KR0153716B1 - Heating apparatus - Google Patents

Abstract

The present invention bypasses the heated circuit (1a) passing through the heat exchanger (J) to the heat exchanger (J) heated by the gas burner (B) and bypasses the heat exchanger (J). Branching is made to the circuit 1b, and the heating circuit 1a and the bypass circuit 1b are joined on the downstream side of the heat exchanger J, and each of these two circuits is provided with an open / close control valve to tap water. In the hot water supply apparatus which can be controlled to open and close by the opening / closing control valve control device according to the condition, it is possible to prevent the occurrence of drain in the heat exchanger during the operation of the apparatus, and to freeze each circuit in the mechanism operation stop state. In order to ensure water draining for prevention, a flow rate sensor 3 for measuring the total flow rate of the two circuits is provided upstream of the branch point 11 of the heated circuit 1a and the bypass circuit 1b. The gas burner (B) is installed The thermal power is controlled by the detected water flow and the tapping set temperature of the flow sensor 3, and the combustion is stopped when the detected water quantity is equal to or lower than the minimum set flow rate. The valve 2a is provided in the bypass circuit 1b, and the open / close control valve 2b is respectively provided. In the normal operating temperature range, all of these open / close control valves are opened, and the amount of detection of the flow sensor 3 is minimum. When the flow rate is less than the set flow rate, only the opening / closing control valve 2a is closed and a control device is provided to close only the opening / closing control valve 2b during hot water supply.

Description

Hot water device

1 is an explanatory diagram of a hot water supply apparatus according to the present invention.

2 is a block diagram of a control system.

3 is a block diagram of another control system.

4 is an explanatory diagram when the on-off control valve is a pilot solenoid valve.

* Explanation of symbols for main parts of the drawings

B: Gas Burner J: Heat Exchanger

1: water supply circuit 1a: heated circuit

1b: bypass circuit 11: branch point

3: flow sensor 2a: on-off control valve

2b: on / off control valve

The present invention relates to a hot water supply device, in particular a hot water supply device having a heat exchanger of a bypass mixing method.

In recent years, the hot water supply system is used to prevent corrosion by drainage of the heat exchanger, or to prevent cold water sandwiching during re-reheating (temporary discharge of cold water after the hot water is discharged during re-elution). A so-called bypass mixing method is adopted in which the feed water circuit is branched into a heated circuit passing through the heat exchanger and a pipe pass circuit bypassing the heat exchanger and joined on the downstream side of the heat exchanger. In such a hot water supply device, by controlling the ratio of the flow rate to the heated circuit and the flow rate to the bypass circuit, the temperature of the heat exchanger can be maintained at a relatively high temperature regardless of the amount of tapping or the tapping temperature. Drain generation can be prevented. In addition, the cold water sand phenomenon can be easily prevented according to the control mode.

By the way, in this kind of hot water supply apparatus, the said to-be-heated circuit and the bypass circuit are always open.

On the other hand, when the total flow rate is extremely small, the gas burner for heating the heat exchanger may be in a combustion stop state, and in this case, drainage is likely to occur in the heat exchanger.

In order to solve this problem, a control valve of an upper-closing type downstream of the branch point branched from the bypass circuit in the circuit to be heated is always open to the bypass circuit.常 開 形: Japanese Patent Application Laid-open No. Hei 5-180510 proposes to provide control valves of a type such that valves are always open, and to open and close the control valves in accordance with tapping conditions and the like.

In the proposed hot water supply device, under a very low flow rate condition in which the gas burner cannot be burned, drain generation in the heat exchanger can be prevented by closing the control valve installed in the circuit to be heated, that is, blocking the heat exchanger side passage. have.

In addition, since the control valve of the bypass circuit is opened and the control valve of the heated circuit is closed, the cold water can be discharged as it is from the hot water supply device while the operation of the hot water supply device is stopped. At this time, since cold water does not flow to the side to be heated, drain generation in the above state can be prevented.

However, in this type of hot water supply device, since the upstream end of the circuit to be heated is blocked by the upper closed type control valve, the part of the heated circuit even if the water is drained to prevent freezing of the water channel in the stopped state of the hot water supply device. Since water cannot be drained off, there is a fear that the portion of the heating circuit to be damaged is caused by freezing.

