JP2011027264A - Combination faucet - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To effectively avoid a hunting phenomenon caused when rapidly closing off a space between a water valve seat and a water valve or a space between a hot water valve seat and a hot water valve. <P>SOLUTION: The valve of the hot water valve or the water valve annularly formed in a control valve body 3, and the valve seat of the hot water valve seat (a) or the water valve seat (b) annularly formed in a casing 2 are arranged side by side such that a center line of the valve of the hot water valve or the water valve faces an axial line of a valve seat of the hot water valve seat (a) or the water valve seat (b) slightly eccentrically to one side. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

The present invention relates to a hot and cold water mixing tap that mixes and discharges hot water and water.
More specifically, among the hot and cold water mixing plugs, the hot water flow is formed on the peripheral wall of a cylindrical casing that is formed in a cylindrical shape and assembled into a cartridge shape in a cylindrical shape that is an outer casing of the mixing tap. An inlet and a water inlet are provided in parallel in the axial direction, and a hot water valve seat and a water valve seat are provided on their inner surfaces so as to face each other in the axial direction. A cylindrical control valve body provided with a hot water valve and a water valve respectively facing the valve seat at both ends in the axial direction is arranged so as to be movable in the axial direction, and the base end side is placed on the control valve body. The tip side of the temperature-sensitive spring supported on the casing and the tip side of the bias spring whose base end side is supported on the adjustment screw are connected to face each other, and the control valve body is pivoted by the balance of the pair of springs. Hot water flowing in from the hot water inlet and the water inlet. When the water is mixed and discharged, the temperature of the mixed water is detected by the temperature-sensitive spring, and the control valve body is controlled by changing the spring constant according to the temperature change of the temperature-sensitive spring. It is related with the improvement about the hot water / water mixing tap of the form which kept the temperature of the mixed water discharged by setting to temperature.

  The control valve movably provided in the axial direction described above is kept in a balanced state between the temperature-sensitive spring and the bias spring, and the control valve operation is automatically controlled by the temperature-sensing operation of the temperature-sensitive spring, and the mixture is discharged. A hot and cold water mixing tap configured to keep water at a set temperature is generally configured as shown in FIGS.

  In FIG. 1, reference numeral 1 shown by a chain line is an outer casing (case) that is an outer box of a hot-water mixing tap A that is constructed and installed in a bathroom or the like for hot water supply or water supply. Are formed with a hot water inlet pipe 10 connected to the hot water tap, a water inlet pipe 11 connected to the water tap, and a discharge pipe 12 for discharging the mixed water.

  Reference numeral 2 denotes a casing for assembling the control valve mechanism w to be assembled into a cartridge that is fitted into the outer casing 1 described above. The casing 2 has a bottomed cylindrical main body 2a and a valve seat fitting 2b that is screwed to the casing. It is formed in a cylindrical shape that is inserted into the tub 1, and a hot water inlet 20 and a water inlet 21 are formed on the peripheral wall thereof at intervals in the axial direction (left-right direction in FIG. 1). is there. And the hot water valve seat a and the water valve seat b are formed in each inner position of the hot water inlet 20 and the water inlet 21 so as to be opposed to each other in the axial direction.

  Reference numeral 3 denotes a control valve body which is disposed in the interval between the hot water valve seat a and the water valve seat b so as to be movable in the axial direction, and is formed in a tubular valve shape. A hot water valve 3a is formed at the edge of the side facing the water valve, and a water valve 3b is formed at the edge of the side facing the water valve seat b.

  Reference numeral 4 denotes a bias spring that urges the control valve body 3 to push out toward the water valve seat b, and reference numeral 5 denotes a temperature-sensitive spring that urges the control valve body 3 to push out toward the water valve seat a.

  The temperature-sensitive spring 5 is made of a shape memory alloy (Shape Memory Alloy, abbreviated SMA), and the temperature-sensitive spring has a lower elastic force due to cooling and a higher elastic force due to heating, so that the load changes depending on the temperature. Since it is expanded and contracted due to temperature by processing it in a spring shape, it is used for a temperature actuator by controlling the control operation by moving the control valve body with a force to be extended as a load.

  6a is an adjustment screw that supports the base end side of the bias spring 4, and is incorporated by engaging the outer peripheral surface with the inner surface of the casing 2 in the circumferential direction so as to move only in the axial direction. An internal thread is formed on the surface.

