Siemens RF340R01 Inductive Tag Reader User Manual SIMATIC RF300
Siemens AG Inductive Tag Reader SIMATIC RF300
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![System overview 3.2 SIMATIC RF300 SIMATIC RF300 18 System Manual, 11/2009 - Zwischenstand 17.09.2009, A5E01642529-04 RF300 system components for low- and high-performance applications 7UDQVSRQGHU 5HDGHU &RPPXQLFDWLRQPRGXOHV3RZHUDQGGDWDWUDQVPLVVLRQ0+]6HULDODV\QFKURQRXVLQWHUIDFH56 56563&LQWHUIDFH7KLUGSDUW\3/&$60IRU6,0$7,&65)&IRU(7SUR$60IRU(7;$60IRU352),%86'39$60bIRU352),%86'3'395)&IRU352),1(7,2,46HQVHLQWHUIDFH[,46HQVHIRU(702Q65)5,46HQVH5)7 5)7 5)7 5)7 5)7 5)75)55)0 5)55)55)5 Figure 3-1 System overview low- and high-performance Table 3- 2 Reader-tag combination options for low- and high-performance applications Tags/ MDS RF310R (IQ-Sense) RF310R (RS422) RF340R RF350R with ANT 1 RF350R with ANT 18 RF350R with ANT 30 RF380R RF320T ✓ ✓ ✓ ✓ ✓ ✓ ✓ RF340T ✓ ✓ ✓ ✓ ✓ ✓ ✓ RF350T ✓ ✓ ✓ ✓ ○ ✓ ✓ RF360T ✓ ✓ ✓ ✓ -- ○ ✓ RF370T ○ ○ ✓ ✓ -- ○ ✓ RF380T ○ ○ ✓ ✓ -- -- ✓](https://usermanual.wiki/Siemens/RF340R01.User-Manual-I/User-Guide-1196867-Page-16.png)
![System overview 3.2 SIMATIC RF300 SIMATIC RF300 System Manual, 11/2009 - Zwischenstand 17.09.2009, A5E01642529-04 19 ✓ Combination possible -- Combination not possible ○ Combination possible, but not recommended @ in Grafik fehlt noch MDS D424 und die Fotos von MDS D460/MDS D424 RF300 system components for medium-performance applications 0'6'5HDGHUV &RPPXQLFDWLRQPRGXOHV3RZHUDQGGDWDWUDQVPLVVLRQ0+]6HULDODV\QFKURQRXVLQWHUIDFH56 56563&LQWHUIDFHWKLUGSDUW\3/&$60IRU6,0$7,&65)&IRU(7SUR$60IRU(7;$60IRU352),%86'39$60bIRU352),%86'3'395)&IRU352),1(7,27UDQVSRQGHU0'6'0'6' 0'6' 0'6' 0'6' 0'6' 0'6'5)0 5)55)5 5)5 5)5 Figure 3-2 System overview medium-performance](https://usermanual.wiki/Siemens/RF340R01.User-Manual-I/User-Guide-1196867-Page-17.png)
![RF300 system planning 4.1 Fundamentals of application planning SIMATIC RF300 36 System Manual, 11/2009 - Zwischenstand 17.09.2009, A5E01642529-04 Operation in dynamic mode When working in dynamic mode, the transponder moves past the reader. The transponder can be used as soon as the intersection (SP) of the transponder enters the circle of the transmission window. In dynamic mode, the operating distance (Sa) is of primary importance. [Operating distances, see Chapter Field data for transponders, readers and antennas (Page 41)] 7UDQVPLVVLRQZLQGRZ7UDQVSRQGHU7UDQVSRQGHU3ODQYLHZ6363 Figure 4-5 Operation in dynamic mode 4.1.7 Dwell time of the transponder The dwell time is the time in which the transponder remains within the transmission window of a reader. The reader can exchange data with the transponder during this time. The dwell time is calculated thus: 0,8 [ ][/]TagvL mtv m s⋅= tV: Dwell time of the transponder L: Length of the transmission window vTag: Speed of the transponder (tag) in dynamic mode 0,8: Constant factor used to compensate for temperature impacts and production tolerances The dwell time can be of any duration in static mode. The dwell time must be sufficiently long to allow communication with the transponder. The dwell time is defined by the system environment in dynamic mode. The volume of data to be transferred must be matched to the dwell time or vice versa. In general:](https://usermanual.wiki/Siemens/RF340R01.User-Manual-I/User-Guide-1196867-Page-34.png)
