DE1907720B2 - ELECTRON BEAM TUBE WITH A COOLED COLLECTOR - Google Patents

Description

One with the known cathode ray tube

The invention relates to a cathode ray tube mixed in stages by a flowing coolant a disadvantage occurring in several separate cool-cooled collector electrodes medium systems by a flowing coolant is that locally overheated areas at the chilled hollow collector. Collector electrodes in areas between the

The invention is applicable to any electron beam coolant outlet openings of an arrangement and tubes with collector electrodes and the coolant inlet openings of the next following

Arrangement can occur. It is easy on itself for the inner surface of the more distant one make sure that a section of the collector wall results at the water inlet opening. Order of coolant ducts, where the water A major advantage of the tube after the Ernoch is not evaporated, the speed of the finding can be seen in the fact that the energy supply is too The coolant flow is relatively low and the cooling 5 can be controlled in certain areas of the collector thus remains relatively weak. However, since the up and thus to the device-technical conditions of the heating of each collector section of the energy cooling arrangement is easily adaptable. supply by electron bombardment to this ab- The invention is in the following in connection depends on the cut and if - as described in the drawing. This shows the inner knew stepwise through a flowing coolant io shaping of a preferred embodiment cooled collector electrode is the case - the In- a collector electrode according to the invention for one intensity of the energy supply to the area in the cathode ray tube. The tube, for example The vicinity of the outlet opening can be a high-performance klystron, with an off-cooling stage and the entrance opening of the next nai-me of the collector electrode is considered to be known Cooling stage is more or less the same as at 15, so that here only the collector electrode other, better cooled sections, so that is what is described. Tendency to develop locally overheated areas. The drawing shows an approximate projectile

The invention is based on the object, the föimige hollow collector electrode, which in two stages Cooling of a cathode ray tube which is initially cooled. The one ... cooling stage is followed by a to improve the named type in such a way, '' ate local over- 20 arrangement of longitudinal cooling hits even with high output power of the middle guides 1, which are evenly drained with particularly high reliability understood around the collector in: ~ in the wall are avoided. are formed, formed. These coolant guides

7ur solution of this task sees the invention proceed over slightly less than half of the before. that the inner wall of the collector is shaped 25 length of the collector electrode and have water, that the surface of this wall in the area inlet openings at 2, which the open F. Ende 3 of the sird located closer to a much smaller collector between two cooling stages. as well as the intensity of the steam outlet of the electron bombardment than the openings at 4. Vapor discharge pipes are average with 5 Draws the intensity of the fire at others. The water inlet piping is not shown exposed to the inner wall. 30 posed. The coolant ducts I are shown in the

According to an advantageous development of the created case parallel to the collector axis, Finding is provided that the inner wall in the The second cooling stage is through a second An-Bei : I between two cooling stages to the outside order of cooling cones running in the longitudinal direction, approximately tangential to the elec- tric medium guides 6 with water entry openings at 7 tronenbahnen verlaufena, is formed. 35 and steam outlet openings at 8 are formed. the end

According to a further advantageous embodiment, the reasons for simplifying the drawing are

the invention provides that the inner wall water and steam pipes for the coolant supply

In the area between two cooling stages, Fig. 6 is not shown. The coolant ducts 6

is formed that their surface under a pointed are also formed in the collector wall and

Angle is inclined away from d: n electron orbits. 4 ° evenly distributed around the collector

A particularly preferred embodiment, however, on the surface of an imaginary cone.

The invention further provides that the inner wall so the more or less of the general shape

is shaped. that they have to be adapted in the other areas as the setting of the collector,

which between two cooling stages has an approximate surface of the inner wall of the collector

wise equal amount of energy input through elec- 45 three main sections, two of which. 9 and 10. how

experiences electron bombardment per unit area. shown in section, are curved, and the

Finally, according to a further advantageous third. 11 which lies between the other two

Further development of the invention provides that this and this connects, is conical to a cone-shaped

Sections of the inner surface of the collector wall so tapering step between the parts 9 and 10 to are shaped so that they only form the equations. The two sections 9 and 10 extend

approximately over the lengths of the two

H / _s in (f.) _Yj) cooling stages, and section 11 extends over

. \ ₂ . ⁼ art. the area between the two cooling levels. the

4.-rr sm au sections 9 and 10 are shaped so that at least

55 of the largest part of its surface approximates that of

meet (where 2 λ is the cone angle of the equation already given in the KoI above,

lector entering electron beam, W the entire electron path with length r to the

Beam power, Θ the angle between a connection point of the sections 9 and 11 is in the

given electron path to the inner wall of the KoI figure by the dashed line darlektors and the axis of the collector, β is the angle ⁶ °, while the angles α, β and Θ by dashed

between the wall and the axis at the point dotted lines are given

at which the given electron path into the wall. In the illustrated embodiment, the

opens, and r is the length of the given Elek cone angle of section 11 chosen so that

tronenbahn from its starting point to its β = Θ , so that the surface of this conical end is on the collector), and that the angle 65 of section is tangential to the path shown. These

between the axis of the collector and the inner shape is preferred because it is related to the

area of the collector in the area between two materials is most economical. However, it can

