KR910002172Y1 - Device for controlling hot water temperature for hot water heater - Google Patents

Abstract

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Description

Tapping temperature control device of gas water heater

1 is a front view showing an example of a water heater having a device of the present invention.

2 is a cutaway plan view of the main portion thereof.

3 is a perspective view of main parts thereof.

4 to 7 are explanatory diagrams showing an operating state.

8 is a plan view of a portion thereof.

9 is an explanatory diagram of the relationship between the amount of water and the amount of gas.

10 is a perspective view showing a rotary motion cam and the auxiliary cam.

11 is a cross-sectional view showing a modification of FIG.

12 is a cross-sectional view showing a part thereof.

* Explanation of symbols for main parts of the drawings

1: hot water main body 2: heat exchanger

3: burner unit 4: push operation

5: gas passage 6: gas valve

7: water passage 8: water valve

9: Hot water outlet 10: Gas flow control valve

11: Quantity control valve 12: Push lever

14: rotational cam 15: stone cam cam

The present invention mainly relates to a push button operating device in the instant water heater.

As such a conventional device, as shown in, for example, Japanese Utility Model Laid-Open Publication No. 60-119061, a press-operation tool on the front of a water heater body having a heat exchanger inside and a burner unit opposed thereto. And the gas valve in the gas passage leading to the burner unit by the pressing operation of the pusher, and the water valve in the water passage leading to the heat exchanger to be heated at the hot water outlet, and the gas flow control valve in the gas passage. It is possible to freely increase and decrease the tapping temperature by installing the water quantity control valve in the water passage and operating both valves in the reverse direction to the increasing side and the decreasing side. It is proposed that the mutual reverse direction operation is released.

In this proposal, however, the temperature regulating member is disposed on the front side freely from side to side, and the rack and pinion are engaged with the water flow control valve as an example, and at the same time, a pin at the end thereof is fitted to the other gas flow control valve. In general, the formula is freely engaged with the cam on the side. In this case, the number of parts is large in total, and the configuration thereof is inevitably complicated and expensive.

The object of the present invention is to obtain a device without such a problem, that is, a device having a small number of parts, and having a press operation tool on the front of the water heater main body having a heat exchanger and a burner unit facing the inside, and pressing operation. By pushing the sphere, the gas valve in the gas passage leading to the burner unit and the water valve in the water passage leading to the heat exchanger can be heated to the hot water outlet, and the gas flow control valve in the gas passage and the quantity control in the water passage. At the same time, the valve is configured to allow both valves to be operated in the opposite direction to each other in the direction of increasing and decreasing of the amount thereof, so that this tapping temperature can be freely added or subtracted. In which the gas flow control valve is push-operated, that is, push-type. In addition, the push lever is installed in the horizontal direction, and the water control valve is configured in a rotary motion type, and is provided with a rotary motion cam that operates continuously in front of it, and the push lever has a predetermined rotation of the rotary motion cam. In the movement position, it is formed by forming a rock cam part engaged with this.

An embodiment of the present invention will be described with reference to the accompanying drawings.

In the drawing, 1 represents a water heater body, and the body 1 has a heat exchanger 2 therein and a burner unit 3 on its lower side facing the same, and at the front of the pushbutton 4a. And a pressing operation tool 4 formed of a pressing part 4b pressed by the pressure control device 4, which is operated by pressing operation of the pressing operation tool 4. As shown in FIG.

Furthermore, in detail, in the case of the push method in which the pusher 4 has the push mechanism 4c on the pusher 4b, it is applied to the spring 4f by the first push action and subsequent push release. The gas valve 6 in the gas passage 5 connected to the burner unit 3 and the water valve 8 in the water passage 7 connected to the heat exchanger 2 are opened and released. The hot water outlet 9 is heated and discharged, and a gas flow rate control valve 10 and a water flow rate control valve 11 are installed in the gas passage 5 and both valves 10 are provided. (1) was configured so that the amount was increased and decreased in the opposite direction to each other in the reverse direction, so that tapping temperature was gradually added or lowered, and the ion was released at a high temperature above a predetermined value.

