The Project Gutenberg eBook of Motion Picture Operation, Stage Electrics and Illusions, by Henry C. Horstmann & Victor H. Tousley.

Bell circuit

FIGURE 153.

Border with lights

FIGURE 154.

Borders.

Borders.—The number of borders used in theaters varies from one to six, the latter number being sufficient for almost any stage. They are generally made of a length about equal to the proscenium opening. The borders placed in the rear are of less importance than those in front and consequently are made shorter and are not provided with so many lights. Each border should have at least three circuits, one for each color; each circuit being taken through a separate dimmer so that any color may be used alone and dimmed as desired.

Figures 154 and 155 show types of borders, and the method of wiring is shown in Figure 156.

Border with lights

FIGURE 155.

Border wiring

FIGURE 156.

Large borders are very heavy and are usually suspended by wire rope and provided with counterweights to make handling easy. The wire rope should be kept well protected by oiling; the moisture given off by fireproofed scenery is liable to rust them very fast, and as the ropes are made up of very fine strands the rust soon cuts entirely through them. The suspending ropes and also cables supplying lights must be long enough to admit of bringing the border within five or six feet of the stage floor for lamp renewals and cleaning. The cleaning is very important as the dust which accumulates may absorb a large part of the light.

The National Electrical Code Rules Governing Border and Proscenium Sidelight Construction.

Must be constructed of steel of a thickness not less than No. 20 U. S. sheet metal gauge; treated to prevent oxidation; be suitably stayed and supported; and so designed that flanges of reflectors will protect lamps.

Must be so wired that no set of lamps requiring more than 1,320 watts nor more than 26 receptacles shall be dependent upon one cut-out.

Must be wired in approved conduit or armored cable, each lamp receptacle to be enclosed within an approved outlet box, or the lamp receptacles may be mounted in an iron or steel box, metal to be of a thickness not less than No. 20 U. S. sheet metal gauge treated to prevent oxidation, so constructed as to enclose all wires. Wires to be soldered to lugs of receptacles.

Must be provided with suitable guards to prevent scenery or other combustible material coming in contact with lamps.

Cable for borders must be of approved type and suitably supported; conduit construction must be used from switchboard to point where cables must be flexible to permit of the raising and lowering of border.

For the wiring of the border proper, wire with approved slow-burning insulation must be used.

Borders must be suitably suspended, and if a wire rope is used same must be insulated by at least one strain insulator inserted at the border.

Box Office.

Box Office.—The box office is often a very stuffy place in summer and very cold in winter. There should be an outlet for a fan motor, and also one for a heater. Very many box offices depend upon electric heating for comfort in winter. Plenty of light should be provided and the light should be at the ceiling, out of the way, and directly over the ticket window.

Brackets.

Brackets.—Any brackets used in theaters should be at least seven feet above the floor. Brackets used for emergency or exit lights must be fitted with keyless sockets. See “Fixtures”.

Branch Circuits.

Branch Circuits.—The term, “branch circuit”, as here used refers to the wires leaving the last cut-outs and connecting directly to the lamps or other devices. Mains are often run from the switchboard to various parts of the building to feed cut-out centers, and the branch circuits are then run from these centers. This is often the cheapest method, but it is by no means the best. In a well designed theater all branch circuits lead out from the vicinity of the switchboard so that, in case of any trouble with fuses, they may be replaced without interfering with any part of the audience and in the shortest possible time. This method of wiring involves some long runs of branch circuit wires and Table V, which shows the drop in voltage, was prepared for the convenience of wiremen. If possible the circuits should be so arranged that the lamps fed are closely together so all may receive nearly the same voltage. The drop should not much exceed two per cent.

Table showing drop in voltage due to 6 amperes, with sizes of wire and distances given:

TABLE V.
DROP IN VOLTAGE DUE TO 6 AMPERES WITH SIZE OF WIRE
AND DISTANCE GIVEN.