![RF300 system planning 4.1 Fundamentals of application planning SIMATIC RF300 38 System Manual, 11/2009 - Zwischenstand 17.09.2009, A5E01642529-04 Time constants K and tbyte for medium and high-performance applications Table 4- 5 Static mode RF300 mode FRAM ISO mode Read/write Read Write Data volume ≤ 233 bytes Data volume >233 bytes Data volume ≤ 233 bytes Data volume >233 bytes Independent of data volume Transfer rate [baud] K [ms] tbyte [ms] K [ms] tbyte [ms] K [ms] tbyte [ms] K [ms] tbyte [ms] K [ms] tbyte [ms] 19200 28 0.67 28 0.67 35 1.08 64 0.75 41 2.66 57600 15 0.30 25 0.22 34 0.59 34 0.59 28 2.28 115200 11 0.21 30 0.12 26 0.56 26 0.56 26 2.17 The values for K and tbyte include the overall time that is required for communication in static mode. It is built up from several different times: Serial communication between communication module, reader and Processing time between reader and transponder and their internal processing time. The values shown in the table must be used when calculating the maximum quantity of user data in static mode. They are applicable for both reading and writing in the FRAM area. For writing in the EEPROM area (max. 20 bytes), the byte time tByte is approx. 11 ms. Table 4- 6 Dynamic mode RF300 tags ISO tags Transfer rate [baud] Memory area K [ms] tbyte [ms] K [ms] tbyte [ms] Independent FRAM 8 0.13 - - Independent Write Read EEPROM 8 8 12.20 0.13 15 12 1.99 0.56 In dynamic mode, the values for K and tbyte are independent of the transmission speed. The communication time only includes the processing time between the reader and the transponder and the internal system processing time of these components. The communication times between the communication module and the reader do not have to be taken into account because the command for reading or writing is already active when the transponder enters the transmission field of the reader. The values shown above must be used when calculating the maximum quantity of user data in dynamic mode. They are applicable for both writing and reading.](https://usermanual.wiki/Siemens/RF340R01.User-Manual-I/User-Guide-1196867-Page-36.png)
![RF300 system planning 4.2 Field data for transponders, readers and antennas SIMATIC RF300 System Manual, 11/2009 - Zwischenstand 17.09.2009, A5E01642529-04 41 4.2 Field data for transponders, readers and antennas The following table shows the field data for all SIMATIC RF300 components of transponders and readers. It facilitates the correct selection of a transponder and reader. All the technical specifications listed are typical data and are applicable for an ambient temperature of between 0 C and +50 °C, a supply voltage of between 22 V and 27 V DC and a metal-free environment. Tolerances of ±20 % are admissible due to production or temperature conditions. If the entire voltage range at the reader of 20 V DC to 30 V DC and/or the entire temperature range of transponders and readers is used, the field data are subject to further tolerances. Note Transmission gaps If the minimum operating distance (Sa) is not observed, a transmission gap can occur in the center of the field. Communication with the transponder is not possible in the transmission gap. 4.2.1 Field data of RF300 transponders Observe the following information for field data of RF300 transponders: ● A maximum median deviation of ±2 mm is possible in static mode (without affecting the field data) ● The field data are reduced by approx. 15% if the transponder enters the transmission window laterally (see also "Transmission window" figure) RF310R reader Table 4- 8 RF310R reader Length of transmission window (L) Operating distance (Sa) Limit distance (Sg) RF320T 30 2...10 16 RF340T 38 2...20 26 RF350T 45 5...22 [26] 30 [35] RF360T 45 5...26 35 All values are in mm Values in brackets [ ] refer to RF310R with the MLFB 6GT2801-1AB10](https://usermanual.wiki/Siemens/RF340R01.User-Manual-I/User-Guide-1196867-Page-39.png)
