the device and can also reduce an air gap in the magnetic circuit.

The fluid control valve 5 can be controlled to a maximum voltage at the start of energization in the open valve state (ie, the beginning of the attraction), and can be controlled to a voltage lower than that at the start of the attraction in the closed valve state is controlled (ie at the time of the holding attraction). If this control is accepted, the fluid control valve can 5 even get the start of attraction and keeping the attraction if the voltage for energizing is reduced because the fluid control valve 5 the first path and the second path described above.

(Second embodiment)

A second embodiment is described with reference to FIG 7 and 8th described. A fluid control valve 5 the second embodiment differs from the first embodiment in the shape of a yoke 156 and the shape of a piston 155 . Configurations, operations, and effects not specifically described in the second embodiment are the same as those in the first embodiment, and only points different from the first embodiment are described below. The 7 and 8th do not show components other than the piston, yoke and spool for easy understanding.

The yoke 156 has an upstream first annular section 560 , an upstream cylindrical section 1561 , an upstream second annular section 562 that extends radially from a downstream end of the upstream cylindrical portion 1561 extends, and a downstream cylindrical portion 563 extending in the axial direction from an outer peripheral edge of the upstream second annular section 562 extends. The yoke 156 namely, does not have an inclined portion that is inclined with respect to the axial direction. The upstream cylindrical section 1561 is a cylindrical section that has an upstream end (that connects to the valve element 57 is directed), that with the upstream first annular portion 560 connected and a downstream end (that to the piston 55 is directed), the upstream second annular portion 562 is connected.

The piston 155 has an upstream annular section 550 , an inclined section 555 which is inclined with respect to the axial direction, a cylindrical portion 551 and a downstream annular portion 552 . The sloping section 555 is a cylindrical section that has an upstream end (which becomes a valve element 57 is directed) that with the upstream annular portion 550 connected and a downstream end (that to the piston 55 is directed) that with the cylindrical portion 551 is connected. The sloping section 555 has a sectional shape that is related to the upstream cylindrical portion 1561 of the yoke 156 is inclined. The sloping section 555 is designed such that an upstream end (which forms a valve element 57 directed) has a smaller diameter than a downstream end. That is why the inclined section 555 with respect to the upstream cylindrical section 1561 inclined so that the diameter increases in a downstream direction.

The upstream end of the inclined section 555 (that to the valve element 57 ) has an outer diameter that is smaller than an inner diameter of the upstream cylindrical portion 1561 is. The upstream cylindrical section is corresponding 1561 positioned such that a distance to the inclined portion 555 gradually with a movement from the open valve condition in the 7 is shown reduced to the closed valve condition shown in the 8th is shown.

At the beginning of the energization in the state of the open valve coming from the 7 can be seen is a distance between the inclined portion 555 and the upstream cylindrical portion 1561 between the piston 155 and the yoke 156 shortest on their upstream sides. Thus, when the valve is open, it has a magnetic one path who is a first path through which the magnetic flux flows between the inclined section 555 and the upstream section 1561 passes through, a larger magnetic flux than the second described above path on. As described above, the first is path a magnetic one at the start of energizing in the open valve state path in which the magnetic flux is greater than that of the second path. In the closed valve state, the second forms path a magnetic path in which the magnetic flux is greater than that of the first path. The upstream second annular section 562 is a flange portion that has a larger outer diameter than the downstream end of the upstream cylindrical portion 1561 and is radial in a direction perpendicular to the downstream cylindrical portion 563 spreads.

Also in the fluid control valve 5 the second embodiment, as from the 7 it can be seen in the open valve state at the time of energizing a magnetic one path provided, in which the first indicated by the solid arrow path dominant over the second indicated by the dashed arrow path becomes. This is because between the piston 155 and the yoke 156 the distance between the inclined section 555 and the upstream cylindrical portion 1561 is shortest where the magnetic resistance is the smallest and the magnetic flux is the greatest. Thus is in the fluid control valve 5 , as in the characteristic diagram of the 6 that was described above, the piston 155 attractive force in the open valve state in the first path larger than in the second path . That's why the piston 155 because the fluid control valve 5 assumes such a configuration in which the attraction of the piston 155 through the first path starts against the on the valve element 57 acting fluid pressure, thereby improving the attraction performance at the start of energizing.

If the in the 7 shown state of the open valve shifts to the closed valve state, and that in the 8th shown closed valve state, a reverse phenomenon occurs in which the second path about the first path becomes dominant. This is because the upstream annular section 550 and the upstream first annular portion 560 that form the parallel portions, come into contact with each other, or between the piston 155 and the yoke 156 closest to each other. Similar to the first embodiment, the fluid control valve 5 In the second embodiment, an electromagnetic valve is prepared that has advantageous properties the attractions of both the first path like the second one path provides how from the 6 can be seen.

