JPH0350367Y2 - - Google Patents

Description

[Detailed explanation of the idea] Technical field The present invention relates to a direct contact hot water heater.

BACKGROUND ART A typical prior art direct contact hot water heater is
An endothermic chamber is formed above the combustion chamber, and water is sprinkled from above the endothermic chamber toward the endothermic material filled in the endothermic chamber, and the water and combustion gas from the burner such as gas provided in the combustion chamber are sprayed. It has a structure that performs heat exchange and heats by directly contacting the

Problems to be Solved by the Invention In such prior art, combustion in the burner starts at the same time as water spraying starts, so by the time water has penetrated to the lowest part of the heat absorbing material, the walls of the combustion chamber and the heat absorbing material are damaged. The lower part is superheated, so hot water at a high temperature is supplied at the start of hot water supply.
Furthermore, since the combustion chamber and the lower part of the heat absorbing material are overheated, damage to these parts is likely to occur. Furthermore, when the hot water supply is stopped, the combustion of the burner is stopped at the same time as the water sprinkling is stopped, so there is a drawback that unheated, low-temperature water accumulates in the lower part of the combustion chamber.

An object of the present invention is to provide a direct contact type hot water heater that can always obtain hot water at a desired constant temperature by shifting the timing of water sprinkling and burner combustion.

Means for Solving the Problems The present invention forms a combustion chamber equipped with a burner in a cylindrical body, forms an endothermic chamber filled with an endothermic material above the combustion chamber, and injects water from above the endothermic chamber. A direct contact type hot water heater that sprays water and brings the water into direct contact with combustion gas from a combustion chamber, characterized by staggering the timing of water spraying and burner combustion to always obtain hot water at the desired temperature. This is a direct contact hot water heater.

In a preferred embodiment, at the start of operation, water spraying is first started, and combustion in the combustion chamber is started when a time W1 approximately equal to the time required for the water to reach the combustion chamber has elapsed. shall be.

In a preferred embodiment, when the operation is stopped,
The present invention is characterized in that combustion in the combustion chamber is stopped after a time W2 that is approximately equal to the time required for water to flow down from the heat absorbing material has elapsed after the water spraying has stopped.

According to the present invention, a combustion chamber equipped with a burner is formed in a cylindrical main body, and an endothermic chamber filled with an endothermic material is formed above the combustion chamber. Hot water can be obtained by spraying water from above the heat absorption chamber toward the heat absorption material and bringing the water into direct contact with the combustion gas from the combustion chamber to perform heat exchange.

At the start of hot water supply, the burner is ignited after a delay of approximately the same amount of time as the time required for the sprinkled water to flow down the heat absorbing material and reach the combustion chamber after the start of water sprinkling. Therefore, supply of high-temperature hot water at the start of hot water supply is prevented. Furthermore, since combustion in the burner starts after a water film begins to form on the wall surface of the combustion chamber and water permeates into the heat absorbing material, deterioration of the heat absorbing material and the combustion chamber can be suppressed.

When hot water supply is stopped, combustion in the combustion chamber is stopped after a period of time approximately equal to the time required for the sprinkled water to flow down from the heat absorbing material after the water sprinkling is stopped. Therefore, after the hot water supply is stopped, unheated low-temperature water is prevented from accumulating in the lower part of the combustion chamber.

