CN205093021U - Relay module based on KNX agreement - Google Patents

Abstract

The utility model discloses a relay module based on KNX agreement, the adoption be the KNX bus. By transceiver, singlechip, relay group, the transceiver be connected to in the KNX bus, the singlechip with the transceiver links to each other, transmit data of each other, the relay group with the delivery outlet of singlechip links to each other, the utility model discloses simple structure, installation, debugging, safeguard conveniently and corresponding expense and the time reduces by a wide margin, extensively is applicable to multiple occasion like large -scale public building, office building, mill, villa etc to can be in use from now on increasing or the function of the system of modification according to user's requirement, and need not not laying the cable again, really become nimble electric installing the system, this is that traditional cable laying mode can't be accomplished.

Description

A kind of relay module based on KNX agreement

Technical field

The utility model relates to a kind of relay module based on KNX agreement; Be applied to intelligent lighting controls field.

Background technology

The more communication modes of switch driver sold in the market is still based on 485 buses, and adopt 485 technology to be that development cost is low, threshold is low.But 485 modes power to down the equipment of connecing, equipment needs to solve powerup issue separately, and 485 bus communications generally should not adopt star, tree-like, annular grade for networking structure, often adopts hand in hand.This, in the job site of complexity, is affected greatly.In order to reach hand in hand, need roundabout a lot of line, cost improves greatly.And the most fatal, an equipment is damaged, and can related the equipment with his physical connection be drawn extremely, " one inflexibly a slice ", is emphasizing that, inside the Lighting control of fail safe, this is very fearful.The relay adopted is plain edition relay, as unexpected power-off, relay just will be in reset mode, and can not power to lighting in time, relay is when conducting, the current sinking of inductance coil own, produce a large amount of noise, spring mechanism is in extended state for a long time, and Long-Time Service affects its elastic force and life-span, relay produces electric arc when folding or closure state conversion in electric shock, and Long-Time Service affects its contact capacity.It is functionally the break-make of simple control load.

Utility model content

The purpose of this utility model solves the deficiency that above-mentioned existing product exists.Provide a kind of relay module based on KNX agreement, power supply and communication multiplex bus, adopt magnetic latching relay, consume energy little, and have auto-lock function, control intelligent lighting controls module easily.

The technical solution of the utility model is as follows:

A kind of relay module based on KNX agreement, comprise transceiver, single-chip microcomputer, relay group, described transceiver is connected in KNX bus, and described single-chip microcomputer is connected with described transceiver, mutual transmission data, described relay group is connected with the delivery outlet of described single-chip microcomputer.Described KNX bus comprises KNX and receives and transtation mission circuit, and described relay group comprises relay control module circuit.

Described KNX receives and comprises resistance R1-R4 with transtation mission circuit, electric capacity C1-C8, inductance L 1, bi-directional voltage stabilizing pipe D1 and integrated chip IC1-IC2, the 1 pin ground connection of integrated chip IC1, 2 pin of integrated chip IC1 are connected with the positive pole of electric capacity C3 and one end of resistance R2 respectively, the other end of resistance R2 is connected with the positive pole of electric capacity C2, the negative pole of electric capacity C2 and the equal ground connection of negative pole of electric capacity C3, 3 pin of integrated chip IC1 are connected with one end of resistance R3, the other end of resistance R3 respectively with 4 pin of integrated chip IC1, 5 pin are connected with the positive pole of electric capacity C4, the minus earth of electric capacity C4, 6 pin of integrated chip IC1 are all connected with one end of inductance L 1 with 7 pin, the other end of inductance L 1 respectively with power supply VCC, 8 pin of integrated chip IC1 are connected with the positive pole of electric capacity C5, the minus earth of electric capacity C5, 9 pin of integrated chip IC1 are connected with electric capacity C6, 14 pin of integrated chip IC1 meet VHH, the 15 pin ground connection of integrated chip IC1, 16 pin of integrated chip IC1 are connected with the positive pole of electric capacity C7 and one end of resistance R4 respectively, the negative pole of electric capacity C7 and the equal ground connection of the other end of resistance R4, 18 pin of integrated chip IC1 are connected with the positive pole of electric capacity C8, the negative pole of electric capacity C8 respectively with 19 pin of integrated chip IC1, 20 pin are connected with one end of resistance R1, the other end of resistance R1 respectively with the positive pole of electric capacity C1, one end of bi-directional voltage stabilizing pipe D1 and 1 pin of integrated chip IC2, 3 pin connect, 2 pin of integrated chip IC2 and 4 pin, the other end of bi-directional voltage stabilizing pipe D1 and the equal ground connection of negative pole of electric capacity C1.

