 |
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
| Datasheet File OCR Text: |
| Low Signal Relay Miniature 9.0 H x 11.5 W x 20.5 L mm (0.35 H x 0.45 W x 0.81 L in) s Shield plate and resin-molded relay base provide excellent high-frequency characteristics: isolation of 68 dB (typ.), insertion loss of 0.20 dB (typ.), and VSWR of 1.30 (typ.) at 900 MHz s Ultrasmall and lightweight with pickup coil power of 170 mW (112 mW for high-sensitivity type) s Plastic sealed construction highly resistant to adverse environmental conditions s s G5Y-1 High shock resistance Ordering Information To Order: Select the part number and add the desired coil voltage rating (e.g., G5Y-1-DC12). Type Standard High-sensitivity Contact form SPDT Construction Fully-sealed Part number G5Y-1 G5Y-1-H Specifications s CONTACT DATA Load Rated load Resistive load (p.f. = 1) 24 VAC 0.01 A 24 VDC 0.01 A 1 W at 900 MHz* Au clad Cu alloy 0.10 A 30 VAC, 30 VDC 0.10 A 1 VA, 1W 10 mA at 10 mVDC Contact material Carry current Max. operating voltage Max. operating current Max. switching capacity Min. permissible load * Denotes the value at VSWR 1.2. G5Y-1 s COIL DATA Standard type Rated voltage (VDC) 5 6 9 12 24 Rated current (mA) 60.20 50.00 33.30 25.00 12.50 Coil resistance () 83 120 270 480 1,920 Must operate voltage % of rated voltage 75% max. Must dropout voltage 10% min. Maximum voltage 150 at 23C (73F) 130 at 50C (122F) G5Y-1 Power consumption (mW) Approx. 300 High-sensitivity type Rated voltage (VDC) 5 6 9 12 24 Rated current (mA) 40.00 33.30 22.20 16.70 8.30 Coil resistance () 125 180 405 720 2,880 Must operate voltage % of rated voltage 75% max. Must dropout voltage 10% min. Maximum voltage 150 at 23C (73F) 130 at 50C (122F) Power consumption (mW) Approx. 200 Note: 1. The rated current and coil resistance are measured at a coil temperature of 23C (73F) with a tolerances of 10%. 2. The operating characteristics are measured at a coil temperature of 23C (73F). s CHARACTERISTICS Contact resistance Operate time Release time Bounce time Operating frequency Insulation resistance Dielectric strength 100 m max. 10 ms max. 5 ms max. 5 ms max. 1,800 operations/hour 1,800 operations/hour (under rated load) 100 M min. (at 500 VDC) 500 VAC, 50/60 Hz for 1 minute between contacts 1,000 VAC, 50/60 Hz for 1 minute between coil and contact 500 VAC, 50/60 Hz for 1 minute between contact and ground 10 to 55 Hz, 1.50 mm (0.06 in) double amplitude 1,000 m/s2 (approx. 100 G) 200 m/s2 (approx. 20 G) -25C to +60C (-13 to 140F) 35% to 85% RH 1 million operations min. (at 1,800 operations/hour) 300,000 operations min. (under rated load at 1,800 operations/hour) Approx. 6g (0.21 oz) Mechanical Electrical Vibration Shock Ambient temperature Humidity Service life Weight Mechanical durability Malfunction durability Mechanical durability Malfunction durability Mechanical Electrical Note: Data shown are of initial value. s HIGH-FREQUENCY CHARACTERISTICS Frequency 250 MHz 70 dB min. 0.5 dB max. 1.5 max. 10 W max. Item Isolation Insertion loss VSWR Carry power 900 MHz 60 dB min. 1.8 max. Note: Line impedance (Zo) of the measuring instrument is 50. 2 G5Y-1 s CHARACTERISTIC DATA High-frequency characteristics Measuring conditions of Type G5Y-1. G5Y-1 The following characteristics, when a signal is applied from input terminal 11 to output terminal 8 or from input terminal 11 to output terminal 14 of the sample, are measured with contacts unrelated to the measurement terminated at 50. 1. Isolation characteristics 2. Insertion loss characteristics 3. Return loss Note: Conversion formula between return loss and VSWR. Isolation characteristics G5Y-1 Frequency vs. isolation G5Y-1 Distribution of isolation at 250 MHz G5Y-1 Distribution of isolation at 900 MHz Insertion loss characteristics G5Y-1 Frequency vs. insertion loss G5Y-1 Distribution of insertion loss at 250 MHz G5Y-1 Distribution of insertion loss at 900 MHz 3 G5Y-1 G5Y-1 High-frequency characteristics (continued) VSWR characteristics G5Y-1 Frequency vs. return loss and VSWR G5Y-1 Distribution of VSWR at 250 MHz G5Y-1 Distribution of VSWR at 900 MHz Ambient temperature vs. operate voltage G5Y-1 Coil temperature rise characteristics Coil current consumption vs. temperature rise G5Y-1 Shock resistance characteristics (unit: G) G5Y-1 4 G5Y-1 G5Y-1 Dimensions Unit: mm (inch) s RELAY Terminal arrangement/ Internal connections (bottom view) Mounting holes (bottom view) Note: Parts marked with Hints on