JP4826613B2 - Discharge lamp - Google Patents

Description

  The present invention relates to a discharge lamp, and more particularly to a discharge lamp having a hermetic sealing structure particularly suitable for a large current.

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

  In high-current mercury lamps or ultra-high-pressure mercury lamps for large currents, the amount of mercury that is the main component of the luminous gas is large, the gas pressure in the arc tube during lighting is very high, and the calorific value is large. In particular, the glass of the hermetic sealing portion needs to have high heat resistance and pressure resistance. During lighting, it is necessary that the mercury in the arc tube is completely evaporated. For this reason, it is necessary that there is no low temperature portion in which the condensation of mercury occurs in the arc tube during lighting.

  For this reason, in the conventional high pressure mercury lamp or ultrahigh pressure mercury lamp, the so-called hermetic sealing of the sealing tube is achieved by directly welding the glass forming the sealing tube to the lead rod for power supply. Instead of a rod seal structure, a so-called foil seal structure using a metal foil for sealing is employed.

  FIG. 7 is an explanatory view showing an example of a high-pressure mercury lamp having a foil seal structure. Reference numeral 1 denotes a discharge vessel composed of an arc tube 11 and a sealing tube 12 subsequent thereto. An electrode 2 is disposed in the arc tube 11 of the discharge vessel 1, and this electrode 2 is supported by an internal lead bar 3. The internal lead bar 3 is held in the sealing tube 12 by a glass holding cylinder 4 that holds the internal lead bar 3.

  The rear end side of the internal lead bar 3 opposite to the electrode 2 is inserted into the through hole of the current collector plate 5 made of a refractory metal such as molybdenum and welded to the current collector plate 5. A power supply metal foil 6 is welded to the surface of the electric plate 5 on the arc tube 11 side. For example, five metal foils 6 for power feeding are arranged in a strip shape in the axial direction of the glass member 7 on the outer periphery of the cylindrical glass member 7 so as to be separated in the circumferential direction.

The power supply metal foil 6 is welded to the dish-shaped metal member 8 at the other end opposite to the direction welded to the current collector plate 5, and the external lead rod 9 is interposed via the metal member 8. And are electrically connected.
The external lead rod 9 is held by a glass holding cylinder 41 that holds the external lead rod 9, penetrates through the metal member 8, is welded to the metal member 8, and the hole 71 formed in the glass member 7. Has been inserted.

A metal foil M 1 made of molybdenum is disposed between the glass member 7 and the current collector plate 5, and the molybdenum-made metal foil M 1 is placed between the holding cylinder 4 that holds the internal lead rod 3 and the current collector plate 5. Metal foil M2 is disposed.
As shown in FIG. 8A, the metal foil M <b> 1 is a disc-shaped metal foil having no through holes, and the diameter thereof is substantially the same as the diameter of the current collector plate 5.
As shown in FIG. 8B, the metal foil M2 is a ring-shaped metal foil in which a through hole through which the internal lead 3 passes is formed at the center, and the diameter thereof is substantially the same as the diameter of the current collector plate 5. It is.
Since the other sealing tube portion has the same structure, the description thereof is omitted.

The electrode 2 is inserted and disposed in the arc tube 11 of the discharge vessel 1 configured as described above. Then, the discharge vessel 1 is heated using a burner or the like from the outside of the sealing tube 12 while being rotated in the circumferential direction by a glass lathe or the like, and the inner periphery of the sealing tube 12 and the outer periphery of the glass member 7. Are hermetically welded via the power supply metal foil 6.
Furthermore, the glass of the sealing tube 12 at the portion facing the holding tube 4 is also heat-treated, and the inner periphery of the sealing tube 12 and the holding tube 4 are welded.
Since the other sealing tube portion has the same structure, the description thereof is omitted.

In the heat treatment process of the sealing tube 12, when the glass member 7 and the current collector plate 5 are in contact with each other, a minute crack may occur in the glass member 7 due to a difference in expansion coefficient between the members. A metal foil M <b> 1 is disposed between the glass member 7 and the current collector plate 5 so that the current collector plate 5 does not contact.
Similarly, in the heat treatment step of the sealing tube 12, when the holding cylinder 4 that holds the internal lead 3 and the current collector plate 5 are in contact with each other, the holding cylinder 4 is changed due to the difference in expansion coefficient of each member. Since a fine crack may occur, the metal foil M2 is disposed between the holding cylinder 4 and the current collector plate 5 so that the holding cylinder 4 and the current collector plate 5 do not contact each other.
Some lamps have a structure in which the metal foil M <b> 2 is not disposed between the holding cylinder 4 and the current collector plate 5.