Described relay control module comprises resistance R1-R3, electric capacity C1-C5, crystal oscillator X1, single-chip microcomputer U1, Control chip U2, relay J D1, Interface Terminal J1, 1st pin of single-chip microcomputer U1, 19th pin, 32nd pin, 48th pin and the 64th pin all with power supply VCC, one end of electric capacity C4 and one end of resistance R2 connect, 12nd pin of single-chip microcomputer U1, 18th pin, 31st pin, 47th pin and the 63rd pin all with power supply be connected, 60th pin of single-chip microcomputer U1 is connected with resistance R3 one end, the other end of resistance R3 is connected with power supply ground, 13rd pin of single-chip microcomputer U1 is connected with one end of resistance R2, one end of electric capacity C4 is connected with power supply ground, 5th pin of single-chip microcomputer U1 is connected with one end of crystal oscillator X1 and one end of electric capacity C2 respectively, 6th pin of single-chip microcomputer U1 is connected with the other end of crystal oscillator X1 and the other end of electric capacity C1 respectively, the other end of electric capacity C2 and the other end of electric capacity C1 all with power supply be connected, 22nd pin of single-chip microcomputer U1 is connected with the 2nd pin of Control chip U2, 23rd pin of single-chip microcomputer U1 is connected with the 1st pin of Control chip U2, 10th pin of relay-operated controller chip U2 is connected with one end of electric capacity C5 and is connected with power supply 12V, 9th pin of Control chip U2 and the other end of electric capacity C5 all with power supply be connected, 17th pin of Control chip U2 is connected with the 1st pin of relay J D1, 18th pin of Control chip U2 is connected with the 2nd pin of relay J D1, 5th pin of relay J D1 is connected with power supply 12V, 4th pin of relay J D1 is connected with the 2nd pin of Interface Terminal J1, 3rd pin of relay J D1 is connected with the 1st pin of Interface Terminal J1.

The beneficial effects of the utility model are:

The utility model structure is simple, install, debugging, easy to maintenance and corresponding expense and time reduce significantly, there is flexibility, ease for use, open, reliability, economy, the advantages such as fail safe, user can revise arbitrarily the function of system according to the hobby of individual, reach the effect required for oneself, be widely used in multiple occasion as large public building, office building, factory, villa etc., the systems such as control are realized intelligent, and can according to the requirement increase of user or the function of amendment system in use from now on, and need not cable laying again, really become electrical installation system flexibly, this is that traditional cable laying mode cannot be accomplished.

Accompanying drawing explanation

In order to be illustrated more clearly in the embodiment of the present application or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment below, apparently, the accompanying drawing that the following describes is only some embodiments recorded in the utility model, for those of ordinary skill in the art, other accompanying drawing can also be obtained according to these accompanying drawings.

Fig. 1 is schematic diagram of the present utility model.

Fig. 2 is that in the utility model, KNX receives and transtation mission circuit schematic diagram.

Fig. 3 is the circuit diagram of the relay control module in the utility model.