Correct Use How to design PC Board s PC BOARD SELECTION Thickness of PC board PC boards are generally available in the following thicknesses: 0.8 (0.03), 1.0 (0.04), 1.2 (0.05), 1.6 (0.06), and 2.0 mm (0.08 in). In determining the thickness of the PC board to be used, the pattern widths of the microstrips must be taken into account. First, determine the applicable pattern widths based on the intended arrangement of components on the PC board. Then select the appropriate PC board thickness. PC board material The base materials of PC boards can be divided into two types: epoxy type and phenolic type. For high-frequency circuits, glass epoxy type double-sided PC boards are recommended because of their distinct dielectric constant and material stability. However, paper epoxy type or paper phenolic type single-sided PC boards may also be used if cost factor is essential. Refer to "Examples of packaging design" for mounting the relay on a single-sided PC board. Terminal hole diameters, land diameters, and land shapes (DC circuit) Terminal hole diameter and land diameter Select the appropriate terminal hole diameter and land diameter from the following table based on the PC board mounting hole drawing. Land diameters may be reduced to less than those listed below if thru-hole connection process is to be employed. Terminal hole diameters and land diameters Unit: mm (inch) Terminal hole diameter Nominal value 0.6 (0.02) 0.8 (0.03) 1.0 (0.04) 1.2 (0.05) 1.3 (0.05) 1.5 (0.06) 1.6 (0.06) 2.0 (0.08) Minimum land diameter 1.5 (0.06) 1.8 (0.07) 2.0 (0.08) 2.5 (0.10) 3.0 (0.12) s PATTERN DESIGN Preparation for pattern design Relay mounting direction The mounting direction of each relay must be taken into account for the relay to function with maximum performance. Shock resistance is one of the representative relay performance characteristics greatly influenced by the relay mounting direction. Refer to the Shock Resistance Characteristic in "Characteristic Data" section. Note that the shock resistance of a relay (NC contact), with its coil in the nonenergized state, is governed greatly by the mounting direction of the relay. 54321 54321 54321 and indicate mounting direction mark on G5Y relay. Tolerance 0.1 ( 0.004) 5 G5Y-1 Shape of land 1. The land section should be on the center line of the copperfoil pattern so that the soldered fillets become uniform. G5Y-1 The characteristic impedance of a transmission line is determined by the type of PC board (specific inductive capacity), its thickness, and the width of the transmission line. This impedance is expressed by the following formula. 2. If the relay and other circuit components are to be soldered manually after the automatic soldering of the PC board, a terminal hole can be secured by providing a break in the land. where w: Width of transmission line e r: Relative dielectric constant er h: Thickness of dielectric PC board, provided that the thickness of copper foil is no greater than h. This relationship is shown the the figure below. Conductor width and microstrip Patterns for DC circuits The following thicknesses of copper foil are standard: 35 m (1.38 mil) and 70 m (2.76 mil). The conductor width is determined by the carry current and allowable temperature rise. Refer to the table on the following page. Conductor width and carry current (according to IEC Pub321) For example, when a 50 transmission line is to be formed using a 1.6 mm (0.06) glass epoxy type double-sided PC board, the width of the transmission line can be obtained in the following manner. Since the specific inductive capacity (er) of this circuit board is 4.8, w/h = 1.7 (obtained from the above table). Based on the thickness of the PC board (e.g., 1.6 mm [0.06]), the thickness of transmission line w can be calculated as follows. w = h x 1.7 = 1.6 (0.06) x 1.7 = 2.7 mm (0.11 in) Note that in this calculation, the thickness of copper foil "t" is ignored, so there may be a greater error in characteristic impedance of t = w. Also, the attenuation constant of the transmission line, due to the effective filling rate of microstrip or dielectric loss and conductor loss, is not taken into account, but these factors must be considered in the actual design of microstrips. In the frequency band for which Model G5Y is intended, however, these factors may be ignored by shortening the length of the transmission line. Bending of strip transmission line s MICROSTRIPS For high-frequency transmission circuits, the use of microstrips is recommended. By adopting this stripline method, a low-loss transmission circuit can be configured. The microstrips are prepared by etching a PC board made of dielectric material and covered on both sides with copper foil. As shown in the figure below, the microstrip utilizes the concentration of the electric field between transmission line and the ground. 