JP3399412B2 - Mercury measuring device, mercury measuring method, and method for manufacturing fluorescent lamp using this method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention is particularly mercury total amount to that mercury thermometer RyoSo location to be sealed in the fluorescent lamp, a method for manufacturing a fluorescent lamp using mercury weighing how and this method .

[0002]

Conventionally, mercury to be sealed in mercury capsules for fluorescent lamps and fluorescent lamp as a total amount to shall, are as follows.

[0003] The first mercury thermometer RyoSo location, as shown in FIG. 7 (a), the container 14 containing the mercury 13 within reciprocated axially through the vessel 14, and one end And a cylindrical rod 16 having a recess 15 on the side surface of the portion.

The operation will be described. First, as shown in FIG.
Located at the bottom of the. At this time, mercury corresponding to substantially the volume of the recess 15 enters the recess 15. After that, the rod 16 is moved in the D direction to position the recess 15 outside the container 14 as shown in FIG. 7B. Then, as shown in FIG. 7B, the mercury drop 17 contained in the recess 15 falls by free fall. Accordingly, a predetermined amount of mercury by defining the size of the recess portion 15 can weighing to Rukoto.

[0005] In this first mercury thermometer RyoSo location is mercury drop 17
The time required for dropping is about 1 second.

[0006] The following describes a second conventional mercury thermometer RyoSo location (JP-A 6-150826 JP).

[0007] The second mercury analyzer RyoSo location is to meter accurately the mercury, as shown in FIG. 8, the tube 18
And is inserted into the tube 18 and the tube 18
And a fine wire 19 having a diameter smaller than the inner diameter of.

The tube 1 in which the thin wire 19 is inserted
One end of 8 is immersed in a container 20 filled with mercury 13 and a vacuum is drawn from the other end of the tube 18. By this evacuation, mercury is sucked to the lower end of the thin wire 19.

After this, the tube 18 is taken out of the container 20. Next, by injecting, for example, high-pressure gas from the other end of the tube 18, the mercury sucked into the tube 18 is discharged. As a result, a predetermined amount of mercury weighing to Rukoto by defining the amount of suction mercury.

[0010]

[SUMMARY OF THE INVENTION However, in the conventional first mercury thermometer RyoSo location, since the surface tension of mercury is high, when the mercury drop 17 falls freely from the recess 15, the recess 15 There is a problem that mercury adheres and the amount of mercury enclosed in a fluorescent lamp or the like varies greatly, and it is impossible to measure an amount of mercury of 3 mg or less.

When mercury is enclosed in a fluorescent lamp, if less than the required amount of mercury is enclosed, mercury is consumed by being formed into a mercury compound such as amalgam, and the mercury in the lamp is exhausted. It cannot be turned on normally. On the other hand, encapsulating mercury more than necessary is an extremely serious environmental problem.

Further, the second mercury analyzer RyoSo location prior to the can, in order not sucked into the gap between the tube 18 and the fine wire 19 undue mercury when aspiration of the mercury from the lower end of the thin wire 19 In addition, the tube 18 and the thin wire 19 are in a state where there is only a small gap. Therefore, in such another conventional device, it takes about 3 to 5 seconds per time for sucking mercury in order to suck the vacuum from the slight gap, so that the production efficiency is poor. was there.

If the gap between the tube 18 and the thin wire 19 is widened or the degree of vacuum is increased in order to shorten the suction time, the variation in the amount of mercury becomes large.

[0014] The present invention has been made to solve such a problem, there is provided a mercury thermometer RyoSo location and mercury weighing how capable of metering mercury accurately and at high speed is there.

The present invention also provides a method of manufacturing a fluorescent lamp which prevents abnormal lighting due to lack of mercury during the rated life and obtains an environmentally friendly fluorescent lamp.

