KR960001234B1 - Hot & cold water mixing device - Google Patents

Abstract

A hot water supplier has a high temperature water circuit (11) through a heat exchanger (12) to branch a bypass circuit (3) so as to detour around the heat exchanger (12) through a distributor (2) from a supply water circuit (1) in an inlet side to this heat exchanger (12), and a combination faucet device is provided in a confluent part of both the circuits (11,13). In the combination faucet device, the upstream end of a tubular main unit part (51) of a casing (5) is closed by a block (30) having a supply water pipe (31) and a connecting part of the bypass circuit (3), to insert a supply hot water pipe (14) of providing an inflow port (15) in a barrel part to the downstream of the closer and a tubular unit of providing a vane plate (41) to the downstream of the pipe (14), and further a supply hot water pipe (13) is connected to the downstream. A check valve (17) can be attached/detached to/from both valve seats (17) provided in the downstream ends of the supply water pipe (31) and the supply hot water pipe (14).

Description

Cold and hot water mixing device

1 is an explanatory diagram of a conventional bypass mixed hot water heater.

2 is an explanatory diagram of an embodiment of the present invention.

3 is an explanatory diagram of the cylindrical body 40.

4 is a detailed view of a water discharge valve.

5 is an explanatory diagram of a second embodiment;

6 is an explanatory view of the open state of the non-return valve 7.

7 is an explanatory diagram of another example.

* Explanation of symbols for main parts of the drawings

11: hot water circuit 13: hot water pipe

14: geumtang pipe 31: water pipe

7: non-return valve 8: annular wall

The present invention relates to a structure of a mixing section for mixing a cold / hot water mixing device, in particular, cold water from a water supply pipe and hot water from a hot water supply pipe in a pipe.

As shown in FIG. 1, the hot water heater includes a high temperature water circuit 11 that is heated through the heat exchanger 12 and is heated by this portion, and the temperature rises, and a water supply circuit 1 that leads upstream of the high temperature water circuit. A bypass circuit (3) diverging from the distributor (2), bypassing the heat exchanger (12), and the bypass circuit (3) and the hot water circuit (11) joined to mix the hot water and cold water. Thereafter, the hot water at a predetermined temperature may be discharged from the tapping pipe 13.

In this case, the temperature of the water supply circuit 1 is detected by the temperature sensor S ₁ , and the outlet temperature of the hot water circuit 11 is adjusted by adjusting the distribution ratio of the distributor 2 according to the detection temperature and the set temperature. Irrespective of the set temperature, the predetermined temperature becomes predetermined. Thereby, even if the set temperature is changed, the temperature of the mixed bath can be set directly to the set temperature without a transient state in the temperature of the mixed bath of the tapping tube 13.

The temperature of the mixed bath of the tapping tube 13 is detected by a temperature sensor S ₂ , and the temperature of the hot water circuit 11 is determined from the detection temperature, the temperature of the water supply circuit 1, and the distribution ratio. By calculating and correcting the distribution ratio on the basis of the thus calculated temperature and the predetermined predetermined temperature, the fluctuation of the tapping temperature from the tapping pipe 13 during intermittent use is prevented.

Furthermore, in order to prevent water movement or heat movement between each of the high temperature water circuit 11 and the bypass cycle 3 during hot water stop, a check valve 7 or 7 is provided in each circuit. It is equipped with the structure provided.

By the way, in the hot water heater of this type, the flow rate ratio of the confluence part changes due to the relationship between the non-return valve and each circuit, or a time shift occurs during the opening operation of the non-return valve at the start of hot water supply. There is a drawback that the tapping temperature control performance is lowered.

The present invention has been made in view of this point, and the water supply pipe 13 is joined by joining the hot water supply pipe 14 at the downstream end of the hot water circuit 11 and the water supply pipe 31 at the downstream end of the water circuit. In the cold and hot water mixing device in which the hot water circuit (11) and the hot water circuit (11) and the back circuit prevention valve are inserted into the hot water circuit (11) and the hot water circuit (13), the cold water from the water circuit and the hot water circuit (11) The problem is to improve the tapping temperature regulating performance by allowing the hot water at the start of tapping to be surely and accurately mixed at the start of tapping.