  An adjustment screw shaft 6b is provided on the casing 2 so as to be rotated by a temperature adjustment dial D1 provided on one end side of the casing 2. A male screw is provided on the outer peripheral surface, and the adjustment screw 6a is screwed on the male screw. Match.

  In the hot water / water mixing tap A of this embodiment, the adjustment screw 6a is displaced in the axial direction by the turning operation of the temperature adjustment dial D1, and the support position on the other end side of the bias spring 4 is set to a desired position. In this state, the control valve body 3 is held in a balanced state by the bias spring 4 and the temperature-sensitive spring 5, and the temperature-sensitive spring 5 from the state position performs a sensing operation by the temperature change of the mixed water. When the generated load is changed, the biasing force of the bias spring is used to displace the control valve body 3 so as to maintain the temperature of the discharged mixed water at the set temperature.

  More specifically, in FIG. 2, the control valve body 3 is supported by the casing 2 on the both ends thereof, the distal end side of the bias spring 4 supported on the adjustment screw 6 a on the proximal end side, and the casing 2 on the proximal end side. By connecting the tip side of the temperature-sensitive spring 5 so as to face each other, it is supported so as to be movable in the axial direction, and is held at a balanced position between the bias spring 4 and the temperature-sensitive spring 5. Hot water flowing into the casing 2 from the hot water inlet 20 through the space between the hot water valve 3a and the hot water valve seat a, and from the water inlet 21 into the casing 2 through the space between the water valve 3b and the water valve seat b. The inflowing water is mixed and mixed in the mixing chamber 22 formed on the other end side of the casing 2 to become mixed water, and when it is discharged from the mixed water outlet 23, it is disposed in the mixing chamber 22. The temperature-sensitive spring 5 senses the temperature of the mixed water and changes the generated load thereby to control the displacement of the control valve body 3 using the biasing force of the bias spring 4. The temperature is controlled so as to be maintained at the set desired temperature.

  That is, when the flow rate of the incoming water decreases due to a decrease in the water pressure or the like, and the temperature of the mixed water in the mixing chamber 22 increases, the temperature-sensitive spring 5 that senses this increases the generated load. The bias spring 4 is pushed and shrunk by the increased load, the control valve body 3 is moved to the left, the distance between the hot water valve 3a and the hot water valve seat a is reduced, and the inflow amount of hot water is reduced. Thereby, the temperature of the mixed water which rose is reduced. And the control valve body 3 is stabilized in the position where the mixing ratio of the hot water of mixed water and water and the mixed water temperature were balanced.

  Further, when the flow rate of the incoming water increases due to an increase in water pressure or the like, and the temperature of the mixed water in the mixing chamber 22 decreases as a result, the temperature-sensitive spring 5 is generated by its sensing operation. When the load is reduced, the bias spring 4 extends by the reduced load, the control valve body 3 is moved to the right, the distance between the water valve 3b and the water valve seat b is narrowed, and the flow rate of the incoming water To reduce the amount of water, thereby increasing the temperature of the mixed water that has been reduced. And the control valve body 3 comes to be stabilized in the position where the mixing ratio of the flowing hot water and water and the mixed water temperature are balanced.

  The hot and cold mixing tap A using the temperature sensing spring 5 composed of the SMA spring that operates in this manner causes the bias spring 4 to rotate by operating the temperature adjusting dial D1 when the cold water is to be discharged. The adjustment screw 6a of the support member g that supports the other end side is moved to the left to displace the control valve body 3 to the side of the hot water valve seat a, and the interval between the hot water valve 3a and the hot water valve seat a is closed. This is done by setting the distance between the seat b and the water valve 3b to a large open state. At this time, the temperature-sensitive spring 5 made of the SMA spring is in a state in which the generated load is reduced due to a decrease in temperature. There may be a case where the force for pushing the valve body 3 toward the hot water valve seat a is insufficient, and the interval between the hot water valve seat a and the hot water valve 3a cannot be closed.

  In order to cope with this situation, the temperature-sensitive spring 5 needs to have a large spring load. By using a large spring having a large generated load, the hot and cold water mixing plug A to be assembled is enlarged. There is a problem to do.