[0016]

Mercury thermometer RyoSo location according to claim 1, wherein the SUMMARY OF THE INVENTION The present invention is formed in the first block, the slide pin to the reciprocating motion is inserted therein and mercury
A through hole for performing metering, it is formed in the second block
And a through hole that can communicate with the through hole and the inside of which is filled with mercury, and the through hole and the recess can communicate with each other .
When in the state, move the slide pin in the specified direction
By allowing the mercury in the recess to
Suctioned into the through hole by an amount corresponding to the
A mechanism for measuring a fixed amount of mercury and the predetermined amount in the through hole.
In a state in which a certain amount of mercury has been sucked , at least one of the first block and the second block is placed in front of the through hole with respect to the boundary surface between the through hole and the recess .
By moving the block in parallel so that it is not positioned, the communication state is released, and the slide pin is moved to the predetermined position.
Through the through-hole by moving in the direction opposite to
A machine for pushing out the predetermined amount of mercury in the outside of the through hole
And a structure having a structure.

Further, mercury weighing how <br/> method according to claim 3 of the present invention is formed in the first block, the slide pin is inserted to a reciprocating motion therein, and a metering mercury Do
The slide pins of mercury in the recess and the through-hole is formed in the second block, and is a recess mercury filled during communication with the interior, by moving the slide pin in a predetermined direction for the amount corresponding to the movement amount narrowing suck in the through hole, after weighing a predetermined amount of mercury, the boundary surface between the first block and the said through-hole and the recess to at least one of the second blocks to The penetration
By releasing the communication state by moving in parallel so that the second block is not positioned in front of the hole, and after releasing the communication state, the slide pin is moved in the direction opposite to the predetermined direction. In front of the through hole
That is, a predetermined amount of mercury is pushed out of the through hole .

[0018] By such a mercury thermometer RyoSo location and mercury weighing how <br/> method, the least of the first block and the second block
Move one side parallel to the interface between the through hole and the recess.
By doing so, the communication between the through hole and the recess is released.
Therefore, in the communication state, mercury is used as a boundary between the through hole and the recess.
It can be cut at the interface, resulting in a negative effect on the surface tension of mercury.
Mercury can be accurately measured without being echoed,
In addition, due to the reciprocating motion of the slide pin, the mercury in the through hole
Sucking in and pushing mercury out of the through holes
As a result, you don't need vacuuming
Allows you to perform high-speed weighing and slide slide
The amount of mercury to be measured
It can be easily adjusted .

Further, in the method for manufacturing a fluorescent lamp according to claim 5 of the present invention, the amount of mercury enclosed in the fluorescent lamp is measured.
In that process, metering a predetermined amount of mercury using mercury <br/> weighing how according to claim 3 or claim 4.

As a result, the optimum amount of mercury can be enclosed, so that abnormal lighting due to lack of mercury during the rated life can be prevented and an environmentally friendly fluorescent lamp can be obtained.

[0021]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

The mercury thermometer RyoSo location according to the embodiment of the present invention, as shown in FIG. 1, and a second block 2 to the first block 1 and the movable fixed.

The flat fixed surface 1a of the first block 1 and the second
The flat movable surface 2a of the block 2 is in contact with each other.

A through hole 3 having an inner diameter of 0.4 mm and a total length of 5 mm is formed in the first block 1. One end of the through hole 3 is provided on the fixed surface 1a. In addition, inside the through hole 3, an inner diameter of 0.4 mm that reciprocates in the axial direction,
A slide pin 4 having a total length of 5.2 mm is inserted. At the other end of the slide pin 4, there is provided a slide pin chuck 5 that reciprocates the slide pin 4 (direction A in FIG. 1, or direction B, which is the opposite direction).

The distance that the slide pin 4 has moved in the direction A in the through hole 3 from the state where one end of the slide pin 4 is on the fixed surface 1a, that is, the slide length is L (mm).

A stopper 6 for defining the slide length L of the slide pin 4 is provided on the opposite side of the slide pin 4 from the second block 2.

The second block 2 has a concave portion 2b filled with mercury (here, mercury means liquid mercury). The opening end 2c of the recess 2b is
It is provided on the movable surface 2a.

In the state shown in FIG. 1, the concave portion 2b and the through hole 3 are formed.
And are in communication.