Distance in feet	50	75	100	125	150	175	200	225	250	300
Size of Wire No. 14	1.58	2.37	3.16	3.95	4.74	5.53	6.32	7.11	7.90	9.48
Size of Wire No. 12	0.99	1.48	1.98	2.47	2.97	3.45	3.96	4.45	4.95	5.94
Size of Wire No. 10	0.63	0.94	1.25	1.56	1.87	2.19	2.50	2.81	3.12	3.75
Size of Wire No. 8	0.39	0.59	0.78	0.97	1.17	1.36	1.56	1.75	1.95	2.34

National Electrical Code Rules Governing Size of Wire for Branch Circuits and Fuses for Same.

No wire smaller than No. 14 B. & S. gauge must be used.

Each branch circuit must be protected by fuses, which must be so placed that no set of small motors, small heating devices, or incandescent lamps, whether grouped on one fixture or on several fixtures or pendants (nor more than 16 sockets or receptacles) requiring more than 660 watts, will be dependent upon one cut-out.

By special permission, in cases where wiring equal in size and insulation to No. 14 B. & S. gauge approved rubber-covered wire is carried direct into keyless sockets or receptacles, and where the location of sockets and receptacles is such as to render unlikely the attachment of flexible cords thereto, the circuits may be so arranged that not more than 1,320 watts (or thirty-two sockets or receptacles) will be dependent upon the final cut-out.

Except for signs and outline lighting, sockets and receptacles will be considered as requiring not less than 40 watts each.

All branches or taps, from any three-wire system, which are directly connected to lamp sockets or other translating devices, must be run as two-wire circuits if the fuses are omitted in the neutral, or if the difference of potential between the two outside wires is over 250 volts, and both wires of such branch or tap circuits must be protected by proper fuses.

The above shall also apply to motors, except that small motors may be grouped under the protection of a single set of fuses, provided the rated capacity of the fuses does not exceed 10 amperes.

When 1,320 watts are dependent upon one fusible cut-out, as is allowed in theater wiring, outline lighting and large chandeliers, the fuses may be in accordance with the following:

125 volts or less	20 amperes
125 to 250 volts	10 amperes

Bus-Bars.

Bus-Bars.—Bus-bars may be made of bare metal. They must, however, be protected against accidental contact. The metal should be ample so that it will not heat more than 50 degrees Fahrenheit above the surrounding air.

It is customary to calculate the metal needed, on the basis of 1,000 amperes per square-inch cross section. On this basis bars of the sizes given below would have the carrying capacities in amperes given in the body of the table.

TABLE VI.
CURRENT-CARRYING CAPACITY OF BUS-BARS.

Thickness			²⁄₃₂	³⁄₃₂	⁴⁄₃₂	⁵⁄₃₂	⁶⁄₃₂	⁷⁄₃₂	⁸⁄₃₂	⁹⁄₃₂	¹⁰⁄₃₂	¹²⁄₃₂	¹⁶⁄₃₂
Width in In- ches		¹⁄₂	30	45	60	75	90	105	120	135	150	165	180
		⁵⁄₈	37	57	75	94	108	132	150	168	188	206	225
		⁶⁄₈	45	68	90	112	135	158	180	202	225	248	270
		⁷⁄₈	53	79	105	130	158	184	210	236	263	289	315
	1	.0	60	90	120	150	180	210	240	270	300	330	360
	1	¹⁄₄	75	112	150	188	225	263	300	338	375	412	450
	1	¹⁄₂	90	135	180	225	270	315	360	405	450	495	540
	1	³⁄₄	105	157	210	263	315	367	420	473	525	577	630
	2	.00	120	180	240	300	360	420	480	540	600	660	720
	3	.00	180	270	360	450	540	630	720	810	900	990	1080

Cabinets.

Cabinets.—Cabinets are required to enclose all fuses. It is advised that they be arranged so that it will not be necessary to open the fuse compartment to operate switches.