Embodiment FIG. 1 is a sectional view of a direct contact hot water heater 1 according to an embodiment of the present invention. A hot water storage section 3 is formed at the lowest part of the heater main body 2, which is formed into a right cylindrical shape. A combustion chamber 4 is formed above this hot water storage section 3 . In this combustion chamber 4, combustion is performed by a burner 5 attached to the side of the heater body 2. Combustion air is force-fed from a centrifugal blower 6 to the burner 5, and fuel gas is supplied from a conduit 7 via a fuel cutoff valve 18. Combustion exhaust gas from the burner 5 is exhausted to the outside from an exhaust pipe 8 at the top of the heater body 2. A heat absorption chamber 9 is formed above the combustion chamber 4, and this heat absorption chamber 9 is separated from the combustion chamber 4 by a perforated plate 10 made of a heat-resistant material such as metal. The top is filled with heat absorbing material 11. A water sprinkling chamber 12 is formed above the heat absorption chamber 9 , and in this water sprinkling chamber 12 , water is supplied from a water supply nozzle 15 via a solenoid valve 17 and an electric flow control valve 14 . Water is sprayed toward the heat absorbing material 11. A cooling conduit 16 is provided directly above the perforated plate 10, and water is supplied to this cooling conduit 16 from an electric flow control valve 14 to cool the perforated plate 10.

The electric flow rate control valve 14 can continuously and steplessly adjust the flow rate of water through the conduit 13 in response to an output from a control means (not shown).

Burner 5 is a so-called blast burner,
Combustion air pressure-fed from the centrifugal blower 6 is passed from the air chamber 21 to the burner body 23 via the rectifying plate 22.
evenly supplied. This burner 5 is provided with a pilot burner 24. While the hot water heater 1 is in operation, the pilot burner 24 is lit and the centrifugal blower 6 is in operation. The main body 23 ignites. In this way, the burner 5 enters a combustion state in which the pilot burner 24 and the burner body 23 are ignited. Fuel cutoff valve 1
8 is controlled by a control means (not shown) similarly to the electric flow control valve described above. Since a constant amount of fuel gas is always supplied during combustion in the burner 5, the amount of heat generated by combustion in the burner 5 is constant. In addition to gas, the fuel for the burner 5 may be a liquid fuel such as petroleum, or a solid fuel such as coal.

The perforated plate 10 has a shape such as a cone shape or a pyramid shape, which has an inclined surface that forms a water film on both upper and lower surfaces of the top portion 10a and allows water to flow down the entire circumference. A large number of holes 10b capable of forming a water film are formed.

The water supplied from the pipe line 13 is passed through the water supply nozzle 15
Water is sprinkled from the heat absorbing material 11 to exchange heat with the combustion gas from the combustion chamber 4 through direct contact with the combustion gas from the combustion chamber 4, and the water flows through the down pipe 26 formed on the bottom plate 25 along the wall surface of the combustion chamber 4 to the hot water storage section 3. flows into and is stored. The lower end of the downpipe 26 is formed above the bottom plate 40 by a height of 1.

The hot water stored in the hot water storage section 3 is taken into the pump 32 from the pipe line 31, and is supplied to the hot water supply pipe 34 through the flow rate control mechanism 33 from the pipe line 48. The pump 32 rotates at a constant speed, and the flow rate of hot water supplied to the hot water supply pipe 34 is adjusted by the flow rate control mechanism 33 according to the water level in the hot water storage section 3 . A plurality of bells 35 are attached to the tip of the hot water supply pipe 34 (only one of the bells 35 is shown in FIG. 1).

By providing the hot water storage section 3 in this manner, hot water can be stably supplied even if the amount of hot water supplied is relatively large. In addition, even when starting hot water supply and when the amount of hot water supplied is small, high-temperature hot water is not supplied, and on the other hand, when the amount of hot water being supplied is large, the temperature of the hot water does not drop. , you will always be able to obtain hot water at the desired constant temperature. Further, the flow rate of water sprinkled on the heat absorbing material 11 is larger than the amount of hot water supplied when a few of the plurality of bells 35 are opened, so even when a small number of the bells 35 are opened, the combustion chamber 4 and There is no possibility that the temperature of the heat absorption chamber 9 becomes excessively high. Furthermore, for example, the burner body 23
The burner 5 can be stably burned without frequently repeating ignition and extinguishing.

The pump 32 may be of a centrifugal type or an axial type, for example. Pipe line 31 that supplies hot water to pump 32
The upper end of the water intake port 46 is formed at a height of 2 from the bottom plate 40, and a temperature detection element 47 is provided near the water intake port 46.

