JP2009074777A - Hot water supply device having drain neutralizing tank - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hot water supply device capable of preventing releasing of an exhaust gas into a room caused by water leakage of a drain neutralizing tank. <P>SOLUTION: A first partitioning wall 25 drooping from an upper part to a lower part with respect to an inflow port 20 at an inflow port 20 side and defining a lower communication passage 24, and a second partitioning wall 27 vertically disposed to an upper part with respect to an outflow port 21 and the lower communication passage 24 between the first partitioning wall 25 and the outflow port 21 and defining an upper communication passage 26 are disposed in the drain neutralizing tank 15 between the inflow port 20 and the outflow port 21, and further as a water level detecting means 28 of which electric potential changes on the basis of water level, is disposed in a first space 29 between the inlet port 20 and the first partitioning wall 25, and further a safety circuit 35 is disposed to detect the potential change of the water level detecting means 28, stop combustion when the water level is lower than a prescribed value, and lock so that the combustion is not performed until the water level is recovered to be more than the prescribed value, safety can be significantly improved. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a hot water supply apparatus having a drain neutralization tank for neutralizing and draining strongly acidic drain.

Conventionally, in this type, drain water generated when the temperature of exhaust gas drops below the dew point due to heat exchange between the exhaust gas after combustion and the latent heat exchanger, The drain is neutralized and drained, and a water level sensor for detecting the level of the drain water is provided in the drain neutralization tank. (For example, see Patent Document 1)
JP 2003-320380 A

  By the way, with this conventional device, the water level sensor detects an abnormal rise in the water level due to clogging of foreign matter etc. in the drain neutralization tank, and warns, and detects the decrease in drain water due to leakage. Since the drain neutralization tank originally communicated with the exhaust path to circulate the drain water, the exhaust gas also circulated at the same time and the amount of drain water was reduced, so that the drain neutralization tank could easily circulate. There was a risk of being released into the room from the inside.

  This invention pays attention to this point, and in order to solve the above-mentioned problem, in particular, the drain water generated when the exhaust gas after combustion falls below the dew point is used as a drain neutralization tank filled with a neutralizing agent in advance. In what is neutralized by circulating, the drain neutralization tank has an inlet for drain water at the upper part of one side wall, and has an outlet for drain water at a position lower than the inlet of the other side wall. In the drain neutralization tank between the inflow port and the outflow port, a first partition wall that hangs from the upper side to the lower side of the inflow port on the inflow port side to form a lower communication path, and the first partition wall and the flow A second partition wall is provided between the outlet and the outlet and the lower communication path to form an upper communication path, and in the first space between the inlet and the first partition wall, A water level detecting means for changing the potential depending on the water level, detecting a potential change of the water level detecting means, There when drops below a predetermined value, stops the combustion, in which water level with a safety circuit for locking so as not Teki combustion until recovers to a predetermined value or more.

  According to the present invention, when the water level of the drain water is lowered, the water level detection means regards this as an increase in potential, stops combustion through the safety circuit, and combustion continues until the water level recovers to a predetermined value or more. Since it is locked so that it does not come, poisoning accidents due to exhaust gas can be prevented in advance, safety can be improved, and in addition, normally strongly acidic drain water is reliably neutralized and treated Therefore, it is possible to provide a hot water supply apparatus that is extremely easy to use, safe, and safe.

Next, an embodiment of the present invention will be described with reference to the drawings.
Reference numeral 1 denotes a water heater body, which is provided with a combustion chamber 3 with a gun-type burner 2 attached downward at the upper end thereof. Primary heat exchanger 4 is provided.

  5 is a communication path that connects the bottom of the combustion chamber 3 to one end, and an exhaust path 7 that has an exhaust port 6 at the top communicates with the other end. The exhaust gas from the combustion chamber 3 is U-turned through the communication path 5 and exhausted. The gas is discharged from the exhaust port 6 through the path 7.

  The exhaust path 7 is partitioned by a first partition plate 8 upward from a lower communication path 5 and a second partition plate 10, and is communicated only with the first flow path 9 only upward. The second flow path 11 through which the exhaust gas flows downward from the second flow path 11 and the second flow path 11 are communicated only in the lower part, and the third flow path 12 through which the exhaust gas directed from the lower part toward the upper exhaust port 6 flows. A three-layered meandering path is formed in the thickness direction.

