JP2671927B2 - Thermostatic mixing valve - Google Patents

Description

The present invention relates to a thermostat mixing valve having a function of automatically adjusting a set temperature of mixed water in a hot water mixing tap.

[Conventional technology]

2. Description of the Related Art Conventionally, a thermostat mixing valve that has a temperature sensitive function built-in and is capable of automatically adjusting the temperature of mixed water to a set value has been widely used. The thermostat mixing valve typically has a structure in which a temporary operation type control valve element is provided in a water and hot water supply passage, and the control valve element is moved forward and backward by an element in which wax pellets are enclosed.

FIG. 4 is a front longitudinal sectional view showing a conventional thermostat mixing valve, and a conventional example will be described below based on this.

In the figure, leg pipes 1a and 1b for water supply and hot water supply are connected to the back of the main body 1, and a water supply chamber 2a and a hot water supply chamber 2b communicating with these leg pipes 1a and 1b are formed, respectively. Also,
A mixing chamber 3a is provided as a room separate from the water supply room 2a and the hot water supply room 2b, and the spout 3b is connected to this.

The water supply chamber 2a and the hot water supply chamber 2b communicate with the mixing chamber 3a by a control valve body 4 slidably arranged on a partition wall 2c between them. The control valve body 4 is a tubular body having an H-shaped cross section, and both ends in the axial direction are the water valve seat 5a and the hot water valve seat of the water supply chamber 2a and the hot water supply chamber 2b.
It is a uniaxial valve structure seated on 5b. Then, the hot water inflow hole 4a is opened in the inner boss, and the water valve seat is opened by the spring 4b.
It is biased toward the 5a side.

On the other hand, an adjusting handle 6 for adjusting the temperature is provided at the right end of the main body 1 and is connected to an operating mechanism in the cartridge case 7. Inside the cartridge case 7, a cylinder 8 spline-engaged with a spindle 6a of an adjusting handle 6 is rotatably screwed, and a sleeve 9 is arranged between the cylinder 8 and the control valve body 4. The sleeve 9 has its left end abutted against the boss of the control valve body 4 and the main body 1
A water inlet 9a is opened in a portion located in the water supply chamber 2a, and a water mixture outlet 9b is provided in a portion located in the mixing chamber 3a. Further, in the sleeve 9, a wax-enclosed temperature sensitive element 10 sensitive to the temperature of the mixed water is provided as a temperature sensitive function section. At the right end of the temperature sensitive element 10, a pin 10a protruding and retracted by the expansion and contraction of wax is projected, and a seat 8a for receiving one end of the temperature sensitive element 10 including this pin 10a is slidably arranged in the cylinder 8. There is. Also, the pin 10a is the spring 8
It is biased toward the temperature sensitive element 10 side by b.

In the above configuration, in the illustrated state, the left end of the control valve body 4 is seated on the hot water valve seat 5b to close the hot water flow passage
5a side is fully opened. At this time, the water in the water supply chamber 2a enters the inside from the water inlet 9a of the sleeve 9 and mixes the water outlet 9b.
From the spout 3b to the mixing chamber 3a. Further, when the adjusting handle 6 is rotated to move the cylinder 8 to the right in the figure, the sleeve 9 also moves to the right with this movement, and the control valve body 4 similarly moves to the right due to the urging force of the spring 4b. . For this reason, the closed bath valve seat
5b side opens, hot water side and water side flow path both open, hot water supply room 2b
The hot water from the above flows into the sleeve 9 from the hot water inlet 4a of the control valve body 4, merges with the water from the water inlet 9a, and is sent to the mixing chamber 3a.

Here, the temperature of the mixed water is determined by the valve openings of the water valve seat 5a and the hot water valve seat 5b, and the valve opening is set by the adjusting handle 6. Then, if the temperature of the mixed water becomes higher than the set value due to fluctuations in the water supply pressure or the hot water supply pressure, the wax in the temperature sensitive element 10 will expand and the pin 10a will protrude, and as a result, the sleeve 9 will move to the left side. By moving, the valve opening on the side of the hot water valve seat 5b is reduced to lower the temperature of the mixed water. On the contrary, when the temperature of the mixed water becomes low, the pin 10a retreats, and the sleeve 9 moves to the right side to increase the valve opening on the side of the hot water valve seat 5b to raise the temperature of the mixed water.