FIG. 2 is a sectional view of the vicinity of the flow rate control mechanism 33. The hot water discharged from the pump 32 flows through the pipe 48
from there to the valve chamber 51 of the flow rate control mechanism 33. The force acting on the float 52 floating in hot water in the hot water storage section 3 is transmitted to the lever 60. lever 60
is fixed to one end of the lever 54 by a pin 61. The lever 54 is swingably supported by a bracket 53 attached to the wall of the hot water storage section 3 by a pin 62. The other end of the lever 54 is
The valve stem 55 is supported by the pin 63 so as to be freely angularly displaceable. The force thus transmitted to the lever 60 is transmitted to the valve body 56. The valve body 56 is biased by a spring 57 in the direction of seating on the valve seat 58 .

Therefore, when the water level in the hot water storage section 3 is lowered, the float 52 descends, the flow path cross-sectional area of the valve hole 59 becomes smaller, and the flow rate of hot water supplied to the hot water supply pipe 34 becomes smaller. Further, when the water level in the hot water storage section 3 is high, the float 52 rises, the flow passage cross-sectional area of the valve hole 59 becomes large, and the flow rate of hot water supplied to the hot water supply pipe 34 becomes large. In this way, the flow rate control mechanism 33 sets the upper limit of the hot water flow rate to the flow rate corresponding to the amount of hot water stored in the hot water storage section 3, that is, the same flow rate as the amount of water sprinkled on the heat absorbing material 11, and the hot water supply pipe 34 Since hot water is supplied to the hot water storage section 3, the water level in the hot water storage section 3 does not drop suddenly, and hot water can be used continuously. Also, the flow rate control mechanism 33
When the water level in the hot water storage section 3 becomes less than the third water level 3, the valve body 56 seats on the valve seat 58 and closes the hot water supply pipe 34.
Hot water supply to the area will be cut off. This third water level 3
At a water level exceeding the upper limit, hot water is supplied at a flow rate less than the upper limit.

An overflow pipe 36 is formed in the hot water storage section 3, and when the water level in the hot water storage section 3 reaches a level exceeding this overflow pipe 36, it is discharged from the overflow pipe 36 to the outside via a drain pipe 43. be done. Water level detection elements 37 to 39, which are water level detection means, are attached to the wall surface of the hot water storage section 3. The water level detection element 37 provided in the upper part of the hot water storage part 3 detects the first water level H, and the water level detection element 3
The water level detection element 38 provided below the second
The water level M is detected, and the water level detection element 39 provided below the water level detection element 38 detects the lower limit value L of the water level. The outputs of these water level detection elements 37 to 39 are given to the control means. When the hot water in the hot water storage section 3 is used and the water level falls to the second water level M, the control means performs water sprinkling and combustion in the burner 5 until the water level returns to the first water level H. The water level detection elements 37 to 39 may, for example, detect whether water is submerged based on the difference in dielectric constant between water and air, or may detect whether water is submerged using the dielectric constant of water. It may also be something that detects.

A pipe line 41 is connected to the bottom plate 40 of the hot water storage section 3 , and this pipe line 41 is connected to a drain pipe 43 via a drain valve 42 . Therefore, when not in use for a long period of time, by opening the drain valve 42,
All the water in the hot water storage section 3 can be discharged. A riser pipe 44 with a height of 4 is also formed on the bottom plate 40 of the hot water storage section 3, and this riser pipe 44 is connected to a drain pipe 43 via a solenoid valve 45 that can be opened and closed. The above water levels H, M, heights 1, 2,
4 and the lower limit L are selected as shown in the formula below.