According to the second embodiment, the first is path a magnetic path in which the magnetic flux between the inclined section 555 that is part of one from the piston 155 and the yoke 156 and has a cross section that is related to the other from the piston 155 and the yoke 156 is inclined, and the other from the piston 155 and the yoke 156 goes through. The second path is a magnetic path in which the magnetic flux flows through the parallel sections of the piston 155 and the yoke 156 passes through, which are directed towards each other in the axial direction and have sectional shapes which extend along one another. The parallel sections consist of the upstream annular section 550 of the piston 155 and the upstream first annular portion 560 of the yoke 156 .

Because the piston 155 and the yoke 156 with the inclined section 555 provided that is inclined with respect to the other, according to this configuration, the first one path be formed at the start of energizing in the open valve state. The first path has a larger magnetic flux than the second path on by the parallel sections of the piston 155 and the yoke 156 goes through.

According to the second embodiment, the yoke 156 the upstream cylindrical section 1561 which extends in the axial direction and the piston 155 has the sloping section 555 which has a cross-sectional shape that is related to the upstream cylindrical portion 1561 is inclined. The parallel sections have the upstream first annular section 560 , the upstream of the upstream cylindrical portion 1561 of the yoke 156 is provided lying in the flow of the working fluid, and the upstream annular portion 550 , the upstream of the inclined section 555 of the piston 155 is provided lying in the flow of the working fluid.

Accordingly, the inclined section 555 that with respect to the upstream cylindrical section 1561 of the yoke 156 is inclined in the piston 155 provided. Thus, an inner diameter of a portion of the piston 155 be increased, the downstream of the inclined portion 555 is positioned horizontally. For this reason, if the configuration is adopted in which the fluid passage within the piston 155 is provided, the fluid control valve 5 can be provided in which a flow resistance of the working fluid can be reduced while the performance for closing the valve against the pressure of the working fluid and the performance for maintaining the closed valve state are improved.

(Third embodiment)

A third embodiment is described with reference to FIG 9 and 10 described. A fluid control valve 5 the third embodiment is different from the first embodiment in that the fluid control valve 5 the piston 155 Has. Configurations, actions, and effects not specifically described in the third embodiment are similar to those of each of the above-described embodiments, and only differences from the first embodiment and the second embodiment are described below. The 9 and 10 do not show components other than the piston, the yoke and the coil for the purpose of easy understanding.

Like from the 9 and 10 can be seen, the fluid control valve 5 the third embodiment obtained by the piston 55 the first embodiment with a piston accommodated in the second embodiment 155 is exchanged.

To begin energizing in an open valve state, such as from the 9 can be seen is a distance between an inclined section 555 and an inclined section 561 that are inclined with respect to the axial direction between a piston 155 and the yoke 56 shortest on their upstream sides. The sloping section 555 and the inclined section 561 form parallel sections that have a cross-sectional shape that extend along each other. Thus, when the valve is open, it has a magnetic one path who is a first path through which the magnetic flux flows between the inclined section 555 and the inclined section 561 passes through, a larger magnetic flux than that of the second path described above. When energization is started in the open valve state, it becomes magnetic path trained such that the first path in its magnetic flux larger than the second path is. In the closed valve state, a magnetic one path formed such that the second path larger than the first in its magnetic flux path is.

Also in the fluid control valve 5 the third embodiment, as from the 9 it can be seen in the open valve state at the time of energizing a magnetic one path provided in which the first path , which is indicated by the solid arrow, becomes dominant over the second arrow, which is indicated by the dashed arrow. This is because between the piston 155 and the yoke 56 the distance between the inclined section 555 and the inclined section 561 is shortest where the magnetic resistance is the smallest and the magnetic flux is the greatest. Thus is in the fluid control valve 5 of the third embodiment, as in the characteristic diagram of FIG 6 that the piston 155 attractive force in the open valve state in the first path larger than in the second path . Because the fluid control valve 5 the third embodiment adopts such a configuration in which the attraction of the piston 155 through the first path starts, therefore the piston 155 against that on the valve element 57 acting fluid pressure, thereby improving the attraction performance at the start of energizing.

If the condition of the open valve coming from the 9 can be seen shifts to the closed valve state and becomes the closed valve state resulting from the 10 it can be seen that a reverse phenomenon occurs in which the second path dominant over the first path becomes. This is because the upstream annular section 550 and the upstream first annular portion 560 which form the parallel sections, come into contact with one another or are closest to one another. Similar to the first embodiment, the fluid control valve 5 In the third embodiment, an electromagnetic valve is ready, which is advantageous in terms of the attractive forces of both the first path like the second one path has, as in the 6 is shown.

