KR101183301B1 - Discharge lamp - Google Patents

Abstract

It is possible to prevent the occurrence of cracks in the glass member disposed in the seal tube, to finally prevent the gas leak of the light emitting tube, to prevent the breakage of the seal tube to provide a discharge lamp that can obtain a long service life.

The discharge lamp of the present invention includes a discharge vessel 1 in which seal tubes 12 are continuously provided at both ends of the light emitting tube 11, columnar glass members 7 disposed inside the seal tube 12, A metal current collector plate 5 and a tip of which are inside the seal tube 12 and disposed opposite to a cross section of the light emitting tube 11 side of the glass member 7, extend into the light emitting tube 11, and the tip thereof is extended. The internal lead rod which is provided in the electrode 2, the rear end side opposite to the electrode 2 is inserted into the through hole P formed in the center of the collector plate 5, and fixed to the collector plate 5 ( In the discharge lamp which consists of 3), the base end 3a of the rear end side of the inner lead rod 3 protrudes from the cross section of the collector plate 5, and is between the glass member 7 and the collector plate 5, and The metal body M is arrange | positioned, the metal body M has the space | gap K into which the base end 3a of the internal lead rod 3 is inserted, and protruded from the end surface 5a of the collector plate 5. The protruding length of the proximal end of the inner lead rod 3 is L1, If the length of the direction in which the base end (3a) of the protruding sokche inner lead pin 3 of the gap provided in (M) to L2, characterized in that L1 <L2.

Description

DISCHARGE LAMP

The present invention relates to a discharge lamp, and more particularly to a discharge lamp having an airtight seal structure suitable for high current.

A discharge lamp, for example, a mercury lamp, is generally used widely in a field using ultraviolet rays emitted from a lamp, for example, in the photochemical industry, in the manufacture of semiconductor devices, and in other fields.

In high-pressure mercury lamps or ultra-high-pressure mercury lamps for large currents, the amount of mercury, which is a main component of the light emitting gas, is large and the gas pressure in the light emitting tube at the time of lighting is very high, and the amount of heat generated is high. And large pressure resistance are required. In addition, during lighting, mercury in the light emitting tube needs to be completely evaporated. Therefore, in the lighting tube during lighting, it is necessary that there is no low temperature portion where mercury condensation occurs.

In view of this, in the conventional high pressure mercury lamp or the ultra high pressure mercury lamp, the glass forming the seal tube is directly welded to a lead rod for power supply, so that it is not a so-called rod seal structure which achieves the airtight seal of the seal tube, and is for sealing. A so-called foil seal structure using a metal foil is employed.

It is explanatory drawing which shows an example of the high pressure mercury lamp which has a thin seal structure. 1 is a discharge container including a light emitting tube 11 and a seal tube 12 subsequent thereto. The electrode 2 is arrange | positioned in the light emitting tube 11 of this discharge container 1, and this electrode 2 is supported by the internal lead rod 3. As shown in FIG. The inner lead rod 3 is held in the seal tube 12 by the glass holding cylinder 4 holding the inner lead rod 3.

The rear end side of the inner lead rod 3 opposite to the electrode 2 is inserted into the through hole of the current collector plate 5 made of a high melting point metal such as molybdenum and welded to the current collector plate 5. The metal foil 6 for power supply is welded to the surface of the light-emitting tube 11 side of this collector plate 5. In the outer periphery of the cylindrical glass member 7, the metal foil 6 for electric power feeding is spaced apart in the circumferential direction, and is arrange | positioned 5 pieces, for example in strip shape in the axial direction of the said glass member 7.

And the metal foil 6 for electric power feed is welded to the plate-shaped metal member 8 in the other end part on the opposite side to the direction welded to the collector plate 5, and the external lead through this metal member 8 is carried out. It is electrically connected to the rod 9.

The outer lead rod 9 is held by a glass holding cylinder 41 holding the outer lead rod 9, penetrates through the metal member 8, and is welded to the metal member 8, thereby providing a glass member ( It is inserted into the hole 71 formed in 7).