1<2<L≦4<M<H (1) Therefore, by opening the solenoid valve 45, the water level in the hot water storage section 3 is lowered to a height of 4, but the lower end of the down pipe 26 Since the section is formed at a height 1 lower than this height 4, water sealing of the combustion chamber 4 is achieved, and combustion gas is prevented from entering the hot water storage section 3 from the combustion chamber 4. Instead of the drain valve 42,
By providing a solenoid valve 45 in the conduit 41, all of the hot water in the hot water storage section 3 may be discharged by opening the solenoid valve 45. Also, pipe line 3
Since the water intake port 46 of No. 1 is also formed at the height 2, which is lower than the height 4, air will not get caught in the hot water supplied to the hot water pipe 34.

Since the height 3 is selected to be greater than the lower limit L, the water level may be lower than the lower limit L due to an abnormality in the flow rate control mechanism 33, etc.
When the water level detecting element 39 detects that the water level has decreased by more than 100, the operation of the pump 32 is stopped and the water seal is maintained.

In the hot water heater 1 configured in this way, the water to be heated comes into direct contact with the combustion gas in the process of flowing down from the heat absorption chamber above the combustion chamber 4 to the hot water storage section 3 below, so that thermal efficiency is improved. Moreover, unlike conventional boilers that obtain hot water in a closed container, the system heats water under atmospheric pressure, so it can be easily used in ordinary households. Furthermore, the hot water obtained is
This hot water has dissolved oxygen and is good for rust prevention, and also contains carbon gas contained in combustion gas, so when used for bathing, it can be used as is for recovering from fatigue. It has an effect that hot water heated in a bathtub does not have.

Moreover, in the process of heating hot water, the perforated plate 1
0 has a slope that allows water to flow down the entire circumference by forming a water film on both its upper and lower surfaces, and the holes 10b provided in large numbers on the slope can form a water film due to surface tension, Moreover, since the heat absorbing material 11 is arranged in such a manner that the heat absorbing material 11 does not protrude from the lower surface of the perforated plate 10, the heat absorbing material 11
The water that is sprinkled on top and falls forms a water film along both the upper and lower surfaces of the perforated plate 10 and flows down.
Since water droplets do not fall into the combustion chamber 4 from b, the burner 5 in the combustion chamber 4 will not misfire or the combustion condition will not deteriorate. In addition, the water that has flowed down through the heat absorbing material 11 forms a water film along both the upper and lower surfaces of the perforated plate 10 and the entire wall surface of the combustion chamber 4 and flows down, overheating the perforated plate 10 and the wall surface of the heater main body 2. Moreover, the contact area between the combustion gas and water increases, thereby making it possible to further improve thermal efficiency.

FIG. 3 is a flowchart for explaining the operation. Move from step n1 to step n2,
When the start switch is turned on, the solenoid valve 45 is closed in step n3, and the discharge of hot water stored in the hot water storage section 3 is stopped. Also, the pilot burner 24 is ignited and the pump 32 is started. In step n4, the centrifugal blower 6 is started.

In step n5, water temperature T1 near the water intake 46 is detected by the temperature detection element 47, and step
In n6, this water temperature T1 is the predetermined desired temperature T
It is determined whether it is smaller than 0, and if so, the process moves to step n7, where the electric flow rate control valve 14 is throttled down to reduce the amount of water supplied to the water supply nozzle 15, and the process moves to step n9; if not, the process moves to step n8. Then, the electric flow rate control valve 14 is throttled down to a flow rate corresponding to the set temperature, and the process moves to step n9. The temperature T0 is set to, for example, 60°C. In step n9, the solenoid valve 17 is opened and water is started to be sprayed from the water supply nozzle 15 toward the heat absorbing material 11 at the flow rate adjusted in step n7 or step n8. At step n11, the fuel cutoff valve 18 is opened and the burner body 2 is delayed by a time W1 that is approximately equal to the time required to reach the
3 ignites.