According to the fluid control valve 5 the third embodiment is the first path a magnetic path in which the magnetic flux flows through the parallel sections of the piston 155 and the yoke 56 passes through, which are inclined with respect to the axial direction and have sectional shapes which extend along each other. These parallel sections are through the inclined section 555 and the inclined section 561 provided. The second path is a magnetic path in which the magnetic flux flows through the parallel sections of the piston 155 and the yoke 56 passes through, which are directed towards each other in the axial direction and have sectional shapes which extend along one another. The parallel sections are from the upstream annular section 550 and the upstream first annular portion 560 educated.

Because the piston 155 and the yoke 56 accordingly with the inclined sections 555 and 561 provided that are inclined with respect to the axial direction may be the first according to this configuration path whose magnetic flux is larger than that of the second path are formed at the start of energization in the open valve state. In addition, the parallel sections are in the piston 155 and the yoke 56 facing each other in the axial direction in the process in which the valve element 57 shifts from the open valve state to the closed valve state. So the first one path to the second path can be switched in the area of overlap or the area of contact between the piston 55 and the yoke 56 is large, and the magnetic flux is large. In this way, the shapes of the piston 155 and the yoke 56 dedicated to provide the magnetic paths, and thus the fluid control valve 5 can be provided which is capable of performing the valve closing operation from the open valve state and maintaining the closed valve state without being dependent on an urging force of a spring.

Fourth Embodiment

A fourth embodiment is described with reference to FIG 11 and 12th described. A fluid control valve 5 the fourth embodiment is different from the fluid control valve 5 the second embodiment that the fluid control valve 5 the piston 255 and the yoke 256 Has. Configurations, actions, and effects not specifically described in the fourth embodiment are similar to those of each of the above-described embodiments, and only differences from the first embodiment and the second embodiment are described below. The 11 and 12th show no components other than the piston, yoke and spool for easy understanding.

Like from the 11 and 12th can be seen, has the fluid control valve 5 a first according to the fourth embodiment path and a second path between the pistons 255 and the yoke 256 at one end as well as at another end of the fluid control valve 5 go through in an axial direction. The piston 255 and the yoke 256 point at one end in the axial direction leading to the valve element 57 is directed (downstream side) the first path and the second path that are similar to those of the fluid control valve 5 of the second embodiment. Thus, the fluid control valve has 5 the fourth embodiment on several second paths.

The piston 255 has an inclined section 556 which is inclined such that a surface of an outer peripheral edge of a downstream annular portion 552 rises in a downstream direction. The yoke 256 has an inclined section 565 which is provided at the other end in the axial direction, that is, an end on a downstream side and which has a sectional shape inclined with respect to the axial direction, and a downstream annular portion 564 connects the inclined section 565 and a downstream cylindrical section 563 . The downstream annular section 564 extends from a downstream end portion of the downstream cylindrical portion 563 in a radial direction, and an outer peripheral side of the downstream annular portion 564 is with the sloping section 565 integrally formed. The downstream annular section 564 and the downstream annular portion 552 form parallel sections that extend along each other. The sloping section 565 has a sectional shape that is related to the downstream annular portion 552 is inclined. The sloping section 565 and the inclined section 556 form parallel portions that have a cross-sectional shape that are along each other in the piston 255 or the yoke 256 extend. In the closed valve state in which the valve element 57 with the valve seat 511 is in contact, there is an upstream surface 552b of the downstream annular section 552 leading to the valve element 57 is directed with a downstream surface 564b of the downstream annular section 564 by the valve element 57 is directed away, in touch. The downstream surface 564b and the upstream surface 552b are parallel portions to face each other in the axial direction and to extend along each other.

As from the 11 it can be seen when the valve is open and energized, the magnetic flux passes through the first path between the inclined section 565 and the downstream annular portion 552 through while the magnetic flux through the second path between the downstream annular section 564 and the downstream annular portion 552 at the downstream end of the piston 255 and the yoke 256 goes through. At the upstream ends of the piston 255 and the yoke 256 are the first path and the second path similar to that of the second embodiment. In the open valve state, there is a distance between the inclined portion 565 and the downstream annular portion 552 between the piston 255 and the yoke 256 shortest on its downstream side.