Thus, by using the temperature sensitive element 10, even if the mixed water temperature deviates from the set value, the valve opening degree can be automatically adjusted to return the mixed water temperature to the set value.

[Problems to be solved by the invention]

However, when the temperature of the mixed water is raised from a low temperature to a high temperature, for example, the protrusion of the pin 10a of the temperature sensitive element 10 causes the sleeve 9 and the control valve body 4 to move together in a direction that hinders the temperature rise. Therefore, the temperature sensitive element 10
On the contrary, the automatic temperature adjustment by means of obstacles to the temperature setting, and it becomes necessary to increase the rotation angle of the adjusting handle 6 to reach the set temperature.

Further, even when the hot water valve seat 5b side is fully opened and the water valve seat 5a side is closed, the pin 10a of the temperature sensing element 10 tends to move in the protruding direction. Therefore, the control valve element 4 may receive a biasing force toward the hot water valve seat 5b side, and the seating on the water valve seat 5a may become loose. Therefore, there is also a problem that water enters the mixing chamber 3a and the temperature of the discharged hot water decreases.

Therefore, in the present invention, the rotation angle of the adjusting handle required until the hot water of the highest temperature is discharged is reduced to make it easier to use, and water is prevented from being mixed when the water side is fully closed to secure the hot water supply temperature. The purpose is to be able to.

[Means for solving the problem]

The thermostat mixing valve of the present invention includes a valve body that opens and closes a water flow path and a hot water flow path, an adjustment handle that adjusts the opening degree of the control valve body, and a pin that is sensitive to the temperature of the mixed water from the main body toward the seat side. In a thermostat mixing valve having a temperature sensitive element for moving the valve body, a stopper is integrally formed on the outer periphery of the end of the temperature sensitive element body, and the stopper is locked at the end of the operation system on the adjustment handle side. The block for use is frozen, whereby the stroke of the temperature-sensitive element in the extending direction is regulated when the temperature of the mixed water becomes high.

〔Example〕

Hereinafter, the features of the present invention will be specifically described with reference to the embodiments shown in the drawings.

FIG. 1 is a front vertical sectional view of a thermostat mixing valve of the present invention. The same members as those shown in the conventional example of FIG. 4 are designated by common reference numerals, and detailed description thereof will be omitted.

The temperature-sensitive element 10 that moves the pin 10a in and out in response to the temperature of the mixed water is a block 11 fixed to the end of the cylinder 8.
Is slidably inserted. And pin 10
The seat 12 that receives the end of the temperature sensitive element 10 including a
A hollow portion 12a is formed in the axial direction, and a stopper 13 that fits into the hollow portion 12a and uses, for example, an E-shaped ring is provided on the circumferential surface of the temperature sensitive element 10. The present embodiment is different from the conventional example in that the stopper 13 and the block 11 with which the stopper 13 is engaged are provided, and other configurations are exactly the same as those in FIG.

FIG. 2 is a cross-sectional view of the main part showing the temperature-sensitive element 10. The seat 12 and the stopper 13 are different in shape from those in FIG. 1, and the stopper 13 is integrated with the temperature-sensitive element 10. Has been formed. These seat 12 and stopper
13 is functionally the same as in the case of FIG. 1, and its operation will be described below with reference to FIG.

FIG. 2 (a) shows the control valve element 4 as in the case of FIG.
Is seated on the hot water valve seat 5b, and only water is fed from the water supply chamber 2a through the sleeve 9 into the mixing chamber 3a. At this time, the wax in the temperature sensitive element 10 contracts, the protruding amount of the pin 10a is small, and the stopper 13 is the hollow portion 1
It hits the inner wall at the right end of 2a.