There is no particular difference from the conventional one, but according to the present invention, the gas flow control valve 10 is configured as a push type, and the push lever 12, which is operated by pressing it in front of it, is moved forward and backward from the shaft 13 at the end. In addition to the horizontal movement so as to tilt freely, the water flow control valve 11 is provided with a rotary motion cam 14 configured to rotate in a forward motion thereof, and is operated in succession thereof, and the lever 12 has a cam 14. At the predetermined position of), the rock cam part 15 engaged with this is formed.

Here, the quantity control valve 11 is a rotational movement type means that the operation of the valve is not performed by the linear movement but the opening and closing action by the rotational movement.

As shown in more detail, the gas flow control valve 10 is set in such a manner that the gas flow is gradually reduced by moving backwards, and the lever 12 controls the quantity of water from the gas flow control valve 10. Extends in a rectangular direction toward the valve 11 to be axially axially supported on the front substrate 16 from the outside thereof, and the quantity control valve 11 is a counterclockwise direction in the drawing, and the amount of water is gradually increased by the rotational movement. In FIG. 9, when the amount of water rotates at a predetermined angle from the minimum starting point position, the cam 14 is engaged with the protrusion cam portion 15, and the protrusion cam portion 15 protrudes forward. Formed to form a gradually higher toward the left in the drawings.

Thus, when the water quantity control valve 11 is rotated from the time point position as shown in the third illustration to the increase amount side, that is, at the position rotated at 90 degrees, for example, as shown in FIG. As shown in FIG. 5 and FIG. 6, for example, the push lever 12 is slid to the left and right over the protrusion cam portion 15 at 135 degrees and 180 degrees. It is operated while being inclined rearward to impart a retraction movement corresponding to the gas flow control valve 10. In doing so, the gas amount is reduced according to the amount of water.

In detail, the amount of gas gradually decreases in response to this when the amount of water reaches a predetermined flow rate or more due to the gradual increase of the quantity of water. At the same time, the temperature is lowered.

In the illustrated example, the auxiliary cam 11a is formed on the rotary cam 14 with its position slightly eccentric to the front. At the 180-degree rotary position, the auxiliary cam 14a is formed as shown in FIG. The rotational movement was restrained when the projection piece 18 protruding forward from the inside of the push hole 16a formed in (16) was reached.

This projection piece 18 is provided at the tip of the lever 19 that engages with the projection piece 4d protruding from the pressing section 4b as described in FIG. It protrudes in the operating position, that is, the position where the gas valve 6 and the water valve 8 are opened by pressing, but enters in the position which does not operate. Thus, in the inoperable position of the pusher 4, the auxiliary cam 14a releases the restraining by it, and reaches, for example, the fixed stopper 28 provided on the substrate 16 side as shown in FIG. Position, that is, allow the rotational movement to a 200-degree position, wherein the auxiliary cam 14a protrudes into the see-through hole 16a to press-in a separate projection piece 20 installed in the rotational movement trajectory of the auxiliary cam 14a. To act inclinedly to operate the separate lever 24 having the protruding piece 20 at the tip, whereby the water valve 8 is pushed through the arm 22 coaxially with the lever 21. It was pressed to make this work.

In other words, the water valve 8 was operated separately from the gas valve 6 and the water valve 8 in the inoperative state by the push button 4 so that only a large amount of water was obtained at the hot water outlet 9. .

The arm 22 is operated so as to open the water valve 8 when the gas valve 6 is opened by the push operation tool 4 by operating the push operation tool 4 in succession.

To explain this, the arm 22 extends from the gas valve shaft to the water valve 8 side by supporting the intermediate shaft, and the bracket 4e protruding from the pressing section 4b of the pressing operation tool 4. The projection piece 25 which is engaged with the rear end 22a of the arm 22 and cooperates with it is axially supported by the shaft 25a of the connecting portion, and it is held by the spring 25b to counterclockwise direction. At the time of the rotational movement, the position of the stopper 4g rising upward from the bracket 4e and the inner edge of the see-through hole 16b provided in the substrate 16 was reached.

In this case, by the pressing operation of the first pressing operation tool 4, the cam portion 25d of the projection piece 25 first reaches the rear end 22a of the arm, thereby resisting the spring 4g. While rotating in a clockwise direction, the protruding portion 25e comes over the rear end 22a and comes to a position opposite to the rear surface of the rear end 22a.

Subsequently, when releasing the pressing operation of the pressing operation tool 4 in this state and returning it to the intermediate position, this arm 22 has its rear end 22a pressed against the projection 25e and moves forward.

