JPS61243341A - Water sampler for calorimeter - Google Patents

Abstract

PURPOSE:To facilitate the sampling of a fixed amount of water with a fixed temperature in a short time, by draining water from an outer tank which holds water of a fixed temperature to a fixed level until it reaches the prescribed level after supplied excessively into an inner tank. CONSTITUTION:While solenoid valves 14 and 15 communicating with a hot water tank 16 are opened and closed measuring the temperature of water in an outer tank 11 with a sensor 28, water is agitated with the rotation of a motor 24 to adjust the temperature thereof to a specified level. Then, a pump 38 is driven to supply water in the outer tank 11 excessively into an inner tank 30 and then, a pipe 44 is moved vertically with a lift mechanism 55 according to the necessary amount of water. Then, with solenoid valves 47 and 49 opened, a pump 51 is driven to drain excessive water outside and water of a fixed temperature is sampled by a prescribed amount. Thereafter, the rise in the temperature of water in the inner tank 30 is measured with a temperature sensor 28 stirring water in the inner tank 30 with an agitator 36 thereby enabling the measurement of heat generated from a sample to be measured.

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention relates to a water sampling device for a calorimeter, and particularly to a water sampling device for a calorimeter, in which a pressure vessel containing a sample to be measured is installed in a tank.
It relates to something that makes it easy to collect a certain amount of water at a certain temperature.

[Technical Background of the Invention] As is well known, calorimeters are used to determine, for example, the quality of fossil fuels and the calorific value of food products. This calorimeter attaches the sample to be measured to a small pressure vessel (hereinafter referred to as a pump) and pumps oxygen into the vessel at a rate of, for example, 25 KI/c.
Inject about rA, and turn the pump around, for example, 2000 to 2200
The calorific value is determined by immersing the device in a water tank filled with g of water and burning it, and measuring the temperature rise of the water.

By the way, the change in the temperature rise of water varies depending on the amount of water put into the aquarium and its temperature, so it is necessary to make water at a constant temperature and measure a certain amount of it into the aquarium. .

Therefore, conventionally, as a means of collecting a certain amount of water at a certain temperature into an aquarium, water at a certain temperature is prepared in a container in advance, the aquarium is placed on a scale, and the water is poured into the aquarium until it reaches a certain weight. In some cases, water at a constant temperature is made in a container, and the water is pumped into a tank fixed in the container from the bottom, and the water level in the tank is measured with a level meter. There is.

[Problems with Background Art] However, the following problems occur with the conventional water sampling means as described above. First, the method of placing the water tank on a scale to draw water is complicated and is prone to human error. In addition, when measuring the water level in an aquarium with a level meter, the water surface must be kept flat to prevent waves, and the response of the level meter cannot respond to excessive rises in the water level. There is a limit to the water injection speed, and the water supply time is long.

Roughly speaking, when draining the water in the aquarium after the measurement is completed, people either take it out and drain it, or they open the bottom of the tank and drain it by its own weight, so this is a problem. However, this makes the work more complicated and causes problems in the structure.

[Purpose of the invention] This invention was made in consideration of the above circumstances.

It is an object of the present invention to provide an extremely good water sampling device for a calorimeter that can easily collect a certain amount of water in a short period of time and can contribute to improved workability.

[Summary of the Invention] That is, the water sampling device for a calorimeter according to the present invention is a calorimeter in which a pressure vessel containing a sample to be measured is immersed in water and the calorific value is measured based on the temperature change of the water. , forming an outer tank filled with water at a certain temperature up to a certain water level, an inner tank installed in the outer tank and housing the pressure vessel inside, and a flow channel connecting the inside of the outer tank and the inside of the inner tank. a supply means for supplying water stored in the outer tank to the inner tank in excess of a specified level by a pump; and a supply means for discharging the water supplied to the inner tank by the supply means to the outside of the inner tank. By forming a flow channel and discharging the water in the inner tank using a pump until it reaches the specified level, a certain amount of water can be easily collected in a short time, and work efficiency is improved. It is designed to contribute to the improvement of

[Embodiment of the Invention] Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. In the figure, 11 is an outer tank, and its bottom surface 11
A pedestal 12 is installed on the pedestal 12, and an inner tank 13, which will be described later, is installed on the pedestal 12. Water is supplied into the outer tank 11 by opening the solenoid valve 14, and hot water is supplied from the hot water tank 16 by opening the solenoid valve 15.

