I think there is no magic bullet for this case. But, you can accomplish the goal with some mathematics.

jsfiddle is here in advance.

## Ticks

Ticks can be drawn based on trigonometric functions. If you are scared about tons of formulas, just take a look at this and use them. He described it very neatly as pseudo-code (I guess).

```
var radius = 80;
var tickLength = 10;
var circleDegree = 360;
clockGroup.append('g')
.attr('class', 'ticks')
.selectAll('path')
.data(splitDegrees(12))
.enter()
.append('path')
.attr('d', function(d) {
var coord = {
outer: getCoordFromCircle(d, 0, 0, radius),
inner: getCoordFromCircle(d, 0, 0, radius - tickLength)
};
return 'M' + coord.outer[0] + ' ' + coord.outer[1] + 'L' + coord.inner[0] + ' ' + coord.inner[1] + 'Z';
});
function degToRad(degrees) {
return degrees * Math.PI / 180;
}
// it'll give you xy-coord by degree from 12(or 0) o'clock
function getCoordFromCircle(deg, cx, cy, r) {
var rad = degToRad(deg);
var x = cx + r * Math.cos(rad);
var y = cy + r * Math.sin(rad);
return [x, y];
}
function splitDegrees(num) {
var angle = circleDegree / num;
var degrees = [];
for (var ang = 0; ang < circleDegree; ang += angle) {
degrees.push(ang);
}
return degrees;
}
```

## Arc range

In this case, you can draw it via simple d3 methods.

```
var fromClock = 9;
var toClock = 6;
var arc = d3.svg.arc()
.innerRadius(0)
.outerRadius(radius)
.startAngle(clockToRad(fromClock, -1))
.endAngle(clockToRad(toClock, 1));
clockGroup.append('path')
.attr('d', arc)
.style('fill', 'orange');
function clockToRad(clock, direction) {
var unit = circleDegree / 12;
var degree = direction > 0 ? unit * clock : unit * clock - circleDegree;
return degToRad(degree);
}
```