When the adjusting handle 6 is operated to open the flow passage on the hot water side from the state of FIG. 2 (a), both the sleeve 9 and the control valve body 4 move to the right as shown in FIG. 2 (b). At this time, both ends of the control valve body 4 are both the water valve seat 5a and the hot water valve seat 5b.
The temperature of the mixed water is set by the size of these valve openings. Then, since the hot water flows into the sleeve 9 by opening the hot water valve seat 5b, the wax of the temperature sensitive element 10 located in the flow path expands and the pin 10a projects. Therefore, as shown in the figure, the stopper 13 moves to a position away from the inner wall at the right end of the hollow portion 12a, and the temperature-sensitive element 10 can move in the axial direction in accordance with the protruding and retracting of the pin 10a. Therefore, if the temperature of the mixed water is within a certain range, the temperature sensitive element 10 moves to move the control valve body 4 to the water valve seat 5a.
Alternatively, it can be moved toward the hot water valve seat 5b, and automatic temperature adjustment can be performed even if the mixed water is separated from the set temperature. The stroke of the temperature sensitive element 10 in the axial direction is the second stroke.
In the figure (a), from the axial length of the cavity 12a to the stopper 13
Equal to the distance less the axis length of.

Further, when the valve opening on the hot water valve seat 5b side is increased to raise the temperature of the mixed water, the wax expands more than in the case of FIG. 2 (b), so that the protruding amount of the pin 10a also increases. For this reason, the temperature sensitive element 10 is pushed to the left side, and the stopper 13 finally hits the block 11 and cannot move. Then, when the temperature of the mixed water further rises and the pin 10a extends, the spring 8b urging the seat 12 contracts to absorb the movement of the pin 10a.

In the above operation, in the case of FIGS. 2A and 2C, the stopper 13 is restrained from moving in the axial direction by the seat 12 and the block 11. Therefore, when the mixed water temperature is in a certain temperature range of low temperature or high temperature, the automatic temperature adjustment by the temperature sensing element 10 is not substantially performed. In other words, as described in the section of the prior art, when the temperature of the mixed water rises from the low temperature to the high temperature due to the protruding and retracting of the pin 10a of the temperature sensing element 10, the protrusion of the pin 10a causes the temperature rise to be hindered. The sleeve 9 and the control valve body 4 move together. Therefore, the temperature sensitive element
On the contrary, the automatic temperature control by 10 becomes an obstacle to the temperature setting, and the rotation angle of the adjusting handle 6 must be increased to reach the set temperature.

FIG. 3 is a diagram showing changes in the temperature of the mixed water with respect to the rotation angle of the adjusting handle 6, and the solid line shows the case of using the conventional example of FIG. The zero value of the rotation angle of the adjusting handle 6 taken along the horizontal axis corresponds to the state where the hot water valve seat 5b side is closed and the water valve seat 5a side is fully opened, as shown in FIGS. 1, 2 (a) and 4. doing.

As can be seen from this diagram, the temperature does not change and water at room temperature is discharged until the adjusting handle 6 is rotated about 100 degrees from the origin. Then, when it is further rotated, the temperature gradient becomes large, and the temperature of the mixed water becomes T at a rotation angle of about 120 degrees.
It reaches _1. After that, the temperature gradient becomes smaller, the temperature of the mixed water rises in proportion to the rotation angle of the adjusting handle 6, and when the temperature exceeds about 330 degrees, the temperature gradient further increases, and finally the hot water supply is almost completed. The temperature of the mixed water is close to the temperature.

As described above, with respect to the temperature change indicated by the solid line, the temperature change indicated by the broken line or the alternate long and short dash line in the figure is obtained in the configuration according to the present invention in FIG.

The pattern shown by the broken line is the same as that of the conventional example when the pattern from temperature T ₁ to temperature T ₂ is used. Then, when the mixed water temperature T is T of <T ₁ corresponds to the state of FIG. 2 _{(a), T 1 ≦ T} ≦ T Figure 2 if ₂ (b) in and T ₂
When <T, each corresponds to FIG. 2 (c). That is, between the temperature T ₁ and the temperature T ₂ , there is a region where the temperature sensing element 10 can automatically adjust the temperature, and as described with reference to FIG. Can be moved.

Here, when the temperature T of the mixed water exceeds T ₂ , the state shown in FIG. 2C is reached, the stopper 13 hits the block 11, and the temperature sensitive element 10 is locked. For this reason,
The wax expands and pin 10
Even if “a” is projected, the temperature sensing element 10 itself is stationary, and automatic temperature control is not performed. Therefore, when the temperature exceeds T ₂ , the temperature gradient becomes larger than in the case of using the conventional example, and the rotation angle of the adjusting handle 6 until the maximum temperature is reached becomes smaller.