  However, even in the structure in which the metal foil M <b> 1 is disposed between the glass member 7 and the current collector plate 5, the glass member 7 is sometimes used in the heat treatment process using a burner or the like from the outside of the sealing tube 12. There is a case where a crack enters a portion in contact with the metal foil M1, the crack grows during lighting, and eventually the gas in the arc tube 11 leaks or the sealing tube 12 is destroyed. It was.

As shown in FIG. 9, the rear end side of the internal lead bar 3 opposite to the electrode 2 is inserted into the through hole of the current collector plate 5 and welded to the current collector plate 5. The base end 3a on the rear end side of the inner lead bar 3 and the end face 5a of the current collector plate 5 are difficult to match, and the base end 3a of the inner lead bar 3 protrudes from the end face 5a of the current collector plate 5 and is welded. There is a case.
In the case of such a structure, in the step of heat treatment from the outside of the sealing tube 12 using a burner or the like, the protruding base end 3a of the internal lead bar 3 presses the metal foil M toward the glass member 7 side, The glass member 7 in the pressed portion was cracked.
JP 2000-149873 A

  The present invention has been made on the basis of the above circumstances, and its purpose is to prevent the occurrence of cracks in the glass member disposed in the sealing tube, and finally to prevent gas leakage in the arc tube. Thus, it is possible to provide a discharge lamp that can prevent the breakage of the sealed tube and obtain a long service life.

  The discharge lamp according to claim 1 includes a discharge vessel in which a sealing tube is continuously provided at both ends of an arc tube, a columnar glass member disposed inside the sealing tube, and an inside of the sealing tube. A metal current collector disposed opposite the end face of the glass member on the arc tube side, a tip extending into the arc tube, and an electrode provided at the tip, on the opposite side of the electrode An inner lead bar inserted into a through hole formed in the center of the current collector plate at the rear end side and fixed to the current collector plate, and between the outer periphery of the inner lead rod and the inner periphery of the sealing tube A glass holding cylinder for holding the arranged internal lead bar, and extending along the outer periphery of the glass member, one end connected to the current collector plate, and the other end electrically connected to the external lead bar In the discharge lamp composed of the connected power supply metal foil, the proximal end of the rear end side of the internal lead bar is the A metal body disposed between the glass member and the current collector plate, the metal body having a gap into which a base end of the internal lead bar is inserted, and Assuming that the protruding length of the base end of the internal lead rod protruding from the end face of the electric plate is L1, and the length of the gap provided in the metal body in the direction in which the base end of the internal lead rod protrudes is L2, L1 < It is characterized by being L2.

  The discharge lamp according to claim 2 is the discharge lamp according to claim 1, and in particular, the metal body is formed by laminating a plurality of ring-shaped metal foils each having a through-hole formed in the center. The through holes of the respective metal foils are overlapped to form a communication hole, and the communication hole is a void provided in the metal body.

  The discharge lamp according to claim 3 is the discharge lamp according to claim 1, and in particular, the metal body includes 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. A recess formed by the inner lead bar side surface of the flat portion of the metal foil and the inner edge of the bent portion of the metal foil, and the recess was provided in the metal body. It is characterized by a void.

  According to the discharge lamp of the present invention as set forth in claim 1, the columnar glass member is disposed inside the current collector plate and the sealing tube, the rear end side of the internal lead bar being welded to the through hole of the current collector plate. Since the metal body is disposed between the glass member and the current collector plate, the metal body can be isolated without contacting the current collector plate. Furthermore, the metal body has a gap into which the proximal end of the rear end side of the internal lead rod is inserted, and the proximal end of the internal lead rod protrudes from the end face of the current collector plate and protrudes from the end face of the current collector plate. Since the length of protrusion of the base end of the inner lead bar is L1, and the length of the gap provided in the metal body in the direction in which the base end of the inner lead bar protrudes is L2, L1 <L2. When the heat treatment using a burner or the like is performed from the outside of the inner lead bar, even if the rear end side base end of the inner lead bar protrudes from the end face of the current collector plate, the base end of the inner lead bar and the glass member Since it is structured so as not to contact, the base end of the internal lead rod does not press the glass member, so it is possible to prevent the glass member from cracking and ultimately prevent gas leakage in the arc tube. Can prevent damage to the sealing tube and can obtain a long service life .