Embodiment

In order to make those skilled in the art understand the technical solution of the utility model better, below in conjunction with accompanying drawing, the utility model is further detailed.A kind of relay module based on KNX agreement, comprise transceiver, single-chip microcomputer, relay group, described transceiver is connected in KNX bus, and described single-chip microcomputer is connected with described transceiver, mutual transmission data, described relay group is connected with the delivery outlet of described single-chip microcomputer.Described KNX bus comprises KNX and receives and transtation mission circuit, and described relay group comprises relay control module circuit.

Described KNX receives and comprises resistance R1-R4 with transtation mission circuit, electric capacity C1-C8, inductance L 1, bi-directional voltage stabilizing pipe D1 and integrated chip IC1-IC2, the 1 pin ground connection of integrated chip IC1, 2 pin of integrated chip IC1 are connected with the positive pole of electric capacity C3 and one end of resistance R2 respectively, the other end of resistance R2 is connected with the positive pole of electric capacity C2, the negative pole of electric capacity C2 and the equal ground connection of negative pole of electric capacity C3, 3 pin of integrated chip IC1 are connected with one end of resistance R3, the other end of resistance R3 respectively with 4 pin of integrated chip IC1, 5 pin are connected with the positive pole of electric capacity C4, the minus earth of electric capacity C4, 6 pin of integrated chip IC1 are all connected with one end of inductance L 1 with 7 pin, the other end of inductance L 1 respectively with power supply VCC, 8 pin of integrated chip IC1 are connected with the positive pole of electric capacity C5, the minus earth of electric capacity C5, 9 pin of integrated chip IC1 are connected with electric capacity C6, 14 pin of integrated chip IC1 meet VHH, the 15 pin ground connection of integrated chip IC1, 16 pin of integrated chip IC1 are connected with the positive pole of electric capacity C7 and one end of resistance R4 respectively, the negative pole of electric capacity C7 and the equal ground connection of the other end of resistance R4, 18 pin of integrated chip IC1 are connected with the positive pole of electric capacity C8, the negative pole of electric capacity C8 respectively with 19 pin of integrated chip IC1, 20 pin are connected with one end of resistance R1, the other end of resistance R1 respectively with the positive pole of electric capacity C1, one end of bi-directional voltage stabilizing pipe D1 and 1 pin of integrated chip IC2, 3 pin connect, 2 pin of integrated chip IC2 and 4 pin, the other end of bi-directional voltage stabilizing pipe D1 and the equal ground connection of negative pole of electric capacity C1.

Described relay control module comprises resistance R1-R3, electric capacity C1-C5, crystal oscillator X1, single-chip microcomputer U1, Control chip U2, relay J D1, Interface Terminal J1, 1st pin of single-chip microcomputer U1, 19th pin, 32nd pin, 48th pin and the 64th pin all with power supply VCC, one end of electric capacity C4 and one end of resistance R2 connect, 12nd pin of single-chip microcomputer U1, 18th pin, 31st pin, 47th pin and the 63rd pin all with power supply be connected, 60th pin of single-chip microcomputer U1 is connected with resistance R3 one end, the other end of resistance R3 is connected with power supply ground, 13rd pin of single-chip microcomputer U1 is connected with one end of resistance R2, one end of electric capacity C4 is connected with power supply ground, 5th pin of single-chip microcomputer U1 is connected with one end of crystal oscillator X1 and one end of electric capacity C2 respectively, 6th pin of single-chip microcomputer U1 is connected with the other end of crystal oscillator X1 and the other end of electric capacity C1 respectively, the other end of electric capacity C2 and the other end of electric capacity C1 all with power supply be connected, 22nd pin of single-chip microcomputer U1 is connected with the 2nd pin of Control chip U2, 23rd pin of single-chip microcomputer U1 is connected with the 1st pin of Control chip U2, 10th pin of relay-operated controller chip U2 is connected with one end of electric capacity C5 and is connected with power supply 12V, 9th pin of Control chip U2 and the other end of electric capacity C5 all with power supply be connected, 17th pin of Control chip U2 is connected with the 1st pin of relay J D1, 18th pin of Control chip U2 is connected with the 2nd pin of relay J D1, 5th pin of relay J D1 is connected with power supply 12V, 4th pin of relay J D1 is connected with the 2nd pin of Interface Terminal J1, 3rd pin of relay J D1 is connected with the 1st pin of Interface Terminal J1.