  13 is a secondary heat exchanger for recovering the latent heat of the exhaust gas provided in the second flow path 11, and is connected to the primary heat exchanger 4 and the water intake pipe 14. The heated water is passed through the secondary heat exchanger 4 and the temperature is further raised and discharged as hot water as appropriate.

  15 is a drain neutralization tank provided at the lower part of the exhaust path 7, which collects strongly acidic drain water generated by latent heat recovery by the secondary heat exchanger 13, neutralizes it, and drains it from the drain pipe 16. The bottom plate 17 of the exhaust path 7 is inclined, and a collecting tube 18 communicating with the drain neutralization tank 15 is attached to the lowest part thereof.

  The drain neutralization tank 15 is preliminarily filled with a neutralizing agent 19 made of calcium oxide. The drain neutralization tank 15 is provided with a drain water inlet 20 at an upper portion of one side wall and at a position lower than the inlet 20 on the other side wall. Is provided with a drain water outlet 21, and further, in the drain neutralization tank 15 between the inlet 20 and the outlet 21, hangs down from the upper plate 22 below the inlet 20 and between the bottom plate 23. Is a first partition wall 25 that forms a lower communication path 24, and between the first partition wall 25 and the outlet 21, and stands between the outlet 21 and the lower communication path 24 and between the upper plate 22. And a second partition wall 27 having an upper communication passage 26 formed therein, and a flow path meandering up and down.

  Reference numeral 28 denotes a water level detection means comprising a pair of electrodes provided in the first space 29 between the inlet 20 and the first partition wall 25 in the drain neutralization tank 15 and is usually suspended from the upper plate 22. At the time, the tip portion is put in the drain water, and as shown in FIG. 4 in terms of electrical circuit, two resistors 32 and 33 and the water level detecting means 28 are provided between the 5 V power terminal 30 and the base 31. Are connected in series, and between the two resistors 32 and 33 are connected to the input side of a safety circuit 35 comprising a microcomputer via a resistor 34, and the safety circuit is detected by detecting a voltage that changes according to the water level. In the normal state where the drive circuit 36 and the display unit 37 of the water heater main body connected to the output side of 35 are controlled via the safety circuit 35, the tip portion of the water level detection means 28 is slightly submerged in the drain water. The voltage Vx input to the safety circuit 35 is 3.5. In ≧ Vx ≧ 1.5V, be between 3.5V and 1.5V, the safety circuit 35 is one that does not output any.

  However, in a full state where most of the water level detection means 28 is submerged in the drain water, the voltage Vx input to the safety circuit 35 is 1.5 V> Vx and is smaller than 1.5 V, so that the safety circuit 35 Determines that the water is full and sends a signal to the drive circuit 36 and the display unit 37 to stop the combustion and display the full water on the display unit 37. Further, the water level of the drain water decreases due to leakage or the like, and the water level is detected. When the means 28 comes out above the drain water, Vx is inputted as it is with Vx ≧ 5V, and the safety circuit 35 judges that there is an abnormality such as leakage, and sends a signal to the drive circuit 36, and during combustion, Immediately stops the combustion, and if not burning, locks this combustion stop state until a normal signal is input, and prevents the risk of exhaust gas being discharged out of the instrument through the drain neutralization tank 15 It is.

Next, the operation of this embodiment will be described.
When a hot water tap (not shown) at an appropriate location is opened and hot water supply is started, a flow sensor (not shown) detects this hot water flow, and the burner 2 starts combustion. The generated exhaust gas makes a U-turn through the communication path 5 from the combustion chamber 3 and flows into the exhaust path 7, and flows through the second flow path 11 of the exhaust path 7 from the upper side to the lower side, whereby the secondary heat exchanger 13. Heat is exchanged with the feed water flowing into the interior and exhausted from the exhaust port 6.