Furthermore, according to the discharge lamp of the present invention described in claim 2, the metal body is formed by laminating a plurality of ring-shaped metal foils each having a through-hole formed at the center, Through holes are overlapped to form a communication hole, and this communication hole is a space provided in the metal body, and the base end of the internal lead bar protruding from the end surface of the current collector plate is inserted into this space. Therefore, it is possible to reliably prevent the proximal end of the internal lead bar from coming into contact with the glass member while having a simple structure.
Further, according to the discharge lamp of the present invention described in claim 3, the metal body is a metal foil comprising 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. A recess is formed by the surface of the flat portion of the metal foil on the side of the internal lead bar and the inner edge of the bent portion of the metal foil, and the recess is a space provided in the metal body. Since the base end of the internal lead rod protruding from the end face of the electric plate is inserted, it is possible to reliably prevent the base end of the internal lead rod from coming into contact with the glass member while having a simple structure.

The discharge lamp of the present invention will be described with reference to the drawings.
FIG. 1 is a cross-sectional view of a discharge lamp of the present invention.
Reference numeral 1 denotes a discharge vessel composed of an arc tube 11 and a sealing tube 12 subsequent thereto. An electrode 2 is disposed in the arc tube 11 of the discharge vessel 1, and the electrode 2 is provided at the tip of an internal lead bar 3 whose tip extends into the arc tube 11.
The internal lead rod 3 is inserted into a through hole of a glass holding cylinder 4 disposed between the outer periphery of the internal lead rod 3 and the inner periphery of the sealing tube 12 and is held in the sealing tube 12. Has been.
The rear end side of the internal lead bar 3 opposite to the electrode 2 is inserted into a through-hole formed at the center of the current collector plate 5 made of a refractory metal such as molybdenum and welded to the current collector plate 5 to be fixed. Has been.

A cylindrical glass member 7 is disposed inside the sealing tube 11.
The current collecting plate 5 is disposed inside the sealing tube 12 and facing the end surface of the glass member 7 on the arc tube 11 side.
The glass member 7 has a flat surface facing the current collector plate 5.
One end side of the power supply metal foil 6 is welded to the surface of the current collector plate 5 on the arc tube 11 side, and the power supply metal foil 6 extends in the axial direction along the outer periphery of the cylindrical glass member 7. The glass member 7 is spaced in the circumferential direction and is arranged in a strip shape, and the other side opposite to the direction welded to the current collector plate 5 of the power supply metal foil 6 is welded to the dish-like metal member 8. The external lead rod 9 is electrically connected through the metal member 8.
One end side of the power supply metal foil 6 may be welded to the side surface of the current collector plate 5.

  The external lead rod 9 is held by a glass holding cylinder 41 that holds the external lead rod 9, penetrates through the metal member 8, is welded to the metal member 8, and the hole 71 formed in the glass member 7. Has been inserted.

A metal body M is disposed between the glass member 7 and the current collector plate 5, and a metal foil M 2 made of molybdenum between the current collector plate 5 and the holding cylinder 4 that holds the internal lead bar 3. Is arranged.
The metal body M will be described in detail later.
As shown in FIG. 8B, the metal foil M2 is a ring-shaped metal foil in which a through hole through which the internal lead 3 passes is formed at the center, and the diameter thereof is substantially the same as the diameter of the current collector plate 5. It is.
Since the other sealing tube portion has the same structure, the description thereof is omitted.
Depending on the lamp, the metal foil M <b> 2 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.
FIG. 2 is an enlarged cross-sectional view showing only the glass member, the metal body, the current collector plate, and the internal lead bar.
As shown in FIG. 2, a metal body M is disposed between the glass member 7 and the current collector plate 5, and this metal body M has an outer diameter of the current collector plate 5 and the current collector plate 5 of the glass member 7. A through hole P having an outer diameter of 10 mm, which is substantially the same as the diameter of the end face on the side, and an inner diameter of 5 mm larger than the outer diameter of the proximal end on the rear end side of the internal lead rod is formed in the center, and is made of molybdenum having a thickness of 0.05 mm. This is one metal foil.