  Further, the temperature control dial D1 is turned to move the control valve body 3 so as to discharge hot water, the interval between the water valve seat b and the water valve 3b is closed, and the interval between the hot water valve seat a and the hot water valve 3a. Or when the interval between the hot water valve seat a and the hot water valve 3a is closed and the interval between the water valve seat b and the water valve 3b is opened so that water is discharged. There is a problem of causing a hunting phenomenon and causing damage to the instrument by suddenly shutting off.

  Further, the hot and cold water mixing plug A is connected to the control valve body 3 so that the temperature sensitive spring 5 and the bias spring 4 are opposed to each other, and the control valve body 3 is movably supported in the axial direction by the balance of the two springs. Since the control operation is performed on the control valve body 3 by the balance of the two springs facing each other, the operation of the control valve body 3 is caused by the variation of the contact portion at the position where the two springs are connected to the control valve body 3. In order for this operation to be performed smoothly, the end face that is the connection point of the two springs to the control valve body 3 is finished to a flat surface, and even if the spring is bent, the spring pressure is not increased. It is necessary to make it act on the control valve body 3 correctly, and there exists a problem which increases the manufacture cost of a spring.

  The problem to be solved in the present invention is to effectively eliminate the hunting phenomenon that occurs when the interval between the water valve seat b and the water valve 3b or the interval between the hot water valve seat a and the hot water valve 3a is suddenly closed. It is to develop means that can be avoided.

In the present invention, as means for solving the above-described problems,
The hot water inlet 20 and the water inlet 21 are provided on the peripheral wall of the cylindrical casing 2 in parallel in the axial direction, and the annular hot water valve seat a and the water valve seat b are provided so as to face each other at their inner positions. In the cylindrical casing 2, a cylindrical control valve body 3, in which a hot water valve 3 a and a water valve 3 b are formed in an annular shape at both end edges, is movably inserted in the axial direction, and at both end sides thereof. The base end side of the bias spring 4 supported by the adjusting screw 6a and the base end side of the temperature sensitive spring 5 supported by the casing 2 are opposed to each other, and the control valve body 3 is connected to the front end side. The bias spring 4 and the temperature sensitive spring 5 are held at the balance position of the two springs, and the adjusting screw 6a for supporting the bias spring 4 is turned by rotating the temperature adjustment dial D1 assembled to one end of the casing 2. Screwed into the moving adjustment screw shaft 6b, the rotation of the adjustment screw shaft 6b In the hot and cold water mixing tap in which the adjustment screw 6a is moved in the axial direction to change and set the support position of the bias spring 4, the hot water valve 3a or the water valve 3b formed in the control valve body 3 in an annular shape and the casing 2 in the annular shape The center line X of the valve valve of the hot water valve seat a or the water valve seat b is connected to the axial center line Z of the valve seat of the hot water valve seat a or the water valve seat b. A hot and cold water mixing tap characterized by being installed so as to be slightly eccentric to one side and face each other.
Is to raise.

  This means is that when the temperature control dial D1 is operated to move the set position of the control valve body 3, and when the hot water valve seat a side or the water valve seat b side is closed, a hunting phenomenon that may be caused by this will occur. Since the hot water or water flow path is abruptly closed, for example, at the upper end portion of the valve seat fitting 2b, the seat surface of the water valve seat b formed in an annular shape around the center of the axis, When the control valve body 3 descends and the water valve 3b formed annularly contacts the lower edge of the control valve body 3 to block the flow path, the virtual center line of the water valve 3b formed annularly is The annular seal surface of the water valve 3b of the control valve body 3 is partly in contact with the seat surface of the water valve seat b sequentially from the eccentric side. By doing so, the seat surface of the water valve seat b will not be closed all at once. Hunting phenomenon conceive that capable of eliminating, were tested in this configuration, it has been completed by the expected results were obtained. As a result, the hunting phenomenon can be effectively eliminated.

  In the present invention, the hot water valve 3a and water valve 3b formed annularly on the control valve body 3 and the annular hot water valve seat a and water valve seat b formed on the casing 2 are connected to the hot water valve 3a and water valve. Since the center line X of the valve 3b is eccentrically set to one side with respect to the axial center line Z of the hot water valve seat a and the water valve seat b, the valve and valve are installed. When the space between the seat and the seat is closed, the seat surface of the valve seat is not sealed at a time but is partially sealed sequentially so that the hunting phenomenon can be effectively eliminated.