![RF300 system planning 4.2 Field data for transponders, readers and antennas SIMATIC RF300 System Manual, 11/2009 - Zwischenstand 17.09.2009, A5E01642529-04 43 RF350R reader / ANT 30 Table 4- 12 RF350R reader / ANT 30 Diameter of the transmission window (Ld) Operating distance (Sa) Limit distance (Sg) RF320T 15 2...11 15 RF340T 25 5...15 20 RF350T 25 5...16 22 RF380R reader Table 4- 13 RF380R reader Length of the transmission window in the x-direction (Lx) in the y-direction (Ly) Operating distance (Sa) Limit distance (Sg) RF320T 100 40 2...30 [40] 47 [55] RF340T 115 50 20...70 [80] 90 [100] RF350T 120 60 35...70 [100] 105 [130] RF360T 120 70 40...120 140 [150] RF370T 135 65 35...85 [100] 125 [135] RF380T 155 75 25...85 [110] 125 [140] All values are in mm Values in brackets [ ] refer to RF380R with the MLFB 6GT2801-3AB10 The RF380R with MLFB 6GT2801-3AB10 enables the user to set the transmission output power with the aid of the "distance_limiting" input parameter. For this, values from approx. 0.5 W to approx. 2.0 W can be set in 0.25 W increments. Depending on the setting, the change to the transmission output power increases the performance in the lower operating distance (low performance) or in the upper limit distance (high performance). The "dili" value range goes from 02 (= 0.5 W) and 05 (default value: 1.25 W) to 08 (= 2 W). Note A dili value setting outside of the value range of 02 to 08 leads to the default setting (05) and does not generate an error message. Also see Chapter Minimum clearances (Page 47) Section "Minimum distance from reader to reader". You can find exact information regarding the parameters in the Product Information "FB 45 and FC 45 input parameters for RF300 and ISO transponders" (http://support.automation.siemens.com/WW/view/en/33315697).](https://usermanual.wiki/Siemens/RF340R01.User-Manual-I/User-Guide-1196867-Page-41.png)
![RF300 system planning 4.6 Chemical resistance of the transponders SIMATIC RF300 System Manual, 11/2009 - Zwischenstand 17.09.2009, A5E01642529-04 81 Concentration 20 °C 60 °C Nitrobenzol ○○○ ○○ Phosphoric acid 10 ○ V Propane ○○○○ ○○○○ Mercury ○○○○ ○○○○ Nitric acid 10 ○ ᅳ Hydrochloric acid 10 ○ ᅳ Sulphur dioxide Low ○○○○ ○○○○ Sulphuric acid 25 ○○ ᅳ 10 ○○○ ᅳ Hydrogen sulphide Low ○○○○ ○○○○ Carbon tetrachloride ○○○○ ○○○○ Toluene ○○○○ ○○○ Detergent High ○○○○ ○○○○ Plasticizer ○○○○ ○○○○ Abbreviations ○○○○ Resistant ○○○ Virtually resistant ○○ Partially resistant ○ Less resistant ᅳ Not resistant w. Aqueous solution k. g. Cold saturated Transponder RF380T The housing of the heat-resistant data storage unit is made of polyphenylene sulfide (PPS). The chemical resistance of the data storage unit is excellent. No solvent is known that can dissolve the plastic at temperatures below 200 °C. A reduction in the mechanical properties has been observed in aqueous solutions of hydrochloric acid (HCl) and nitric acid (HNO3) at 80 °C. The excellent resistance to all fuel types including methanol is a particular characteristic. The following table provides an overview of the chemicals investigated. Test conditions Substance Time[days] Temperature[°C] Evaluation Acetone 180 55 + n-Butanol (butyl alcohol) 180 80 + Butanon-2 (methyl ethyl ketone) 180 60 + n-butyl acetate 180 80 + Brake fluid 40 80 + Calcium chloride (saturated) 40 80 + Diesel fuel 180 80 +](https://usermanual.wiki/Siemens/RF340R01.User-Manual-I/User-Guide-1196867-Page-79.png)
![RF300 system planning 4.6 Chemical resistance of the transponders SIMATIC RF300 82 System Manual, 11/2009 - Zwischenstand 17.09.2009, A5E01642529-04 Test conditions Substance Time[days] Temperature[°C] Evaluation Diethyl ether 40 23 + Frigen 113 40 23 + Anti-freeze 180 120 + Kerosine 40 60 + Methanol 180 60 + Engine oil 40 80 + Sodium chloride (saturated) 40 80 + Sodium hydroxide (30%) 180 80 + Sodium hypochlorite (5%) 30 80 / 180 80 – Caustic soda (30%) 40 93 + Nitric acid (10%) 40 23 + Hydrochloric acid (10%) 40 80 – Sulphuric acid (10%) 40 23 + (10%) 40 (30%) 40 Tested fuels: 40 80 + (FAM-DIN 51 604-A) 180 80 / Toluene 1, 1, 1-trichloroethane 180 80 + Xylene Zinc chloride (saturated) 180 80 / 180 75 + 180 80 + 40 80 + Assessment: + Resistant, weight