If the one from the 11 apparent state open valve is moved to the state closed valve and that in the 12th shown closed valve state, a reverse phenomenon occurs in which the second path about the first path becomes dominant. This is because the downstream annular section 552 and the downstream annular portion 564 that form the parallel portions, come into contact with each other, or between the piston 255 and the yoke 256 closest to each other in their downstream parts. In the downstream parts of the piston 55 and the yoke 56 is a section between the downstream annular section 552 and the downstream annular portion 564 smallest in magnetic resistance and greatest in magnetic flux. In the fluid control valve 5 the fourth embodiment is even on the downstream sides, as in the characteristic diagram of FIG 6 that the piston 255 attractive attraction in the second path larger than in the first path just before the valve closed state where a stroke is small. Because the fluid control valve 5 has such a configuration on the downstream side where the valve element 57 on the valve seat 511 through the second path the valve element can be tightened and ensured that it touches it 57 against that on the valve element 57 acting fluid pressure can be closed, thereby improving the attraction holding force at the time of closing the valve.

The first path and the second path in the fluid control valve 5 the fourth embodiment are between the pistons 255 and the yoke 256 arranged and provided at both the one end, which is the upstream side in the flow of the working fluid, and the other end, which is the downstream side in the flow of the working fluid. According to the fourth embodiment, an electromagnetic valve can be provided on both the upstream and the downstream sides, which has advantageous properties with respect to the attractive forces of both the first path like the second one path has, as from the 6 can be seen.

In the fluid control valve 5 the fourth embodiment is the second path set at several positions. At least one of the second paths set in the plurality of positions can be formed in a part in which the piston 255 and the yoke 256 are in contact with each other when the valve is closed. Because at least one of the plurality of second paths is provided on the part where the piston 255 and the yoke 256 are in contact with each other, the attractive force that is able to provide the valve element can be provided 57 against that on the valve element 57 to close acting fluid pressure, and the attraction holding force in the closed valve state can be increased.

(Fifth embodiment)

A fifth embodiment is described with reference to FIG 13 and 14 described. A fluid control valve 5 the fifth embodiment is different from the fluid control valve 5 the second embodiment that the fluid control valve 5 the piston 355 and the yoke 356 Has. Configurations, actions, and effects not specifically described in the fifth embodiment are similar to those of each of the above-described embodiments, and only differences from the first embodiment and the second embodiment are described below. The 13 and 14 show no components other than the piston, the yoke and the spool for the purpose of easy understanding.

Like from the 13 and 14 can be seen, has the fluid control valve 5 according to the fifth embodiment, a first one path and a second path leading to the piston 355 and the yoke 356 at both ends of the fluid control valve 5 go through in an axial direction. The piston 355 and the yoke 356 assign the first path and the second path that are similar to those of the fluid control valve 5 of the second embodiment are, at one end in the axial direction, toward the valve element 57 is directed (upstream side).

The piston 355 has a cylindrical portion located at a downstream end 57 that is provided at the other end in the axial direction, which is an end on a downstream side, and has a cross-sectional shape that is downstream from an outer peripheral edge of the downstream annular portion 552 extends. The cylindrical section located at the downstream end 557 is inclined with respect to the axial direction, the cylindrical section 551 or the downstream annular section 552 such that a diameter of the cylindrical portion located at the downstream end 557 increases in a downstream direction. The yoke 356 has a cylindrical portion at a downstream end 556 that is provided at the other end in the axial direction, which is an end on a downstream side, and has a cross-sectional shape that is inclined with respect to the axial direction. The cylindrical section located at the downstream end 556 extends from a downstream end of the cylindrical portion located at a downstream end 563 further downstream and has a shape that is related to the downstream annular portion 552 or the downstream cylindrical section 563 is inclined such that a diameter of the cylindrical portion located at a downstream end 566 increases in the downstream direction. The cylindrical section located at the downstream end 566 and the cylindrical portion at the downstream end 557 form parallel sections that have cross-sectional shapes that are along each other in the piston 355 or the yoke 356 extend. The cylindrical section located at the downstream end 566 is positioned such that an inner edge surface 566b of the cylindrical portion located at the downstream end 566 to an inner edge surface 557b of the cylindrical portion located at the downstream end 557 is directed in the closed valve state where the valve element 57 with the valve seat 511 is in contact. The inner edge surface 566b and the inner edge surface 557b form parallel portions that are directed toward each other in the axial direction and extend along each other.

As from the 13 it can be seen that the magnetic flux passes through the first path between the cylindrical portion at the downstream end 566 and the downstream annular portion 552 and at the downstream end of the piston 355 and the yoke 356 when the valve is open and energized. At the upstream ends of the piston 355 and the yoke 356 are the first path and the second path similar to that of the second embodiment. In the valve open state, there is a distance between the cylindrical portion located at the downstream end 566 and the downstream annular portion 552 between the piston 355 and the yoke 356 shortest in their downstream sides.