Care should be exercised in locating cut-out cabinets. They should be in a dry place, easily accessible to authorized persons, and not accessible to the general public or miscellaneous employes. If too accessible they are likely to be made receptacles for all sorts of rubbish. Wooden or composition cabinets must not be used in theaters. Use only approved cabinets.

In some cities special rules, governing the construction of cabinets for theaters, exist and these should be looked up.

Cables.

Cables.—For construction rules, see “Stage Cables” in the chapter on “Portable Stage Equipment”. Cables are required to connect border lights. The cable is usually run from an outlet on the grid floor above the center of the border. It must be long enough to allow the border to be lowered for the cleaning and renewal of lamps. The slack cable must be taken up when the border is raised and some provision must be made to support the cable without injury to the insulation. Wire ropes or cables are generally used to support the borders, but the lower end, which is handled by the stage crew, is of ordinary manilla rope. Wire cables must be insulated from the border by strain insulators.

Canopies.

Canopies.—Very many theaters are provided with canopies which extend over the street. Sometimes these are fitted out with glass signs behind which incandescent lamps are installed. Often, also, a row of lights is arranged around the bottom of the canopy ceiling. The number of lights to be used depends upon the design of the canopy, but the effect is best if a large number of small candle-power lamps are used. These lamps should be of low intrinsic brilliancy. If possible, the lamps and sockets should be arranged to be out of the weather. In addition to the small outline lamps, other lights are often placed under canopy to provide bright illumination. Each circuit may carry 1,320 watts.

National Electrical Code Rule.

Where insulating joints are required, fixture canopies of metal must be thoroughly and permanently insulated from metal walls or ceilings, or from plaster walls or ceilings on metal lathing, and from outlet boxes.

Canopy insulators must be securely fastened in place, so as to separate the canopies thoroughly and permanently from the surfaces and outlet boxes from which they are designed to be insulated.

Carriage Call.

Carriage Call.—See “Program Board”.

Carrying Capacity of Wires.

Carrying Capacity of Wires.—Table VII is designed to help the wiremen select the proper size of wire to use in supplying a certain number of lights. The first column at the left gives the B. & S. gauge number. The second column gives the number of amperes allowed on each wire according to the National Electrical Code. The third column gives the distance in feet which will cause a loss of 2 volts with the current given; thus a current of 70 amperes in a No. 4 B. & S. gauge wire will lose 2 volts over a distance of 56 feet. The proper size of wire to be used can easily be determined from the table. The loss will always be in proportion to the product of distance and current. The balance of the table is devoted to showing the number of watts and lamps of various sizes the wires will be allowed to supply.

Ceiling Fans.

Ceiling Fans.—Must be hung from insulated hooks, or else there must be an insulator interposed between the motor and its support. Not more than 660 watts may be on one circuit.

Chandeliers.

Chandeliers.—Large and elaborate chandeliers are sometimes used in the center of the auditorium ceiling for purposes of illumination. Such chandeliers should be suspended in a manner which will admit of readily raising or lowering them for lamping up or repairs. For rules governing wiring, see “Fixtures”.

TABLE VII.

TABLE SHOWING CARRYING CAPACITY OF WIRES; DISTANCE TO WHICH FULL LOAD MAY BE CARRIED AT 2 VOLTS DROP AND NUMBER OF LIGHTS EQUIVALENT TO FULL CURRENT GIVEN.