gain < 3 % or weight loss < 0.5 % and/or reduction in fracture resistance < 15 % / Partially resistant, weight gain 3 to 8 % or weight loss 0.5 to 3 % and/or reduction in fracture resistance 15 to 30 % – Not resistant, weight gain > 8 % or weight loss > 3 % and/or reduction in fracture resistance > 30 % 4.6.2 Chemical resistance of the ISO transponders MDS D100, MDS D200 The housing of the MDS D100 is made of PVC. MDS D100 is resistant to the substances specified in the following table.](https://usermanual.wiki/Siemens/RF340R01.User-Manual-I/User-Guide-1196867-Page-80.png)
![RF300 system planning 4.6 Chemical resistance of the transponders SIMATIC RF300 System Manual, 11/2009 - Zwischenstand 17.09.2009, A5E01642529-04 83 Table 4- 35 Chemical resistance of MDS D100, MDS D200 Substance Concentration Saline solution 5 % Sugared water 10 % Acetic acid, aqueous solution 5 % Sodium carbonate, aqueous solution 5 % Ethanol, aqueous solution 60 % Ethylene glycol 50 % Fuel B according to ISO 1817 Human sweat (Reference: ISO 10373 / ISO 7810) MDS D139, MDS D124 The housing of the heat-resistant data storage unit MDS D139 is made of polyphenylene sulfide (PPS). The chemical resistance of the data storage unit is excellent. No solvent is known that can dissolve the plastic at temperatures below 200 °C. A reduction in the mechanical properties has been observed in aqueous solutions of hydrochloric acid (HCl) and nitric acid (HNO3) at 80 °C. The excellent resistance to all fuel types including methanol is a particular characteristic. The following table provides an overview of the chemicals investigated. Table 4- 36 Chemical resistance of MDS D139, MDS D124 Test conditions Substance Time [days] Temperature [°C] Evaluation Acetone 180 55 + n-Butanol (butyl alcohol) 180 80 + Butanon-2 (methyl ethyl ketone) 180 60 + n-butyl acetate 180 80 + Brake fluid 40 80 + Calcium chloride (saturated) 40 80 + Diesel fuel 180 80 + Diethyl ether 40 23 + Frigen 113 40 23 + Anti-freeze 180 120 + Kerosine 40 60 + Methanol 180 60 + Engine oil 40 80 + Sodium chloride (saturated) 40 80 + Sodium hydroxide (30 percent) 180 80 + Sodium hypochlorite (5 percent) 30 180 80 80 / - Caustic soda (30 percent) 40 93 +](https://usermanual.wiki/Siemens/RF340R01.User-Manual-I/User-Guide-1196867-Page-81.png)
![RF300 system planning 4.6 Chemical resistance of the transponders SIMATIC RF300 84 System Manual, 11/2009 - Zwischenstand 17.09.2009, A5E01642529-04 Test conditions Substance Time [days] Temperature [°C] Evaluation Nitric acid (10 percent) 40 23 + Hydrochloric acid (10 percent) 40 80 - Sulphuric acid (10 percent) (10 percent) (30 percent) 40 40 40 23 80 23 + / + Tested fuels: 40 80 + (FAM-DIN 51604-A) Toluol 180 80 / 1, 1, 1-trichloroethane xylene 180 80 + Zinc chloride (saturated) 180 180 180 40 80 75 80 80 / + + + Assessment: + Resistant, weight gain < 3 % or weight loss < 0.5 % and/or reduction in fracture resistance < 15 % / Limited resistance, weight gain 3 to 8 % or weight loss 0.5 to 3 % and/or reduction in fracture resistance 15 to 30 % - Not resistant, weight gain > 8 % or weight loss > 3 % and/or reduction in fracture resistance > 30 % MDS D324, MDS D421, MDS D424, MDS D460 The housing of the MDS D124 is made of epoxy casting resin. The following table provides an overview of the chemical resistance. Table 4- 37 Chemical resistance of MDS D324, MDS D421, MDS D424, MDS D460 Chemical compound Concentration 20 °C 40 °C 60 °C Formic acid 50 % ■ Ammonia liquid, water-free □ Ethanol ■ ■ Gasoline, aromatic-free/containing benzol ■ Benzol, benzoic acid ■ Borax ■ Boric acid ■ Bromine, liquid, bromine water □ Butyric acid 100 % ◪ Carbonate (ammonium, sodium, etc.) ■ Chlorine, liquid □ Chlorobenzene ■ Chloroform □](https://usermanual.wiki/Siemens/RF340R01.User-Manual-I/User-Guide-1196867-Page-82.png)
