US2254836A

US2254836A - Impulse voltage apparatus

Info

Publication number: US2254836A
Application number: US280218A
Authority: US
Inventors: Boldingh Willem Hondius
Original assignee: Hartford National Bank and Trust Co
Current assignee: Hartford National Bank and Trust Co
Priority date: 1938-06-22
Filing date: 1939-06-20
Publication date: 1941-09-02
Anticipated expiration: 1958-09-02

Description

Sept. 2, 1941.

W. H. BOLDINGH IMPULSE VOLTAGE APPARATUS Filed June 20. .1939 2 Sheets-Sheet l u/E 7-0, Balding 22 [fflpn kn t Sept. 2, 1941. w. H. BOLDINGH v IMPULSE VOLTAGE APPARATUS Filed June 20, 1939 2 Sheets-Sheet 2 Patented Sept. 2, 1941 IMPULSE VOLTAGE APPARATUS Willem Hondius lands, assignor,

ford National Bank a ford, Conn, as truste Boldingh, Eindhoven, Netherby mesne assignments, to Hartnd Trust Company, Harte Application June 20, 1939, Serial No. 280,218 In Germany June 22, 1938 14 Claims.

My invention relates to an impulse voltage apparatus.

As is well-known, an apparatus of this type comprises a plurality of condensers connected in parallel through resistances and connected in series through spark gaps. The condensers are charged from a source of direct current, and at a determined voltage the spark gaps break down and the charges of the condensers flow away through a resistance. The voltage can be regulated by varying the spacing of the spark-gap electrodes. However, if the voltage selected is lower, 1. e. short spark gaps, the available energy also is lower.

I have found that, irrespective of the value of the voltage, it is usually desirable in practice to have a substantially constant energy, and the main object of the invention is to provide an apparatus in which the voltage may be varied in stages without any variation of the available energy.

The apparatus according to the invention comprises bi-polar high-voltage change-over switches with which a few condensers may be connected either in parallel to form a group, or connected in series through spark gaps. The resistances for the charging of the condensers remain connected in the usual manner to the condensers.

If there are, for example, twelve condensers in the apparatus, and if the charging voltage amounts to 100 kv., it is possible, apart from the loss of voltage in the spark gaps and the damping resistances, to set up a voltage of 1200 kv. when all the condensers are located in series through the spark gaps. In such a case I may provide, for example, six series-parallel switches with which the twelve condensers may be divided into six groups each comprising two condensers connected in parallel. Because of the parallel connection of the condensers, the voltage is reduced to half its value, but the available number of watt-seconds remains constant. These six switches may be mechanically connected to one another in such a manner that the change-over from 1200 to 600 kv. can be effected in one switching operation.

It is also possible with the aid of eight changeover switches, to divide the condensers into four groups each comprising three condensers or with the aid of nine switches to divide the condensers into three groups each comprising four condensers, so that it is possible to reduce the voltage to 400 and 300 kv. respectively. By using ten switches it is possible to connect six condensers I the n-l-Zth, the 2n+2th, etc.

in parallel to thereby obtain a voltage of 200 kv. Finally, it is possible, when using eleven switches, to connect all twelve condensers in parallel and to utilize the same energy with 100 kv.

According to another embodiment of the invention, I assemble condensers in columns in which they are separated from one another by insulators, and arrange these columns at the corners of a regular polygon. Assuming that the number of columns is n (n being greater than 2) one column would comprise the 1st and the n+lth condenser and, as the case may be, the 2n+lth condenser, etc. The second column would comprise the 2nd condenser of the system, The third column would comprise the condensers numbered 3, n+3, 2n+3, etc., and the fourth column would comprise the condensers 4, n+4, 2n+4 etc. In such an arrangement the switches of condensers 1 and n+1, 2 and n+2, 3 and n+3, etc.,

can be easily mechanically interconnected because these condensers would be arranged in a straight line one above the other.

To obtain a satisfactory spatial potential distribution and a practical arrangement, I prefer to so arrange the condensers that each condenser is the same distance above the condenser of the preceding number in the series. For example, in the case of 11 columns, the insulator which separates the 1st and the n-l-lth condenser and the 1st condenser itself would together have a length of d cms., whereas the second condenser should be arranged d/n cms. higher, the third condenser 2d/n cms. higher, the fourth condenser 3d/n cms. higher than the first condenser, etc.