B. & S. Gage	Rub- ber Insu- lation	Dis- tance in Feet Caus- ing a Loss of 2 Volts	Total Capacity in Watts		Total Number of Lamps of Different Voltages and Wattages that may be supplied
	Rub- ber Insu- lation		Total Capacity in Watts		25-Watt		40-Watt		60-Watt		100-Watt		150-Watt		250-Watt
	Am- peres		110 V.	220 V.	110 V.	220 V.	110 V.	220 V.	110 V.	220 V.	110 V.	220 V.	110 V.	220 V.	110 V.	220 V.
14	15	26	1650	3300	66	132	41	82	27	54	16	33	11	22	6	13
12	20	30	2200	4400	88	176	55	110	36	73	22	44	14	29	8	17
10	25	38	2750	5500	110	220	68	137	46	91	27	55	18	36	11	22
8	35	43	3850	7700	154	308	96	192	64	128	38	77	25	61	15	30
6	50	50	5500	11000	220	440	137	275	91	183	55	110	36	73	22	44
5	55	56	6050	12100	242	484	151	302	100	201	60	121	40	80	24	48
4	70	56	7700	15400	308	616	192	385	128	256	77	154	49	99	30	61
3	80	61	8800	17600	352	704	220	440	146	292	88	176	58	117	35	70
2	90	68	9900	19800	396	792	247	494	165	330	99	198	66	132	39	78
1	100	67	11000	22000	440	880	275	550	183	366	110	220	73	146	44	88
0	125	78	13750	27500	550	1100	343	686	229	458	137	274	91	182	55	110
00	150	82	16500	33000	660	1320	412	824	275	550	165	330	110	220	66	132
000	175	89	19250	38500	770	1540	481	962	320	640	192	384	128	256	77	154
0000	225	87	24750	49500	990	1980	618	1236	412	824	247	404	165	330	99	198
200000	200	92	22000	44000	880	1760	550	1100	367	734	220	440	146	292	88	176
300000	275	101	30250	60500	1210	2420	756	1512	504	1008	302	604	201	402	121	242
400000	325	114	35750	71500	1430	2860	893	1786	596	1192	357	714	238	476	143	286
500000	400	117	44000	88000	1760	3520	1100	2200	733	1455	440	880	293	586	176	352
600000	450	123	49500	99000	1980	3960	1237	2474	825	1650	495	990	330	660	198	396
700000	500	130	55000	110000	2200	4400	1375	2750	916	1832	550	1100	366	732	220	440
800000	550	135	60500	121000	2420	4840	1512	3024	1008	2016	605	1210	403	806	242	484
900000	600	139	66000	132000	2640	5280	1650	3300	1100	2200	660	1320	440	880	264	528
1000000	650	143	71500	143000	2860	5720	1787	3574	1191	2382	715	1430	476	952	286	572
1100000	690	147	75900	151800	3036	6072	1897	3794	1264	2528	759	1518	506	1012	303	606
1200000	730	151	80300	160600	3212	6424	2007	4014	1338	2676	803	1606	535	1070	321	642
1300000	770	155	84700	169400	3388	6776	2117	4234	1412	2824	847	1694	564	1128	338	676
1400000	810	161	89100	178200	3564	7128	2227	4454	1485	2970	891	1782	594	1188	356	712
1500000	850	164	93500	187000	3740	7480	2337	4674	1558	3116	935	1870	623	1246	374	748