And the molybdenum metal foil M1 is arrange | positioned between the glass member 7 and the collector plate 5, and it is made of molybdenum between the holding cylinder 4 and the collector plate 5 which hold | maintain the inner lead rod 3, Metal foil M2 is disposed.

As shown to Fig.8 (a), metal foil M1 is a disk shaped metal foil which does not have a through hole, and the diameter is substantially the same as the diameter of the collector plate 5.

As shown to FIG. 8 (b), metal foil M2 is a ring-shaped metal plate in which the through-hole which the internal lead 3 penetrates in the center is formed, and the diameter is substantially the same as the diameter of the collector plate 5.

In addition, since the other seal pipe part is also the same structure, description is abbreviate | omitted.

The electrode 2 is placed in the light emitting tube 11 of the discharge container 1 configured as described above. And while this discharge container 1 is rotated in the circumferential direction by a glass shelf etc., it heat-processes using the burner etc. from the exterior of the seal tube 12, and the inner periphery of this seal tube 12 and the glass member 7 are carried out. ) Is hermetically welded through the metal foil (6) for power supply.

Moreover, the glass of the seal tube 12 of the part which opposes the holding cylinder 4 is also heat-processed, and it welds to the inner periphery of this seal tube 12, and the holding cylinder 4.

In addition, since the other seal pipe part is also the same structure, description is abbreviate | omitted.

In the heat treatment process of the seal tube 12, when the glass member 7 and the collector plate 5 contact, when a crack is generated in the glass member 7 by the difference of the expansion coefficient of each member, Therefore, metal foil M1 is arrange | positioned between the glass member 7 and the collector plate 5 so that the glass member 7 and the collector plate 5 may not contact.

Similarly, in the heat treatment process of the seal tube 12, when the holding cylinder 4 holding the inner lid 3 and the current collector plate 5 are in contact with each other, the holding tube 4 is held by the difference in the expansion coefficient of each member. Since fine cracks may generate | occur | produce in the cylinder 4, the metal foil M2 is arrange | positioned between the cylinder 4 and the collector 5 so that the cylinder 4 and the collector 5 may not contact. Doing.

Moreover, depending on the lamp, there exists a lamp of the structure which does not arrange | position metal foil M2 between the holding cylinder 4 and the collector plate 5, too.

However, even in a structure in which the metal foil M1 is disposed between the glass member 7 and the current collector plate 5, in the step of heat treatment using a burner or the like from the outside of the seal tube 12, in some cases, the glass member ( Cracks occurred in the portion in contact with the metal foil M1 of 7), the cracks grew during lighting, and finally the gas in the light emitting tube 11 leaked or the seal tube 12 was broken.

As shown in FIG. 9, the rear end side opposite to the electrode 2 of the internal lead rod 3 is inserted into the through hole of the current collector plate 5 and welded to the current collector plate 5. It is difficult to match the base end 3a of the rear end side of the lead rod 3 with the end surface 5a of the collector plate 5, and the base end 3a of the inner lead rod 3 is made into the end surface of the collector plate 5 ( It may be welded protruding from 5a).

In the case of such a structure, in the process of heat-processing using the burner etc. from the exterior of the seal pipe 12, the base end 3a of this protruding inner lead rod 3 makes metal foil M hold | maintain the glass member 7 It pressed to the side and the crack generate | occur | produced in the glass member 7 of the pressed part.

[Patent Document 1] Japanese Unexamined Patent Publication No. 2000-149873

This invention is made | formed based on the above circumstances, The objective is to prevent a crack generate | occur | produce in the glass member arrange | positioned in a seal tube, to prevent the gas leak of a light tube finally, and to prevent the damage of a seal tube. It is possible to provide a discharge lamp that can achieve a long service life.