According to claim 1, the technical means of the present invention for solving the above-mentioned problems, the <backflow of the water supply pipe 14 and the water supply pipe 31 in the same direction in the same direction, opening and closing the two outlets at the same time The prevention valve 7 is provided.

The technical means act as follows.

The outlets of the hot water supply pipe 14 and the water supply pipe 31 face in the same direction in parallel, and a backflow prevention valve 7 for opening and closing these two outlets at the same time is arranged. Accordingly, when a discharge pressure is generated at the outlet of the hot water supply pipe 14 and the water supply pipe 31 by opening the tap on the downstream side of the hot water supply pipe 13, the non-return valve 7 simultaneously opens, and in the same direction. Cold and hot water merge at the two outlets which are arranged to face each other, and one pressure hardly gives a direction to the other.

On the contrary, even when the discharge pressure is lost and the check valve 7 is operated, the outlets of the hot water supply pipe 14 and the water supply pipe 31 are simultaneously opened, so that the hot water supply pipe 14 is similar to the case where there is a time difference in the opening timing. ) And the water supply pipe (31) does not cause heat or water movement between each other.

Since the outflow pressure is not influenced at the confluence of the hot water from the hot water supply pipe 14 and the cold water from the water supply pipe 31, the flow rate ratio of the two paths is stabilized, and the cold / hot water mixing accuracy is further improved. do. As a result, the tapping temperature control performance is improved.

Since there is no heat movement or water movement between the hot water supply pipe 14 and the water supply pipe 31 in the non-return valve, the two paths are outflowed at the same time by opening one of the non-return valves. The error of hot water mixing ratio, and thus the temperature of tapping temperature, can be eliminated.

Moreover, since the two paths can be opened and closed by one non-return valve, the structure can be simplified by that amount.

According to claim 2, the present invention provides a hot / cold water mixing ratio even under the condition that the amount of tapping is narrowed when the non-return valve 7 is pushed in the opening direction in the invention of claim 1. The object of the pipe 14 and the water supply pipe 31 is to be stabilized at a predetermined value.

The technical means specified for this purpose is 〈formation in which the normal closing force of the non-return valve 7 is applied, and forms an annular wall 8 surrounding the outlet of the hot water supply pipe 14 and the water supply pipe 31 together. The non-return valve 7 is accommodated in the annular wall 8 so as to have a small outer circumferential interval.

Since the non-return valve 7 has a form in which a pushing force for closing the valve normally acts, the outlets of the tapping pipe 14 and the water supply pipe 31 are closed in the state until tapping is started.

From this state, when tapping is started, the backflow prevention valve becomes an opening degree corresponding to the tapping amount. In the absence of the annular wall 8, the opening degree corresponds to the interval (lift) between the outlet of the hot water supply pipe 14 and the water supply pipe 31 and the non-return valve 7, which is determined by the flow rate from the two paths. When the flow rate is small, the lift amount is a small value. Therefore, at the minimum tapping amount or a flow rate condition close thereto, the hot water supply pipe 14 and the water supply pipe 31 are affected by the relative position and mutual pressure. The flow rate ratio changes from the preset value.

By the way, in the said means, since the backflow prevention valve 7 is accommodated in the annular wall 8 at the shape which has a space | interval a little, the state which the backflow prevention valve 7 fell from the open end of this annular wall 8 exits. The opening degree corresponding to the amount of hot water is obtained. Therefore, even when the amount of tapping water is small, there is a sufficient distance between the hot water supply pipe 14 of the check valve and the outlet of the water supply pipe 31, and after flowing out from these two paths in this space, the tapping pipe 13 on the downstream side is discharged. Since the flow rate is 0, the preset flow rate does not change even under the above conditions. Further, a slight deviation in opening / closing timing of the outlet of the hot water supply pipe 14 and the water supply pipe 31 by the non-return valve 7 (deviation due to the dimensional error between the positions of the outlet of the hot water supply pipe 914 and the water supply pipe 31) ], However, its influence is unlikely to occur.