To give the switches the simplest possible construction they may be secured to arms which extend radially towards the middle of the apparatus. In this case each arm carries a fixed switching member and a movable switching member, the former co-operating with the one neighbouring condenser and the latter with the other. A damping resistance may be arranged within each arm, and such an arrangement has the additional advantage that when two, or more than two, condensers are connected in parallel the corresponding damping resistances are automatically also connected in parallel.

In order that the invention may be clearly understood and readily carried into effect I shall describe the same in more detail with reference to the accompanying drawings.

Figure 1 is a front view in perspective of a voltage impulse apparatus according to the invention,

Figure 2 is a top View of the apparatus of Figure 1,

Figure 3 is a diagrammatical view of a portion of a device for actuating the high-voltage change-over switches of Figure 1, and

Figure 4 is a schematic wiring diagram of the apparatus shown in Figure 1. V

The apparatus shown on Figure 1 comprises a suitable base $9 at the corners of which are arranged four columns A, B, C, and D. Column A comprises three condensers I, 5, and 9 separated by insulators 93, column B comprises three

condensers

2, 6, and it separated by insulators 93, column C comprises two condensers 3 and T separated by insulators 93, and column D comprises two condensers i and 8 separated by an insulator 93. Insulators 83 are also provided at each end of column C and at the bottom of columns B, C and D, and an insulator IE is provided at the bottom of column A. It will be noted that each of the condensers I to It is located the same distance above the condenser having the next lowest reference numeral.

Condensers I to ill are connected in parallel by charging resistances II to 28 inclusive. More particularly and as shown in Figure 4, the terminals of condenser l are connected to the terminalsof condenser 2 by the resistances II and 20, the terminals of condenser 2 are connected to the terminals of condenser 3 by resistances l2 and 2|, etc. As shown in Figure 1 the ends of the condensers l to IE] are provided with bosses to which the resistances H to 28 are connected in order to avoid corona phenomena. The bosses on condenser are indicated by

reference numerals

33 and 39.

As shown on Figure 1, each of the condensers l to It carries two stationary arms each provided at its end with a ball which acts as a stationary contact and to which is rotatably secured a movable switching member. For example, the lower end of condenser 3 supports a stationary arm 5! provided with a ball-shaped contact 53 to which is rotatably secured a switching member 55, and the upper end of this condenser carries a stationary arm 52 provided with a ball-shaped contact 54 to which is rotatably secured a switching member 55. In a similar manner condensers I, 2, 4, 5, 6, I, 8, 9, and H1 are'provided with stationary arms llll-IH, IlJl-|52, 13-404, l05l06, lei-I08, 5fi-54, 59-58, 39-68 and 122-59 respectively provided with ball-shaped contacts H2-I l3, Ell-4M, H5-H6, [IL-H8, Mil-23, 5'l55, 6l55, l2l-'H, and 123-1 2 respectively. Rotatably mounted on the ends of the stationary arms of

condensers

2, 4, 5, 6, 1, 8, 9, and iii are switching members |24-l25, l21-l26, l28-!29, Hit-43c, l33-l32, 63-52, l3 lld, and Mia-l5 respectively.

In Figure l the switching arms and ball-shaped contacts are shown schematically and are indicated by the reference numerals used on Figure 1.

When the switching members 55 and 56 are raised, the end of member 55 is placed in the vicinity of the ball-shaped contact H4 with the result that

condensers

2 and 3 are placed in series by the spark gap so formed. By regulating the length of this spark gap it is possible to adjust the voltage at which the break-down of the gap will occur. When members 55 and 56 are moved downwardly the ends. thereof efiect an electrical connection with the ball contacts 51 and H4 respectively to thereby place

condensers

2 and 3 in parallel. In a similar manner the ends of switching

members

62 and 63 of condenser 8 form the poles of a series-parallel switch and when these members are raised the end of member 53 comes into the vicinity of the ball-shaped contact 65 of condenser l and a spark is formed between the same; switching member 62 being inoperative in this position. When members 62 7 and 63 are lowered, ball contact 6! is connected by switching member 63 to ball contact 6'! and ball contact is connected to ball contact 65 with the result that condensers I and 8 are connected in parallel.