Further, as shown in FIG. 2, it is difficult to match the end surface 5 a of the current collector plate 5 with the base end 3 a of the internal lead bar 3, and the base end 3 a of the internal lead bar 3 is slightly connected to the current collector plate 5. L1 protrudes from the end surface 5a, and L1 is 0.033 mm when the protruding length of the base end 3a of the internal lead bar 3 protruding from the end surface 5a of the current collector plate 5 is L1.
Furthermore, if the length of the gap K provided in the metal body M in the direction in which the base end 3a of the inner lead bar 3 protrudes is L2, L2 is 0.05 mm. The length of L2 is the thickness of one metal foil.
That is, the protruding length of the base end 3a of the internal lead bar 3 protruding from the end surface 5a of the current collector plate 5 is L1, and the length of the gap K provided in the metal body M in the direction in which the base end 3a of the internal lead bar 3 protrudes. When the length is L2, the relationship of L1 <L2 is satisfied.

As a result, when the glass member 7 and the sealing tube 12 are welded by heat treatment from the outside of the sealing tube 12 using a burner or the like, the metal body M is placed between the glass member 7 and the current collector plate 5. This arrangement prevents the metal member M from completely separating and contacting the glass member 7 and the current collector plate 5, and the base end 3 a of the internal lead bar 3 protrudes from the end surface 5 a of the current collector plate 5. However, since the base end 3a of the protruding portion does not contact the glass member 7, it is possible to prevent the glass member 7 from cracking and finally prevent gas leakage of the arc tube and break the sealing tube Can be prevented, and a long service life can be obtained.
In addition, as a combination of the metal body M, the current collector plate 5, and the glass member 7, for example, the outer diameter of the metal body M and the current collector plate 5 is substantially the same as the diameter of the end surface of the glass member 7 on the current collector plate 5 side. The same effect can be obtained by a combination of 15 mm and the inner diameter of the through hole of the metal body M being 6 mm. Further, for example, the outer diameter of the metal body M and the current collector plate 5 and the diameter of the end surface of the glass member 7 on the current collector plate 5 side are substantially the same 30 mm, and the inner diameter of the through hole of the metal body M is 6 mm. The same effect can be obtained by combining.

FIG. 3 is an enlarged cross-sectional view showing only a glass member, a metal body, a current collector plate, and an internal lead bar, which is another embodiment of the discharge lamp of the present invention, and FIG. 4 is a view of the metal shown in FIG. It is the perspective view which took out only the metal foil which comprises a body.
As shown in FIG. 3, a metal body M is disposed between the glass member 7 and the current collector plate 5, and the metal body M has an internal lead bar protruding from the end surface 5 a of the current collector plate 5 at the center. 3 has a gap K into which the base end 3a is inserted.
The metal body M has a structure in which three ring-shaped metal foils Ma each having a through hole P formed at the center shown in FIG.
The current collecting plate 5 is a metal plate made of molybdenum, and has a thickness of 2 mm, an outer diameter of 10 mm, and a through-hole with an inner diameter of 5 mm through which the internal lead 3 communicates.
As shown in FIG. 4, the metal foil Ma has a through hole P having an outer diameter of 10 mm, which is substantially the same as the outer diameter of the current collector plate 5 and the end face of the glass member 7 on the current collector plate 5 side. 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 to form a communication hole, and the communication hole is a gap K provided in the metal body M. .

Further, as shown in FIG. 3, it is difficult to match the end surface 5 a of the current collector plate 5 with the base end 3 a of the internal lead bar 3, and the base end 3 a of the internal lead bar 3 slightly touches the current collector plate 5. L1 protrudes from the end surface 5a, and L1 is 0.033 mm when the protruding length of the base end 3a of the internal lead bar 3 protruding from the end surface 5a of the current collector plate 5 is L1.
Furthermore, if the length of the gap K provided in the metal body M in the direction in which the base end 3a of the inner lead bar 3 protrudes is L2, L2 is 0.045 mm.
In FIG. 3, for the sake of explanation, it is depicted that gaps are formed between the respective metal foils Ma, but in reality there is no gap and the metal foil Ma is in close contact, and this L2 The length is equal to the total thickness of the three metal foils Ma.
That is, the protruding length of the base end 3a of the internal lead bar 3 protruding from the end surface 5a of the current collector plate 5 is L1, and the length of the gap K provided in the metal body M in the direction in which the base end 3a of the internal lead bar 3 protrudes. When the length is L2, the relationship of L1 <L2 is satisfied.