  Next, embodiments of the present invention will be described with reference to the accompanying drawings.

  FIG. 3 shows an example of a hot and cold water mixing tap according to the present invention. In this example, the body of the hot and cold water mixing tap A is constituted by an outer casing 1 that is an outer box shown by a chain line, and a cylindrical casing 2 that is detachably inserted into the outer casing 1 and is controlled. The valve mechanism w is assembled so as to be stored in the casing 2 and assembled into a cartridge shape. This is an example in which the hot water mixing tap A is configured by fitting the valve mechanism w into the outer casing 1 in a cartridge shape. 2 shows a casing 2 and a control valve mechanism w which are loaded into the outer casing 1 like a cartridge.

  As shown in FIG. 4, the casing 2 has a bottom wall having a bottom wall in which a female screw 24 is formed on the other end side (right end side in the drawing) and a through hole 25 is formed in the shaft core portion on one end side. The cylindrical body 2a and the cylindrical valve seat fitting 2b provided with a male screw 26 screwed to the female screw 24 of the main body 2a on one end side are screwed and connected to each other, thereby forming a hollow body. The hot water inlet 20 and the water inlet 21 are formed in the cylindrical wall of the main body 2a, and the hot water valve seat a is formed on the inner end side of the hot water inlet 20. Is shaped. The water valve seat b formed at the inner position of the water inlet 21 is formed at the inner end edge of the valve seat fitting 2b that is screwed into the main body 2a. The valve seat fitting 2b is formed with a mixed water outlet 23 at one end side and is used as a mixing chamber 22 on the inner side.

  The control valve mechanism w is formed in a cylindrical valve shape, a control valve body 3 having a hot water valve 3a formed at one end edge of the cylindrical wall thereof and a water valve 3b formed at the other end edge thereof, and the control valve body 3 The bias spring 4 is connected to one end edge side and biased to the water valve seat b side, and the temperature sensitive spring 5 is connected to one end side of the control valve body 3 and biased to the hot water valve seat a side. The base end side of the bias spring 4 that urges the control valve body 3 toward the water valve seat b is supported by a support member g formed separately from the adjustment screw 6a.

  In this example, the support member g is formed in the shape of a shaft rod, and one end side (left end side in FIG. 3) of the support member g is slidable in a through hole 63 provided in the shaft core portion of the adjustment screw 6a. An abutting portion t1 made of a flange or a retaining ring is provided on the other end side that is inserted and protrudes rightward from the through-hole 63, so that the adjustment screw 6a is located on the other end side of the support member g (see FIG. 3 to the right) and when it collides with the abutting portion t1, it is integrally connected to the supporting member g and thereafter the supporting member g is moved to the other end side. The bias spring 4 formed in a coil shape is fitted on the other end side from t1, and the base end side of the spring receiver 40 that stores the bias spring 4 is brought into contact with the end surface on the other end side of the abutting portion t1. The adjustment screw 6a supports the base end side of the bias spring 4 via the support member g.

  As a result, the control valve element 3 is composed of a bias spring 4 having the base end side supported by the adjusting screw 6a via the support member g and a temperature-sensitive spring 5 having the base end side supported by the valve seat fitting 2b. The two springs are movably supported in the axial direction, and the control operation is performed by the temperature sensing operation of the temperature sensing spring 5 located in the mixing chamber 22.

  y is a temperature adjusting means for adjusting the control operation of the control valve body 3 to a desired set temperature, and is inserted into the through hole 25 on one end side of the main body portion 2a of the casing 2 so as to be freely rotatable. The adjustment screw shaft 6b whose side is connected to the temperature control dial D1, the outer peripheral surface is fitted to the inner surface of the main body 2a via the spline-shaped engagement portion 60 along the axial direction, and the inner peripheral surface is the adjustment screw shaft 6b and the above-described adjusting screw 6a formed on the female screw 62 that is screwed to the male screw 61 formed on the outer surface of the inner end side of 6b, and the temperature adjusting dial D1 is rotated via the adjusting screw 6a. By moving the support member g in the axial direction, the balance position between the bias spring 4 and the temperature sensitive spring 5 is changed, and the set temperature is set.

