JP2015175415A - Distribution valve for hot water supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a distribution valve for a hot water supply device in which a flow rate to a heat exchanger does not become zero even when a motor for driving a valve shaft runs away.SOLUTION: A distribution valve for a hot water supply device has a distribution chamber in which water from outside flows. In the distribution chamber, a valve port 13a for a heat exchanger for communicating with a heat exchanger and a valve port 14a for a bypass passage for communicating with a bypass passage are provided. A valve body 23 for a heat exchanger for reducing a flow rate to the heat exchanger by moving toward the valve port for a heat exchanger from the distribution chamber side, and a valve body 24 for a bypass passage for reducing the flow rate to the bypass passage by moving toward the valve port for a bypass passage from the distribution chamber side are moved by a motor 2. A diameter of the valve port for a heat exchanger is set to be larger than an outer diameter of the valve body for a heat exchanger, and it is configured so that the valve body for a heat exchanger can pass through the valve port for a heat exchanger.

Description

  The present invention relates to a distribution valve for a hot water supply device that is incorporated in a hot water supply device and distributes water flowing from the outside to both a heat exchanger and a bypass passage that bypasses the heat exchanger.

  For example, one distribution chamber is provided, and two outlets facing each other are provided in the distribution chamber so that the fluid flowing in from one path is distributed in two directions, and flows into the distribution chamber. There is known one that allows fluid to flow out from both outlets (see, for example, Patent Document 1).

  In this case, in order to change the ratio of the flow rate of each of the two outlets, that is, the distribution ratio, one valve shaft penetrating both outlets is provided, and each valve shaft is provided on the valve shaft from the distribution chamber side. Two valve bodies corresponding to each of the outlets are provided, and the opening degree of both outlets is increased or decreased by moving the valve shaft in the axial direction. In this case, the valve shaft is driven by a motor.

Japanese Patent Laying-Open No. 2011-7263 (FIG. 1)

  In the hot water supply device, if the heating power of the gas burner that heats the heat exchanger is made too small, drainage is generated in the heat exchanger and the heat exchanger may be corroded, so that the heating power cannot be kept below a certain level. Moreover, when the flow rate of the water flowing through the heat exchanger is increased too much, the heat exchanger is cooled and drainage is also generated. Therefore, since the temperature of the hot water heated with the heat exchanger becomes high, the tapping temperature cannot be lowered.

  Therefore, it is conceivable to provide a bypass passage that bypasses the heat exchanger, and to mix hot water heated by the heat exchanger with cold water flowing through the bypass passage to lower the temperature of the hot water. In addition, since it is desirable that the ratio of the flow rate of hot water passing through the heat exchanger and the flow rate of cold water passing through the bypass path can be changed, a distribution valve as described above is provided on the upstream side of the heat exchanger. One of the two systems flowing out from the pipe is led to the heat exchanger, and the other is led to the bypass path.

  However, the above distribution valve is configured such that when the valve body attached to the valve shaft approaches the outlet, the outlet is closed and no water flows out from the outlet. Therefore, if a motor that drives the valve shaft runs out of control and causes a failure that completely closes the outlet on the heat exchanger side, boiling occurs in the heat exchanger, causing a large noise to the outside, or There is a risk of damaging the heat exchanger.

  In view of the above problems, an object of the present invention is to provide a distribution valve for a hot water supply device in which the flow rate to the heat exchanger does not become zero even if the motor that drives the valve shaft runs away.

  In order to solve the above problems, a distribution valve for a hot water supply apparatus according to the present invention distributes water introduced from the outside into two systems of a heat exchanger and a bypass passage that does not pass through the heat exchanger. A distribution chamber into which water from the outside flows, and a heat exchanger valve port that communicates with the heat exchanger, and a bypass channel valve port that communicates with the bypass channel. A heat exchanger valve body that reduces the flow rate to the heat exchanger by moving from the distribution chamber side toward the heat exchange device valve port, and from the distribution chamber side toward the bypass channel valve port. The bypass passage valve body that reduces the flow rate to the bypass passage by moving is moved by a motor, and the diameter of the heat exchanger valve port is set larger than the outer diameter of the heat exchanger valve body. , Heat exchanger valve body is for heat exchanger Characterized by being configured so as to pass through the mouth.

  According to the above configuration, even if the motor runs away and the heat exchanger valve body approaches the heat exchanger valve opening, the heat exchanger valve body passes through the heat exchanger valve opening as it is. Is not closed and water flow to the heat exchanger can be secured.

  The flow rate to the heat exchanger is minimized when the heat exchanger valve body passes through the heat exchanger valve port, and immediately after the heat exchanger valve body passes through the heat exchanger valve port, the heat exchanger valve It is desirable to configure so that the flow rate increases.

  As is apparent from the above description, the present invention can avoid a state in which no water flows to the heat exchanger because the heat exchanger valve port is not closed even if the motor runs out of control. Therefore, boiling in the heat exchanger due to runaway of the motor can be prevented.