  As a result, when the glass member 7 and the sealing tube 12 are welded by heat treatment from the outside of the sealing tube 12 using a burner or the like, the metal body M is placed between the glass member 7 and the current collector plate 5. This arrangement prevents the metal member M from completely separating and contacting the glass member 7 and the current collector plate 5, and the base end 3 a of the internal lead bar 3 protrudes from the end surface 5 a of the current collector plate 5. However, since the base end surface 3a of the base end 3a of the protruding portion does not contact the glass member 7, it is possible to prevent the glass member 7 from cracking, and finally prevent gas leakage of the arc tube, Damage to the sealing tube can be prevented, and a long service life can be obtained.

  In the above embodiment, the metal body M has a structure in which three metal foils Ma having the through holes P are laminated, but the base end 3a of the internal lead bar 3 protruding from the end face 5a of the current collector plate 5 is used. Depending on the length, the number of stacked metal foils Ma may be changed as appropriate.

FIG. 5 is an enlarged cross-sectional view showing only a glass member, a metal body, a current collector plate, and an internal lead bar when a metal body according to another embodiment is used.
In FIG. 5, the direction in which the base end 3a of the internal lead bar 3 of the gap K provided in the metal body M protrudes from the length L1 of the base end 3a of the internal lead bar 3 protruding from the end surface 5a of the current collector plate 5. The length L2 has a longer structure, and a disc-shaped metal foil M1 having no through hole as shown in FIG. 8A is a metal closest to the current collector plate 5 among the plurality of stacked metal foils Ma. It is arranged on the current collecting plate 5 side of the foil Ma.
In such a discharge lamp, when heat-treating the sealing tube, the metal foil M1 having no through hole is deformed so as to enter the gap K by the base end 3a of the internal lead bar 3.
However, since L1 <L2, even if the metal foil M1 without the through hole is deformed, the base end 3a of the internal lead bar 3 and the glass member 7 are not in contact with each other, and the glass member 7 is cracked. It can be prevented from occurring.

  Although not shown, the sealing tube is heat-treated even when the disc-shaped metal foil M1 having no through hole as shown in FIG. 8A is arranged between the metal foils Ma shown in FIG. At this time, the metal foil M1 having no through-hole is deformed so as to enter the gap K by the base end 3a of the internal lead bar 3, but the total thickness of the metal body Ma (in this case, all the metal bodies Ma are The inner lead rod 3 protruding from the end face 5a of the current collector plate 5) L2 becomes the same as the length L2 of the gap K provided in the metal body Ma in the direction in which the proximal end 3a of the inner lead rod 3 protrudes. Since the base end 3a of the internal lead bar 3 and the glass member 7 are not in contact with each other, the glass member 7 can be prevented from cracking.

FIG. 6 is an enlarged sectional view showing only a glass member, a metal body, a current collector plate and an internal lead bar, which is 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 current collecting plate 5, and this metal body M is the structure which bent the periphery of one metal foil Mb.
The current collecting plate 5 is a metal plate made of molybdenum, and has a thickness of 2 mm, an outer diameter of 10 mm, and a through-hole with an inner diameter of 5 mm through which the internal lead 3 communicates.
As for the glass member 7, the diameter of the end surface at the side of the current collecting plate 5 is 10 mm.
The metal foil Mb is composed of a flat portion Mb1 and a bent portion Mb2 in which the periphery of the flat portion Mb1 is bent in the direction of the current collector plate, and the surface Mb10 on the inner lead bar 3 side in the flat portion Mb1 and the bent portion. A recess K2 is formed by the inner edge Mb20 of Mb2, and the base end 3a of the internal lead bar 3 protruding from the end surface 5a of the current collector plate 5 is inserted into the recess 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.