The present invention has been made in view of this point, and the " passing the water supply circuit 1 to the heat exchanger J heated by the gas burner B through the heat exchanger J upstream of the heat exchanger J. Branching to the to-be-heated circuit 1a and the heat exchanger J by the bypass circuit 1b, and downstream of the heat exchanger J, the to-be-heated circuit 1a and the bypass circuit 1b. ), And a hot water supply device in which two open circuit control valves are provided in each of the two circuits so that the open / close control valve can be controlled by the open / close control valve controller according to the tapping condition. It is an object of the present invention to be able to prevent the occurrence of drainage and to ensure the draining of water for preventing the freezing of each circuit in the state of stopping the operation of the apparatus.

The technical means of the present invention for solving the above problems is "flow rate sensor (3) for measuring the total flow rate to the two circuits upstream of the branch point (11) of the heating circuit (1a) and bypass circuit (1b). The gas burner (B) is configured such that the thermal power is controlled by the detection water flow and tapping set temperature of the flow sensor 3, and the combustion is stopped when the detection water amount is below the minimum set flow rate. The open / close control valve 2a is provided in the heating circuit 1a, and the open / close control valve 2b is provided in the bypass circuit 1b, respectively. When the amount of detection of the flow sensor 3 is less than or equal to the minimum set flow rate, only the opening / closing control valve 2a is closed, and at the time of high temperature hot water supply, a control device is provided so as to close only the opening / closing control valve 2b.

The technical means act as follows.

When the hot water in the normal temperature range is used, both the open / close control valves 2a and 2b are kept open, so that the hot water on the side of the heating circuit 1a and the cold water on the bypass circuit 1b side are joined at the point where the two circuits join. Mixed and tapped.

On the other hand, at the time of high temperature tapping, only the opening / closing control valve 2b closes the valve to supply water through the heated circuit 1a side, so that the hot water on the heated circuit 1a side is tapped out as it is.

When the amount of detection of the flow rate sensor 3 reaches the minimum flow rate, only the on / off control valve 2a closes the valve by the output thereof, so that water of this flow rate is discharged from the hot water supply device through the bypass circuit 1b side. do.

At this time, the gas burner B is not burned and the heat exchanger is in a non-heated state. However, since water does not flow into the heated circuit 1a including the heat exchanger, it is possible to prevent the occurrence of drainage.

In the operation stop state, since the opening / closing control valves 2a and 2b are all open type, when the draining upstream side of the heating circuit 1a and the bypass circuit 1b is opened when water is drained to prevent freezing, The water downstream of the heated circuit 1a and the bypass circuit 1b can be completely drained.

Since the circuit on the side of the heating circuit 1a is cut off when the detection quantity of the flow sensor 3 is equal to or less than the minimum set flow rate, the gas burner B is not burned, that is, the heat exchanger is not heated. Drain generation by passing through the pass circuit 1b can be prevented.

In addition, since water in the heating circuit 1a and the bypass circuit 1b can be reliably discharged when draining water for freezing prevention, freezing due to the presence of so-called deceased remains in a part of the water supply circuit 1. There is no concern.

EMBODIMENT OF THE INVENTION Hereinafter, the Example of this invention is described in detail based on drawing.

In the embodiment of the present invention, as shown in FIG. 1, the combustion amount of the gas burner B for heating the heat exchanger J is controlled by the proportional valve V. As shown in FIG. Moreover, the flow sensor 3 is provided in the upstream of the branch point 11 of the to-be-heated circuit 1a and the bypass circuit 1b in the water supply circuit 1 which supplies water to the heat exchanger J, The main valve 31 is provided in the inlet side circuit 10 connected to the water supply circuit 1 by the joint 32. Therefore, the amount of water supplied to the water supply circuit 1 is detected by the flow sensor 3.

The open / close control valve 2a is provided in the heated circuit 1a passing through the heat exchanger J, and the open / close control valve 2b is provided in the bypass circuit 1b bypassing the heat exchanger J. These open / close control valves 2a and 2b are all open type solenoid valves.