A mercury supply tube 7 for replenishing mercury into the recess 2b is provided on the side of the recess 2b opposite to the opening end 2c. The mercury supply pipe 7 is connected to a mercury tank (not shown), and the mercury in the recess 2b is always filled up to the opening end 2c by being pressurized.

On the opposite side of the second block 2 from the first block 1, an elastic body 8 composed of a coiled compression spring is provided. One end of the elastic body 8 is in contact with the elastic body receiving portion 2d of the second block 2. The second block 2 is pressed against the first block 1 side by the elastic body 8. As a result, it is possible to prevent mercury from leaking between the first block 1 and the second block 2.

[0031] Next, the operation of such a mercury thermometer RyoSo location, described mercury weighing how according to the present invention.

2 to 5 are plan sectional views of the mercury measuring apparatus according to the present invention. Further, FIG. 6 is a front sectional view.

First, as shown in FIG. 2, the through hole 3 and the recess 2b are in communication with each other. Further, one end of the slide pin 4 is on the fixed surface 1a. That is, the slide length L is 0
mm.

As shown in FIG. 3 from the state shown in FIG. 2, the slide pin 4 is moved in the direction A by the slide pin chuck 5 until the slide pin chuck 5 comes into contact with the stopper 6, so that the mercury in the recess 2b is removed. Is partially drawn into the through hole 3 (slide length L> 0).

By changing the slide length L,
The amount of mercury drawn into the through hole 3 changes, that is, the amount of mercury measured can be changed. The slide length L can be adjusted by the position of the stopper 6. Therefore, the necessary amount of mercury can be easily adjusted by adjusting the position of the stopper 6. For this reason, for example, it is possible to easily arrange various fluorescent lamps having different required amounts of mercury on the same line to manufacture them with one apparatus.

Next, as shown in FIG. 4 from the state shown in FIG. 3, the second block 2 slides the fixed surface 1a and the movable surface 2a in the direction C, that is, the through hole 3 and the recess 2b. Is translated to the boundary surface of. As a result, the communication state between the through hole 3 and the recess 2b is released. However,
In the state shown in (1), since the slide pin 4 is fixed, the mercury drawn into the through hole 3 is prevented.
Never fall from.

After that, as shown in FIG. 5 from the state shown in FIG. 4, the slide pin 4 is moved in the B direction by the slide pin chuck 5, so that the mercury in the through hole 3 is pushed out. Due to the surface tension, the extruded mercury is suspended in one end of the through hole 3 as a mercury drop 9.

Next, as shown in FIG. 6, the mercury drop 9 is supplied by being dropped into a funnel-shaped guide 11 made of glass by blowing, for example, argon gas from a gas injection port 10 located above. It

In this way, for example, by blowing argon gas to drop the mercury drop 9, the mercury drop 9 can be reliably dropped without being attached to one end of the through hole 3 by the surface tension. it can.

The method of manufacturing a fluorescent lamp according to the present invention is as follows:
It is to use mercury which is metered by mercury weighing how the present invention. That is, as shown in FIG. 6, by enclosing the mercury drop 9 in the mercury capsule 12 via the guide 11, for example, a predetermined amount of mercury can be enclosed in the fluorescent lamp.

After the mercury is encapsulated in the mercury capsule 12 as described above, the fluorescent lamp can be manufactured by a usual method.

It should be noted, mercury thermometer RyoSo location after the state shown in FIG. 6, returns to the state shown in FIG. 2, and repeat the operation to enclose the mercury in the following mercury capsule.

Next, examined the measurement accuracy of such mercury thermometer RyoSo location (hereinafter, referred to as the present invention).

In the product of the present invention, the amount of mercury sucked into the through hole 3 was set to 3.0 mg. Therefore, the inner diameter of the through hole 3 is 0.4 mm and the maximum slide length L is
_{The max} was 1.75 mm. However, the specific gravity of mercury is 1
It is 3.6 g / cm ³ .

In addition, 100 pieces of the present invention were produced and the weighing accuracy of each was examined.