The discharge lamp of Claim 1 is the discharge container provided with the seal tube continuously in the both ends of a light emitting tube, the columnar glass member arrange | positioned inside the said seal tube, and the inside of the said seal tube, The light emitting tube side of the said glass member A metal current collector plate disposed opposite to the end face of the metal, and a tip thereof extends into the light emitting tube, and an electrode is provided at the tip thereof, and a rear end side opposite the electrode is inserted into a through hole formed in the center of the current collector plate. An inner lead rod fixed to the current collector plate, a glass holding cylinder for holding an inner lead rod disposed between the outer circumference of the inner lead rod and the inner circumference of the seal tube, and one end portion is extended along the outer circumference of the glass member. In the discharge lamp which consists of a metal foil for power supply connected to the said collector board and the other end electrically connected to the external lead rod, the base end of the rear end side of the said inner lead rod, Protruding from an end surface of the current collector plate, wherein a metal body is disposed between the glass member and the current collector plate, and the metal body has a gap into which the base end of the inner lead rod is inserted, and the metal body protrudes from the end surface of the current collector plate. When the length of the protruding length of the proximal end of the inner lead rod is L1 and the length in the direction in which the proximal end of the inner lead rod of the cavity provided in the metal body protrudes is L2, L1 <L2.

The discharge lamp of Claim 2 is the discharge lamp of Claim 1, In particular, the said metal body is what laminated | stacked the some ring-shaped metal foil in which the through-hole was formed in the center, and the through-holes of each said metal foil overlap each other, A communication hole is formed, and the said communication hole becomes the space | gap provided in the said metal body, It is characterized by the above-mentioned.

The discharge lamp of Claim 3 is the discharge lamp of Claim 1, In particular, the said metal body is a metal foil which consists of a flat part and the bent part by which the periphery of the said flat part was bent in the direction of the said collector plate, A recess is formed by the surface of the inner lead rod side in the flat part of the said metal foil, and the inner edge of the bending part of the said metal foil, The said recess is characterized by the space | gap provided in the said metal body, It is characterized by the above-mentioned.

According to the discharge lamp of this invention of Claim 1, since the rear end side of an inner lead rod is welded to the through-hole of a collector plate, and a metal body is arrange | positioned between this collector plate and the columnar glass member arrange | positioned inside the seal tube. By this metal body, a glass member and a collector plate can be isolate | separated, without contacting. In addition, the metal body has a gap into which the base end of the rear end side of the inner lead rod is inserted, and the base end of the inner lead rod protrudes from the end face of the current collector plate, and the protruding length of the base end of the inner lead rod protruded from the end face of the current collector plate. When L1 and the length of the direction where the base end of the said inner lead rod of the space | gap provided in the metal body protrudes are L2, since L1 <L2, when heat-processing using a burner etc. from the exterior of a seal tube, Even if the proximal end has a shape protruding from the end face of the current collector plate, the proximal end of the inner lead rod and the glass member do not come into contact with each other. Generation can be prevented, and finally, gas leakage of the light emitting tube can be prevented, and damage to the sealing tube can be prevented, resulting in a long service life. have.

Moreover, according to the discharge lamp of this invention of Claim 2, the metal body is what laminated | stacked the some ring-shaped metal foil in which the through-hole was formed in the center, and through-holes of each metal foil overlap each other, and the communication hole is formed, The communication hole is a cavity provided in the metal body, and the base end of the inner lead rod protruding from the end face of the current collector plate is inserted in the gap, so that the base end of the inner lead rod can be prevented from contacting the glass member with a simple structure. .

Moreover, according to the discharge lamp of this invention of Claim 3, a metal body is a metal foil which consists of a flat part and the bending part bent in the direction of a collector plate in the periphery of this flat part, The internal lead in the flat part of this metal foil Since a recess is formed by the surface of the rod side and the inner edge of the bent portion of the metal foil, the recess is formed into a gap provided in the metal body, and the base end of the inner lead rod protruding from the end face of the current collector plate is inserted into the gap. It is possible to prevent the base end of the inner lead rod from touching the glass member with a simple structure.

The discharge lamp of this invention is demonstrated using drawing.

1 is a cross-sectional view of the discharge lamp of the present invention.

1 is a discharge container including a light emitting tube 11 and a seal tube 12 subsequent thereto. The electrode 2 is arrange | positioned in the light emitting tube 11 of this discharge container 1, and this electrode 2 is provided in the front-end | tip of the internal lead rod 3 by which the front end extends into the light emitting tube 11. .

The inner lead rod 3 is inserted into the through hole of the glass holding cylinder 4 disposed between the outer circumference of the inner lead rod 3 and the inner circumference of the seal tube 12 and held in the seal tube 12. It is.