Therefore, when the tapping temperature is set by adjusting the distribution ratio to the bypass circuit 3 when the cold / hot water mixing device is assembled in a so-called bypass mixing type hot water heater, the tapping temperature in the tapping pipe 13 is set. Since the detection accuracy of is improved, the setting accuracy of the tapping temperature is improved.

Next, embodiments of the present invention described above will be described in detail with reference to the drawings.

The hot water heater employing the cold / hot water mixing device of this embodiment is a hot water circuit 11 through the heat exchanger 12 and a distributor 2 from the water supply circuit 1 on the inlet side to the heat exchanger 12. The bypass circuit 3 which is divided and bypasses the heat exchanger 12, the temperature sensor S ₁ for detecting the water temperature of the water supply circuit ₁ , and the hot water temperature of the tapping tube 13 for detecting the hot water temperature. It is a bypass mixing type hot water heater having a temperature sensor S ₂ and other control device C (not shown) and the like, and is next to the confluence of the high temperature water circuit 11 and the bypass circuit 3. The cold / hot water mixing device of the embodiment is employed, and as shown in FIG. 2, the downstream end 11 of the hot water circuit 11 and the bypass circuit 3 downstream to the casing 5 of the cold / hot water mixing device. The stage and tapping pipe 13 connect the upstream stage.

Example 1

The upstream end of the cylindrical main body portion 51 of the casing 5 is sealed by a hermetic body 30 including a water supply pipe 31 and a connecting portion of the bypass circuit 3, and on the downstream side of the casing 5. The tubular hot water supply pipe 14 provided with the inlet 15 is inserted into the portion, and the tubular body 40 provided with the wing plates 41 and 41 on the downstream side is inserted.

The downstream end of the tubular body 40 is in contact with the end portion 52 provided at the downstream end of the tubular body portion 51, and the hot water pipe 14 is inserted so as to contact the tubular body 40 accommodated in this manner. After that, when the upstream end opening of the cylindrical main-body part 51 is sealed by the sealing body 30, the said each part is assembled in a predetermined state.

In this assembled state, the connecting cylindrical portion 53 protruding from the trunk portion of the cylindrical body portion 51 and the inlet port 15 coincide with each other, and the downstream end of the high temperature water circuit 11 is connected to the connecting cylindrical portion 53. The lower surface of the hot water pipe 14 communicates with the high temperature water circuit 11. Moreover, the downstream part of this hot water supply pipe | tube 14 becomes a flange part which protrudes inward, and the downstream periphery edge of the outlet 16 enclosed by this flange part becomes the valve support 17. As shown in FIG.

In the space 50 formed between the flange portion and the sealing body 30, the water supply pipe 31 provided at the downstream end face of the sealing body 30 protrudes downstream to be coaxial with the outlet 16, and the water supply pipe The tip of 31 is coincident with the valve support 17.

The tubular body 40 protrudes radially the many wing plates 41 and 41 inclined in the same direction from the downstream inner periphery as shown in FIG. 3, and the inner peripheral ends are integrally formed by the cylindrical part 42. As shown in FIG. The tubular portion 42 is coaxially opposed to the water supply pipe 31. Therefore, in the tapping state, since the swirl flow is enabled by the vane plates 41 and 41, the downstream side is stirred by the swirl flow.

In addition, in order to prevent backflow into the bypass circuit 3 and the high temperature water circuit 11, a backflow prevention valve 7 is provided, which is provided at the downstream end of the water supply pipe 31 and the valve support 7. The valve shaft 71 is supported by the tubular portion 42 so that the valve shaft 71 is freely moved forward and backward. In addition, since the downstream ends of the valve support 17 and the water supply pipe 31 are set at the same position, when the reverse flow occurs, the seating surface of the non-return valve 7 comes into contact with each valve support at the same time.

