DE257245C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

The invention relates to a rotating absorption dynamometer, namely the Kind that the volume of the medium which passes through the dynamometer and acting on it can be changed while the apparatus is in motion the purpose, the resistance that the dynamometer opposes the machine to be tested, to change. Mainly come

ίο such dynamometers into consideration, which oneself to rotate in the air. The change that corresponds to the change in load should be can be made conveniently. The dynamometer is notable for its portable Shape as well as the fact that there are no special connections for the braking Medium owns.

The absorption force depends on the supply of air to the dynamometer, and to for this purpose the cross-section for the inlet is through an expandable membrane a slotted disc or the like. Changed. Instead, you can also use the outlet Narrow an annular screen or the like.

The dynamometer is calibrated so that for a given cross-section of the inlet or Outlet and the number of revolutions per minute the power of the engine can easily be determined according to horse power. That The dynamometer can be surrounded by a solid case to keep the air flowing from the The periphery of the rotor continues to be discharged, and the cross section of the outlet from this Housing can be changed. If the cross section of the inlet is a maximum, it offers the greatest resistance, and as the cross-section decreases, so does the resistance and consequently the force absorbed by the dynamometer decreases accordingly.

In Fig. 1 to 6 the invention is drawn in several embodiments.

Fig. I, 2 and 3 show longitudinal sections for dynamometers with centrifugal blades. It is the display mechanism is only shown in FIG. 1, but omitted in FIGS. 2 and 3.

Fig. 4 is another embodiment in cross section, and the same applies to Fig. 5, to which the front view (Fig. 6) belongs.

The axis α of the machine that is to be examined is directly coupled to the dynamometer. The dynamometer consists of the rotor bb, the wings of which are attached to the ring c and held by the ring d . The ring c can be coupled to the flange-shaped end of the axis α by means of screws and nuts and has an axial spindle guide e. A regulating ring f can move lengthwise within the impeller. At its end the hollow shaft g is fixed, which has the screw thread h with the handwheel / carried by the bearing h with the stand I. A locking nut m locks the rod h with the screw thread in any position. The rod h or the hollow axis g has a pointer n which moves when the handwheel / for regulating the disc / is turned, with a scale on the arm 0 for reading off the respective position. The regulating wheel is provided with a hub onto which the hollow spindle is screwed. If the disc is now moved using the handwheel, the effective volume changes. The way of the air supply

leadership is indicated by arrows. The calibration to directly display horse forces is done by coupling the dynamometer to a known motor. In use, the dynamometer is coupled to the axis of the machine to be tested. The disk is adjusted by loosening the nut m and turning the handwheel, whereby the disk does not take part in the rotation of the dynamometer. The further the ring is moved inwards, the greater the volume of the admitted air and consequently the greater the resistance of the dynamometer.

It should be emphasized that the disk / ¹ can also be adjusted when the centrifugal fan rotates, and that consequently the dynamometer can be adjusted without stopping the machine.

Fig. 2 shows another embodiment. Here, instead of the disk f, a regulating housing p, which is guided through the arms q on a hub r , is used. The adjustment is again done by means of a handwheel and screw as before. The adjustment more or less releases the periphery of the centrifugal fan and in this way changes the volume of the exiting air. In the embodiment of FIG. 3, a regulating sleeve s is used instead of the housing ft , which changes the volume of the permitted air when its position is adjusted. The movement of the sleeve occurs in a similar way as before. The impeller can be completely surrounded by a solid housing as usual. However, in order to change the resistance, the cross-section of the inlet and outlet can be regulated by sliding grilles and the like.

Fig. 4 shows another embodiment in which the resistance results from the rotation of radially positioned vanes. Here the surfaces of these wings are changed. t is a ring or frame which can be coupled to the axis a of the machine to be tested and which is equipped with, for example, four equally spaced blades u at right angles to it. The frame t also has an axial guide axis to which a second ring or frame w with four wings u 'is attached. The ring or frame w has a hub χ and is connected to the axis ν by a wedge y , so that it rotates with it, but remains longitudinally displaceable on it.

The blades «'and u, the number of which is indifferent, overlap one another. In order to move the hub, it has a circumferential groove in which the fork piece 2 engages, which, as before, is moved by means of the screw and the handwheel i , the pointer η again indicating the displacement on the scale 0. By moving the frame w , the wings overlap each other more or less according to the displacement.

In the embodiment according to FIGS. 5 and 6, two concentric impellers 1 and 2 are arranged. The inner one is attached to the hub 3, which is connected to the axis 4 by means of a wedge and can be coupled to the axis of the machine to be examined by means of the coupling 4 ^a. The outer impeller is guided by the spoke frame 5 which is fastened by means of the ball bearings 6, 6 on a sleeve 5 which rotates freely on the axis 4. Attached to the front end of the outer impeller 1 is a suitable number of radial rods which are connected at their outer ends to the frame of the impeller 1 and which end in the hub 9 at their inner ends. A circular disc 10, the diameter of which is sufficient to close the open end of the outer impeller ι, is attached to the rod 11, which is provided with screw thread. Again, the device of the handwheel 12 is provided, by means of which the disk 10 is displaced, whereby the open end of the impeller 1 is more or less opened or closed, thus also causing a corresponding change in volume. In this case, the horse forces are measured by the resisting torque of the outer impeller 1. The air, which has a rotational movement when it leaves the inner wings of the wheel 2, acts on the outer wings, which thus receive the corresponding torque, which can be measured in any known manner by springs, weights, Hebei and the like.

Claims (4)

Pa te nt-An Proverbs: 1. Dynamometer with centrifugal fan, characterized in that a member is provided is, which when moving against the rotor of the dynamometer, the admission of air by changing the effective cross section of the rotor and thus the resistance changes. 2. absorption dynamometer according to claim i, characterized in that one Disk inside the impeller changes the flow of air during its displacement, while the displacement of the Disk the change in the effective cross-section and thus the changed resistance indicates. 3. embodiment of the absorption dynamometer according to claim 1, characterized marked that the blades in two Sets are arranged so that when they move towards each other a set of blades overlaps the other and thereby reduces the effective cross-section. 4. embodiment of the absorption dynamometer according to claim i, in which a pair of concentric blades is arranged, of which the outer wheel is attached to the axle and serves to Measure the performance of the inner wheel, which is with the machine under test is coupled, characterized in that one element is axially relative to the rotor is movable and is used to regulate the volume of air and thus the resistance of the dynamometer. 1 sheet of drawings.