Further, when the rotation angle of the adjusting handle until reaching the maximum temperature is set to be the same as that used in the conventional example, the temperature changes as indicated by the one-dot chain line in the figure. In this case, since the temperature gradient after passing the temperature T ₂ is large, the temperature T ₂
The temperature gradient up to can be laid down. Therefore, with respect to the same temperature difference from the temperature T ₁ to the temperature T ₂ , the rotation angle of the adjustment handle 6 is rotated to approximately 370 degrees, and the rotation angle of the adjustment handle 6 per unit temperature becomes large. Therefore, it is possible to set a fine temperature and improve the temperature control performance.

Further, when the end face of the control valve body 4 is pressed against the water valve seat 5a to shut off the water flow path, the stopper 13 as shown in FIG.
Hits block 19. Since the members such as the cylinder 8 are pulled to the right side in the drawing, the pulling force is also transmitted to the control valve body 4 by the engagement of the block 19 and the stopper 13. For this reason, in the prior art, there is a risk of water leakage even if the control valve body 4 is seated on the water valve seat 5a, but it is possible to reliably stop the water supply and supply hot water at a stable temperature.

〔The invention's effect〕

As described above, in the thermostat mixing valve of the present invention, the temperature sensitive element of the temperature sensitive function unit is provided with the stopper so that the stopper is engaged with the actuation mechanism on the adjustment handle side. Therefore, when the temperature of the mixed water becomes high, the temperature-sensitive element cannot be moved due to the locking by the stopper, and the hot water flow path does not expand when the temperature is raised. Therefore, the temperature gradient of the temperature change up to the maximum temperature can be increased, and the rotation angle of the adjusting handle can be smaller than that of the conventional structure.

Even when setting the temperature with the same rotation angle as the conventional product, the temperature gradient from the low temperature range to the high temperature range until the stopper is locked is large because the temperature gradient during the period when the maximum temperature is reached is large. Can be loosened. Therefore, the rotation angle of the adjusting handle per unit temperature becomes large, and minute temperature setting becomes easy.

Furthermore, when the position of the control valve element is set to the maximum temperature by turning the adjustment handle, the control valve element does not open the water side flow path due to the action of the stopper mechanism that controls the stroke of the temperature sensing element, and the set hot water supply Hot water at the same temperature can be supplied. Therefore, even if the maximum temperature is set, the problem of the conventional structure that water flows in and hot water having a temperature slightly lower than the hot water supply temperature is supplied is also solved.

[Brief description of the drawings]

FIG. 1 is a front longitudinal sectional view of a thermostat mixing valve showing an embodiment of the present invention, FIG. 2 is a sectional view of a main part showing the movement of a control valve body, and FIG. 3 includes a case where a conventional product is used. FIG. 4 is a sectional view showing a conventional example. 1: Main body, 1a, 1b: Leg pipe 2a: Water supply room, 2b: Hot water supply room 2c: Partition, 3a: Mixing room 3b: Spout, 4: Control valve body 4a: Hot water inlet, 4b: Spring 5a: Water valve seat , 5b: hot water valve seat 6: adjusting handle, 6a: spindle 7: cartridge case 8: cylinder, 8a: seat 8b: spring, 9: sleeve 9a: water inlet, 9b: mixed water outlet 10: temperature sensing element, 10a : Pin 11: Block, 12: Catch 12a: Cavity, 13: Stopper

Claims (1)

(57) [Claims] 1. A valve body that opens and closes a water flow path and a hot water flow path, an adjustment handle that adjusts the opening degree of the control valve body, and a pin that is sensitive to the temperature of the mixed water are projected from and retracted from the main body to the seating side. In a thermostat mixing valve having a temperature sensitive element for moving a valve element, a stopper is integrally formed on the outer periphery of the end of the temperature sensitive element body, and a stopper locking block is provided at the end of the operation system on the adjustment handle side. A thermostat mixing valve, which is connected, thereby restricting the stroke of the temperature sensing element in the extension direction when the temperature of the mixed water becomes high.