In this embodiment, the cold water flowing into the casing 5 through the water supply pipe 31 and the hot water flowing from the outlet 16 through the inlet 15 and the space 50 from the high temperature water circuit 11 are coaxial. Then, in the state where the flow direction of both becomes the same direction, it joins in the space between the wing plates 41 and 41 and the hot water supply pipe 14. On the downstream side, the joined hot water and cold water are agitated while passing through the wing plates 41 and 41 to flow into the tapping pipe 13 on the downstream side.

Since the temperature sensor S ₂ is disposed downstream of the vane plates 41 and 41, the temperature of the mixing bath sufficiently stirred as described above is detected by the temperature sensor S ₂ , and this detection result is obtained. The distributor 2 is controlled by the output of the controller C, and the tapping temperature is maintained at the set temperature.

Moreover, in this embodiment, as shown in FIG. 4, the water discharge valve 6 is provided which simultaneously discharges water from the circuit on the bypass circuit 3 side and the circuit on the high temperature water circuit 11 side.

For this reason, the 1st water discharge port part 32 which penetrates this radially downward is provided in the upstream part of the water supply pipe 31, and the lower part becomes the enlarged diameter part 33. As shown in FIG. On the other hand, in the cylindrical body part 51, the part which opposes this enlarged diameter part 33 penetrates the 2nd water discharge port part 54, and is carried from the outer peripheral part of this 2nd water discharge port part 54 by the holding cylinder. 55 protrudes downward. The water discharge valve 6 is housed in the holding cylinder 55.

The water discharge valve 6 has a small diameter portion 61 at the tip, an intermediate shaft portion 62 at the lower end thereof, a large diameter portion 63 at the lower side thereof, and furthermore, is connected to the lower portion thereof and the holding cylinder 55 is provided. It consists of a screw shaft portion 64 for screwing in the screw portion in the vicinity of the lower end of the opening. And the diameter of the said intermediate shaft part 62 is set smaller than the diameter of the holding cylinder 55, and larger than the diameter of the 2nd water discharge opening part 54, and the enlarged diameter part 33 is provided in the front-end | tip of the small diameter part 61. The O-ring for securing the airtightness of the coupling portion with the) is placed in contact with the valve support of the lower surface of the second water outlet portion 54 at the boundary between the intermediate shaft portion 62 and the small diameter portion 61 so as to face the second water outlet portion. The 0 ring which seals the 54 is attached to the predetermined | prescribed place, and the 0 ring which ensures the airtightness between the inner peripheral part of the holding cylinder 55, and the large diameter part 63, respectively.

In addition, an inverted L-shaped water discharge passage 60 through which the upstream end opens to the trunk portion of the intermediate shaft portion 62 and the downstream end opens to the lower end of the screw shaft portion 64 penetrates the water discharge valve 6. Formed.

When the water discharge valve 6 is screwed as shown in Fig. 4, the tip of the small diameter portion 61 is inserted into the enlarged diameter portion 33, and at this time, the small diameter portion 61 and the intermediate shaft portion 62 The 0 ring sandwiched between the inner and outer circumferential surfaces of the second water outlet port 54 is in contact with the valve support on the outer circumferential surface of the second water outlet port 54 so that the first water outlet port 32 and the second water outlet port 54 are simultaneously sealed. It becomes the normal use state of a cold / hot water mixing apparatus.

From this state, when the water discharge valve 6 is loosened, the second water discharge port portion 54 is opened, and the zero ring attached to the small diameter portion 61 escapes downward from the enlarged diameter portion 33, The inside of the water supply pipe 31 communicates with the inside of the holding container 55 through the first water discharge port 32, the enlarged diameter portion 33, the space 50, and the second water discharge port 54. Moreover, the space 50 communicates with the inside of the holding cylinder 55 through the opening 18 formed in the lower body part of the hot water supply pipe 14 by opening of the 2nd water discharge port part 54. As shown in FIG. Since the diameter of the intermediate shaft portion 62 is set smaller than the inner diameter of the holding cylinder 55, the inside and the outside of the water discharge valve 6 communicate with each other through the water discharge passage 60, so that the second water discharge portion 54 is formed. A circuit (for example, the bypass circuit 3, etc.) and a circuit (for example, the high temperature water circuit 11, etc.) to communicate with the water supply pipe 31 flowing out from the second water discharge port portion 54 through the space 50. Residual shoes on both sides of the can be discharged from the water discharge passage 60 of the water discharge valve (6). In this case, even if the non-return valve 7 closes both circuits, water discharge is not impeded.