The rear end side of the inner lead rod 3 opposite to the electrode 2 is inserted into a through hole formed in the center of the current collector plate 5 made of a high melting point metal such as molybdenum and welded to the current collector plate 5 to be fixed. It is.

The cylindrical glass member 7 is arrange | positioned inside the seal pipe 11.

The current collector plate 5 is inside the seal tube 12 and is disposed to face the end surface of the light emitting tube 11 side of the glass member 7.

As for the glass member 7, the surface which faces the collector plate 5 is planar.

One end side of the metal foil for power supply 6 is welded to the surface of the light-emitting tube 11 side of the current collector plate 5, and the metal foil 6 for power supply is formed along the outer circumference of the cylindrical glass member 7. Extending in the direction, for example, spaced apart in the circumferential direction of the glass member 7 and arranged in a strip shape, and the other side opposite to the direction welded to the current collector plate 5 of the metal foil 6 for power supply. The side is welded to the dish-shaped metal member 8, and is electrically connected to the external lead rod 9 via this metal member 8. As shown in FIG.

In addition, one end side of the metal foil 6 for electric power feeding may be welded to the side surface of the collector plate 5.

The outer lead rod 9 is held by a glass holding cylinder 41 holding the outer lead rod 9, penetrates through the metal member 8, and is welded to the metal member 8, thereby providing a glass member ( It is inserted into the hole 71 formed in 7).

And the metal body M is arrange | positioned between the glass member 7 and the collector plate 5, and it is made of molybdenum between the holding cylinder 4 which hold | maintains the inner lead rod 3, and the collector plate 5; Metal foil M2 is disposed.

The metal body M will be explained in detail later.

As shown in FIG. 8 (b), the metal foil M2 is a ring-shaped metal foil having a through hole through which the inner lead 3 penetrates at the center thereof, and the diameter thereof is almost the same as the diameter of the current collector plate 5.

In addition, since the other seal pipe part is also the same structure, description is abbreviate | omitted.

In addition, depending on the lamp, the metal foil M2 may not be disposed between the holding cylinder 4 and the current collector plate 5.

Next, the function of the metal body M will be described in detail.

2 is an enlarged cross-sectional view showing only the glass member, the metal body, the current collector plate, and the inner lead rod.

As shown in FIG. 2, the metal body M is arrange | positioned between the glass member 7 and the collector plate 5, and this metal body M is the outer diameter of the collector plate 5, and the glass member 7 Molybdenum has an outer diameter of 10 mm, which is approximately equal to the diameter of the cross section on the current collector plate 5 side, and a through hole P having an inner diameter of 5 mm larger than the outer diameter of the proximal end on the rear end side of the inner lead rod, and having a thickness of 0.05 mm. It is a metal foil of one piece.

In addition, as shown in FIG. 2, it is difficult to match the end surface 5a of the collector plate 5 and the base end 3a of the internal lead bar 3, and the base end 3a of the internal lead bar 3 is slightly When the protruding length of the base end 3a of the inner lead rod 3 protruding from the end surface 5a of the collector plate 5 and protruding from the end surface 5a of the collector plate 5 is L1, L1 is 0.033. mm.

In addition, when length of the direction where the base end 3a of the inner lead rod 3 of the space | gap K provided in the metal body M protrudes is set to L2, L2 is 0.05 mm. The length of this L2 is the thickness of one metal foil.

That is, the protruding length of the base end 3a of the inner lead rod 3 protruding from the end surface 5a of the current collector plate 5 is L1 and the inner lead rod 3 of the void K provided in the metal body M. If the length in the direction in which the base end 3a of the projection protrudes is L2, the relationship L1 <L2 is satisfied.

As a result, when heat-processing using the burner etc. from the exterior of the seal tube 12, and welding the glass member 7 and the seal tube 12, the metal body M is connected to the glass member 7 and the collector plate. By arrange | positioning between (5), the metal member M prevents the glass member 7 and the collector plate 5 from being completely in contact with each other, and from the end surface 5a of the collector plate 5, Even if the proximal end 3a of the inner lead rod 3 protrudes, since the proximal end 3a of the protruding portion does not contact the glass member 7, it is possible to prevent cracks in the glass member 7. Finally, gas leakage of the light emitting tube can be prevented, and damage to the seal tube can be prevented, resulting in a long service life.