If the condition of the open valve coming from the 13 As can be seen, when the valve shifts to the closed valve state and becomes the closed valve state, a reverse phenomenon occurs in which the second path dominant over the first path becomes. This is the case because of the the downstream end cylindrical portion 566 and the cylindrical portion located at the downstream end 557 , which forms the parallel sections, are directed towards each other and between the piston 355 and the yoke 356 come closest to each other in their downstream sides. Between the cylindrical portion at the downstream end 566 and the cylindrical portion at the downstream end 557 the magnetic resistance is the smallest and the magnetic flux is the greatest on the downstream side. In the fluid control valve 5 the fifth embodiment is even on the downstream sides as in the characteristic diagram of FIG 6 the the piston 355 attractive force just before the closed valve state, in which one stroke is small, in the second path is larger than in the first path . Because the fluid control valve 5 has such a configuration on the downstream side where the valve element 57 through the second path is tightened and it is ensured that it is the valve seat 511 touched, the valve element 57 against that on the valve element 57 acting fluid pressure can be closed, thereby improving the attraction holding force at the time of closing the valve. In the from the 14 Visible state closed valve show the inner edge surface 566b of the cylindrical portion at the downstream end 566 and the inner edge surface 557b of the cylindrical portion located at the downstream end 557 a positional relationship to be directed towards each other. The first path is between the cylindrical portion at the downstream end 566 and the cylindrical portion at the downstream end 557 educated.

The first path and the second path in the fluid control valve 5 the fifth embodiment are between the pistons 355 and the yoke 356 and provided at both the one end that is the upstream side in the flow of the working fluid and the other end that is the downstream side in the flow of the working fluid. According to the fifth embodiment, an electromagnetic valve can be provided on both the upstream and downstream sides, which has excellent characteristics with respect to the attractive forces of both the first path like the second one path has, as in the 6 is shown.

(Sixth embodiment)

A sixth embodiment is described with reference to FIG 15 and 16 described. A fluid control valve 5 the sixth embodiment is different from the fluid control valve 5 the second embodiment in that the fluid control valve 5 the piston 255 and the yoke 456 Has. Configurations, actions, and effects not specifically described in the sixth embodiment are the same as those of each of the above-described embodiments, and only differences from the first embodiment, the second embodiment, and the fourth embodiment are described below. The 15 and 16 show no components other than the piston, the yoke and the spool for the purpose of easy understanding.

Like from the 15 and 16 can be seen, has the fluid control valve 5 according to the sixth embodiment, a first one path and a second path between the pistons 255 and the yoke 456 at both ends of the fluid control valve 5 go through in an axial direction. The piston 255 and the yoke 456 assign a first path and a second path that are similar to those of the fluid control valve 5 of the second embodiment are, at one end in the axial direction, towards the valve element 57 is directed (upstream side). Thus, the fluid control valve has 5 the sixth embodiment has a plurality of second paths.

The configuration of the piston 255 is the same as the descriptions in the fourth embodiment. The yoke 456 has a cylindrical portion located at a downstream end 567 that is provided at another end in the axial direction, that is, an end on a downstream side, and has a sectional shape that extends in the axial direction, and a downstream annular portion 564 connects the cylindrical portion located at the downstream end 567 and a downstream cylindrical section 563 . The annular portion located at the downstream end 564 extends in a radial direction from a downstream end portion of the downstream cylindrical portion 563 , and an outer peripheral side of the downstream annular portion 564 is with the cylindrical portion at the downstream end 567 integrated. The sloping section 556 has a sectional shape that is related to the cylindrical portion located at the downstream end 567 is inclined.

As from the 15 it can be seen that the magnetic flux passes through the first path between the downstream annular section 552 and the cylindrical portion at the downstream end 567 at the downstream end of the piston 255 and the Yokes 456 through when the valve is open and energized. At the upstream ends of the piston 255 and the yoke 456 are the first path and the second path similar to that of the second embodiment. In the valve open state, there is a distance between the downstream annular portion 552 and the cylindrical portion at the downstream end 567 between the piston 255 and the yoke 456 shortest in their downstream sides.

If the condition of the open valve coming from the 15 can be seen shifts to the closed valve state and becomes the closed valve state resulting from the 16 it can be seen that a reverse phenomenon occurs in which the second path dominant over the first path becomes. This is because the downstream annular section 552 and the downstream annular portion 564 that form the parallel portions, come into contact with each other, or between the piston 255 and the yoke 456 closest to each other in their downstream parts. In the downstream parts of the piston 55 and the yoke 56 is a section between the downstream annular section 552 and the downstream annular portion 564 smallest in its magnetic resistance and greatest in its magnetic flux. The first path which is smaller than the second in its magnetic flux path is between the inclined section 556 and the cylindrical portion at the downstream end 567 educated.