The variation in the amount of mercury weighed with a mercury thermometer RyoSo location of the present invention was 0.15mg against 3 mg. Therefore, in the product of the present invention, the variation in the amount of mercury is shown in FIG.
It can be reduced to 1/20 with respect to variations in the first conventional mercury thermometer RyoSo location as shown in (a) 3 mg.

The time required from the beginning of the drawing of mercury into the through hole 3 to the dropping of the mercury drop 9 into the mercury capsule 12 was 0.5 seconds. That is, the mercury meter of the present invention
RyoSo location single per 7200 times / hour mercury weighing can be carried out. Therefore, the measurement speed of mercury is shown in Fig. 7 (a).
1/2 in comparison with the first conventional mercury thermometer RyoSo location as shown in
To, and may be reduced to 1 / 10-1 / 6 as compared with the second conventional mercury thermometer RyoSo location as shown in FIG.

[0048] According to a mercury thermometer RyoSo location and mercury weighing how the above-described the present invention, it is possible to cut the mercury at the interface between the through-hole 3 and the recess 2b. In other words, since mercury can be measured without being affected by the surface tension of mercury and vacuuming is not required, mercury can be measured accurately and at high speed.

When mercury is sealed in a fluorescent lamp,
The use of the mercury weighing how, it is possible to reduce variation in the amount of mercury, it is possible to encapsulate the just enough optimum amount of mercury, to prevent abnormal lighting by mercury shortage in nominal life It is possible to obtain a fluorescent lamp that is environmentally friendly.

In the above embodiment, the case where only the second block 2 is moved has been described, but only the first block 1 or the first block 1 and the second block 2 are penetrated through the through holes 3 in opposite directions. Even if it is moved in parallel to the boundary surface between the concave portion 2b and the concave portion 2b, the same effect as above can be obtained.

Further, in the above embodiment, the case where mercury is enclosed in the mercury capsule 12 has been described, but the same effect as above can be obtained even when the mercury is directly enclosed in the fluorescent lamp.

Further, in the above embodiment, the second block 2 is pressed to the first block 1 side by the elastic body 8, but the first block 1 is pressed to the second block 2 side by the elastic body 8. However, the same effect as above can be obtained.

[0053]

As described in the foregoing, the first aspect of the present invention
The invention according to claim 1 has a small number of first blocks and second blocks.
Move at least one side to the interface between the through hole and the recess
By doing so, the communication between the through hole and the recess is released.
Therefore, in the communication state, the mercury penetrates the through-holes and recesses.
Can be cut at the interface of the resulting mercury surface tension
The mercury can be measured accurately without being affected by
And the slide pin reciprocates into the through hole.
Suction of mercury and extrusion of mercury to the outside of the through hole
As a result, it does not require vacuuming.
In Ino, it is possible to weigh at high speed, Sly
Mercury to be measured by adjusting the amount of movement of the dopin
It is capable of providing a mercury weighing device can easily adjust the amount. Further, in claim 2 of the present invention
In the invention, particularly, mercury is contained in the first block and the second block.
A mercury metering device that can prevent leakage from between
A storage device can be provided. In addition, according to the present invention
The invention according to claim 3 is the first block and the second block.
At least one of the
By moving in parallel, the communication between the through hole and the
Since it has been released, mercury will penetrate through
Can be cut at the interface between the concave and the
Accurately weigh mercury without being affected by surface tension
Can be penetrated by the reciprocating movement of the slide pin
Suction of mercury into the hole and mercury to the outside of the through hole
As a result, vacuuming is required.
Since it does not require, it is possible to measure at high speed.
In addition, by adjusting the movement amount of the slide pin,
Mercury measuring method that can easily adjust the amount of mercury to be used
The law can be provided. In addition, according to the present invention
In the invention according to claim 4, particularly, the mercury drop is near one end of the through hole.
Can be reliably dropped without adhering to the side
It is possible to provide a mercury measuring method.