The water supply 13 is connected to the downstream side of the confluence point 12 of the heated circuit 1a and the bypass circuit 1b. Moreover, the temperature sensor S which detects the temperature downstream of the confluence point 12 is provided between the said confluence point 12 and the water supply 13.

In addition, in this embodiment, as shown in FIG. 2, in the tapping temperature setter 4, the detection temperature detected by the temperature sensor S and the tapping temperature can be set between 35 ° C and 85 ° C. The set value and detection amount from the flow sensor 3 are input to the control unit C, and the opening degree of the proportional valve V is controlled by the output from the control unit C, and at the same time, the opening / closing control valve 2a 2b) is controlled.

For example, when the tapping temperature is set to the normal use temperature, the control device C maintains the open / close control valves 2a and 2b open, and also detects the amount of water detected by the flow sensor 3 and the set temperature. The amount of combustion gas of the gas burner B is calculated and the opening degree of the proportional valve V is set accordingly. Thus, it can be obtained at the confluence point 12 of the set temperature. In addition, even if the opening degree of the water supply 13 is changed on the downstream side of the confluence point 12 and the tapping amount is changed, the tapping temperature is set to the set temperature because the control device C sequentially executes the calculation according to the tapping amount change. maintain.

Since the opening degree of the water supply 13 at the downstream side of the confluence point 12 becomes extremely narrow, when the detection water amount of the flow sensor 3 becomes the minimum set water amount, the opening / closing control valve ( 2a) is in a conductive state, the valve is closed, and only the open / close control valve 2b is in a non-conductive state and the valve is kept open so that water does not pass through the heat exchanger J. Therefore, it is possible to prevent the occurrence of drainage caused by passing cold water in the state of excess heat.

When the set temperature is set to a predetermined high temperature (for example, 80 ° C. or more), the open / close control valve 2a is in a non-conductive state, the valve is kept open, and the open / close control valve 2b is in a conductive state. The valve is kept closed. Accordingly, water passes only through the side of the heating circuit 1a, and the amount of combustion gas under this condition is calculated to set the opening degree of the proportional valve V corresponding thereto.

When the operation is stopped, the valve is returned to the open state because the open / close control valves 2a and 2b are all open type solenoid valves. In this state, in order to drain the water to prevent freezing, the main valve 31 is closed and the water supply 13 is opened. The said main valve 31 is well-known in the form which communicates the downstream side to the atmospheric side, and cuts off an upstream circuit in the state in which the valve was closed. Therefore, since all the water in the circuit of the to-be-heated circuit 1a and the bypass circuit 1b is discharged | emitted by the said water drain in the water supply 13, there is no possibility that a standing person may remain.

In addition, as shown by the imaginary line of FIG. 1, when the air suction valve body 33 is provided separately in the downstream of the main valve 31, it is necessary to make the main valve 31 the special structure as mentioned above. It may be a normal on-off valve without. In addition, a drain valve dedicated to draining water may be provided separately from the water supply station 13 to drain water.

In addition, in the present embodiment, as shown in Figs. 1 and 2, when the operation switch SW installed in the remote controller is turned on, the temperature sensor S, the flow sensor 3, and the control device C are turned on. The output of the control device C is configured to operate each output device such as an open / close control valve.

The present invention is different from the above embodiment, as shown in FIG. 3, the flow rate sensor 3 is connected directly to the flow rate sensor 3 and the on / off control valve 2a without the operation switch SW. Control unit C1 for detecting the flow rate at all times, and closing the valve by bringing the on / off control valve 2a provided in the heated circuit 1a into a conductive state when the flow rate sensor 3 detects the flow rate. It is also possible to provide a configuration such that the auxiliary control device (C1) is always supplied with electricity.

In this embodiment, since the power is always supplied to each of the above-mentioned parts regardless of whether the operation switch SW is opened or closed except when the power plug is unplugged or in the case of a power failure, after the hot water stop or the operation switch ( Even after the water supply 13 is opened and the cold water flows through the water heater immediately after the SW) is turned "OFF", since the open / close control valve 2a is closed by the output of the auxiliary control device C1, the cold water is The problem which flows into the non-heating circuit 1a provided with the heat exchanger J is eliminated.