B. & S. Gage	Rub- ber Insu- lation	Dis- tance in Feet Caus- ing a Loss of 2 Volts	Total Capacity in Watts		Total Number of Lamps of Different Voltages and Wattages that may be supplied
	Rub- ber Insu- lation		Total Capacity in Watts		25-Watt		40-Watt		60-Watt
	Am- peres		110 V.	220 V.	110 V.	220 V.	110 V.	220 V.	110 V.	220 V.
14	15	26	1650	3300	66	132	41	82	27	54
12	20	30	2200	4400	88	176	55	110	36	73
10	25	38	2750	5500	110	220	68	137	46	91
8	35	43	3850	7700	154	308	96	192	64	128
6	50	50	5500	11000	220	440	137	275	91	183
5	55	56	6050	12100	242	484	151	302	100	201
4	70	56	7700	15400	308	616	192	385	128	256
3	80	61	8800	17600	352	704	220	440	146	292
2	90	68	9900	19800	396	792	247	494	165	330
1	100	67	11000	22000	440	880	275	550	183	366
0	125	78	13750	27500	550	1100	343	686	229	458
00	150	82	16500	33000	660	1320	412	824	275	550
000	175	89	19250	38500	770	1540	481	962	320	640
0000	225	87	24750	49500	990	1980	618	1236	412	824
200000	200	92	22000	44000	880	1760	550	1100	367	734
300000	275	101	30250	60500	1210	2420	756	1512	504	1008
400000	325	114	35750	71500	1430	2860	893	1786	596	1192
500000	400	117	44000	88000	1760	3520	1100	2200	733	1455
600000	450	123	49500	99000	1980	3960	1237	2474	825	1650
700000	500	130	55000	110000	2200	4400	1375	2750	916	1832
800000	550	135	60500	121000	2420	4840	1512	3024	1008	2016
900000	600	139	66000	132000	2640	5280	1650	3300	1100	2200
1000000	650	143	71500	143000	2860	5720	1787	3574	1191	2382
1100000	690	147	75900	151800	3036	6072	1897	3794	1264	2528
1200000	730	151	80300	160600	3212	6424	2007	4014	1338	2676
1300000	770	155	84700	169400	3388	6776	2117	4234	1412	2824
1400000	810	161	89100	178200	3564	7128	2227	4454	1485	2970
1500000	850	164	93500	187000	3740	7480	2337	4674	1558	3116

B. & S. Gage	Rub- ber Insu- lation	Dis- tance in Feet Caus- ing a Loss of 2 Volts	Total Capacity in Watts		Total Number of Lamps of Different Voltages and Wattages that may be supplied
	Rub- ber Insu- lation		Total Capacity in Watts		100-Watt		150-Watt		250-Watt
	Am- peres		110 V.	220 V.	110 V.	220 V.	110 V.	220 V.	110 V.	220 V.
14	15	26	1650	3300	16	33	11	22	6	13
12	20	30	2200	4400	22	44	14	29	8	17
10	25	38	2750	5500	27	55	18	36	11	22
8	35	43	3850	7700	38	77	25	61	15	30
6	50	50	5500	11000	55	110	36	73	22	44
5	55	56	6050	12100	60	121	40	80	24	48
4	70	56	7700	15400	77	154	49	99	30	61
3	80	61	8800	17600	88	176	58	117	35	70
2	90	68	9900	19800	99	198	66	132	39	78
1	100	67	11000	22000	110	220	73	146	44	88
0	125	78	13750	27500	137	274	91	182	55	110
00	150	82	16500	33000	165	330	110	220	66	132
000	175	89	19250	38500	192	384	128	256	77	154
0000	225	87	24750	49500	247	404	165	330	99	198
200000	200	92	22000	44000	220	440	146	292	88	176
300000	275	101	30250	60500	302	604	201	402	121	242
400000	325	114	35750	71500	357	714	238	476	143	286
500000	400	117	44000	88000	440	880	293	586	176	352
600000	450	123	49500	99000	495	990	330	660	198	396
700000	500	130	55000	110000	550	1100	366	732	220	440
800000	550	135	60500	121000	605	1210	403	806	242	484
900000	600	139	66000	132000	660	1320	440	880	264	528
1000000	650	143	71500	143000	715	1430	476	952	286	572
1100000	690	147	75900	151800	759	1518	506	1012	303	606
1200000	730	151	80300	160600	803	1606	535	1070	321	642
1300000	770	155	84700	169400	847	1694	564	1128	338	676
1400000	810	161	89100	178200	891	1782	594	1188	356	712
1500000	850	164	93500	187000	935	1870	623	1246	374	748

National Electrical Code Rules for Fusing Chandelier Circuits.

When 1,320 watts are dependent upon one cut-out, as is allowed in theater wiring, outline lighting, and large chandeliers, the fuse may be in accordance with the following:

125 volts or less	20 amperes
125 to 250 volts	10 amperes