In the fluid control valve 5 the sixth embodiment is even on the downstream sides as in the characteristic diagram of FIG 6 the the piston 255 attractive force just before the closed valve state where one stroke is small in the second path larger than in the first path . Because the fluid control valve 5 has such a configuration on the downstream side where the valve element 57 through the second path to the valve seat 511 the valve element can be tightened and ensured that it touches it 57 against that on the valve element 57 acting fluid pressure can be closed, thereby improving the attraction holding force at the time of closing the valve.

The first path and the second path in the fluid control valve 5 the sixth embodiment are between the pistons 255 and the yoke 456 and provided at both the one end that is the upstream side in the flow of the working fluid and the other end that is the downstream side in the flow of the working fluid. According to the sixth embodiment, an electromagnetic valve can be provided on both the upstream and the downstream side, which has advantageous properties with respect to the attractive forces of both the first path like the second one path has, as in the 6 is shown.

In the fluid control valve 5 the sixth embodiment is the second path set at several positions. At least one of the second paths set in the plurality of positions may be formed in a part where the piston 255 and the yoke 456 are in contact with each other when the valve is closed. Because at least one of the plurality of second paths is provided on the part where the piston 255 and the yoke 456 are in contact with each other, the attractive force that is able to provide the valve element can be provided 57 against that on the valve element 57 to close acting fluid pressure, and the attraction holding force in the closed valve state can be increased.

(Seventh embodiment)

A seventh embodiment is described with reference to FIG 17th and 18th described. A fluid control valve 5 the seventh embodiment is different from the fluid control valve 5 the second embodiment, which is the fluid control valve 5 the piston 355 of the fifth embodiment. Configurations, actions, and effects not specifically described in the seventh embodiment are the same as those of each of the above-described embodiments, and only differences from the first embodiment, the second embodiment, and the fifth embodiment are described below. The 17th and 18th show no components other than the piston, the yoke and the spool for the purpose of easy understanding.

Like from the 17th and 18th can be seen, forms the fluid control valve 5 the seventh embodiment by the piston 355 the fifth embodiment and the yoke 156 the second embodiment a magnetic path out. The fluid control valve 5 according to the seventh embodiment has a first path between the pistons 355 and the yoke 156 at both ends of the fluid control valve 5 passes in an axial direction. The piston 355 and the yoke 156 points the first path and the second path that are similar to those of the fluid control valve 5 the second embodiment, at one end in the axial direction, toward the valve element 57 is directed (upstream side). The configuration of the piston 355 is the same as the descriptions in the fifth embodiment. The configuration of the yoke 156 is the same as descriptions in the second embodiment. A cylindrical section located at a downstream end 557 has a sectional shape that is related to a downstream cylindrical portion 563 of the yoke 156 is inclined, and forms an inclined portion.

As from the 17th it can be seen that the magnetic flux passes through the first path between the downstream cylindrical section 563 and the cylindrical portion at the downstream end 557 at the downstream end of the piston 355 and the yoke 156 through when the valve is open and energized. At the upstream ends of the piston 355 and the yoke 156 are the first path and the second path similar to that of the second embodiment. In the open valve state, there is a distance between the downstream cylindrical portion 563 and the cylindrical portion at the downstream end 557 between the piston 355 and the yoke 156 shortest in its downstream side.

If the one from the 17th apparent state open valve changes to a closed state and in the out of the 18th apparent closed state, the distance between the downstream cylindrical portion decreases 563 and the cylindrical portion at the downstream end 557 further. Therefore, that between the downstream cylindrical section 563 and the cylindrical portion at the downstream end 557 continuous magnetic flux in the valve closed state is greater than in the valve open state. Between the downstream cylindrical section 563 and the cylindrical portion at the downstream end 557 the magnetic resistance is the smallest and the magnetic flux is the greatest on the downstream side.

(Eighth embodiment)

An eighth embodiment is described with reference to FIG 19th and 20 described. A fluid control valve 5 the eighth embodiment is different from the fluid control valve 5 the second embodiment that the fluid control valve 5 the yoke 456 the sixth embodiment. Configurations, actions, and effects not specifically described in the eighth embodiment are the same as those of each of the above-described embodiments, and only differences from the first embodiment, the second embodiment, and the sixth embodiment are described below. The 19th and 20 show no components other than the piston, the yoke and the spool for the purpose of easy understanding.