  Further, the control valve body 3 of the control valve mechanism w is provided with a through hole 30 penetrating in the axial direction in the axial center portion thereof, and the other end side of the support member g formed in the shape of the shaft rod is provided there. The sliding member is inserted so that the movement during the control operation is guided, and the other end side of the support member g is inserted into the shaft-shaped guide tube 27 provided in the valve seat fitting 2b and supported. Thus, when the control valve body 3 performs the control operation by being assembled in a fixed state with respect to the casing 2, the movement is performed only in the axial direction by the other end side of the support member g. In the control operation, the control valve body 3 is prevented from moving in an irregular direction inclined with respect to the axial direction.

  Reference numeral 7 denotes a pulling spring incorporated in the control valve mechanism w so as to bias the control valve body 3 toward the hot water valve seat a only when the set temperature is adjusted to the water discharge state.

  In this example, the pulling spring 7 is assembled using the support member g formed in the shape of the above-mentioned shaft rod, and the support member g is a group used when the control valve mechanism w is assembled to the casing 2. It is also used as a frame.

  When the control valve body 3 is assembled to the casing 2, first, as shown in FIG. 5, a retaining ring serving as the abutting portion t <b> 1 is fitted in a portion close to one end side of the support member g formed in the shape of a shaft rod. Then, the spring receiver 40 formed in a sheath shape is inserted into this from the other end side of the support member g, then the bias spring 4 formed in a coil shape is inserted, and then the control valve body 3 is inserted, In this state, a retaining ring t2 is fitted on one end side of the support member g to prevent escape, thereby assembling a unit integrally combined with the bias spring 4 and the support member g. At this time, on the other end side of the support member g, the protruding end portion protruding from the abutting portion t1 for restricting the movement of the support member g of the spring receiver 40 to the other end side is provided. The aforementioned adjusting screw 6a to be screwed onto the adjusting screw shaft 6b is attached to the bottom wall of the adjusting screw 6a. The pulling spring 7 is slidably inserted through a through-hole 63 provided in the core portion, and a pulling spring 7 formed into a coil shape is further inserted, and the other end of the pulling spring 7 is projected from the other end of the support member g. By restricting by a retaining ring t3 attached to the end portion, the escape from the support member g is prevented, and is integrally assembled together with the aforementioned unit, and is inserted into the casing 2, Assemble to the state.

  In this state, the pulling spring 7 acts to push the adjustment screw 6a toward the other end of the support member g, but the adjustment screw 6a abuts against the abutting portion t1 and stops, and is supported further. The pulling spring 7 is in a state in which no spring load acts on the bias spring 4 and the control valve body 3 because it does not move toward the other end side of the member g.

  That is, when the pulling spring 7 assembled to the control valve mechanism w is set so as to discharge the mixed water of hot water and water in the normal temperature range, the supporting member g is held in the state shown in FIG. Since it is not performed, it is held in a state where it does not work. Further, even when the water valve seat b is closed to discharge hot water, the state shown in FIG. 8 is obtained, and the pulling spring 7 is not compressed and is kept in a state in which no load is generated. However, as shown in FIG. 9, when the hot water valve seat a is closed and the water discharge state is set, the adjustment screw 6a moves in the pull-back direction with respect to the support member g, thereby compressing the pulling spring 7 Thus, a load is generated, and the load of the support member g is added to the load of the temperature-sensitive spring 5 that pushes the control valve body 3 toward the hot water valve seat a.

  FIG. 10 shows another example. In this example, the casing 2 is formed by a body portion 2a and a valve seat fitting 2b screwed to the casing portion 2 into a cylindrical shape that is fitted in a cartridge shape in the outer casing 1 that forms the case of the hot and cold mixing tap A. The control valve mechanism w to be incorporated in the hot water inlet 20 and the water inlet 21 formed on the cylindrical wall of the main body 2a, the hot water valve seat a formed on the inner side of the hot water inlet 20, and the water inlet The water valve seat b which is arranged at the inner side of the valve seat 21 and is formed on the inner edge of the valve seat fitting 2b, and a cylinder which is formed separately from the casing 2 and is inserted into the casing 2 and is movably assembled in the axial direction. A valve-shaped control valve body 3, a bias spring 4 that is connected to one end edge side (upper edge side in the drawing) of the control valve body 3, and is biased to the water valve seat b side, and is connected to the other end edge side of the control valve body 3. A temperature sensing spring 5 urged toward the hot water valve seat a side is used, and the control valve body 3 is balanced between the two springs of the bias spring 4 and the temperature sensing spring 5. A control operation is performed by a temperature sensing operation of a temperature sensing spring 5 located in a mixing chamber 22 formed in a lumen of a valve seat fitting 2b on one end side of the casing 2 so as to be movably supported in the longitudinal direction. This is the same as the previous example.

