JPS60143799A - Rain gauge - Google Patents

Abstract

PURPOSE:To obtain a water storage type rain gauge having no valve body, constituted so that the drainage of rainwater in a water storage tank is performed by the rotation of the water storage tank and storage of water is performed in a separate water storage tank simultaneously with the drainage of rainwater. CONSTITUTION:A water storage body 4 is supported around a rotary shaft 5 between two supports 8 provided on a base 9 vertically in a freely rotatable manner while a gear 61 is fixed to the rotary shaft 5 and rotated around the rotary shaft 5 integrally along with the water storage body 4. A rotary mechanism part is constituted so that the rotation of a motor 10 is transmitted to the water storage body 4 through gears 62, 63, 64 to rotate the water storage body 4. In this case, the water storage body 4 and the rotary mechanism part placed on the base 9 and all other elements are entirely weighed by th wt. sensor 11 on a stand 13. When there is rain, rainwater poured in a water receiving cylinder 1 is accumulated in either one of water storage tanks A-D and measured by the sensor 11. When continuous measurement is performed, the water storage body 4 is driven when a measured value reaches a prescribed value at a certain point of time and, by measuring the number of supply times of a driving order signal, a cumalative total rainfall can be measured.

Description

[Detailed description of the invention] The present invention relates to a water storage type rain gauge.

The rainwater storage type rain gauge stores the rainwater received at the water receiving part (・1・・
Measure the amount of water stored in the cypress by volume or weight.
A rain gauge that measures rainfall by converting this into rainfall.

In the above-mentioned water storage type rain gauge, it is necessary to drain the rainwater from the water tank when it is full, and it is also necessary to temporarily drain the rainwater that enters the water receiving part during ice removal. It is necessary to provide a means to collect the stored rainwater and add it to the next measurement.

For this reason, conventionally, a drain valve is installed at the bottom of the water tank, and a water storage valve is installed in the pipe that leads rainwater from the water receiving part to the water tank, but this type of rain gauge requires reliable operation of the two valve bodies. Poor performance and imbalance in mutual operation relationships cause measurement errors.

The present invention was made to solve the above-mentioned conventional problems, and an object of the present invention is to obtain a water storage type rain gauge that does not require a valve body.

Hereinafter, the present invention will be explained in detail with reference to the drawings.

The drawings all explain the present invention in detail: Fig. 1 is a structural diagram, Fig. 2 is a perspective view of the main part (water storage body), and Fig. 3 (
1) to (■) are operation explanatory diagrams.

In FIGS. 1, 2, and 3, 1 is a water tank, 2 is a water receiving funnel, 3 is a water guide pipe, 4 is a water storage body, A-D is a water tank configured in the water storage body 4, and 5 is a water storage tank. Rotating shaft, 61 to 63 are gears, 7 is a cover, 8 is a column, 9 is a base, 10 is a motor, 11 is a weight sensor, 12 is a drainage receiver, 13 is a frame,
14 is a drainage outlet, 15 is a rainwater catchment port, 16 is a water storage cover,
17 is a water leak catcher, 18 is a partition plate, 19a and 19b are rainwater, and 20 is a rainwater outflow stopper.

Functionally, the rain gauge of the embodiment can be divided into four parts: a water receiving part that receives water, a water storage part that collects rainwater, a rotation mechanism part that rotationally drives the water storage part, and a weight measurement part that measures the weight of the mountain water that has run out of water storage. It consists of a drainage section that discharges stored rainwater to the outside, and also consists of a cover, a pedestal, etc.

The water receiving part is composed of a water receiving tube 1 with an open top, a funnel-shaped water receiving funnel 2 that is open upward and is fitted closely into the inner wall of the water receiving tube 1, and a water guide pipe 3 that serves as a drainage port for the water receiving funnel. There is.

The tip position of the water guide pipe 3 is shifted to the right end in FIG. 1 from the position of the rainwater receiver of the water storage body 4, which will be described in detail later, and the opening 15.