6 G5Y-1 The separation between the strip line and each ground pattern should be approximately the same as the strip line width. * Conductive patterns should be designed to be as short as possible. Meandering of the strip transmission line will adversely affect the high-frequency characteristics of the relay. * Each ground pattern should be designed to be as wide as possible so as not to generate a potential difference between ground patterns. * Avoid directing of conductive lines in the area of the PC board on which the relay bottoms, as this can result in shortcircuiting. G5Y-1 The method of packaging using a single-sided PC board s EXAMPLES OF PACKAGING DESIGN Since these examples are presented with an eye to low cost packaging, expensive packaging methods, such as thru-hole connection, are not described. For this reason, the characteristics of each circuit board should be checked thoroughly before putting it to practical use. The method of packaging using paper epoxy type doublesided PC board. The dielectric constant of a paper epoxy type double-sided PC board is considered to be approximately the same as that of a glass epoxy type PC board (er = 4.8). The width of a strip transmission line is as follows: Unit mm (inch) Thickness of PC board 1.6 (0.06) 1.0 (0.04) Impedance () 50 75 50 75 Width of strip line 2.7 (0.11) 1.3 (0.05) 1.7 (0.07) 0.8 (0.03) When a relay is mounted on a single-sided PC board, an isolation of only 60 to 70 dB can be obtained at 200 MHz. Therefore, to permit the relay on the single-sided PC board in a higher frequency range, a metallic plate can be inserted between the PC board and the relay, then connected to the ground pattern. As seen in the figure to the left, a metallic plate is sandwiched between the relay and the PC board to connect to the pattern. The key is that the ground terminal of the Type G5Y-1 relay, the bent tabs A of the metallic plate, and the ground pattern must be soldered together at one time. This combination of a low-cost, single-sided PC board and a low-cost, metallic plate, provides the same high-frequency characteristics as when the relay is mounted on a doublesided PC board. By grounding the ground terminal of the Type G5Y-1 relay and the metallic plate at the same place, excellent high-frequency characteristics can be obtained. In this method, the metallic plate must adhere firmly to the PC board. The design of strip transmission lines should be the same as when a double-sided PC board is employed. s HOW TO DESIGN PC BOARD CAUTION: A key point in mounting the relay on a single-sided PC board is to ensure that the relay base is not floating above the PC board or metallic plate, but bottoms firmly upon them. The figure above shows the conductive pattern side. The microstrip connected to the contact terminal must be of the above-mentioned pattern width. Ensure that the distance between microstrip and each ground pattern is approximately the same as the width of the microstrip. Connect with jumpers between the top and bottom of the pattern at the points marked "X" in the figure. The greater the number of jumper points, the better the high-frequency characteristics. In this manner, an isolation of 65 to 75 dB at 500 MHz or 50 dB at 900 MHz can be obtained. In this case, the components mounting side of the PC board is entirely the ground pattern. Remove the pattern around each of the contact terminals and coil terminal in size 2.0x2.0 mm (0.08 x 0.08 in). Note: In the interest of product improvement, specifications are subject to change. 7 G5Y-1 G5Y-1 Omron Europe B.V. EMA-ISD, tel:+31 23 5681390, fax:+31 23 5681397, http://www.eu.omron.com/ema Cat. No. GC RLY6 8 9/97 Specifications subject to change without notice. Printed in the U.S.A. |
Price & Availability of G5Y-1
 |
|
|
|
|
All Rights Reserved © IC-ON-LINE 2003 - 2022 |
| [Add Bookmark] [Contact Us] [Link exchange] [Privacy policy] |
|
Mirror Sites : [www.datasheet.hk]
[www.maxim4u.com] [www.ic-on-line.cn]
[www.ic-on-line.com] [www.ic-on-line.net]
[www.alldatasheet.com.cn]
[www.gdcy.com]
[www.gdcy.net] |