In this way step n7 or step n8 is
Temperature T1 detected by temperature detection element 47
and a predetermined desired temperature T0, the control means controls the electric flow rate control valve 14,
Since the temperature of the hot water flowing into the hot water storage section 3 is adjusted, the temperature T1 drops to, for example, 20°C when the operation is resumed, such as in the morning.
In this way, when the temperature difference is large, hot water with a high temperature is generated, and when the temperature difference is small, hot water with a temperature close to the desired temperature T0 is generated. Therefore, the hot water storage section 3 can always store hot water at the desired constant temperature T0.

Also, after watering is started in step n9, it is delayed by time W1 in step n10, and
Since the burner body 23 is ignited at n11, the burner body 23 is prevented from being ignited before water permeates into the heat absorbing material 11, and therefore high-temperature hot water is prevented from flowing into the hot water storage section 3. . Since combustion in the burner 5 is performed after water has permeated into the heat absorbing material 11 and a water film has started to be formed on the wall surface of the combustion chamber 4, deterioration of these parts can be suppressed.

In step n12, it is determined whether the water level in the hot water storage section 3 is equal to or higher than the first water level H that can be detected by the water level detection element 37, and if so, step
Moving on to n13, the solenoid valve 45 is opened for a time W4, and even if newly generated hot water flows into the hot water storage section 3, the water level in the hot water storage section 3 remains at the first water level H, which is an appropriate amount.
The water whose temperature has decreased is discharged to the drain pipe 43 so that the temperature is between the second water level M and the second water level M. This time W4 is
It is determined according to the temperature difference between a predetermined desired temperature T0 and the actual hot water temperature T1. Therefore, the larger the temperature difference is, the longer the time W4 is, and the longer the time W4 is
Even if watering is performed until the temperature T1 of the hot water inside reaches the temperature T0, there is no risk that the hot water storage section 3 will overflow. The relationship between temperature difference and time W4 is
It is shown in FIG.

In step n14, it is determined whether the stop switch has been operated, and if not, the step
The process moves to step n15, and it is determined whether the water level in the hot water storage section 3 has recovered to the first water level H. If not, the process returns to step n5. When the water level has recovered to the first water level H, the process moves to step n16, where the electromagnetic valve 17 is closed to stop water sprinkling from the water supply nozzle 15. After a delay of a time W2 approximately equal to the time required for this, for example 2 to 3 seconds, the fuel cutoff valve 18 is closed in step n18 and the burner 23 is extinguished. In this way, the generated hot water is used and the water level is raised to the second water level M in step n19.
If it is determined that the level has decreased to
Return to By repeating the operations from step n5 to step n19, hot water at a constant temperature T0 reaches the first water level H.
will be stored up to.

Also stop watering in step n16, and step
After a delay of time W2 in step n17, by extinguishing the burner body 23 in step n18, the unheated, low-temperature water flows into the hot water storage section 3, and the temperature of the hot water in the hot water storage section 3 increases. This will prevent this from dropping. Therefore, the temperature of the hot water stored in the hot water storage section 3 can be maintained at a predetermined desired constant temperature T0.

When the water level in the hot water storage section 3 is less than the first water level H in step n12, the process moves to step n20;
It is determined whether the water level is less than the lower limit L,
Otherwise, that is, when the water level is greater than or equal to the lower limit value L and less than the first water level H, the process moves to step n14, and hot water is generated as described above until the water level reaches the first water level H. When the water level is less than the lower limit L in step n20, that is, even if hot water continues to be used beyond the second water level M, the amount of hot water flowing into the hot water storage section 3 will decrease due to an abnormality in the flow rate control mechanism 33 or the like. When the amount of hot water supply cannot keep up, in order to maintain a water seal, the solenoid valve 17 and the fuel cutoff valve 18 are closed in step n21, water sprinkling and combustion of the burner 5 are stopped, and the pump 32 and centrifugal blower 6 are turned off. It stops and generates an alarm in step n22.