The water storage part is a cylindrical water storage body having a rotation axis 5 at the center and water storage tanks A to D divided at equal angles around the rotation axis 5 (divided into four equal parts in the embodiment). 4, this water storage body 4 is rotatable around a rotation axis 5 between two columns 8 (only the front column is shown in FIG. 1) provided vertically on a base 9. Further, a gear 61 is fixed to the rotating shaft 5, and the gear 61 rotates around the rotating shaft 5 integrally with the water storage body 4.The water storage body 4 is shown in FIG. As shown, it has the shape of a cylinder lying on its side, and the interior is a space, which is divided into equal angles (90 degrees in the example) by partition plates 18 around the central axis where the rotating shaft 5 is provided. A plurality of (four in the embodiment) double-column spaces are partitioned and each have the same volume. For example, these four pillar-shaped spaces each serve as separate water storage tanks A-D.The circumference of the water storage body 4 is covered with a water storage cup <-16 to minimize evaporation of stored rainwater. , the water tanks A to D are formed in a so-called closed space, and the water storage cover 16 is provided with approximately T-shaped slits for each of the water tanks A to D, and the slits in the circumferential direction are The rainwater catcher forms an opening 15, and the slit perpendicular to the circumference forms a drain port 14. The drain port 14 is formed in a part partitioned by a partition plate 18, and is formed in a water storage tank A when draining water, which will be described later.
-D is formed so that rainwater does not remain in the tank, and there is no continuous slit between the drain port 14 of the adjacent water tank and the rainwater catch port 15, and this part is connected to the water storage body rotation described later. A water leakage catcher 17 is formed to collect rainwater during driving,
Furthermore, inside the water leakage catcher 17 and at the boundary with the drain port 14,
A rainwater outflow stopper 20 is provided in a vertical shape to prevent inflowing rainwater from being washed away due to splashing.

The rotation mechanism unit includes a motor 10 placed on the base 9, a gear 62 fixed to the output shaft of the motor 10, and a gear 61 attached to the gear 62 and the rotation shaft 5 of the water storage body 4.
The rotation of the motor 10 is transmitted to the water storage body 4 via the gears 62, 63 and 61, and the water storage body 4 is rotationally driven. The motor 10 rotates so as to rotate the water storage body 4 by the dividing angle (90 degrees in the embodiment) for forming the water storage tanks A-D each time it receives a drive command from a control section (not shown).

The weight measurement section is composed of a weight sensor 11 placed on a pedestal 13, and the pace 9 as well as the water storage section and rotation mechanism section configured on the pace 9 are placed at the load point of the weight sensor 11, and a water storage tank The weight of rainwater stored in A-D is expressed as the water storage part,
Rotating mechanism part and its support (pillar 8 and pace 9)
Weigh together with the weight of.

The drainage section is composed of a substantially funnel-shaped drainage receiver 12.

This drainage receiver 12 is connected to the water storage tank A by rotationally driving the water storage body 4.
- It is a receptacle for the rainwater collected in D when it is discharged, and after receiving the rainwater, the rainwater is discharged outside the cover 7. Referring to FIG. Explain the effect of It is assumed that the state of the water storage body 4 is such that the water storage tank A is located at the upper part as shown in FIG.

When it rains, the rainwater that falls into the water tank 1 is received by the water receiving funnel 2, passes through the water guide pipe 3, and is stored in the water tank A as shown in FIG. 3 (1). When it is time to measure the amount of rain, the rainwater 19a that has been stored in the water storage tank A up to that time is measured by the weight sensor 11 together with the water storage section and the rotary drive section, etc., and is sent to a recording section (not shown), where it is converted into a rainfall amount and recorded.

The above measurement operation is performed every time it is time to measure the amount of rainfall, and if the measured value at a certain measurement point exceeds the standard value, a drive command is issued from the control section (not shown) to the motor 10 after measurement at that measurement point. A signal is supplied to rotate the water storage body 4 by 90 degrees in the direction of the arrow shown in FIG. As a result, the rainwater 19a stored in the water tank A is instantly discharged from the drain port 14 as shown in FIG. be discharged.

Although the above operation uses a method of intermittently measuring the amount of rain, it is of course possible to use a continuous measurement method of continuously measuring the weight using the weight sensor 11. In this case, the water storage body 4 is driven when the measured value at a certain point reaches a specified value. Further, in the above operation, it is possible to measure the total amount of rainfall by counting the number of rotations of the water storage body 4, that is, the number of times the drive command signal is supplied.

In parallel with the above drainage operation, Fig. 3 (It) to (III)
As shown in , water tank B adjacent to water tank A moves to the upper part, so that from now on, the rainfall that falls on water tank 1 is transferred to water tank B.
The measurement operation described above is performed for water tank B. The above operation is repeated for water tanks A to D. The installation position of the tip of the water guide pipe 3 is set near the boundary with the next water tank when the water storage body 4 is at rest, and from the time when the water storage body 4 rotates slightly, water is stored in the next water storage tank, for example, B. Moreover, the rainwater receiver has an opening 15 set long in the direction of rotation of the water storage body 4, and a leak stopper 20 is installed inside the water leakage receiver 17.
Because of this provision, the rainwater 19b that flows in and is stored during the rotation operation does not flow out of the water tank B through the rainwater receiver opening 15, and is stored in the water storage tank B even during the rotation operation.

