Multi-hydraulic control circuit

What is claimed is: 1. A multi-control hydraulic circuit for supplying receivers with hydraulic fluid delivered by a pump with an output controlled by a control pressure of a control line depending on a load pressure of the receivers and delivering the hydraulic fluid at a regulated pressure, the hydraulic circuit comprising: a plurality of hydraulic modules each associated with one of the receivers, each hydraulic module comprising: a slide valve configured for activation by an operator, the slide valve further configured to regulate a variable output supplying the receiver via a variable choke, the slide valve having a slide valve outlet downstream of the variable choke that has a slide valve outlet pressure; and a pressure compensator comprising a compensator inlet connected to the slide valve outlet, a compensator outlet connected to a supply of the receiver by a non-return valve, and a plunger configured to manage a connection between the compensator inlet and the compensator outlet, wherein the plunger comprises: a first face exposed to the slide valve outlet pressure; and a second face exposed to the control pressure of the control line, wherein, in an equilibrium state of the plunger, the slide valve outlet pressure and the control pressure are equal such that the slide valve of each hydraulic module is subjected to a fixed pressure difference corresponding to a difference between the control pressure and a pump pressure of the pump, wherein the plunger defines a lateral passage connecting the compensator inlet and the compensator outlet according to a position of the plunger, and wherein the pressure compensator further includes a fluid link having a choke through which the compensator outlet is permanently connected to the control line, irrespective of the position of the plunger. 2. The hydraulic circuit according to claim 1 , wherein: the fluid link traverses the plunger and connects a side region at a side of the plunger and the second face of the plunger, the side region is always connected to the compensator outlet, and the second face adjoins the control line. 3. The hydraulic circuit according to claim 2 , wherein: the lateral passage starts at the compensator inlet and defines a lateral passage outlet configured to open out laterally into the compensator outlet with a variable cross-section which depends on an equilibrium position of the plunger as a function of the slide valve outlet pressure; a separation zone which closes the lateral passage outlet in a depressed position of the plunger when the slide valve outlet pressure is less than the control pressure, wherein the side region, where the fluid link opens into the compensator outlet, is on an opposite side of the separation zone from the lateral passage so se that the fluid link remains open when the plunger is in the depressed position. 4. The hydraulic circuit according to claim 3 , wherein the fluid link is formed by (i) a transverse passage which opens out into the compensator outlet on the side region on the opposite side of the separation zone from the lateral passage such that the transverse passage is separated from the lateral passage opening and (ii) a longitudinal passage that opens from the second face. 5. The hydraulic circuit according to claim 4 , wherein the choke of the fluid link is formed in the longitudinal passage. 6. The hydraulic circuit according to claim 3 , wherein: the fluid link is formed by: a first transverse passage which opens out into the compensator outlet of the pressure compensator on an opposite side of the separation zone from the lateral passage, a second transverse passage which is open laterally beneath the second face of the plunger, and a longitudinal passage connecting the first and second transverse passages, wherein the choke of the fluid link connects the second transverse passage to the second face, opening out into the control line.