Further, the invention according to claim 5 of the present invention provides a method of manufacturing a fluorescent lamp which can prevent abnormal lighting due to lack of mercury during the rated life and can obtain an environmentally friendly fluorescent lamp. What can be provided.

[Brief description of drawings]

Plan sectional view of a mercury thermometer RyoSo location is a preferred embodiment of the invention; FIG

[Figure 2] Similarly plan sectional view of a mercury thermometer RyoSo location for explaining the operation of a mercury thermometer RyoSo location

[Figure 3] Similarly plan sectional view of a mercury thermometer RyoSo location for explaining the operation of a mercury thermometer RyoSo location

[4] Also plan sectional view of a mercury thermometer RyoSo location for explaining the operation of a mercury thermometer RyoSo location

[5] Also plan sectional view of a mercury thermometer RyoSo location for explaining the operation of a mercury thermometer RyoSo location

[6] Also front sectional view of a mercury thermometer RyoSo location for explaining the operation of a mercury thermometer RyoSo location

[7] (a) a front sectional view of a conventional mercury thermometer RyoSo location (b) a front sectional view of a conventional mercury thermometer RyoSo location

[8] Another front cross-sectional view of a conventional mercury thermometer RyoSo location

[Explanation of symbols]

1st block 2 Second block 3 through holes 4 slide pins 8 elastic body

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Hiroyuki Miyake, 1-1, Sachimachi, Takatsuki, Osaka Prefecture Matsushita Electronics Industrial Co., Ltd. (56) Reference JP-A-5-242757 (JP, A) Sho 63-138631 (JP, A) Actual Kaihei 6-33031 (JP, U) Japanese Patent Publication 7-24187 (JP, B2) Japanese Patent Publication 7-27756 (JP, B2) (58) Fields investigated (Int .Cl. ⁷ , DB name) G01F 11/06

Claims (5)

(57) [Claims] 1. A through hole formed in the first block, into which a reciprocating slide pin is inserted, and for measuring mercury, and a second block, wherein the through hole is formed. When the concave portion that is capable of communicating with the concave portion filled with mercury and the through hole and the concave portion are in communication with each other, the mercury in the concave portion is removed by moving the slide pin in a predetermined direction. A mechanism for sucking a predetermined amount of mercury into the through hole by an amount corresponding to the amount of movement of the slide pin and a mechanism for measuring the predetermined amount of mercury, and a state in which the predetermined amount of mercury is sucked into the through hole. The communication state is released by translating at least one of the second blocks with respect to the boundary surface between the through hole and the recess so that the second block is not positioned in front of the through hole. And a mechanism for pushing out the predetermined amount of mercury in the through hole to the outside of the through hole by moving the slide pin in a direction opposite to the predetermined direction. apparatus. 2. The mercury metering device according to claim 1, wherein at least one of the first block and the second block is pressed toward the other block by an elastic body. 3. A through hole formed in the first block, into which a reciprocating slide pin is inserted, and through which mercury is measured, and a second block, in which mercury is formed. When the filled recess is in communication, the slide pin is moved in a predetermined direction so that the mercury in the recess is sucked into the through hole by an amount corresponding to the amount of movement of the slide pin, and a predetermined amount of mercury is obtained. After measuring, at least one of the first block and the second block with respect to the boundary surface between the through hole and the recess,
The communication state is released by parallel movement so that the second block is not positioned in front of the through hole, and after the communication state is released, the slide pin is moved in the direction opposite to the predetermined direction. Thereby, the predetermined amount of mercury in the through hole is pushed out of the through hole. 4. The slide pin is moved in a direction opposite to the predetermined direction to push out the predetermined amount of mercury in the through hole to the outside of the through hole and then hang down at one end of the through hole. The mercury measuring method according to claim 3, wherein the mercury drop is blown off from above the mercury drop by a gas and dropped. 5. A method for measuring mercury enclosed in a fluorescent lamp.
In the step, the mercury meter according to claim 3 or 4.
Fluorescent lamp manufacturing method of which is characterized by metering a predetermined amount of mercury using the amounts how.