Here, water is supplied into the hot water tank 16 by opening the electromagnetic valve 17. The water supplied into the hot water tank 16 is controlled to have a constant water level by a water level sensor 18, and is also controlled to have a constant temperature by a heater 19 and a temperature sensor 20. In the figure, 21 is a solenoid valve for discharging water from the outer tank, and 22 is a drain pipe for overflow.

Further, the upper opening in the figure of the outer tank 11 is closed with M23, and a motor 24 is installed on the lid 23. The rotating shaft 24a of the motor 24 is extended into the outer tank 11 by loosely inserting the lid 23, and a plurality of (four in the illustrated case) fins 25 are attached to the rotating shaft 24a of the agitator 26. is configured. Furthermore, inside the outer tank 11,
A water level sensor 27 and a temperature sensor 28 are installed.

On the other hand, the inner tank 13 is composed of an intermediate tank 29 fixed to the pedestal 12 and an inner tank 30 installed in the intermediate tank 29 so that its peripheral side does not contact the intermediate tank 29. There is. Therefore, a space 31 is formed between the intermediate tank 29 and the inner tank 30.

The upper end of the inner tank 30 in the drawing is open, and the upper opening of the intermediate tank 29 in the drawing is closed by a lid 32. An opening 32a that is opened and closed by the lid 33 is formed in the center of the lid 32, and a pump (not shown) containing a sample to be measured is taken in and out of the inner tank 30 through the opening 32a. It is something.

Here, a motor 34 is installed on the lid 23 of the outer tank 11. The rotating shaft 34a of the motor 34 extends into the inner tank 30 by loosely inserting the lid 23 and the lid 32 of the intermediate tank 29, and has a plurality of (four in the illustrated case) fins 35 attached thereto. The stirrer 36 is constructed by the following. Roughly, inside the inner tank 30, the water level sensor 27 and the temperature sensor 28 are installed.

Next, inside the outer tank 11, a pipe 37. pump 38
, pipe 39. Nf! i valve 40. Pipe 41. A first flow channel consisting of a solenoid valve 42 and a pipe 43 allows communication with the inside of the inner tank 30 . Also,
Inside the inner tank 30 is a pipe 44. Telescopic pipe 45
゜Pipe 46. Solenoid valve 47. Pipe 48. Solenoid valve 49.
Pipe 50. A second flow channel consisting of a pump 51 and a pipe 52 allows communication with the outside. Roughly speaking, inside the inner tank 30 is a pipe 43. Solenoid valve 42
, pipe 53. Solenoid valve 54. Pipe 48. Solenoid valve 49° pipe 50. It is also possible to communicate with the outside through a third flow channel consisting of a pump 51 and a pipe 52.

Here, the pipe 4 entering the inside of the inner tank 30 is
4 is moved up and down in the figure by the action of a lifting mechanism 55 installed on the lid 23 of the outer tank 11.

In the above configuration, means for collecting a certain amount of water at a certain temperature into the inner tank 30 will be explained below.

First, the solenoid valve 14 is opened to supply water into the outer tank 11. When the water level sensor 27 detects that the water in the outer tank 11 has reached a certain level, the solenoid valve 14 is closed and the water supply is stopped.

Thereafter, while measuring the temperature of the water in the outer tank 11 with the temperature sensor 28, the solenoid valves 14 and 15 are opened and closed, and the motor 24 is rotated to stir the water in the outer tank 11. The water in the tank 11 is controlled to a predetermined temperature. When the water in the outer tank 11 reaches a predetermined temperature, the motor 24 is stopped, and water at a constant temperature can be stored in the outer tank 11.