Like from the 19th and 20 can be seen, has the fluid control valve 5 a first according to the eighth embodiment path and a second path between the pistons 155 and the yoke 456 at one end as well as at another end of the fluid control valve 5 go through in an axial direction. The piston 155 and the yoke 456 assign a first path and a second path that are similar to those of the fluid control valve 5 of the second embodiment are, at one end in the axial direction, towards the valve element 57 is directed (upstream side). The configuration of the piston 155 is the same as the descriptions of the second embodiment, and the configuration of the yoke 456 is the same as the descriptions of the sixth embodiment

As from the 19th it can be seen when the valve is open and energized, the magnetic flux passes through the first path between the downstream annular section 552 and the cylindrical portion at the downstream end 567 at the downstream end of the piston 155 and the yoke 456 by. In the valve open state, there is a distance between the downstream annular portion 552 and the cylindrical portion at the downstream end 567 between the piston 155 and the yoke 456 shortest in their downstream sides. At the upstream ends of the piston 155 and the yoke 456 are the first path and the second path similar to that of the second embodiment.

If the condition of the open valve coming from the 19th can be seen, shifts to the closed valve state and the closed valve state becomes, as from the 20 is evident, a reverse phenomenon occurs in which the second path dominant over the first path becomes. This is because the downstream annular section 552 and the downstream annular portion 564 that form the parallel portions, come into contact with each other, or closest to each other between the piston 255 and the yoke 456 in their downstream parts. In the downstream part of the piston 55 and the yoke 56 is a section between the downstream annular section 552 and the downstream annular portion 564 in lowest in magnetic resistance and greatest in magnetic flux.

In the fluid control valve 5 the eighth embodiment is even on the downstream sides as in the characteristic diagram of FIG 6 the the piston 155 attractive force just before the closed valve state where one stroke is small in the second path larger than in the first path . Because the fluid control valve 5 the eighth embodiment has such a configuration on the downstream side where the valve member 57 through the second path to the valve seat 511 the valve element can be tightened and ensured that it touches it 57 against that on the valve element 57 acting fluid pressure can be closed, thereby improving the attraction holding force at the time of closing the valve.

The first path and the second path in the fluid control valve 5 the eighth embodiment are between the pistons 155 and the yoke 456 and disposed at both the one end that is the upstream side in the flow of the working fluid and the other end that is the downstream side in the flow of the working fluid. According to the eighth embodiment, an electromagnetic valve can be provided on both the upstream and the downstream side, which has advantageous properties with respect to the attractive forces of both the first path like the second one path has, as in the 6 is shown.

The configuration related to the inclined portion on the upstream side of the fluid control valve 5 the eighth embodiment can be replaced by the configuration that relates to the inclined portion on the upstream side of the fluid control valve 5 of the first embodiment.

(Other embodiments)

The disclosure in the present description is not limited to the illustrated embodiments. The disclosure includes the illustrated embodiments and variations based on the embodiments by those skilled in the art. For example, the disclosure is not limited to the combinations of components and elements shown in the embodiments, but can be implemented with various modifications. The disclosure can be implemented in various combinations. The disclosure may include additional sections that may be added to the embodiments. The disclosure includes omitting parts and elements of the embodiments. The disclosure includes the exchange or combination of components, elements between one embodiment and another embodiment. The disclosed technical scope is not limited to the description of the embodiment. It should be understood that the technical field disclosed is defined in the claims and includes meanings that are equivalent to the claims and all modifications in the claims area.

In the fluid control valves of the fourth to eighth embodiments, the inclined portion that faces the first path on the upstream and / or downstream side forms a cross-sectional shape such that a part of one of the piston and the yoke is inclined with respect to part of another of the piston and the yoke. In the fourth to eighth embodiments, the first one path on the upstream side the same configuration as the first path the first embodiment or the third embodiment. The shape of the piston on the downstream side in the fourth and fifth embodiments may be the same as the shape of the piston on the downstream side in the first embodiment.

The fluid control valve 5 , which can solve the problem disclosed in the description, limits the first path and the second path not to the positions described in the above-described embodiments. Each of the above-described embodiments may be configured such that the shapes of the piston and yoke are magnetic path are reversed between their upstream sides and their downstream sides.

In the embodiment described above, the valve element 57 an element that with the through the piston 55 driven support element 58 is connected, but the fluid control valve 5 that can achieve the objects disclosed in the description is not limited to these embodiments. For example, the valve element 57 be an element since it's integral with the piston 55 is provided, or it may be part of the piston 55 determine.

In the fluid control valves 5 according to the above-described embodiments, the controller 8th be a duty cycle control valve that is a ratio of an ON time to a cycle time consisting of the ON time and an OFF time of energizing, that is, a duty cycle to energize the electromagnetic coil. According to such control of the Energy supply for the fluid control valve 5 can be a flow rate through the second flow path 11 flowing cooling water can be adjusted as desired.