In this manner it is possible to connect, for example, the condensers of columns A and B and the condensers of columns C and D simultaneously in series or in parallel. With the remaining switch arms it is possible to connect the condensers 5 and 9 of column A, and to connect condensers 3 and I of column C in series or parallel with the

condensers

2 and 6 of column B,

As shown more clearly in Figure 2, the upper

stationary arms

58, 68, G9, and it of the condensers 8, 9, it], and the high-voltage terminal 91 respectively are provided with ball-shaped contacts 60, l I, I2, and i3 respectively to which are rotatably secured movable switching members 52, l4, l5, and 95 respectively.

As shown in Figure 1 the switching members are actuated by rods I6, l1, l8, l8, and of insulating material. More particularly, rod 16 actuates the switching members l24l25, [iii-I35, and I35-l5, rod H actuates the switching members 55-55 and 133-432, rod 73 actuates the switching members i2l-i26 and 63-452, and rod 19 actuates the switching members [28-429 and lM-Hl. The central rod Si) serves to actuate only the arm 95.

'As shown in Figure 2 a guide SI for rod 80 is secured to the stationary arm HI, and a rod 82 connects arm 95 to rod 3!].

Rods I6, 11, I8, i9, and 80 are actuated in such a manner that the lengths of all the spark gaps between the ball contacts and the ends of the switching members can be changed in a similar manner and in one operation. A suitable mechanism for obtaining this result is diagrammatically illustrated in Figure 3, which mechanism is assumed to apply to an installation comprising a number of condensers which is a multiple of four, for example, twelve, i. e., an installation comprising four columns each having the same number of condensers.

As shown in Figure 3, the lower ends of rods 15, 11, 18, l9,and Bil bear upon the upper surface of a disc 83 which is located within the base 99 of Figure 1. Disc 83 is adapted to be raised or lowered in a directionperpendicular to the plane of the drawing in Figure 3, for instance by an electric motor (not shown). This disc is also adapted to be rotated about its center so as to be placed in one of four positions indicated by I, II, III, and IV. When the disc is in its lower position, the rods 76, ll, '58, E9, and 80 are clear of the upper surface and the switching members 01" Figure 1 are supported by the ball-shaped contacts and thus are in contact therewith. The disc 83 is also provided with nine holes 84 to 92 inclusive arranged in a circle and of a larger diameter than rods '15 to It.

With disc 83 in position I as shown, all of the rods 16 to 89 will be raised when the disc is raised.

When the disc 83 is rotated clockwise into position II, the holes 3% and 85 will lie beneath rods 2,254,836 16 and 18 respectively with the result that when the disc is raised only rods 11, 19, and 80 will be raised. As a result condensers I and 2, 3 and 4, and B, 1 and 8, and 9 and III, and as the case may be the eleventh and twelfth condenser, will remain connected in parallel, whereas regulatable spark gaps are formed between

condensers

2 and 3, 4 and 5, 6 and 1, and 8 and 9, and as the case may be In and the eleventh condenser and at the high-voltage terminal (in the Figure 4 between ball-shaped contact 12 of condenser I9 and terminal 91).

When disc 83 is placed in position III, holes 86, 81, and 88 will be beneath rods 16, 11, and 18 respectively with the result that these rods will not be raised when the disc is raised. This position is only important for the casein which the installation comprises a number of condensers equal to a multiple of four. In this position only rods 19 and 80 will be raised when the disc 83 is raised with the result that the condensers will be divided into groups of four parallel connected condensers.

When disc 83 is placed in position IV, holes 89, 90, 9|, and 92 will be beneath rods 16, 11, 18 and 19 respectively with the result that when the disc is raised only rod 80, and thus switching member 95 will be raised. In such a position all the condensers will be connected in parallel and the voltage will be adjusted to the lowest stage.

An apparatus of the type described above has a high mechanical rigidity because it has a unitary structure. Furthermore, the weight of the apparatus as well as the volume thereof and the floor space required are very small.

The operation of the apparatus will be described in more detail with reference to Figure 4, which is a schematic diagram of the apparatus shown in the preceeding figures.

The condensers I to II] may have a capacity of 0.125 ll, each of the resistances II to I9 may have a value of 500 ohms, and each of the resistances 20 to 28 may have a value of 10,000 ohms.