Next, by opening the electromagnetic valves 40, 42 and driving the pump 38, water in the outer tank 11 is supplied into the inner tank 30 via the first flow channel. At this time, the water level of the water supplied to the inner tank 30 is detected by the water level sensor 27, and when the water level of the inner tank 30 reaches a predetermined level, the solenoid valve 60.42 is closed. Pump 38 is stopped. In this case, the water level stored in the inner tank 30 is set to be in excess of the required level, and the water level in the inner tank 30 is detected by the water level sensor 27. .

From the temperature and density of water in the outer tank 11,
The volume within the inner tank 30 corresponding to the required weight of water to be sampled into the inner tank 30 is calculated, and the pipe 44 is raised or lowered by the elevating mechanism 55 in accordance with this result. Thereafter, by opening the electromagnetic valves 47 and 49 and driving the pump 51, excess water in the inner tank 30 is discharged to the outside through the second flow channel, and the It is possible to collect a specified amount of water at a constant temperature.

Here, after collecting the water in the inner tank 30 as described above, while stirring the water in the inner tank 30 with the agitator 36, the temperature sensor 28 measures the temperature rise of the water in the inner tank 30. By measuring this, it is possible to measure the calorific value of the sample to be measured.

Therefore, according to the configuration of the above embodiment, water in excess of the required amount is supplied into the inner tank 30 via the first flow channel by the driving force of the pump 38, and the excess water is supplied to the inner tank 30 through the first flow channel. Since the water is discharged by the pump 51 through the flow channel No. 2, a certain amount of water can be collected into the inner tank 30 with a simple operation, so that water can be collected easily and in a short time. This will enable you to do this. After the measurement is completed, the water in the inner tank 30 is discharged to the outside through the third flow channel by opening the solenoid valves 42, 54, and 49 and driving the pump 51. The water in the inner tank 30 can be easily drained, and workability can be improved in this respect as well.

It should be noted that the present invention is not limited to the above-mentioned embodiments, and can be implemented with various modifications without departing from the gist of this invention.

[Effects of the Invention] Therefore, as described in detail above, the present invention provides an extremely good calorimeter that can easily collect a certain amount of water in a short period of time and has the potential to improve workability. A water harvesting device can be provided.

[Brief explanation of the drawing]

The drawing is a side sectional view showing an embodiment of a water sampling device for a calorimeter according to the present invention. 11...Outer tank, 12...Pedestal, 13...Inner tank, 1
4.15... Solenoid valve, 16... Water tank, 17... Solenoid valve, 18... Water level sensor, 19... Heater,
20... Temperature sensor, 21... Solenoid valve, 22...
・Drain pipe, 23...lid, 24...motor, 25...
・Fin, 26... Stirrer, 27... Water level sensor, 28... Temperature sensor, 29... Intermediate tank, 30.
...Inner tank, 31...Space, 32...Lid, 33...
・Lid body, 34...Motor, 35...Fin, 36.
... Stirrer, 37... Pipe, 38... Pump, 3
9... Pipe, 40... Solenoid valve, 41... Pipe, 42... Solenoid valve, 43. a4...pipe, 45
... telescopic pipe, 46 ... pipe, 47 ... solenoid valve, 48 ... pipe, 49 ... solenoid valve, 50 ...
Pipe, 51...pump, 52, 53...pipe,
54... Solenoid valve, 55... Lifting mechanism.

Claims (1)

[Claims] In a calorimeter, a pressure vessel containing a sample to be measured is immersed in water and the calorific value is measured based on temperature changes in the water. an inner tank installed in the tank and accommodating the pressure vessel therein;
A supply means that forms a flow channel connecting the inside of the outer tank and the inside of the inner tank and supplies water stored in the outer tank to the inner tank in excess of a specified level by a pump; It is characterized by comprising a discharge means that forms a flow channel for discharging the water supplied in the inner tank to the outside of the inner tank, and discharges the water in the inner tank using a pump until it reaches the specified level. Water sampling device for calorimeter.