The fluid control valve 5 that can achieve the object disclosed in the description is not limited to an electromagnetic valve that controls the flow rate of the cooling water in a cooling water circuit 1 can control in which the cooling water of the machine 2nd circulates. This fluid control valve 5 For example, an electromagnetic valve that controls a flow rate of a working fluid that can cool an engine, a converter, a semiconductor device, etc., an electromagnetic valve that can control a flow rate of a working fluid used for air conditioning or air heating, and a solenoid valve, that controls a flow of an operating oil such as an automatic oil.

While the present disclosure has been described with reference to embodiments thereof, it is to be understood that the disclosure is not limited to the embodiments and constructions. In contrast, the present disclosure is intended to cover various modifications and equivalent arrangements. In addition, while various elements are shown in various combinations and configurations that are exemplary, other combinations and configurations including more, less, or only a single element are also within the spirit and scope of the present disclosure.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• JP 2017179306 [0001]
• JP 5811797 B2 [0004]

Claims (10)

Fluid control valve with: a housing (51) having an inner passage (512) through which a liquid working fluid flows, a valve element (57) that opens and closes the inner passage to switch between an open valve state and a closed valve state, the valve element being separated from a valve seat (511) in the open valve state to prevent flow of the Enable working fluid through the inner passage, wherein pressure of the working fluid in a direction toward the valve open condition acts on the valve element; a piston (55; 155; 255; 355) that drives the valve element in an axial direction of the valve element; a coil (540) that generates a magnetic force that drives the piston in the axial direction to switch from the open valve state due to energization of the coil to the closed valve state; a yoke (56; 156; 256; 356; 456) which, together with the piston, forms a magnetic circuit while being energized; a first path (551, 561; 555, 1561; 555, 561; 556, 565; 557, 566; 556, 567; 557, 563), which is a magnetic path through which the magnetic flux between the piston and the yoke goes through; and a second path (550, 560; 552, 564; 557, 566), which is a magnetic path through which the magnetic flux passes between the piston and the yoke at a position different from the first path, in which the first path and the second path are positioned such that the first path to start energizing in the open valve state is larger in its magnetic flux than the second path, and that the second path in its magnetic flux is in the state closed valve is larger than the first path. Fluid control valve after Claim 1 wherein the first path is a magnetic path in which the magnetic flux between an inclined portion (561; 555; 556; 557) that is a portion of one of the piston and the yoke and has a sectional shape that is related to a portion (551; 1561; 567; 563) of another from the piston and the yoke is inclined, and the portion of the other from the piston and the yoke passes through, the second path is a magnetic path in which a magnetic flux passes through parallel Goes through portions (550, 560; 552, 564; 557, 566) of the piston and the yoke, which are directed towards each other in the axial direction and have sectional shapes which extend along each other. Fluid control valve after Claim 2 wherein the piston has a cylindrical portion (551) extending in the axial direction, the yoke has the inclined portion (561) having the sectional shape inclined with respect to the cylindrical portion, and the parallel portions have an upstream annular portion (550) provided upstream of the cylindrical portion of the piston in the flow of the working fluid and an upstream annular portion (560) provided upstream of the inclined portion of the yoke in the flow of the working fluid. Fluid control valve after Claim 2 wherein the yoke has an upstream cylindrical portion (1561) extending in the axial direction, the piston has the inclined portion (555) having the sectional shape inclined with respect to the upstream cylindrical portion, and the parallel portions have an upstream annular portion (560) provided upstream of the upstream cylindrical portion of the yoke in the flow of the working fluid and an upstream annular portion (550) provided upstream of the inclined portion of the piston in the flow of the working fluid. Fluid control valve after Claim 1 , the first path being a magnetic path in which magnetic flux passes through parallel portions (555, 561) of the piston and yoke that are inclined with respect to the axial direction and have intersecting shapes extending along each other, and the second Path is a magnetic path in which the magnetic flux passes through parallel portions (550, 560) of the piston and yoke that are directed towards each other in the axial direction and have intersecting shapes that extend along each other. Fluid control valve after Claim 1 , wherein the first path and the second path are each provided at both an end part on an upstream side in the flow of the working fluid and another end on a downstream side in the flow of the working fluid between the piston and the yoke. Fluid control valve according to one of the Claims 1 to 6 , with a fluid passage (553) within the piston through which the working fluid flows. Fluid control valve according to one of the Claims 1 to 6 , with a fluid passage (553) within the piston and the spool through which the working fluid flows. Fluid control valve according to one of the Claims 1 to 8th wherein the second path is formed at a position where the piston and the yoke are in contact with each other in the valve closed state. Fluid control valve according to one of the Claims 1 to 8th wherein the second path is one of a plurality of second paths at a plurality of positions, and at least one of the plurality of the second paths at the plurality of positions may be formed at a position where the piston and the yoke are in contact with each other in the closed valve state .

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