When the stop switch is operated in step n14, the process moves to step n23, in which the solenoid valve 17 is closed to stop water sprinkling from the water supply nozzle 15, and the solenoid valve 45 is opened, and the hot water in the hot water storage section 3 is discharge begins. After a delay of a predetermined time W3 in step n24, the fuel cutoff valve 18 is closed in step n25, the burner body 23 and the pilot burner 24 are extinguished, and the pump 32 is
Then, the centrifugal blower 6 is stopped, and all operations are completed in step n26.

In this way, watering is stopped in step n23, and after a delay of time W3 in step n24, the burner body 23 is extinguished, so that the heat absorbing material 11 and the perforated plate 10 are brought into a so-called dry firing state and are dried with hot air. , it is possible to obtain a sterilization effect that suppresses the growth of bacteria and algae, and it is possible to supply hygienic hot water. In this case, the time W3 is selected to be, for example, about 10 seconds so that the temperature of the heat absorbing material 11 and the perforated plate 10 is 200 to 300°C or higher. Instead of drying the burner body 23 for the time W3 to dry the heat absorbing material 11 and the perforated plate 10, only the pilot flame by the pilot burner 24 may be lit for a relatively long time. Note that when the apparatus is not operated for a relatively long period of time, it is preferable to completely blow out the canned water in the hot water storage section 3.

In addition, since the operation is stopped after opening the solenoid valve 45 and starting discharging hot water, the water level in the hot water storage section 3 is set to a height of 4 when operation is restarted.
Since this height 4 is lower than the second water level M, water sprinkling and burner combustion are started.
The generated relatively high temperature hot water is replenished,
Hot water at a predetermined desired temperature T0 is stored up to a first water level H. Therefore, even at the start of operation, hot water at the desired temperature T0 can be used.

Effects As described above, according to the present invention, since the timing of water sprinkling and burner combustion is shifted, hot water at the desired constant temperature can always be obtained. Furthermore, since combustion in the burner is performed after water has permeated into the heat absorbing material and a water film has begun to form on the wall surface of the combustion chamber, deterioration of these parts can be suppressed.

[Brief explanation of the drawing]

Fig. 1 is a sectional view of a direct contact hot water heater 1 according to an embodiment of the present invention, Fig. 2 is a sectional view of the vicinity of the flow rate control mechanism 33, Fig. 3 is a flowchart for explaining the operation, and Fig. 4 is a graph showing the opening time W4 of the electromagnetic valve 45 with respect to the difference between the temperature T1 of hot water stored in the hot water storage section 3 and a predetermined temperature T0. 1...Hot water heater, 2...Heater body, 3...
Hot water storage section, 4... Combustion chamber, 5... Burner, 6... Centrifugal blower, 9... Endothermic chamber, 10... Perforated plate, 11
... Endothermic material, 12 ... Water sprinkling chamber, 14 ... Electric flow control valve, 15 ... Water supply nozzle, 17 ... Solenoid valve,
18...Fuel cutoff valve, 33...Flow control mechanism, 3
4...Hot water pipe, 37-39...Water level detection element, 4
7...Temperature detection element.

Claims (1)

[Scope of claim for utility model registration] (1) A combustion chamber equipped with a burner is formed in a cylindrical body, an endothermic chamber filled with an endothermic material is formed above the combustion chamber, and water is sprinkled from above the endothermic chamber. In a direct contact type hot water heater that brings the water into direct contact with combustion gas from a combustion chamber, the timing of water sprinkling and burner combustion is staggered to always obtain hot water at a desired temperature. A direct contact hot water heater. (2) At the start of operation, water spraying is first started, and combustion in the combustion chamber is started when a time W1 approximately equal to the time required for the water to reach the combustion chamber has elapsed. A direct contact hot water heater according to claim 1 of the utility model registration claim. (3) A utility model registration request characterized in that when the operation is stopped, combustion in the combustion chamber is stopped after a time W2 that is approximately equal to the time required for water to flow down from the heat absorbing material after watering stops. A direct contact hot water heater according to item 1.