RU127837U1 - TWO-CURRENT VACUUM PUMP - Google Patents

Abstract

A two-rotor vacuum pump containing a housing, profiled rotating driving and driven rotors, discharge and suction windows, a synchronization mechanism, characterized in that on the back side of each tooth of the driving rotor there are discharge grooves emanating from the top of the tooth.

Description

Appendix No. 2 to the decision on the grant of a patent to the application No. 2012152735/06 (083999)

Double rotor vacuum pump

The utility model relates to vacuum pumps used in milking installations in agricultural production.

A double-rotor type pump is known (see US 3981646, 09/21/1976, F04C2 / 08), having a housing, a driving and driven rotors, in which, in order to prevent cavitation of the tooth surfaces, grooves are made on the back of each tooth, both the driving and driven rotors . However, the use of the discharge groove reduces only the pressure in the interdental pinched space and only partially reduces the harmful volume transferred to the suction cavity.

A two-rotor vacuum pump is known (see RU 2193689 C2, 11.27.2002, F04C25 / 02), the disadvantage of this pump is that gas is trapped in the mating zone of the tooth and cavity. This leads to additional energy costs.

The objective of the utility model is to increase the efficiency of the pump by reducing the harmful volume of gas transferred to the suction cavity.

EFFECT: reduced harmful volume of gas transferred to the suction cavity, which will reduce energy costs.

To solve this problem, in a two-rotor vacuum pump containing a housing, profiled rotating driving and driven rotors, discharge and suction windows, a synchronization mechanism, according to a utility model, unloading grooves emanating from the top of the tooth are made on the back side of each tooth of the driving rotor.

Thus, the compressed gas located in the pinched interdental space is forced back into the injection cavity.

The two-rotor vacuum pump shown in Fig. 1 consists of a housing 1, profiled leading 2 and driven 3 rotors, injection 4 and suction 5 windows and a synchronization mechanism 6. On the back side of each tooth of the leading rotor, discharge grooves are made, coming from the top of the tooth.

In figure 2. - presents the profile side of the tooth with grooves. In figure 3. - sectional pump.

The principle of operation of the pump is as follows. When the rotors rotate in the indicated direction into the suction cavity “B”, the volume expands, as a result of which the gas is sucked in. With further rotation of the rotors, a closed volume is formed in which the gas is transferred to the discharge cavity. In the injection cavity “H”, a decrease in volume occurs, as a result of which the gas is compressed, and then, when the injection window in the area of the driven rotor opens, the gas will be displaced through it. When the tooth of the driving rotor enters the cavity of the driven rotor, the volume of gas is displaced into the injection cavity by rolling the tooth along the involute surface of the cavity. The minimum harmful volume in the interdental space will be when the tooth fully enters the cavity. In order to more fully remove the compressed gas located in the cavity of the driven rotor on the back of the tooth of the driving rotor, unloading grooves are made (Fig. 2), coming from the top of the tooth. The displacement of gas through the discharge grooves ends when the tooth completely enters the cavity. For elongated rotors, it is advisable to have several parallel discharge grooves. The implementation of the discharge grooves at the top of the tooth on the back of the tooth reduces the flow of gas from the harmful volume into the suction cavity and thereby reduces energy costs.

Claims (1)

A two-rotor vacuum pump containing a housing, profiled rotating driving and driven rotors, discharge and suction windows, a synchronization mechanism, characterized in that on the back side of each tooth of the driving rotor there are discharge grooves emanating from the top of the tooth.

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