  However, in this example, as shown in FIG. 11, a control valve in which the seat surface of the water valve seat b formed annularly on the inner end edge (upper end edge in the figure) of the valve seat fitting 2b is formed in a cylindrical valve shape. A tapered surface that is formed in a band shape wider than the width of the water valve 3b formed on the lower edge side of the cylindrical wall of the body 3, and the wide sheet surface forms a funnel shape that gradually decreases in diameter toward the lower side. Further, the imaginary center line X of the annular water valve seat b is eccentrically formed so as to be slightly deviated to one side (left side in the figure) with respect to the axial center line Z of the valve seat fitting 2b. It is.

  Further, the control valve body 3 has a water valve 3b formed in an annular shape facing the water valve seat b at the lower end edge of the cylindrical wall thereof so that its virtual axis core line is aligned with the axis core line of the control valve body 3 And formed on a tapered surface that is narrower than the seat surface of the water valve seat b and is substantially parallel to the seat surface. Further, the control valve body 3 is provided with a lower guide g2 on the lower end side thereof. This is inserted into a guide tube 27 provided in the inner cavity of the valve seat fitting 2b, so that the annular water valve 3b has its axis line aligned with the axis line of the valve seat fitting 2b, and the water valve seat When the water valve 3b is abutted against the water valve seat b, the water valve 3b abuts in an eccentric state on one side (right side in the figure) as shown in FIG. I am doing so.

  For this reason, when the control valve body 3 descends and the water valve 3b abuts the water valve seat b to close the water flow path between the water valve 3b and the water valve seat b, FIG. As shown in the figure, the eccentric side (right side in FIG. 12) of the water valve 3b is partially sealed, but the opposite side of the eccentricity is kept open without being sealed, and the subsequent control valve body. 3 is lowered, the water valve 3b slides on the seat surface of the water valve seat b and moves downward to be sealed. As a result, when the water flow path between the water valve 3b and the water valve seat b is closed, the space between the water valve 3b and the water valve seat b is not closed at once, but is partially sealed sequentially. Therefore, since the temperature change does not occur suddenly and becomes gentle, the hunting phenomenon is eliminated.

  The means for decentering the valve (water valve 3b) formed annularly at the end of the cylindrical wall of the control valve body 3 with respect to the axial core line of the control valve body 3 is arranged so that the eccentricity with respect to the axial core line is on the side of the hot water valve 3a. In order to avoid sudden shut-off when the hot water flow path is closed, the hot water flow path shut-off and water shut-off are also provided in both the water valve 3b and the hot water valve 3a. There are cases in which both are implemented.

  Valves (water valve 3a / water valve 3b) formed in an annular shape at the edge of the cylindrical wall of the control valve body 3 are formed in an annular shape and provided in the body 2a / valve seat fitting 2b (water valve seat a. The cancellation of the hunting phenomenon by means of eccentrically facing the water valve seat b) is explained only based on the operation when the control valve body 3 is closed. Even at that time, the sealed annular valve and the valve seat are partially separated sequentially so that the hunting phenomenon at the time of valve opening is also eliminated.

  In this example, the support member g provided to guide the operation of the control valve body 3 in the direction along the axial direction is divided into an upper guide g1 and a lower guide g2, and an upper guide g1 thereof. In this case, one end side (the upper end side in FIG. 10) is inserted into the through hole 63 formed in the adjustment screw 6a until the abutting portion t1 comes into contact therewith, and the pulling spring 7 is assembled thereto, The other end side that extends downward from the joint portion t1 is inserted into a bottomed cylindrical tube-shaped spring case 32 formed in the shaft core portion of the control valve body 3, and the bias spring 4 stored in the spring case 32 Is supported by a spring seat 31 and connected to a bias spring. In the lower guide g2, the lower end side of the control valve body 3 is integrally extended so as to extend therefrom. The guide which connected and provided the valve seat metal fitting 2b lumen | bore It is not fit inserted to 27.