Cooling stages is not smaller than the angle Θ , which is also a larger cone angle for the surface

of section 11 can be used, d. that is, this could, if desired, obliquely from the one shown Run out of the train. If the cone angle is smaller than shown, which is permissible in some cases, then occurs an energy supply by electron bombardment for the section 11, which occurs when the cone angle is reduced increases. The cone angle must therefore not be reduced so far that the heating of the Section 11 is sufficient to cause local overheating in this area.

1 sheet of drawings

Claims (5)

1 2 is particularly suitable for application to KIy patent claims: strons. It is well known that in high-power elec- 1. Cathode ray tube with a sine in multiple cathode ray tubes for the collector electrode To provide reren separate axial coolant S flow cooling, such systems through a flowing coolant flow cooling usually a water and cooled hollow collector, which is characterized by steam cooling. draws that the inner wall of the collector from British patent specification 113887 % is shaped in such a way that the surface of this wall collector electrode arrangement is known, the hollow collector electrode of which in the area (11) between two cooling stages is essentially projectile-shaped (2-4, 7- 8) is of a significantly lower intensity and which, with its open end, faces the electrons of the electron bombardment as the average beam source of the tube, while its lent intensity of the bombardment at other locations is designed in such a way that in the longitudinal direction (9,10) the inner wall is exposed to the formation of running coolant ducts, which 2. Tube according to claim 1, characterized in that it is characterized over almost the entire length of the collector, that the inner wall extend in the area between electrodes and are arranged around them see two cooling calls conical outwards, are. The electron beam enters the open end approximate: =; tangential to the electrons of the collector electrode, and the electrons were traced running, is formed. on the inner wall of the collector electrode 3. Tube according to claim 1, characterized in that it collects 20, where it draws a considerable amount of heat, that the inner wall testify in the area. That on the electron beam source in between two cooling stages is designed in such a way, facing side of the Koliektorelectrode in the pardaß their surface at an acute angle of coolant ducts arranged all the way to one another is inclined away from the electron orbits. incoming water is evaporated in this. Of the 4. Tube according to one of claims 1 to 3, 25 steam is thereby at the other ends of the coolant characterized in that the inner wall is diverted guides, then normally condensed is that it siert in the other areas and fed back to the cooling water tank. (9, 10) than those between two cooling stages. However, such an arrangement is often not approximate same amount of energy sufficient to adequately cool the collector supply by electron bombardment per surface gate electrode of a high-performance klystron or the like unit experiences. cause, if not this collector electrode un- 5. The tube was designed to be economically large and long, and with unsatisfactory characterized in that the economic provided many coolant ducts sections (9, 10) of the inner surface of the collector will. To avoid this difficulty are one wall are shaped so that they provide approximately 35 plurality of coolant guide stages, the equation each of which has a different section of the Κοίΐεκ- gate length cools and each has its own water inlet Wsin (θ -β) _. In the case of the British patent 4.-7r ² sin- '\ / 2 ~~ 1138 874 known arrangement of this kind has the 40 collector has two arrangements of coolant ducts - but it is possible to fill more than two (where 2 a is the cone angle of the electron beam entering in the orders - where the collector guides are entering the electron beam, W both arrangements run in the longitudinal direction and the total beam power, Θ the angle are arranged around the collector around between, and a given electron path to the inner wall 45 which guides an array across a collector and the axis of the collector, the first portion of the collector length and said angle arrival ß between the wall and the axis thereof arrangement opens, via a second section at the point at which extend the given electron collector length. in the normal track in the wall, and r is the length practice extends, each assembly on some of the given electron path from their initial 50 less than half of the total length of the electrical point to its end on the collector Either arrangement is to which the electron gate is), and that the angle between the axis beam source closer ends water is supplied, the collector and the inner surface of the collector and at the other ends steam is discharged, tor in the area (11) between two Cooling collector electrodes, which in this way are step-by-step not smaller than the angle Θ, which flows through arrangements of coolant ducts for the inner surface of the more distant mung-cooled, which results from the different section (10) of the collector wall. Lent, successive sections of the collector length and each of which has its own coolant inlet openings are hereinafter referred to as 60 referred to collectors cooled in stages by a flowing coolant.