As a result, the water valve 8 is opened by pressing the other end 22b of the arm 22.

Subsequently, when returning it to the original position by the pressing operation of the second pressing operation tool 4, the projection piece 25 swings clockwise as the inclined surface 25c of the cam piece 25 enters the see-through hole 16b. The engagement state between the arm 22 and the protrusion 25e is released.

For this reason, the arm 22 is pressed by the water valve 8 and returns to an original position.

In the drawing, reference numeral 26 denotes a locking member which causes the pressing operation tool 4 to be in an inoperable state when the rotary shaft 1la of the water quantity control valve 11 is rotated at a 200 degree position. In the embodiment shown in FIG. 8, the locking member 26 includes a leading edge 26a in which the reciprocating motion is freely supported on the substrate 16 and a leading edge 26a provided in the pressing rod 4b. The latching | joint 26a to the see-through hole 16b was comprised by the press piece 26d which pushes against the see-through hole 16b side against the spring 26c. Therefore, this pressing piece 26d protrudes from the rear end of the lever 21 so that the protrusion piece 20 is pressed against the auxiliary cam 14a so that the latching section 26a swings through the projection hole 16b when the lever 21 swings. It was supposed to fit inside.

However, as shown in Figs. 11 and 12, when the rotary shaft 11a is rotated to the position of 200 degrees, the tip of the projection piece 18 on the lever 19 is placed on the back of the auxiliary cap 14a. In other words, the lever 19, the projection piece 18, and the auxiliary cam 14a can also serve as the locking member 26.

In this embodiment, the stone piece 20 is installed on the arm 22, and the direct arm 22 is operated by the auxiliary cam 14a to open the water valve 8.

In addition, a second rotary cam (23) separate from the rotary cam (14) described above is installed on the gas flow control valve (10) and at the same time the projection cam portion 15 on the push lever (12) Separately from the second rotational cam (23) to form a second protrusion cam portion 24 to cooperate with the second rotational cam (23) by using the second protrusion cam portion 24 also by the rotational movement The lever 12 was operated to be inclined backward so as to control the amount of gas in the control valve 10. (Figure 2)

In other words, only the amount of gas is allowed to be allowed regardless of the quantity.

As described above, that is, the water quantity control valve 11 is gradually rotated from the start point position of the third illustration to the increase amount side, that is, at the start end of the protrusion cam part 15 on the push lever 12 side at the 90 degree position. If the rotation continues over, the cam 14 reciprocates on the protrusion cam portion 15 as shown in FIGS. 4, 5, and 6, and the lever 12 gradually inclines backward and moves along with the gas flow control valve. 10 is pressed against this, and the amount of gas gradually decreases.

In other words, only the quantity is gradually increased first by the rotation of the water quantity control valve 11, and the gas quantity control valve 10 is subsequently operated by the rotation beyond the predetermined rotational movement position so that the amount of gas gradually decreases.

This quantity and the change with the gas quantity are as shown in FIG. 9, for example.

In this way, according to the present invention, a predetermined successive operation on both valves and release of the operation are formed in the push lever controlling the gas flow control valve so as to form a protrusion cam portion engaged with the cam at a predetermined rotational position of the cam. Can be given simply and surely, and its structure is simpler than the conventional one described above, and at the same time, the operation can be smoothly obtained at low cost.

Claims (1)

A press operating mechanism 4 is provided on the front of the hot water main body 1 having the heat exchanger 2 and the burner unit 3 facing the inside thereof, and the burner is operated by the pressing operation of the press operating mechanism 4. The gas valve 6 in the gas passage 5 connected to the unit 3 and the water valve 8 in the water passage 7 connected to the heat exchanger 2 are provided, and the gas flow rate in the gas passage 5 is provided. In the control valve 10 and the water passage 7, the water flow control valve 11 includes a push lever 12 configured to push the gas flow control valve 10 into a push type and press it to the bottom surface thereof. ), And the water flow control valve (11) in the rotational movement type at the same time, with a rotary motion cam (14) actuated to the front side thereof, and a predetermined rotation of the rotary motion cam (14) on the push lever (12). A tap water temperature control device for a gas water heater, characterized in that the position is formed by forming a rock cam portion (15) to be engaged with this.