  The guide cylinder 27 into which the lower guide g2 is inserted is formed so that the inner diameter thereof is slightly increased toward one end side (outer end side), whereby the control valve as shown in FIG. When the body 3 moves to the valve seat fitting 2b side and the water valve 3b comes into contact with the water valve seat b, the lower guide g2 expands the inner diameter of the guide cylinder 27 with the upper end side of the guide cylinder 27 as a fulcrum. Tilt rotation is possible by the diameter, and this tilt rotation smoothly guides the movement of the control valve body 3 so as to shift to the side opposite to the eccentric side.

It is a cross-sectional top view of the hot and cold water mixing tap of the form which supports the conventional control valve body by the balance of two springs. It is sectional drawing of the principal part same as the above. It is a longitudinal cross-sectional view of the example of the hot / cold mixing tap which implements this invention means. It is explanatory drawing of the assembly process of the example same as the above. It is sectional drawing of the state which assembled | attached the adjustment screw and the raising spring further to the unit of the example same as the above. It is explanatory drawing of the process of assembling a unit same as the above to the main-body part of a casing. It is sectional drawing of the state made into the setting which discharges mixed water of the example same as the above. It is sectional drawing of the state set to hot water discharge of the example same as the above. It is sectional drawing of the state set to the water discharge of the example same as the above. It is a longitudinal cross-sectional view of another example. It is a longitudinal cross-sectional view of the valve seat metal fitting of the example same as the above. It is a longitudinal cross-sectional view of the valve seat metal fitting of an example same as the above, and the control valve body which collides with this.

A Hot water mixing tap D1 Temperature control dial X Virtual center line Z Axis core wire a Hot water valve seat b Water valve seat g Support member g1 Upper guide g2 Lower guide t1 Abutting part t2 Flange t3 Flange w Control valve mechanism y Temperature adjustment means 1 Outside筺 10 Hot water inlet pipe 11 Water inlet pipe 12 Discharge pipe 2 Casing 2a Body 2b Valve seat fitting 20 Hot water inlet 21 Water inlet 22 Mixing chamber 23 Mixed water outlet 24 Female screw 25 Through hole 26 Male screw 27 Guide cylinder 3 Control valve body 3a Hot water valve 3b Water valve 30 Through hole 31 Spring seat 32 Spring case 4 Bias spring 40 Spring receiver 5 Temperature sensitive spring 6a Adjustment screw 6b Adjustment screw shaft 60 Engagement part 61 Male screw 62 Female screw 63 Through hole 7 Pulling spring.

Claims (1)

  The hot water inlet 20 and the water inlet 21 are provided on the peripheral wall of the cylindrical casing 2 in parallel in the axial direction, and the annular hot water valve seat a and the water valve seat b are provided so as to face each other at their inner positions. In the cylindrical casing 2, a cylindrical control valve body 3, in which a hot water valve 3 a and a water valve 3 b are formed in an annular shape at both end edges, is movably inserted in the axial direction, and at both end sides thereof. The base end side of the bias spring 4 supported by the adjusting screw 6a and the base end side of the temperature sensitive spring 5 supported by the casing 2 are opposed to each other, and the control valve body 3 is connected to the front end side. The bias spring 4 and the temperature sensitive spring 5 are held at the balance position of the two springs, and the adjusting screw 6a for supporting the bias spring 4 is turned by rotating the temperature adjustment dial D1 assembled to one end of the casing 2. Screwed into the moving adjustment screw shaft 6b, the rotation of the adjustment screw shaft 6b In the hot and cold water mixing tap in which the adjustment screw 6a is moved in the axial direction to change and set the support position of the bias spring 4, the hot water valve 3a or the water valve 3b formed in the control valve body 3 in an annular shape and the casing 2 in the annular shape The center line X of the valve valve of the hot water valve seat a or the water valve seat b is connected to the axial center line Z of the valve seat of the hot water valve seat a or the water valve seat b. A hot and cold water mixing tap characterized by being installed so as to be slightly eccentric to one side and face each other.

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