When the water does not flow, that is, when the output of the flow sensor 3 is "0", both the on-off control valve 2a and the on-off control valve 2b are kept open.

It is also possible to further employ a water flow switch for the flow sensor 3 as an input device for the auxiliary control device C1 for determining the presence or absence of water flow.

In addition, the open / close control valves 2a and 2b may be pilot solenoid valves as shown in FIG.

The pilot solenoid valve shown in FIG. 4 is comprised from the electromagnet 5 and the valve apparatus 6. As shown in FIG. The main circuit and the pilot circuit are formed in the valve box 60 of the valve device 6. An upper diaphragm valve 62 is provided to face the valve seek 61 formed in the file circuit at intervals therebetween, and is formed by the diaphragm valve 62 and the electromagnet 5 attachment portion. The partition plate 63 is partitioned into a first chamber 64 on the electromagnet 5 side and a second chamber 65 on the diagram valve 62 side.

The first chamber 64 communicates with the upstream side of the valve seat 61, and the second chamber 65 communicates with the downstream side of the open / close control valve 2b provided in the bypass circuit 1b. In addition, a leak hole 66 is formed in the circumferential wall of the second chamber 65 in the valve box 60, and the open / close control valve 2b provided with the leak hole 66 in the bypass circuit 1b. Is connected so as to communicate with the downstream side.

In addition, a valve hole 67 is formed in the partition plate 63, and the valve body 52 attached to the tip of the rod 51 of the electromagnet 5 faces the valve hole 67. When the electromagnet 5 is in a non-conductive state, the rod 51 is supported by the spring in a direction protruding therefrom, and when the electromagnet 5 is in a conductive state, the rod 51 is retracted against the holding force of the spring. .

The pilot solenoid valve has a diaphragm valve 62 open when the electromagnet 5 is in a non-conductive state, but the rod 51 is pulled up when the electromagnet 5 is in the "on" state. As a result, the valve body 52 is opened and the pilot is routed from the upstream side of the valve seek 61 to the first chamber 64 to the valve life 67 to the second chamber 65 to the leak life 66. The flow path is in communication. Since the leak amount of the leak hole 66 is set to a predetermined value in advance based on the relationship with the absorption pressure, and the orifice 69 is formed on the outlet side of the open / close control valve 2b, the valve box 60 The diaphragm valve 62 is closed by the pressure difference between the main circuit and the pilot circuit in the circuit.

Similarly to the on-off control valve 2a, the on-off control valve 2b adopts a differential pilot solenoid valve, and the leak hole 66 and the downstream side of the orifice 69 communicate with each other. Similarly to the opening / closing control valve 2a, when the electromagnet 5 is brought into a conductive state, it is closed.

As described above, when the open / close control valves 2a and 2b are differential type pilot solenoid valves, the power consumption when closing the valve is lower than that of the direct type upper solenoid valve.

Claims (2)

The heated circuit 1a and the heat exchanger J passing the water supply circuit 1 to the heat exchanger J heated by the gas burner B through the heat exchanger J upstream of the heat exchanger J. ) Is diverted to the bypass circuit 1b bypassing the heat exchanger J, and the heated circuit 1a and the bypass circuit 1b are joined on the downstream side of the heat exchanger J. In a hot water supply device in which an open / close control valve is provided so that the open / close control valve can be controlled by the open / close control valve control device according to a tapping condition, the hot water supply device includes the above-mentioned two points on the upstream side of the branch point 11 of the heated circuit 1a and the bypass circuit 1b. A flow rate sensor 3 for measuring the total flow rate into the circuit is provided, and the gas burner B has its fire power controlled by the detection flow and the tapping set temperature of the flow sensor 3, and the detection quantity The combustion is stopped when the flow rate is lower than the minimum set flow rate. Opening and closing control valves 2b are respectively provided in the furnace 1a, and all of these opening and closing control valves are opened in the normal use temperature range, and when the detection water amount of the flow sensor 3 is below the minimum set flow rate, the opening and closing control is performed. A hot water supply device comprising a control device for closing only the valve (2a) and closing only the opening / closing control valve (2b) during high temperature hot water supply. The hot water supply apparatus according to claim 1, wherein the open / close control valves (2a, 2b) are both pilot solenoid valves of differential type.