Further, as shown in FIG. 6, if the protruding length of the base end 3a of the internal lead bar 3 protruding from the end face 5a of the current collector plate 5 is L1, L1 is 0.033 mm.
Furthermore, if the length in the direction in which the base end 3a of the inner lead bar 3 of the recess K2 that is the gap K provided in the metal body M protrudes is L2, L2 is 0.045 mm. In the case of this embodiment, the length of L2 is the length between the surface Mb10 of the flat part Mb1 and the tip of the inner edge Mb20 of the bent part Mb2 on the current collector plate 5 side.
That is, the protruding length of the base end 3a of the internal lead bar 3 protruding from the end surface 5a of the current collector plate 5 is L1, and the length of the gap K provided in the metal body M in the direction in which the base end 3a of the internal lead bar 3 protrudes. When the length is L2, the relationship of L1 <L2 is satisfied.
As a result, even if the base end 3 a of the internal lead bar 3 protrudes from the end surface 5 a of the current collector plate 5, the protruding portion of the base end 3 a is inserted into the recess K 2 of the metal foil Mb. The end 3 a is not in contact with the glass member 7.

  As a result, when the glass member 7 and the sealing tube 12 are welded by heat treatment from the outside of the sealing tube 12 using a burner or the like, the metal body M is placed between the glass member 7 and the current collector plate 5. This arrangement prevents the metal member M from completely separating and contacting the glass member 7 and the current collector plate 5, and the base end 3 a of the internal lead bar 3 protrudes from the end surface 5 a of the current collector plate 5. However, since the base end 3a of the protruding portion does not contact the glass member 7, it is possible to prevent the glass member 7 from cracking, and finally prevent gas leakage of the arc tube, Breakage can be prevented and a long service life can be obtained.

It is explanatory drawing of the discharge lamp of this invention. It is an expanded sectional view which takes out and shows only the glass member of the discharge lamp of this invention, a metal body, a current collecting plate, and an internal lead bar. It is an expanded sectional view which takes out and shows only the glass member of the discharge lamp of this invention, a metal body, a current collecting plate, and an internal lead bar. It is the perspective view which took out only the metal foil which comprises the metal body shown in FIG. It is an expanded sectional view which takes out and shows only the glass member of the discharge lamp of this invention, a metal body, a current collecting plate, and an internal lead bar. FIG. 4 is an enlarged cross-sectional view showing only a glass member, a metal body, a current collector plate, and an internal lead bar, which is another embodiment of the discharge lamp of the present invention. It is explanatory drawing of the conventional discharge lamp. It is the perspective view which took out only the metal foil of the discharge lamp shown in FIG. It is explanatory drawing which shows the fixation structure of a current collecting plate and an internal lead.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Discharge vessel 11 Arc tube 12 Sealing tube 2 Electrode 3 Internal lead bar 4 Holding cylinder 5 Current collector plate 6 Power supply metal foil 7 Glass member 8 Metal member 9 External lead rod

Claims (3)

A discharge vessel in which sealing tubes are connected to both ends of the arc tube;
A columnar glass member disposed inside the sealing tube;
A metal current collector disposed inside the sealing tube and facing an end surface of the glass member on the arc tube side;
A tip extends into the arc tube, an electrode is provided at the tip, and a rear end 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. An internal lead bar;
A holding cylinder made of glass for holding the internal lead bar disposed between the outer periphery of the inner lead bar and the inner periphery of the sealing tube;
In the discharge lamp, which extends along the outer periphery of the glass member, one end is connected to the current collector plate, and the other end is electrically connected to an external lead rod and a metal foil for feeding,
The base end on the rear end side of the internal 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 proximal end of the internal lead rod is inserted,
The protruding length of the base end of the internal lead bar protruding from the end face of the current collector plate is L1,
When the length in the direction in which the base end of the internal lead bar protrudes in the gap provided in the metal body is L2,
A discharge lamp characterized by L1 <L2. The metal body is a laminate of a plurality of ring-shaped metal foils having a through-hole formed at the center,
The through holes of the respective metal foils overlap to form a communication hole,
The discharge lamp according to claim 1, wherein the communication hole is a gap provided in the metal body. The metal body is a metal foil comprising 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,
A concave portion is formed by the inner lead bar side surface in the flat portion of the metal foil and the inner edge of the bent portion of the metal foil,
The discharge lamp according to claim 1, wherein the concave portion is a gap provided in the metal body.

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