In addition, as a combination of the metal body M, the collector plate 5, and the glass member 7, the outer diameter of the metal body M, the collector plate 5, and the collector plate of the glass member 7, for example ( The same effect can be acquired even if the combination whose diameter of the cross section of the side of 5) is 15 mm which is substantially the same, and the inner diameter of the through hole of the metal body M is 6 mm. For example, the diameter of the metal body M, the outer diameter of the collector plate 5, and the diameter of the cross section on the collector plate 5 side of the glass member 7 are substantially the same, and is 30 mm of the through-hole of the metal body M. The same effect can be obtained even if the combination has an inner diameter of 6 mm.

3 is an enlarged cross-sectional view showing only a glass member, a metal body, a current collector plate, and an internal lead rod, which is another embodiment of the discharge lamp of the present invention, and FIG. 4 is only a metal foil constituting the metal body shown in FIG. 3. It is a perspective view taken out.

As shown in FIG. 3, the metal body M is arrange | positioned between the glass member 7 and the collector plate 5, and this metal body M is the cross section 5a of the collector plate 5 in the center. It has a space K into which the base end 3a of the internal lead rod 3 which protrudes from is inserted.

The metal body M is a structure which laminated three sheets of ring-shaped metal foil Ma in which the through-hole P was formed in the center shown in FIG.

The current collector plate 5 is a metal plate made of molybdenum, and has a through hole having an inner diameter of 5 mm having a thickness of 2 mm and an outer diameter of 10 mm in which the inner lead 3 communicates with the center.

As shown in FIG. 4, metal foil Ma is the outer diameter of the collector plate 5 and the outer diameter 10 mm which is substantially equal to the diameter of the cross section of the collector plate 5 side of the glass member 7, and has a through-hole with an inner diameter of 5 mm in the center. (P) is formed and is a metal foil made of molybdenum having a thickness of 0.015 mm.

As shown in FIG. 3, in the metal body M, the through holes P of the three metal foils Ma overlap with each other to form a communication hole, and the communication holes become the voids K provided in the metal body M. As shown in FIG. have.

In addition, as shown in FIG. 3, it is difficult to match the end surface 5a of the current collector plate 5 with the base end 3a of the inner lead rod 3, and the base end 3a of the inner lead rod 3 is slightly When the protruding length of the base end 3a of the inner lead rod 3 protruding from the end surface 5a of the collector plate 5 and protruding from the end surface 5a of the collector plate 5 is L1, L1 is 0.033. mm.

Moreover, when length of the direction where the base end 3a of the inner lead rod 3 of the space | gap K provided in the metal body M protrudes is set to L2, L2 is 0.045 mm.

In FIG. 3, for the purpose of explanation, a gap is formed between the metal foils Ma, but in reality there are no voids and the metal foil Ma is in close contact, and the length of this L2 is equal to the thickness of the sum of the three metal foils Ma. will be.

That is, the protruding length of the base end 3a of the inner lead rod 3 protruding from the end surface 5a of the current collector plate 5 is L1 and the inner lead rod 3 of the void K provided in the metal body M. When the length in the direction in which the base end 3a of the projection protrudes is L1, the relationship L1 <L2 is satisfied.

As a result, when heat-processing using the burner etc. from the exterior of the seal tube 12, and welding the glass member 7 and the seal tube 12, the metal body M is connected to the glass member 7 and the collector plate. By arrange | positioning between (5), the metal member M prevents the glass member 7 and the collector plate 6 from being completely in contact with each other, and from the end surface 5a of the collector plate 5, Even when the proximal end 3a of the inner lead rod 3 protrudes, the proximal end surface 3a of the proximal end 3a of the protruding portion does not touch the glass member 7, so that a crack occurs in the glass member 7. Can be prevented, and finally, the gas leak of the light emitting tube can be prevented, and the seal tube can be prevented from being damaged, so that a long service life can be obtained.