As shown in Figure 4 the two movable arms associated with each of the condensers 2 to ID are I connected together to form nine series-parallel switches 29-31. A suitable D. C. source of supply voltage I59 has its terminals connected to points I5I and I 52 which correspond to the

bosses

38 and 39 respectfully of condenser I (see Figure 1). Point I5I is preferably grounded as shown, and a suitable load M is connected between the highvoltage terminal 91 and ground. The highvoltage terminal 40 of condenser I0 is connected to ground through a spark gap 94 and the series connection of resistances II to I9 inclusive and 95.

It should be noted that each of the movable switching members are electrically connected to the corresponding terminals of the condensers through a damping resistance 98, for example, a 25 ohm resistance. In Figure 1 these resistances are located within the stationary arms to which the switching members are rotatably secured as indicated for arm 52.

When the installation is placed into operation, the condensers are simultaneously charged through resistances II to 28 inclusive. Before they have reached the final voltage the spark gaps 4250 and 94 break down. The condensers are now connected in series and their voltages are additive. The nominal value of the high voltage is 10 V if V is the voltage of the supply source I50.

When switches 29, EN, 33, 35 and 31 are shifted,

condensers I and 2, 3 and 4, 5 and 6,1 and 8, and 9 and I0, together with their damping resist ances 98, are connected in parallel and consequently six groups each consisting of two condensers connected in parallel are formed, these groups being located in series Via the spark gaps 43, 45, 41 and 49. The nominal value of the voltage is now 5 V volts. In this position the switches occupy the position indicated in dotted lines for switch 29.

When, in addition, the

switches

30, 32, 34 and 36 are shifted, all the condensers are connected in parallel and the voltage amounts to V volts. In each of these three cases the energy is, however, 5 CV in which C is the capacity of each of the condensers.

There is also provided a switch by means of which, if each of the switches 29-31 takes its lower position, the high-voltage terminal 91 may be grounded through switch arms I35, I34, 63, I33, I3I, I28, I21, 55 and I24. Otherwise this terminal is permanently connected through resistances 96 and II to I9 to the ground.

I wish it to be understood that I do not desire to be limited to the exact details of construction shown and described, because obvious modifications will readily occur to a person skilled in the art.

What I claim is:

1. An impulse voltage apparatus comprising a plurality of condensers, resistances connecting said condensers in parallel, said condensers being connected in series through spark gaps, and means to remove some of said spark gaps and shunt the resistances connected thereto to thereby divide the condensers into a plurality of groups each comprising the same number of condensers, the condensers of each group being connected in parallel by the non-shunted resistances and in series by the remaining spark gaps,

2. An impulse voltage apparatus comprising a plurality of condensers, resistances connecting said condensers in parallel, switching members forming spark gaps connecting said condensers in series, and means including said switching members to simultaneously remove said spark gaps and shunt the resistances.

3. An impulse voltage apparatus comprising a plurality of condensers, resistances connecting said condensers in parallel, switching members forming spark gaps connecting groups of said condensers in series, and a two-position switch between each two adjacent condensers of each group, said switch in one position establishing a spark gap connecting the adjacent condensers in series and in its second position shunting the resistances connected between the adjacent condensers.

4. An impulse voltage apparatus comprising a plurality of condensers, resistances connecting said condensers in parallel, and a two-position switch between each. two adjacent condensers, each switch in one position establishing a spark gap connecting the adjacent condensers in series and in its second position shunting the resistances connected between the adjacent condensers.

5. An impulse voltage apparatus comprising a plurality of condensers arranged in n columns each located at the corner of a polygon, n being more than two, a plurality of resistances connecting said condensers in parallel, insulators separating the condensers of each column, the 187/, 1 the 2n+1st, etc. condensers being arranged in one column, the 2nd, n-l-Znd, 2n+2nd, etc. condensers being arranged in a second column and the remaining condensers being arranged in similar manner, switching members adapted to form spark gaps, and switching means including said members to se ectively connect all the condensers in parallelor in series through said spark gaps.

6. An impulse voltage apparatus comprising a plurality of condensers arranged inn columns each located at the corner of a polygon, n being more than two, a plurality of resistances connecting said condensers in parallel, insulators separating the condensers of each column, the 1st, n-l- 1st, the 211+ 1st, etc. condensers being arranged in one column and the remaining condensers being arranged in a similar manner in the other columns, a plurality of two pole doublethrow switches connected to the condensers and adapted to form spark gaps, switching means 'to selectively connect all the condensers in parallel or in series through said spark gaps, said means including said switches and a member mechanically interconnecting the switches associated with the condensers of each column.