The storage of rainwater while the water storage body 4 is rotating will be described below.

If it rains while the water storage body 4 is rotating, as shown in Fig. 3 (
As shown in TI), rainwater is also poured from the water guide pipe 3 when the rainwater 19a stored in the water tank A is drained. Rainwater poured before the lower partition plate 18 of the water storage tank B becomes horizontal is drained from the partition plate 18 as shown by 19b in FIG. 3 (It).
When the water storage body 4 rotates further and the partition plate 18 is placed in a horizontal position, the rainwater 19b is stored in the space formed by the rainwater and the leakage catcher 17, as shown in FIG. 3 (III). The water is stored in the space formed by the two partition plates 18 of tank B. In this way, even when rainwater is drained, the rainwater is stored on the other side, so that the rainwater received in the water tank 1 does not leak, making it possible to measure the amount of rain with extremely high accuracy.

In addition, in the state shown in FIG. 3 (It), that is, in the state where the lower partition plate 18 of the water tank B-, where rainwater has newly started to accumulate, is downwardly directed outward (toward the water leakage catcher 17). When it rains heavily, rainwater collects in water tank B and causes water leakage.
There is a risk that the rainwater will flow forcefully towards the rainwater and be splashed up by the leakage catcher 17 and be washed away from the opening 15, but this rainwater is prevented from flowing away by the outflow stopper 20.

Next, the timing for controlling the rotation of the water storage body 4 will be described.

In the embodiment described above, the water storage body 4 is rotated when the amount of water stored is more than a certain set amount. In this control method, the rotation control setting mode of the water storage body 4 is performed when rainwater exceeding a set amount is measured, but the rotation control mode may also be performed at every set time period. Modes may be set in combination.

A mode in which the rotation control mode is performed at each set time period, or a mode in which the rotation control mode is performed in combination with the set time period when rainwater exceeds the set amount accumulates is effective in preventing measurement errors due to evaporation when a long dry period continues after a rainfall. effective.

゛ As explained in detail above, according to the present invention, rainwater in a water tank is drained by rotating the water tank, and at the same time as water is drained, water is stored in a separate water tank. Since one water tank rotates and the next water tank captures rainwater from the water guide pipe 3 while the water is being drained, a special mechanism is required to store the rainwater that is being drained. is also unnecessary.

As described above, the present invention makes it possible to measure rainfall with high accuracy without using a special mechanism using a valve body or the like, and its effects are extremely large.

[Brief explanation of the drawing]

The drawings are all for detailed explanation of the present invention, and Fig. 1 is a structural diagram, Fig. 2 is a perspective view showing the structure of the main part (water storage body), and Fig. 3 (1) to (turn) show the operation. It is an explanatory diagram. (Main symbols) 4...Water storage body A, D...Water tank 10...Soter 11...Weight sensor 14...
Drain port 15...Rainwater catcher is port 16...Water storage cover
17...Water leak catcher 18...Partition plate 20...Rainwater outflow prevention Figure 1 Figure 2 (1) Figure 3 (1)

Claims (1)

[Scope of Claims] 1. A rain gauge that collects rainwater received at a water receiving part in a water tank and converts the amount of stored water into rainfall amount, comprising: a support; and a rain gauge rotatably attached to the support. a water storage body consisting of a plurality of water storage tanks divided into equal angles around the rotation axis; and a driving means for controlling the rotation of the water storage body in equal angle increments around the rotation axis according to a set mode. A rain gauge comprising a weight unit for measuring the weight of rainwater accumulated in the - of the water tank together with the weight of the support, the water storage, and the driving means. 2 Claim 1 in which the setting mode is for each set weight
Rain gauge as described in section. 3. The rain gauge according to claim 1, wherein the setting mode is a setting time period. 4. The rain gauge according to claim 1, wherein the setting mode is a combination of a set time period and each set weight. 5 Cover the water storage body with a cover, and connect to the cover a slit-shaped drainage outlet whose longitudinal direction is in the direction of the rotational axis of the water storage body, and a slit-shaped rainwater catchment opening whose longitudinal direction is the rotational direction of the water storage body. A rain gauge according to claim 1, which is provided for each water tank. 6. The rain gauge according to claim 5, wherein the rainwater receiver has a plate-shaped rainwater outflow stopper erected inside the end portion of the side not connected to the drain outlet.