  The hot water whose temperature has risen in the secondary heat exchanger 13 flows into the primary heat exchanger 4, where it is further heated by heat exchange with the exhaust gas generated by the combustion of the burner 2, and discharged from the hot water tap as hot water. The combustion amount (thermal power) of the burner 2 at this time is such that the temperature of the hot water discharged from the primary heat exchanger 4 is detected by a temperature sensor, and this temperature becomes the hot water supply set temperature set by the user himself / herself. The temperature is adjusted or a mixing valve is provided to adjust the hot water temperature mixed with the feed water to the hot water supply set temperature.

  Next, in the second flow path 11 of the exhaust path 7, the drain water generated by the latent heat recovery of the feed water and the exhaust gas of the secondary heat exchanger 13 is suppressed downward and scattered by the flow of the exhaust gas from the upper side to the lower side. It is prevented, and flows along the inclined bottom plate 17 and is stored in the drain neutralization tank 15 from the collecting pipe 18, neutralized sequentially with the neutralizing agent 19, and then discharged through the drain pipe 16. It is what is done.

  At this time, in the drain neutralization tank 15, drain water is stored from the inlet 20 to the upper end of the second partition wall 27, and drained from the portion exceeding the upper end of the second partition wall 27 through the outlet 21. Further, the water level detection means 28 located in the first space 29 on the inlet 20 side is configured so that the tip portion is submerged by several millimeters in a state where the drain water level stored under the pressure of the exhaust passage 7 is compressed. In this state, the voltage Vx input to the safety circuit 35 is 3.5V ≧ Vx ≧ 1.5V, and is between 3.5V and 1.5V, and the safety circuit 35 does not output anything and combustion continues. The drain water is neutralized and the drained neutralized water is continuously discharged.

  Next, when drain water in the drain neutralization tank 15 leaks for some reason, the water level detection means 28 is exposed to the air before the lower communication path 24 becomes an air flow path, so Vx is Vx ≧ 5V. 5V is input as it is, and the safety circuit 35 determines that there is an abnormality such as leakage, and sends a signal to the drive circuit 36. When combustion is stopped, combustion is stopped immediately. When combustion is not being performed, a normal signal is input. The combustion stop state is locked until the exhaust gas is discharged from the appliance through the drain neutralization tank 15 in advance, and the display unit 37 is in danger due to drain water leakage. indicate.

  Moreover, since the inside of the drain neutralization tank 15 is empty at the first use, the drain neutralization tank 15 is used after it has been filled with priming water or the like.

  Furthermore, when the inside of the drain neutralization tank 15 is clogged with dust or the like, the level of the drain water rises, so that most of the water level detection means 28 is submerged in the drain water, so that the voltage Vx input to the safety circuit 35 Is 1.5V> Vx and becomes smaller than 1.5V, the safety circuit 35 determines that the water is full and sends a signal to the drive circuit 36 and the display unit 37 to stop combustion and display the full water on the display unit 37. It is designed to eliminate clogging by cleaning or the like.

The schematic block diagram of one Embodiment of this invention. Explanatory drawing of the exhaust path. Explanatory drawing of the drain neutralization tank. The block diagram of the principal part electric circuit. The drain neutralization tank explanatory drawing of the same water leak state.

Explanation of symbols

15 Drain neutralization tank 19 Neutralizing agent 20 Inlet 21 Outlet 24 Lower communication path 25 First partition wall 26 Upper communication path 27 Second partition wall 28 Water level detection means 29 First space 35 Safety circuit

Claims (1)

  In the case of neutralizing drain water generated when the exhaust gas after combustion falls below the dew point by circulating a drain neutralization tank filled with a neutralizing agent in advance, the drain neutralization tank has one side wall. A drain water inlet is provided at the top, and a drain water outlet is provided at a position lower than the inlet of the other side wall. Further, in the drain neutralization tank between the inlet and the outlet, the inlet side A first partition wall that hangs down from above the inflow port to form a lower communication passage, and an upper communication between the first partition wall and the outflow port that stands above the outflow port and the lower communication passage. A second partition wall having a passage is provided, and the first space between the inflow port and the first partition wall is provided with a water level detection means whose potential changes depending on the water level, and the potential change of the water level detection means is detected. If the water level falls below a predetermined value, combustion is stopped and the water level is Water heater having a drain neutralization tank, characterized in that with a safety circuit for locking so as not Teki combustion to recovery above value.

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