The figure which shows the pipe line structure in a hot-water supply apparatus Cross section of distribution valve in normal condition Cross section when the distribution valve is abnormal Diagram showing change in distribution ratio

  With reference to FIG. 1, this figure has simplified and shown the internal structure of the hot-water supply apparatus. Reference numeral 1 denotes a hot water supply device distribution valve (hereinafter simply referred to as a distribution valve) according to the present invention, in which water supplied through an inlet pipe 101 connected to an external water pipe is connected to a heat exchanger 105 via a connection pipe 103. And heated by the heat exchanger 105 to make warm water, mixed with the water from the bypass 104, and discharged from the hot water discharge pipe 106 to the outside. In the figure, reference numeral 102 denotes a flow meter, and the distribution valve 1 branches and flows the water introduced through the flow meter 102 into a heat exchanger 105 and a bypass passage 104 that bypasses the heat exchanger 105. The distribution ratio, which is the ratio of the flow rate to the heat exchanger 105 and the flow rate to the bypass 104, can be varied.

  Referring to FIG. 2, the flow meter 102 is connected to the water inlet 11, and water flows from the water inlet 11 into the internal space 12. Then, the inflowing water branches out to the heat exchanger port 13 connected to the heat exchanger 105 and the bypass channel port 14 connected to the bypass channel 104 and flows out. A heat exchanger valve port 13a and a bypass passage valve port 14a are formed in the space 12 so as to face each other, and the heat exchanger valve body 23 and the bypass for increasing and decreasing the opening degree of the heat exchanger valve port 13a are formed. A bypass valve body 24 that increases or decreases the opening degree of the road valve port 14 a is attached to one valve shaft 22.

  The valve shaft 22 is connected to the stepping motor 2 via a gear portion 21 and is configured such that the valve shaft 22 moves forward and backward in the figure when the stepping motor 2 rotates in the forward and reverse directions. Yes.

  The maximum diameter of the bypass passage valve element 24 is set to be larger than the inner diameter of the bypass passage valve opening 14a. Therefore, when the bypass passage valve element 24 approaches the bypass passage valve opening 14a, the bypass passage opening 14 bypasses the bypass passage opening 14a. When the flow rate of water flowing to the passage 104 decreases and the bypass passage valve body 24 is seated on the bypass passage valve port 14a, the flow amount flowing to the bypass passage 104 becomes zero.

  On the other hand, the maximum diameter 23D of the heat exchanger valve body 23 was set smaller than the inner diameter 13D of the heat exchanger valve port 13a. Since the setting is such that 23D <13D, for example, when the stepping motor 2 runs away and the valve shaft 22 moves upward beyond the normal use region, as shown in FIG. 23 passes through the heat exchanger valve port 13a, and further moves upward until it abuts against a mechanical stopper (not shown) and stops. Therefore, the heat exchanger valve port 13a is not closed. The inner peripheral surface of the heat exchanger valve port 13a is not cylindrical so that the flow rate to the heat exchanger 105 increases rapidly after the heat exchanger valve body 23 passes through the heat exchanger valve port 13a. Tapered.

  The distribution ratio of the distribution valve 1 having such a configuration is shown in FIG. In the normal use region, in the state where the valve shaft 22 is positioned at the lower end, the bypass passage valve port 14a is closed by the bypass passage valve body 24, so the distribution ratio becomes “0”. When the valve shaft 22 moves upward from this state, the flow rate to the bypass passage 104 gradually increases, so that the distribution ratio continuously increases as indicated by A.

  If the valve shaft 22 moves upward beyond the normal use region due to an abnormality in the stepping motor 2, the flow rate to the heat exchanger 105 decreases. Rose sharply. However, in the distribution valve 1 according to the present invention, as described above, the heat exchanger valve element 23 does not close the heat exchanger valve opening 13a, and the heat exchanger valve element 23 does not close the heat exchanger valve opening 13a. Since the flow rate to the heat exchanger 105 increases rapidly after passing through, the distribution ratio decreases as shown in C.

  In addition, this invention is not limited to an above-described form, You may add a various change in the range which does not deviate from the summary of this invention.

DESCRIPTION OF SYMBOLS 1 Distribution valve 2 Stepping motor 11 Water inlet 12 Space 13 Heat exchanger port 13a Heat exchanger valve port 14 Bypass passage port 14a Bypass passage valve port 21 Gear part 22 Valve shaft 23 Heat exchanger valve body 24 Bypass passage valve body 101 Inlet pipe 104 Bypass path 105 Heat exchanger

Claims (2)

  A distribution valve for a hot water supply device that distributes water flowing in from the outside into two systems, a heat exchanger and a bypass passage that does not pass through the heat exchanger, and has a distribution chamber into which water from the outside flows. The distribution chamber is provided with a heat exchanger valve port communicating with the heat exchanger and a bypass channel valve port communicating with the bypass channel, from the distribution chamber side toward the heat exchange device valve port. A heat exchanger valve body that reduces the flow rate to the heat exchanger by moving, and a bypass path valve body that reduces the flow rate to the bypass path by moving from the distribution chamber side toward the bypass path valve port And the diameter of the heat exchanger valve port is set to be larger than the outer diameter of the heat exchanger valve body so that the heat exchanger valve body can pass through the heat exchanger valve port. For water heaters Haiben.   When the heat exchanger valve body passes through the heat exchanger valve port, the flow rate to the heat exchanger is minimized, and immediately after the heat exchanger valve body passes through the heat exchanger valve port, the flow rate to the heat exchanger The distribution valve for a hot water supply device according to claim 1, wherein the distribution valve is configured to increase.

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