In addition, in the said Example, although the metal body M is the structure which laminated | stacked three pieces of metal foil Ma which have the through-hole P, the internal lead rod 3 which protrudes from the end surface 5a of the collector plate 5 is mentioned. Depending on the length of the base end 3a of), the number of laminations of the metal foil Ma may also be appropriately changed.

FIG. 5 is an enlarged cross-sectional view showing only the glass member, the metal body, the current collector plate, and the internal lead rod in the case of using the metal body of another embodiment.

In FIG. 5, the inner lead rod 3 of the gap K provided in the metal body M is longer than the length L1 of the base end 3a of the inner lead rod 3 protruding from the end face 5a of the current collector plate 5. The length L2 in the direction in which the base end 3a of () is protruding is long, and the most current collector plate 5 of the metal foil Ma which laminated | stacked the disk shaped metal foil M1 without a through hole as shown in FIG. It is arrange | positioned at the collector plate 5 side of metal foil Ma near.

In such a discharge lamp, when heat-sealing a seal tube, the metal foil M1 without the through hole deform | transforms so that it may enter into the space | gap K by the base end 3a of the inner lead rod 3. As shown in FIG.

However, since L1 <L2, even if the metal foil M1 without the through hole deforms, the base end 3a of the inner lead rod 3 and the glass member 7 do not reliably contact each other, and the glass member 7 ) Can prevent cracks from occurring.

In addition, although not shown, even when the disk shaped metal foil M1 which does not have a through hole as shown to FIG. 8 (a) is arrange | positioned between metal foil Ma shown to FIG. 3, when the seal tube is heat-processed, there will be no through hole. The metal foil M1 is deformed to enter the gap K by the base end 3a of the inner lead rod 3, but the thickness of the sum of the metal bodies Ma (in this case, if the metal bodies Ma are in close contact with each other, the metal bodies Ma are in contact with each other). The internal lead rod 3 which protrudes from the end surface 5a of the collector plate 5 by L2 becomes the length L2 of the direction where the base end 3a of the internal lead rod 3 of the space | gap K provided protrudes. Since the base end 3a of the base end 3a is larger than the length L1, the base end 3a of the inner lead rod 3 and the glass member 7 do not reliably contact each other, and the cracks are generated in the glass member 7. You can prevent it.

6 is an enlarged cross-sectional view showing only a glass member, a metal body, a current collector plate, and an internal lead rod as another embodiment of the discharge lamp of the present invention.

As shown in FIG. 6, the metal body M is arrange | positioned between the glass member 7 and the collector plate 5, and this metal body M is a structure which bend | folded the periphery of one metal foil Mb. .

The current collector plate 5 is a molybdenum metal plate, and has a through hole having a thickness of 2 mm and an outer diameter of 10 mm with an inner diameter of 5 mm through which the inner lead 3 communicates with the center.

The diameter of the cross section of the glass member 7 on the collector plate 5 side is 10 mm.

The metal foil Mb consists of the flat part Mb1 and the bent part Mb2 in which the periphery of this flat part Mb1 was bent in the direction of the collector plate, and the surface Mb10 and the bent part Mb2 on the inner lead rod 3 side of the flat part Mb1. The recessed part K2 is formed by the inner edge Mb20 of and the base end 3a of the inner lead rod 3 which protruded from the end surface 5a of the collector plate 5 is inserted in this recessed part K2.

This metal foil Mb has a thickness of 0.10 mm, an outer diameter of 10 mm, and an opening diameter of the inner edge Mb20 of the bent portion Mb2 of 7 mm.

As shown in FIG. 6, when the protruding length of the base end 3a of the inner lead rod 3 protruding from the end face 5a of the current collector plate 5 is L1, L1 is 0.033 mm.

In addition, L2 is 0.045 mm when the length of the direction where the base end 3a of the inner lead rod 3 of the recessed part K2 which is the gap K provided in the metal body M protrudes is set to L2. In the case of this embodiment, the length of L2 is the length between the surface Mb10 of the flat part Mb1, and the front end part of the collector plate 5 side of the inner edge Mb20 of the bend part Mb2.