Furthermore, in this embodiment, since the non-return valve 7 which closes the downstream end of the water supply pipe 31 and the valve support 17 at the same time is attached, the water supply pipe 31 side and the hot water supply pipe 14 when the reverse flow condition occurs. The side is opened and closed at the same time, the structure is simplified, and there is no deviation of the opening timing of both circuits, and the fluctuation of the mixing ratio of cold and hot water at the time of tapping can be prevented.

Example 2

The cold / hot water mixing apparatus of this embodiment corresponds to the invention according to claim 2, and as shown in FIG. 5, the annular wall 8 is formed on the outer circumference of the valve support 17, and the non-return valve 7 Except for the configuration in which a spring 73 for imparting a tight pushing force to the valve shaft 71 of the c) is mounted between the non-return valve 7 and the tubular portion 42, the same as in the first embodiment described above. Configuration.

This annular wall 8 is formed integrally with the hot water supply pipe 14, and its inner diameter is set slightly larger than the outer diameter of the non-return valve 7. The interval between the outer diameter of the non-return valve 7 and the inner diameter of the annular wall 8 is set such that the flow rate becomes smaller than the minimum tapping amount from the tapping pipe 13 through the gap, In this case, the diameter difference may be about 0.5 mm. In this way, at the start of tapping, the non-return valve 7 is located downstream of the open end of the annular wall 8 as shown in FIG. 6 against the valve closing force of the spring 73. Sufficient space is formed between the non-return valve 7 and the open end of the water supply pipe 31 and the valve support 17, and after the hot water discharged from the two paths is equalized in the space, the non-return valve It flows out to the tapping pipe 13 from the space | interval of 7 and the edge part of the annular wall 8. As shown in FIG.

Moreover, the height from the valve support 17 to the end of the annular wall 8 is better in the practical range, but the opening of the water supply pipe 31 in the minimum flow rate state when the annular wall 8 is not provided. 2 to 5 times the gap between the stage and the valve support 17 and the non-return valve 7 is sufficient, and when the diameter of the valve support 7 is 18 mm, the height of the annular wall 8 is about 3 mm. The flow rate ratio from the water supply pipe 13 and the hot water supply pipe 14 did not fluctuate even at the start of tapping under the flow rate condition in which the tapping amount was reduced to about 3 liters per minute.

[Other example]

In addition, in each of the above embodiments, the water supply pipes 31 are arranged concentrically in the hot water supply pipe 14, but these relational positions may be reversed, and are also shown in Fig. 7 (a) (b). As described above, the two paths may be provided in parallel. It goes without saying that the cold / hot water mixing device has various uses in addition to the hot water heater internal part shown in FIG.

Claims (2)

The hot water supply pipe 14 at the downstream end of the hot water circuit 11 and the hot water supply pipe 31 at the downstream end of the water circuit are joined to guide the hot water supply pipe 13 to the hot water circuit 11 and the water circuit. In a cold / hot water mixing device in which a non-return valve is inserted, the outlets of the hot water supply pipe 14 and the water supply pipe 31 are disposed in the same direction, and a backflow prevention spit 7 is provided to open and close the two outlets simultaneously. Cold and hot water mixing device. 2. The annular wall (8) according to claim 1, wherein a pushing force for normally closing the non-return valve (7) acts, and an annular wall (8) surrounding the outlet portion of the hot water supply pipe (14) and the water supply pipe (31) is formed, A cold / hot water mixing device in which a non-return valve (7) is accommodated in the annular wall (8) to have a small outer circumferential interval.