'7. An impulse voltage apparatus comprising a plurality of condensers arranged in n columns each located at the corner of a polygon, n being more than two, a plurality of resistances connecting said condensers in parallel, insulators separating the condensers of each column, the 1st, n+lst, the 2n+ 1st, etc. condensers being arranged in one column and the remaining condensers being arranged in similar manner, a plurality of double-throw switches each connected to a condenser and movable in vertical planes to form spark gaps, and means to selectively connect all the condensers in parallel or in series through said spark gaps, said means including said switches and actuating members mechanically interconnecting the switches.

8. An impulse voltage apparatuscomprising a plurality of condensers arranged in n vertical columns each located at the corner of a polygon, n being more than two, a plurality of resistances connecting said condensers in parallel, insulators separating the condensers of each column, the 1st, n-i-lst, the 2n+1st, etc. condensers being arranged in one column and the remaining condensers being arranged in similar manner, 1 each condenser being located an equal distance above the condenser which proceeds it in the system, switching members adapted to form spark gaps, and means including said members to selectively connect all the condensers in parallel or in series through said spark gaps.

9. An impulse voltage apparatus comprising a plurality of condensers arranged in 12 columns each located at the corner of a polygon, n being more than two, a plurality of resistances connecting said condensers in parallel, insulators separating the cendensersof each column, the

1st, n+1st, the 2n+1st, etc, condensers being arranged as one column and the remaining condensers being arranged in similar manner, and means to selectively connect all the condensers in parallel or in series said means comprising a contact member secured to each terminal of the condensers and'extending radially, and a movable switching member carried by said contact member and adapted to form a spark gap with the contact member of the adjacent condensers.

10. An impulse voltage apparatus comprising a plurality of condensers arranged in n columns each located at the corner of a polygon, n being more than tvo, a plurality of resistances conmeeting said condensers in parallel, insulators separating the condensers of each column, the 1315, 11+ 1st, the 211+ 1st etc. condensers being arranged as one column and the remaining condensers being arranged in similar manner, means to selectively connect all the condensers in parallel or in series, said means comprising a contact member for each terminal of the condensers and extending radially, and a movable switching member carried by said contact memher and. adapted to form a spark gap with the contact member of the adjacent condensers, and a damping resistance connection between each contact member and the corresponding condenser.

11. An impulse voltage generator comprising a number of condensers which is a multiple of two, said condensers being arranged in four columns located at the corners of a rectangle, a plurality of resistances connecting said condensers in parallel, means to divide the condensers into groups each comprising two parallel-connected condensers, said means comprising series parallel switches for interconnecting the condensers of the first and second columns and the condensers or the third and fourth columns.

12. An impulse voltage generator comprising a number of condensers which is almultiple of four, said condensers being arranged in four columns located at the corners of a rectangle, a

plurality of resistances connecting said condensers in parallel, means to divide the condensers into groups each comprising four parallel-connected condensers, said means comprise.

ing'series-parallel switches for interconnecting the condensers of the first and second columns, for intercomiecting the condensers of the third and fourth columns, and for interconnecting the condensers of the second and third columns.

13. An impulse voltage generator comprising a number of condensers which is a multiple of two, said condensers being arranged in four columns located at the corners of a rectangle, a plurality of resistances connecting said condensers in parallel, means for connecting all the condensers in parallel comprising series parallel switches for interconnecting the condensers of the second and fourth columns to the condensers of the third and first columns respectively,

14. An impulse voltage apparatus comprising a number of condensers which is a multiple of two, a plurality of resistances connecting said condensers in parallel, said condensers being arranged successively in four columns located at the corners of a rectangle, an inwardly-extending arm at each end of each condenser, a stationary contact on the end of each arm and connected to the corresponding terminal of the condenser, a movable switching member mounted on the top arm of the first condenser and on each arm of the remaining condensers, the switching members of each condenser cooperating with the stationary contacts of the preceding condenser of the parallel connection, and actuating means mechanically interconnecting the movable switching members of the condensers of each column.

WILLEM HONDIUS BOLDINGH