That is, the protruding length of the base end 3a of the inner lead rod 3 protruding from the end surface 5a of the current collector plate 5 is L1 and the inner lead rod 3 of the void K provided in the metal body M. If the length in the direction in which the base end 3a of the projection protrudes is L2, the relationship L1 <L2 is satisfied.

As a result, even if the base end 3a of the inner lead rod 3 protrudes from the end surface 5a of the collector plate 5, the part which the base end 3a protrudes is inserted into the recessed part K2 of the metal foil Mb, and it is inside. The base end 3a of the lead rod 3 does not contact the glass member 7.

As a result, when heat-processing using the burner etc. from the exterior of the seal tube 12, and welding the glass member 7 and the seal tube 12, the metal body M is connected to the glass member 7 and the collector plate. By arrange | positioning between (5), the metal member M prevents the glass member 7 and the collector plate 5 from being completely in contact with each other, and from the end surface 5a of the collector plate 5, Even if the proximal end 3a of the inner lead rod 3 protrudes, since the proximal end 3a of the protruding portion does not contact the glass member 7, it is possible to prevent cracks in the glass member 7. Thus, gas leakage of the light emitting tube can be finally prevented, and damage to the seal tube can be prevented, thereby achieving a long service life.

1 is an explanatory view of a discharge lamp of the present invention.

2 is an enlarged cross-sectional view showing only the glass member, the metal body, the current collector plate, and the inner lead rod of the discharge lamp of the present invention.

3 is an enlarged cross-sectional view showing only the glass member, the metal body, the current collector plate, and the internal lead rod of the discharge lamp of the present invention.

It is a perspective view which took out only the metal foil which comprises the metal body shown in FIG.

5 is an enlarged cross-sectional view showing only the glass member, the metal body, the current collector plate, and the internal lead rod of the discharge lamp of the present invention.

6 is an enlarged cross-sectional view showing only a glass member, a metal body, a current collector plate, and an inner lead rod as another embodiment of the discharge lamp of the present invention.

7 is an explanatory diagram of a conventional discharge lamp.

FIG. 8: is a perspective view which took out only the metal foil of the discharge lamp shown in FIG.

9 is an explanatory diagram showing a fixing structure of a current collector plate and an internal lead.

<Code description>

1: discharge vessel 11: light emitting tube

12: seal tube 2: electrode

3: internal lead rod 4: holding cylinder

5: collector plate 6: metal foil for feeding

7: glass member 8: metal member

9: external lead rod

Claims (3)

A discharge vessel in which seal tubes are continuously installed at both ends of the light emitting tube, A columnar glass member disposed inside the seal tube; A metal current collector plate which is inside the seal tube and is disposed opposite to a cross section of the light emitting tube side of the glass member; An inner lead rod whose tip is extended into the light emitting tube, an electrode is provided at the tip, and a rear end side opposite to the electrode is inserted into a through hole formed in the center of the current collector plate and fixed to the current collector plate; A glass cylinder for holding an inner lead rod disposed between an outer circumference of the inner lead rod and an inner circumference of the seal tube; In the discharge lamp which extends along the outer periphery of the said glass member, one end part is connected to the said electrical power collector plate, and the other end is electrically connected to the external lead rod, The base end of the rear end side of the inner lead rod protrudes from the end face of the current collector plate, A metal body is disposed between the glass member and the current collector plate, The metal body has a gap into which the base end of the inner lead rod is inserted, L1, the protruding length of the proximal end of the inner lead rod protruding from the end surface of the current collector plate; A discharge lamp according to claim 1, wherein L1 &lt; L2 when the length in the direction in which the base end of the inner lead rod of the void provided in the metal body projects is L2. The method according to claim 1, The said metal body is what laminated | stacked the some ring-shaped metal foil in which the through-hole was formed in the center, Through-holes of the respective metal foils overlap each other to form a communication hole, A discharge lamp, wherein said communication hole is a gap provided in said metal body. The method according to claim 1, The metal body is a metal foil composed of a flat portion and a bent portion in which the periphery of the flat portion is bent in the direction of the current collector plate, The recessed part is formed by the surface of the inner lead rod side in the flat part of the said metal foil, and the inner edge of the bending part of the said metal foil, A discharge lamp, characterized in that the recess is a gap provided in the metal body.

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