See Fig. 1, a kind of relay module based on KNX agreement, comprise transceiver, single-chip microcomputer, relay group, single-chip microcomputer on described switch driver receives the scenery control instruction of the correspondence in KNX bus, the pulse of one fixed width is sent to the relay of corresponding circuit, relay is made to carry out closed and folding, and one end is directly connected with zero line in lighting apparatus, the other end is linked into live wire via relay, be responsible for by relay the break-make controlling lighting circuit loop, thus control the break-make of lighting equipment circuit.

Mode above only by illustrating describes some one exemplary embodiment of the present utility model, undoubtedly, for those of ordinary skill in the art, when not departing from spirit and scope of the present utility model, can revise described embodiment by various different mode.Therefore, above-mentioned accompanying drawing is illustrative with being described in essence, should not be construed as the restriction to the utility model claims.

Claims (5)

1. the relay module based on KNX agreement, comprise transceiver, single-chip microcomputer, relay group, it is characterized in that: described transceiver is connected in KNX bus, described single-chip microcomputer is connected with described transceiver, mutual transmission data, described relay group is connected with the delivery outlet of described single-chip microcomputer.

2. the relay module based on KNX agreement according to claim 1, is characterized in that, described KNX bus comprises KNX and receives and transtation mission circuit, and described relay group comprises relay control module circuit.

3. the relay module based on KNX agreement according to claim 2, is characterized in that, described relay control module comprises resistance R1-R3, electric capacity C1-C5, crystal oscillator X1, single-chip microcomputer U1, Control chip U2, relay J D1, Interface Terminal J1.

4. the relay module based on KNX agreement according to claim 3, it is characterized in that, 1st pin of single-chip microcomputer U1, 19th pin, 32nd pin, 48th pin and the 64th pin all with power supply VCC, one end of electric capacity C4 and one end of resistance R2 connect, 12nd pin of single-chip microcomputer U1, 18th pin, 31st pin, 47th pin and the 63rd pin all with power supply be connected, 60th pin of single-chip microcomputer U1 is connected with resistance R3 one end, the other end of resistance R3 is connected with power supply ground, 13rd pin of single-chip microcomputer U1 is connected with one end of resistance R2, one end of electric capacity C4 is connected with power supply ground, 5th pin of single-chip microcomputer U1 is connected with one end of crystal oscillator X1 and one end of electric capacity C2 respectively, 6th pin of single-chip microcomputer U1 is connected with the other end of crystal oscillator X1 and the other end of electric capacity C1 respectively, the other end of electric capacity C2 and the other end of electric capacity C1 all with power supply be connected, 22nd pin of single-chip microcomputer U1 is connected with the 2nd pin of Control chip U2, 23rd pin of single-chip microcomputer U1 is connected with the 1st pin of Control chip U2, 10th pin of relay-operated controller chip U2 is connected with one end of electric capacity C5 and is connected with power supply 12V, 9th pin of Control chip U2 and the other end of electric capacity C5 all with power supply be connected, 17th pin of Control chip U2 is connected with the 1st pin of relay J D1, 18th pin of Control chip U2 is connected with the 2nd pin of relay J D1, 5th pin of relay J D1 is connected with power supply 12V, 4th pin of relay J D1 is connected with the 2nd pin of Interface Terminal J1, 3rd pin of relay J D1 is connected with the 1st pin of Interface Terminal J1.

5. the relay module based on KNX agreement as described in any one of claim 1-4, is characterized in that: described relay module adopts EIB bus communication mode.